This belt belonged to a WW1 Australian Anzac who most probably, because of the buttons and badges, served on the Western Front. Records destroyed in 1969 bush fires at Lara means we are unable to determine who owned this in the RSL. The belts is called a 'stable belt' and the one you have acquired is an early example with a leather pocket. It became common in WW1 for both, leather belts (especially that from the 1903 bandolier equipment as worn by those in the Boer War), and stable belts to be used to hold badges collected from fellow soldiers and for that reason it was often known as a 'souvenir belt'. The evolution of the stable belt: It seems that stable belts began to become popular across the Army as a whole around the turn of the 20th century, although they probably originated with the cavalry a little earlier sometime in the 1880s/1890s. All units at that time had horses on their establishment and those soldiers told off to attend them reported for Stable Parade in Stable Dress which consisted of very high waisted and pocket less breeches, or trousers, held up by braces and collarless, woollen flannel shirts with sleeves rolled up. This was to facilitate the rigorous physical effort and flexibility of movement necessary for mucking out and grooming. Braces at that time had no elastic as rubber was expensive, they were made of cotton with no 'give' whatsoever and so soldiers commonly allowed the braces to flop down from the waist so that they could bend over freely. For trousers that fitted loosely (due to the high waist) this meant that they tended to slip down and at first soldiers cinched them in with leather belts. Later on the regimental saddlers began to make belts from the same, plain canvas or wool strapping used for the horses Surcingle and utilising the same double leather strap and buckle arrangement for security (if one strap broke the other would hold and prevent the saddle from coming unseated). One particular feature of these early stable belts was a sewn on (or in) pocket, secured by a stud or clip, within which loose change could be kept, or a pocket watch, as there were no pockets in the breeches. As you might imagine these became very popular as the pocket was useful and the extra breadth afforded by the canvas strapping made them very comfortable. Around about the turn of the 20th century it began to be popular for officers to wear neckties in regimental colours both for sport and less formal, country dress. This habit probably began with the Queens Household troops and Line Cavalry, but quickly spread throughout the Army and it appears as if this use of regimental colours spread to the canvas or wool strapping used to make stable belts. For this reason the stable belts invariably followed the same colour scheme (but not always the same pattern arrangement) of regimental neck ties.This belt is an example of what Australian troops collected when on the Western Front during WW1 and when on leave.Webbing Belt with Badges and Buttons WW1See Mediaarmy, australian army, western front, aif, s.w.ellis, service number 640, 2 m.g.c., buttons, badges, belt, stable belt

In 1978 Diamond Valley Shire recognised the need for a new public hall in Diamond Creek. Council considered the Bini shell form of construction which was in operation overseas and in use in New South Wales as libraries, gymnasiums, sports centres and multi-purpose centres. The Council gave the go-ahead. A site was chosen opposite the Hotel and close to the railway line. One day in - the following year, in 1979, activity stood still in Diamond Creek as school children and other excited spectators watched the one-hour inflation of the Bini Shell. This unusual method of construction was invented by Italian industrial designer and architect Dante Bini. The construction pneumatically raises a level of reinforced concrete from ground level which has not been set, using an internal balloon. The inner membrane inflates and compresses the mesh and concrete against the outer membrane. A net of flexible steel rods was laid on the building’s circular base, on the top of a fabric bladder. 300 tonnes of reinforced concrete were poured onto the mesh and a sealed cover laid over the concrete making a sandwich of cover, bladder and mesh. Compressed air was pumped into the bladder and the sandwich slowly began to rise and become a massive self-supporting dome. After inflation and removal of the outer membrane workmen filled in any holes. It was some days before pneumatic drills pecked out the first opening. The ceiling of the concrete dome was lined with fluffy insulating material. The dome was 36 metres in diameter at the base and 12 metres high in the centre with a usable floor space of 670 square metres. An opening night dinner was held to celebrate the new facility on March 12, 1980. Shire President Ron Pata made a speech and unveiled a plaque. It was the first public building in Victoria to be erected using the Bini Shell design method of construction The facility could cater for up to 400 people and in 1980 a fee for use was $100 for up to 200 people, $150 for up to 300 people and $200 for up to 400 people. For the next ten years or so, locals attended the hall for marital arts classes, basketball and netball games and school discoes and various other activities. After pieces of concrete fell off a Bini shell interstate due to a construction fault, the Council closed the centre. Demotion took place during the Diamond Creek Town Fair in 1991, as part of the annual Town Fair’s program. Research by L.P. Jan 2022This was the first public building in Victoria to be erected using the Bini Shell design method of construction.Colour photograph1991, diamond creek, bini shell, demolition, oval

In 1978 Diamond Valley Shire recognised the need for a new public hall in Diamond Creek. Council considered the Bini shell form of construction which was in operation overseas and in use in New South Wales as libraries, gymnasiums, sports centres and multi-purpose centres. The Council gave the go-ahead. A site was chosen opposite the Hotel and close to the railway line. One day in - the following year, in 1979, activity stood still in Diamond Creek as school children and other excited spectators watched the one-hour inflation of the Bini Shell. This unusual method of construction was invented by Italian industrial designer and architect Dante Bini. The construction pneumatically raises a level of reinforced concrete from ground level which has not been set, using an internal balloon. The inner membrane inflates and compresses the mesh and concrete against the outer membrane. A net of flexible steel rods was laid on the building’s circular base, on the top of a fabric bladder. 300 tonnes of reinforced concrete were poured onto the mesh and a sealed cover laid over the concrete making a sandwich of cover, bladder and mesh. Compressed air was pumped into the bladder and the sandwich slowly began to rise and become a massive self-supporting dome. After inflation and removal of the outer membrane workmen filled in any holes. It was some days before pneumatic drills pecked out the first opening. The ceiling of the concrete dome was lined with fluffy insulating material. The dome was 36 metres in diameter at the base and 12 metres high in the centre with a usable floor space of 670 square metres. An opening night dinner was held to celebrate the new facility on March 12, 1980. Shire President Ron Pata made a speech and unveiled a plaque. It was the first public building in Victoria to be erected using the Bini Shell design method of construction The facility could cater for up to 400 people and in 1980 a fee for use was $100 for up to 200 people, $150 for up to 300 people and $200 for up to 400 people. For the next ten years or so, locals attended the hall for marital arts classes, basketball and netball games and school discoes and various other activities. After pieces of concrete fell off a Bini shell interstate due to a construction fault, the Council closed the centre. Demotion took place during the Diamond Creek Town Fair in 1991, as part of the annual Town Fair’s program. Research by LP January 2022This was the first public building in Victoria to be erected using the Bini Shell design method of construction.Digital copy of colour photographfred mitchell collection, 1983, bini shell, diamond creek

Introduction - Jim Fingleton - Outlines history and problem aspects to do with the formulation of the Native Title Act 1993 and subsidiary /? consultative bodies (eg National Native Title Tribunal and Regulations; Native Title Implementation Task Force); Note: Talks &? discussion papers annotated separately by author/?title/?workshop title; SESSION GROUP DISCUSSIONS ONLY annotated here; First Session: Claims - Matters raised in discussion - timing; restraining orders; requirement for claim acceptance; researching claims; disputes; representative bodies; native title /? compensation claims; Second Session: Hearings - "Main matters raised in discussion" - 1.gender issue in hearings; 2.subjective /? objective tests of native title; 3.use of maps; 4.practice directions; 5. mediation; 6. what precision is needed to prove ownership; Third Session: Determinations - "Matters raised in discussion" - 1.what is a community; 2.the legal process for proof of communal title(i-iv); Fourth Session: New Management Regimes - Main matters raised in discussion - 1. need for new development models; 2. need for new administrative models; 3. is self-sufficiency a realistic goal; 4. actve/?passive income; 5. direct funding of Indigenous bodies; 6. towards self-government; Fifth Session: New Management Decisions - Main matters raised in discussion - 1. different models for money management; 2. local government laws and native title; 3. restrictions on the enjoyment of native title rights; 4. need for flexibility in investigating native title; Sixth Session: Conclusions and Recommendations - Papers as requested; discussion; Main New Matters raised by panel in discussion - 1. recommendations from the Aboriginal caucus; 2. requirements for an application; 3. issues for funding; 4. role of representative bodies; 5. double dipping; 6. role of AIATSIS; 7. trustees or agents; 8. land management issues; Annexes: annotated separately under author /? title.tablesnative title, land tenure

Used in WW2. Basically of german origin and manufacture but 'English' handset suggests capture and use by Australian forces possibly in Middle East Desert warfare.Black Rectangular Metal Box with Lid. Total Height 215mm (with lid closed), Body Height 140mm. Lid Height 75mm.Lid attached by full length Hinge on rear and locking Clip at front.Depth 90mm. Length 275mm. Lid Outside: has overlapping lip to body when closed.Reinforcing metal attachment on left side rolls over to inside of lid and is attached by two screws. Front locking clip is spring loaded and attached to lid by 3 screws. Lid Inside: Flexible metal plate to clip on handset. 2 inscription plates on left and right ends and telephone handset described separately Body Outside:Front: 2 Jack plug points, vertically aligned 85mm from left, 25mm apart either side of mid point of height of bodyprotedted by protective pivot plate. Air vent plate attached with 2 screws adjacent to Jack plug holes (same on Back). Left side at top; metal plate for carry strap (same on right side). carry strap not with item.Right side; hole covered by protective cover plate centred 70mm from base , Wind-Up handle attached (described seoarately. Body Inside: 2/3 filled with visible metal and bakelite components in separate compartment containing unseen working parts. Left side contains morse code key in canvas bag (described separately). Contents Inside Lid. Two schematics of wiring layouts attached to left and right ends. Removable Bakelite handset clipped into postion for carrying, attached cable has 4-pronged attachment connected to main section in body. Contents Inside Body. Most working parts hidden inside metal container. White plastic button 'Pruttaste' is a test button; threaded screws on top for attachments not present.Two pieces of loose wire purpose unknown. Canvas Bag with zip, labelled DD with arrow between (Department of Defence) containing Morse Code Key; wire with large jackplug attachment connected to MC Key through the bag. Jackplug connects via front of body of object. The whole of this item is stored in left inside of body.underside of handset says PRESS KEY WHILE SPEAKING and in smaller font size TELE HD NO 2

Mrs Georgina Hill (wife of Henry), nee Reynolds (of Research, Vic.) in cap [possibly misidentified by donor - see note below] with Mrs Isaac Hill and her children (left to right) Amelia Hill, (born 1853) Mrs Isaac Hill with baby Isaac (born 1860, Eltham) on her lap. Mary Jane Hill (born 1857, Eltham) seated on Mrs Henry Hill's lap and Bob Hill. The Hill family were early settlers of the Eltham area. Daguerreotype photo enclosed in a leather bound clam shell box with felt lining and gold trim. Donated by Mrs Ivy Edna Hill, 4/1 Bridge Street, Eltham, 4 June 1966 and includes copy of her note identifying the people. Daguerreotypes were one of the first forms of early photographs. They initially appeared in Europe in 1839 and were produced in large numbers to the early 1850s but were superseded by more modern and flexible forms of technology by 1860. The photo was usually formed on a thin copper plate with light sensitve silver iodide. They have a mirror-like appearance and the image itself was mirrored. They were usually inserted into a case or frame made of wood bound in leather or velvet and cost about one guinea in Australia, the equivalent of a week's wages. With the advent of the gold-rush and growing population came an increase in numbers of photographers both studio and travelling. The daguerreotype process was protected by patents and could only result in a single image from which no copies could be made. With new technology involving wet colloidion glass plate negatives and albumen paper prints of which multiple copies could be produced at significantly reduced cost, the dauguerreotype quickly fell out of favour. An accompanying note with the photo written by Edna Hill of 4/1 Bridge Street Eltham dated 4 June 1966 states: "Dear Mr Watson, I think the enclosed old time photograph will be of interest to you. It would have been taken about 1860. The two ladies are the wives of the original pioneers of the Hill family. The one in the cap was the wife of Henry Hill, the other of Isaac Hill. The children are those of Mrs Isaac Hill, and grandchildren to Henry Hill. The little girl on the left is Amelia, the baby Isaac, the second girl is Mary Jane, and the boy on the right is Bob Hill. They grew up tobe Uncles and Aunts of my late husband. I greatly appreciated a letter received a few months ago per Cr Pelling, from the Shillinglaw Cottage Committee. Yours sincerely, Edna Hill" Victorian birth registrations show Mary Jane Hill was born 1857 in Eltham (9879 / 1857) and Isaac Hill at Eltham in 1860 (1972/1860) NOTE: Mrs Isaac Hill was Ellen Fitzsimons (1834-1863), mother to Henry Hill. Mrs Georgina Hill, wife of Henry cannot be the lady in the cap as she was not born till 1864. Georgina Reynolds (1864-1927) married Henry Hill (1862-1948) in 1884. This lady has significant wrinkling of the face, especially around her mouth. It is possible that she is the mother of Mrs Isaac Hill (Ellen Fitzsimons) who was Isabella Fitzsimons (nee Ferguson).This photo forms part of a collection of photographs gathered by the Shire of Eltham for their centenary project book,"Pioneers and Painters: 100 years of the Shire of Eltham" by Alan Marshall (1971). The collection of over 500 images is held in partnership between Eltham District Historical Society and Yarra Plenty Regional Library (Eltham Library) and is now formally known as 'The Shire of Eltham Pioneers Photograph Collection.' It is significant in being the first community sourced collection representing the places and people of the Shire's first one hundred years.Digital image 4 x 5 inch B&W Negsepp, shire of eltham pioneers photograph collection, eltham, hill family, research (vic.), women, amelia hill, bob hill, daguerreotype, early settlers, georgina hill (nee reynolds), isaac hill, mary jane hill, mrs henry hill, mrs isaac hill, ellen hill (nee fitzsimons), isabella fitzsimons (nee ferguson)

Mrs Georgina Hill (wife of Henry), nee Reynolds (of Research, Vic.) in cap [possibly misidentified by donor - see note below] with Mrs Isaac Hill and her children (left to right) Amelia Hill, (born 1853) Mrs Isaac Hill with baby Isaac (born 1860, Eltham) on her lap. Mary Jane Hill (born 1857, Eltham) seated on Mrs Henry Hill's lap and Bob Hill. The Hill family were early settlers of the Eltham area. Daguerreotype photo enclosed in a leather bound clam shell box with felt lining and gold trim. Donated by Mrs Ivy Edna Hill, 4/1 Bridge Street, Eltham, 4 June 1966 and includes copy of her note identifying the people. Daguerreotypes were one of the first forms of early photographs. They initially appeared in Europe in 1839 and were produced in large numbers to the early 1850s but were superseded by more modern and flexible forms of technology by 1860. The photo was usually formed on a thin copper plate with light sensitve silver iodide. They have a mirror-like appearance and the image itself was mirrored. They were usually inserted into a case or frame made of wood bound in leather or velvet and cost about one guinea in Australia, the equivalent of a week's wages. With the advent of the gold-rush and growing population came an increase in numbers of photographers both studio and travelling. The daguerreotype process was protected by patents and could only result in a single image from which no copies could be made. With new technology involving wet colloidion glass plate negatives and albumen paper prints of which multiple copies could be produced at significantly reduced cost, the dauguerreotype quickly fell out of favour. An accompanying note with the photo written by Edna Hill of 4/1 Bridge Street Eltham dated 4 June 1966 states: "Dear Mr Watson, I think the enclosed old time photograph will be of interest to you. It would have been taken about 1860. The two ladies are the wives of the original pioneers of the Hill family. The one in the cap was the wife of Henry Hill, the other of Isaac Hill. The children are those of Mrs Isaac Hill, and grandchildren to Henry Hill. The little girl on the left is Amelia, the baby Isaac, the second girl is Mary Jane, and the boy on the right is Bob Hill. They grew up tobe Uncles and Aunts of my late husband. I greatly appreciated a letter received a few months ago per Cr Pelling, from the Shillinglaw Cottage Committee. Yours sincerely, Edna Hill" Victorian birth registrations show Mary Jane Hill was born 1857 in Eltham (9879 / 1857) and Isaac Hill at Eltham in 1860 (1972/1860) NOTE: Mrs Isaac Hill was Ellen Fitzsimons (1834-1863), mother to Henry Hill. Mrs Georgina Hill, wife of Henry cannot be the lady in the cap as she was not born till 1864. Georgina Reynolds (1864-1927) married Henry Hill (1862-1948) in 1884. This lady has significant wrinkling of the face, especially around her mouth. It is possible that she is the mother of Mrs Isaac Hill (Ellen Fitzsimons) who was Isabella Fitzsimons (nee Ferguson).Early pioneer settlers of ElthamAntique daguerreotypes in hinged gold frame, glass encased in a small clam-shell box lined with padded red felt and with catchamelia hill, bob hill, early settlers, eltham, hill family, isaac hill, mary jane hill, mrs henry hill, mrs isaac hill, daguerreotype, georgina hill (nee reynolds), research (vic.), sepp, shire of eltham pioneers photograph collection, women, ellen hill (nee fitzsimons), isabella fitzsimons (nee ferguson)

The sample of steel from which the S.S. Julia Percy’s boiler was made has been tested, according to the attached label. The test involved heating the steel to blood red temperature (or dark red colour) then dipping it into water and bending it when it was cold. A “very severe test for quality” was written on the ticket by T.H. Osborne. (Mr Thomas Hamilton Osborne was the secretary for the Western Steam Navigation Co, established in Warrnambool in 1886. The company’s office was on the corner of Timor and Liebig Streets in Warrnambool and its north-western wall is now part of the current Warrnambool Regional Art Gallery. ) Cold bending of steel in a press or through rollers is the typical method of curving steel for construction. The steel needs to be manufactured in such a way that it is strong enough yet still flexible enough not to crack when bent or rolled. The boiler on the Julia Percy could have been a Scotch Boiler, a design introduced in the 1870’s and still being used today. This design was more robust that previous boilers, generating higher working steam pressures. The design incorporate greater ability to roll iron plates, leading to greater strength, thicker plating and fewer riveted joints. They were originally made of iron then later incorporated steel sections until they were entirely constructed of steel. Many examples of this type of boiler can be found on wreck sites. Shipping was the cheapest and most practical means of carrying produce and goods during the period 1840-1890. Regular domestic steamer services commenced in the Warrnambool district in the late 1850’s and by 1870 the passenger trade was booming. Produce was loaded from the jetty into ‘lighters’ (small boats), which took it to the ships at anchorage in the bay. Passengers were taken to the ship’s side then climbed aboard up ladders or gangways. The coming of the railway in October 1889 meant the gradual decline and end of the steam shipping era. Originally the ship was known as the SS Julia Percy and was later renamed as the Leeuwin. She was an iron passenger-cargo steam ship built in Glasgow by Thomas Wingate for the Warrnambool Steam Packet Company, which commissioned the ship for the steamship trade in Victoria’s western district. She was first registered in Warrnambool, Victoria in 1876. At one point in time the Julia Percy would sail from Warrnambool to Melbourne every Friday and return from Melbourne to Warrnambool every Tuesday. The cost of a return ticket for a Saloon Fare was £1.0.0. She would sail “if practical and weather permitting”. The Julia Percy changed hands several times. Her next owner was the Western Steam Navigaiton Co of Melbourne (1887). It was the manager of this company, Mr. T.H. Osborne, who tagged ths steel sample above. Melbourne Steamship Co became the next owners (1890), followed by William Howard Smith and Sons (1901) for use in Queensland coastal trades, then she was bought by George Turnbull in 1903 and used for local mail contract in Western Australia. She was sold to the Melbourne Steamship Company Ltd. (1906) and re-named the Leeuwi but continued in her Western Australian coastal run. She was converted into a coal hulk in Melbourne in 1910 as a result of damaged caused when she was driven against the jetty at Dongara during a gale. The ship was eventually dismantled and scuttled in Bass Strait on 28 December 1934. The steel sample is significant for its association with the wreck of the Leeuwin (Julia Percy), which is on the Victorian Heritage Register. It is historically significant for being a rare artefact that has potential to interpret aspects of western Victoria’s 19th century steamship trade and Victorian cultural history, including the testing and manufacturing process associated with steam power. Leeuwin is listed on the Victorian heritage Register as being historically significant ‘as one of only four wrecks of steamships in Victorian waters associated with the western district of Victoria’s coastal steamship trade. Her registered number is VHR S413. A sample of the steel from which the boiler of the "SS Julia Percy" (later named Leeuwin) was made. The piece of steel is a ‘C’ shape with the ends almost meeting. A luggage ticket is tied onto the steel and has an inscription on it. The steel is rusty.Ticket with typed information “Steel of which the Boiler of the “Julia Percy” (Warrnambool Steam Navigation Co) was made. TEST: Made Blood hot or Dark Red then dipped into water and bent cold. A very severe test for quality T.H. Osborne. Below these words is the hand written inscription in black “FM 151 / 9.75” julia percy, leeuwin, steel, boiler, steam ship, metal testing, western steam navigation co., flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, t.h. osborne

The Ballarat School of Mines is a predecessor institution of Federation University Australia. Photocopied newsletters with numerous newspaper clippings. 20 June 1994 - Mission, Women's Policy, Kate Wait, Walter Haller, Stewart Moors, Cynthia Jardine, Mark Lynch, R.J. Young Scholarship, David Thomas 22 August 1994 - Wimmera Community College Agreement, SMB/University of Ballarat Affiliation Agreement Signed by Chancellor Geoffrey Blainey, Max Palmer, Matthew Barlow, Mark Dawe, Phillip Lee, John Conaughton, Elizabeth White 05 September 1994 - Employment White Paper, Workcover, Ross Furness, Nance Jeffreys, Keith Chase, Michael Ronaldson, Ron Wild, Paul Jenkins 25 October 1994 - Staff Consultation Committee, Bendix Mintex Award, Rick Williams, Mike Hickey, Sexual Harassment, Ann McCaffrey, Brewery Complex building 07 November 1994 - Karpin Report, Edgar Bartrop Scholarship, Winsome McCaughey 13 June 1995 - Female Participation in TAFE, Lake Bolac Visit, Virginia Fenelon, Hairdressing, Ararat Community College, Brian MCLennan, Forestry Industry Contract, Ararat PRison Education, E.J.T. Tippett Award, Shane Lake, SMB Graduates 1995, Tony Leonard, Colin McCurry, Steph Pilmore 26 June 1995 - Child Care Centre, computer survey responses, Ellimatta, Sharna Whitehand, Jack Veeken, John Hanmer, Aaron Block, Kirsten Martin, Rowena Worth, Jan Croggon, Andrew McEvoy 24 July 1995 - Teaching, Engineering Liaison, Graham Shearer, Carol Durant, Brian McLennan, Market Research, Ararat Campus, Kevin Martin, Myrtle Muir, Hairdressing, Carol McDonald 07 August 1995 - Childcare, Playgroup, Disabilities, Judy Mills, Former Ballarat Gaol, Private Providers, Equal Opportunity, Equal Employment Opportunity 04 September 1995 - Keith Boast, Barkly Street Campus Library, Barrie Firth, Yuille Street Building, Painting and Decorating, Bricklaying, Disability Forum Committee, Belinda Morgan, Fay Guinane, Olivia Guinane, Robert Clarke Community Centre ceramic Tile Mosaic, Neville French, Annelies Egan, Judith Davies, Tanis Yuille, Margaret Komishon, Ruth Zegir, Ray Isaac 18 September - Competition Policy, Public Sector Reform, Brewery Building contract to S.J. Weir, Ararat Campus, BHP, Peter Bell, Mining Industry, Horticulture Facility (Gillies Street), Creche Fairy Mural, Shellagh Kentish, Daylesford Neighbourhood House and Learning Centre, Jenny Beacham, Tom Bates, Colin Trembath, Alan Scanosio, Zaiga Svanosio 16 October 1995 - Rural Studies Staffing, Robyn Greig, Ross Holton, Virginia Fenelon, Michelle Loader, Christina Elshaug, Cynthia Jardine, Morgan B. John death, Ian Pym, Melissa Cameron, hairdressing, Woolshed, Great Southern Woolshed, Graham Shearer October 1995 - Employment Relations Update, Enterprise Bargaining, Sue Wright, Ron Wild 30 October 1995 - 125th anniversary, 125th anniversary Medallions, Bill Murray (died 28 October 1995), Metal Fabrication, Ron Wild, Gael Ramsay, Paul Keating 20 November 1995 - Ceramics Exhibition, Heather Campbell, Marion Byass, Barry Norman, Helen Knowles, Michael Bracher, Brian McLennan, Rural Studies, Carpark, David Nicholson, Linetter Penhall, Suzanne Brown, Marie Bedggood 27 May 1996 - David Brown Farewell, Keith Boast, Educational Services, Wally Gradkowski, Dzintra Crocker, World Wide Web, Ann McCaffrey 17 June 1996 - Lifelong Learning Through Vocational Education and Training, Lyndal Cooper, Engineering Studies, David Manterfield, Rod MacKinney 19 August 1996 - SMB Strategic Plan 1997-2001, Ian Harris, Ararat Prison Education, Moongate 06 September 1996 - Tom Johnson, Bill Gribble, Ron Wild, INternational Projects Report, Cas Anderson, Court House Theatre, Former Court House, The Moongate 11 November 1996 - Brewery Complex Opening by Prime Minister John Howard on 09 December 1996, Human Resources, Marie Kerr, Fran Kisler, Karen Neale, Trudy Horwoood, Graham Hankin, Engineering Studies, David Manerfied, Sheilagh Kentish, Goroke College 12 May 1997 - Ballarat Group Training, Ballarat Aboriginal Co-operative, SMB Flexible Learning Centre, E.J. Tippett Library, Changing Role of the TAFE Teacher, Maree Greig, Colin Prowse, Performing Arts, Dave Knowles, Karyn Kilroy 20 August 1997 - Amalgamation Update, Graham Paynter, Heather MacLeod, Performing Arts 05 September 1997 - From TAFE to VET, Leoda Atkinson, Daniel James, Ararat campus, Mark Bevelander, computers, Craftsmanship Awards, Koorie Programs Unit, Deanne Jakiel, Stephen Burns, Women's Access Program, Internet 20 October 1997 - amalgamation update, Flexible Learning Centre, Andrea Bateman, Val D'Angri, Leoda Atkinson, Paul Mason, Andrea Bateman 10 November 1997 - Ballarat School of Mines/University of Ballarat Amalgamation, Shenzhen Polytechnic China, Videoconferencing, John Ferrier (Science), Performing Arts 08 December 1997 - Last Edition of Miners' Write Ron Wild, Brian McLennan, Max Palmer, Jeanetter John, Farewell to SMB, Time Capsuleminers write, ballarat school of mines, ron wild

Promoting the Graphic Design/Multimedia program being offered by the University of Ballarat at the Mt Helen Campus. Promoted course as "one of the smallest and arguably the best three year programs of its kind in Australia and the South Pacific region." The brochure lists student awards received including Platinum and Gold in the AGFA International Young Designer Contest, 1999; two meritorious awards in The Art Directors Club Student Awards, New York, USA 1999; Graphis New Talent 1999; two Gold in Souther Cross Packaging Awards, 1998. At time of publication, the School of Arts, Visual Arts reportedly had 210 students with majors in Graphic Design/Multimedia, Ceramics/3D, Painting, Drawing, and Multidiscipline. Minors studies included Printmaking, Photography, 3D, 2D, and Graphic Communication. ___ Course aimed to train "independent, flexible thinkers". The course promised to "Promote creativity, originality and imaginative thinking; Develop self-directed learners, displaying initiative in the formation of ideas and the confidence to construct personal responses; Develop appropriate conceptual, technical and professional skills; Develop the student's critical process: ability to undertake research, and to make informed decisions; Clarify thinking, concepts and understanding and deep knowledge, attitudes and skills enabling the designer to respond to community needs." Studio and working environment described as "one open space with working facilities for approximately 75 students across 3 year levels. The area is divided up into work stations where 1st, 2nd and 3rd year students intermix, allowing a natural interaction. These workstations are configurations of six, consisting of two students from each year level. This reinforces the area's ongoing development with an open ethos and cross-level delivery and learning. This maximises the use of information in order for it to be applied throughout all levels of the learning process, whilst allowing a natural mentor arrangment to be developed for all first year students, " "The open ethos approach also encourages students and staff to freely express their opinions in relation to design via cross-level critiques, whilst allowing for a liberal arts approach and structure to the development of the creative process." "Emphasis is placed on experimentation, innovation, expression and the development of the individual's design philosophies, concepts and style." Also notes the 24 hour access Macintosh laboratory, with 34 Power Macintosh computers, ratio of one for every 2.5 students. Each with a Fujitsu Dyna Magneto Optical drive for file storage and transport. Two Sharp scanners, Phaser Dye-Sublimation Extra Tabloid colour printer and Ricoh A3 colour printer. Two large format printers. Digital and video cameras. Software: Adobe Photoshop, Illustrator, Acrobat; QuarkXpress; Macromedia Freehand; Pagemaker; Premier; Director; 3D Extreme; Sound Eidt, Shockwave, Infinite 3D and After Effects. Approx 4.5 staff, "all of whom are practicing designers. They have a full understanding of industry requirements and trends which assists in the development of industrial contacts when specialists are required." Prospective students interviewed in late Nov/ early Dec, face to face. Present a "comprehensive folio of work", academic records, references. "Selection is determined by the perceived potential of the student, their motivation and reason for study within the field as well as their previous experience in the Visual Arts. Folio work should be representative of the individual's ideas and abilities. Qualities of importance are: originality, innovation, imagination, experimentation and a competent display of the basic skills associated with visual arts [evidence of drawing skills should be included]." Demonstration of GD/MM computer skills an advantage. Students also asked to bring sketch books. Promotional brochure for prospective students. 8pp Double fold brochureuniversity of ballarat, federation university, graphic design, multimedia, bachelor, degree

Considered the best of the early mud-brick houses built by Alistair Knox. Covered under Heritage Overlay, Nillumbik Planning Scheme. Published: Nillumbik Now and Then /​ Marguerite Marshall 2008; photographs Alan King with Marguerite Marshall.; p143 The Busst house hidden by trees at the corner of Silver Street and Kerrie Crescent is considered the best of the early mud-brick houses built by Eltham architect, Alistair Knox. Knox himself said, that the Busst house was the most mature mud-brick house designed at that period. ‘It related with true understanding to its steep site and expressed the flexibility of earth building ………to develop a new sense of flowing form and shape’.1 Built in 1948 for artist Phyl Busst, a former art student at Montsalvat, the house helped usher in Eltham Shire’s distinctive mud-brick residential character. Knox was the pivotal figure of the style developed from the 1950s to the 1970s.2 Scarcity of building materials after World War Two encouraged mud-brick building because earth was a cheap and plentiful building medium. But when Knox began building in mud-brick in 1947, no council in Victoria knew anything of this ancient art and he needed a permit. Fortunately the Commonwealth Experimental Building Station at Ryde in NSW, had been experimenting with earth construction to help overcome the shortages of that time. They published a pamphlet that became available in Melbourne on the same day the Eltham Council was to consider whether the earth building should be allowed. Knox caught one of the three morning trains to the city in those days and bought several copies of the pamphlet to give to each councillor. On his return he found the councillors standing on the steps of the shire offices after lunch at the local hotel. He heard that earth building had been discussed before lunch and that they were not in favor of it. Knox gave each councillor a pamphlet. They passed that plan and by doing so, opened the door for all future earth building in Victoria and by default, in Australia.3 Mud-brick houses attracted artists to Eltham, for their aesthetic appeal and because they were cheap. Those who built their own houses, included film maker Tim Burstall, artists Peter Glass, Clifton Pugh, Matcham Skipper, Sonia Skipper and husband Jo Hannan. For Knox, mud-brick building was more than just a cheap building medium. He saw it as harmonising with the surrounding bush and as a way of counteracting the growing materialism of the age. He wrote of its impact on ‘ 20th century man. It should counteract the confusion that the perpetual flow of high technology products have upon him ..’.4 Building the Busst house on a steep site was difficult because most earth-moving equipment was then in its infancy. For instance drilling for explosives was done by hand, which was a slow and painful process. Knox, assisted by his foreman Horrie Judd and Gordon Ford (who was to become a famous landscape designer), built two large main rooms - a living room/ kitchen downstairs - and upstairs, a studio/bedroom. The studio/bedroom opens onto the balcony, which covers the living area. The bath made of solid concrete by stonemason Jack Fabro, is particularly deep. Sunshine pours through the three French windows of the north-east facing kitchen/living area, which is lined with timber. The large hearth can fit a family around the fire while the timber floors and solomite (compressed straw) ceilings add to the cosy atmosphere. The garden is thick with trees, and in the late 1990s, Ford put in a pool near the original dry wall he had built as a young man.This collection of almost 130 photos about places and people within the Shire of Nillumbik, an urban and rural municipality in Melbourne's north, contributes to an understanding of the history of the Shire. Published in 2008 immediately prior to the Black Saturday bushfires of February 7, 2009, it documents sites that were impacted, and in some cases destroyed by the fires. It includes photographs taken especially for the publication, creating a unique time capsule representing the Shire in the early 21st century. It remains the most recent comprehenesive publication devoted to the Shire's history connecting local residents to the past. nillumbik now and then (marshall-king) collection, alistair knox, alistair knox design, busst house, kerrie crescent, mudbrick construction, mudbrick houses, silver street

The word “catheter” comes from Greek, meaning “to let or send down.” Catheters were used as early as 3,000 B.C. to relieve painful urinary retention. In those times, many materials were used to form a hollow catheter shape, including straw, rolled up palm leaves, hollow tops of onions, as well as, gold, silver, copper, brass, and lead. Malleable catheters were developed in the 11th century. In time, silver was used as the basis of catheters as it could be bent to any desired shape and was felt to have an antiseptic function. Benjamin Franklin, the inventor and colonial statesman, fashioned silver catheters for use by his older brother John. John suffered from kidney stones and needed to undergo a daily ritual of placing a bulky metal catheter into his bladder. To make these daily requirements on his brother less painful, Franklin worked with his local silversmith on his design for a flexible catheter. "It is as flexible as would be expected in a thing of the kind, and I imagine will readily comply with the turns of the passage," he wrote to John. Holes were bored into the sides of the catheter to allow for drainage. Coudé tip catheters were developed in the 18th and 19th centuries to facilitate male catheterization and continue to be used for this purpose in current medical practice. Catheters made from rubber were developed in the 18th century but were weak at body temperature, leaving debris in the bladder. The advent of rubber vulcanization, by Goodyear in 1844, improved the firmness and durability of the catheter, and allowed for mass production. Latex rubber became available in the 1930s. Dr. Frederic E.B. Foley (a St. Paul urologist) introduced the latex balloon catheter at a urologic meeting in 1935. Though he lost a legal battle with Davol for the patent, this catheter has since been known as the “Foley.” The earliest self-retaining catheters had wing tips (called Malecot) or flexible shoulders (called Pezzer), and were tied to the male penis or sutured to the female labia. Charriere’s French scale was used to describe the external diameter of a catheter. Thus the term “French (Fr)” size was coined. Joseph-Frederic-Benoit Charriere was a 19th century Parisian maker of surgical instruments. A 12 French catheter is approximately 4 mm in external diameter (0.33 mm = 1 French [Fr]). In French-speaking countries, these catheters may be referred to as the Charriere or abbreviated Ch. Catheterization of the bladder was felt to be fairly safe because of the antiseptic principles of Lister (1867). But many physicians continued to be concerned about catheter-related infections as patients were still developing “catheter fever” (systemic infection) despite antiseptic principles. After World War II, Sir Ludwig Guttman introduced the concept of sterile intermittent catheterization in patients with spinal cord injury. For many years, sterile technique was used for catheterization. In 1971, Dr. Jack Lapides of the University of Michigan at Ann Arbor introduced the clean intermittent catheterization (CIC) technique. Dr. Lapides’ theory was that bacteria weren’t the only cause of infection. He believed that chronic stagnant urine residuals and overstretching of the bladder were also responsible. But the fact that CIC was not performed in totally sterile conditions, Dr. Lapides still felt it was superior to indwelling catheters. Initially, Lapides was scorned in the urology world. Three decades after this debate, clean intermittent catheterization remains the preferred method to treat chronic urine retention and neurogenic bladder. Recent regulatory changes have recommended against the reuse of catheters for CIC in an attempt to further reduce the risk of catheter-associated urinary tract infections. https://www.urotoday.com/urinary-catheters-home/history-of-urinary-catheters.html This catheter was donated to Flagstaff Hill Maritime Village by the family of Doctor William Roy Angus, Surgeon and Oculist. It is part of the “W.R. Angus Collection” that includes historical medical equipment, surgical instruments and material once belonging to Dr Edward Ryan and Dr Thomas Francis Ryan, (both of Nhill, Victoria) as well as Dr Angus’ own belongings. The Collection’s history spans the medical practices of the two Doctors Ryan, from 1885-1926 plus that of Dr Angus, up until 1969. ABOUT THE “W.R.ANGUS COLLECTION” Doctor William Roy Angus M.B., B.S., Adel., 1923, F.R.C.S. Edin.,1928 (also known as Dr Roy Angus) was born in Murrumbeena, Victoria in 1901 and lived until 1970. He qualified as a doctor in 1923 at University of Adelaide, was Resident Medical Officer at the Royal Adelaide Hospital in 1924 and for a period was house surgeon to Sir (then Mr.) Henry Simpson Newland. Dr Angus was briefly an Assistant to Dr Riddell of Kapunda, then commenced private practice at Curramulka, Yorke Peninsula, SA, where he was physician, surgeon and chemist. In 1926, he was appointed as new Medical Assistant to Dr Thomas Francis Ryan (T.F. Ryan, or Tom), in Nhill, Victoria, where his experiences included radiology and pharmacy. In 1927 he was Acting House Surgeon in Dr Tom Ryan’s absence. Dr Angus had become engaged to Gladys Forsyth and they decided he further his studies overseas in the UK in 1927. He studied at London University College Hospital and at Edinburgh Royal Infirmary and in 1928, was awarded FRCS (Fellow from the Royal College of Surgeons), Edinburgh. He worked his passage back to Australia as a Ship’s Surgeon on the on the Australian Commonwealth Line’s T.S.S. Largs Bay. Dr Angus married Gladys in 1929, in Ballarat. (They went on to have one son (Graham 1932, born in SA) and two daughters (Helen (died 12/07/1996) and Berenice (Berry), both born at Mira, Nhill According to Berry, her mother Gladys made a lot of their clothes. She was very talented and did some lovely embroidery including lingerie for her trousseau and beautifully handmade baby clothes. Dr Angus was a ‘flying doctor’ for the A.I.M. (Australian Inland Ministry) Aerial Medical Service in 1928. Its first station was in the remote town of Oodnadatta, where Dr Angus was stationed. He was locum tenens there on North-South Railway at 21 Mile Camp. He took up this ‘flying doctor’ position in response to a call from Dr John Flynn; the organisation was later known as the Flying Doctor Service, then the Royal Flying Doctor Service. A lot of his work during this time involved dental surgery also. Between 1928-1932 he was surgeon at the Curramulka Hospital, Yorke Peninsula, South Australia. In 1933 Dr Angus returned to Nhill and purchased a share of the Nelson Street practice and Mira hospital (a 2 bed ward at the Nelson Street Practice) from Dr Les Middleton one of the Middleton Brothers, the current owners of what previously once Dr Tom Ryan’s practice. Dr Tom and his brother had worked as surgeons included eye surgery. Dr Tom Ryan performed many of his operations in the Mira private hospital on his premises. He had been House Surgeon at the Nhill Hospital 1902-1926. Dr Tom Ryan had one of the only two pieces of radiology equipment in Victoria during his practicing years – The Royal Melbourne Hospital had the other one. Over the years Dr Tom Ryan had gradually set up what was effectively a training school for country general-practitioner-surgeons. Each patient was carefully examined, including using the X-ray machine, and any surgery was discussed and planned with Dr Ryan’s assistants several days in advance. Dr Angus gained experience in using the X-ray machine there during his time as assistant to Dr Ryan. When Dr Angus bought into the Nelson Street premises in Nhill he was also appointed as the Nhill Hospital’s Honorary House Surgeon 1933-1938. His practitioner’s plate from his Nhill surgery is now mounted on the doorway to the Port Medical Office at Flagstaff Hill Maritime Village, Warrnambool. When Dr Angus took up practice in the Dr Edward and Dr Tom Ryan’s old premises he obtained their extensive collection of historical medical equipment and materials spanning 1884-1926. A large part of this collection is now on display at the Port Medical Office at Flagstaff Hill Maritime Village in Warrnambool. In 1939 Dr Angus and his family moved to Warrnambool where he purchased “Birchwood,” the 1852 home and medical practice of Dr John Hunter Henderson, at 214 Koroit Street. (This property was sold in1965 to the State Government and is now the site of the Warrnambool Police Station and an ALDI sore is on the land that was once their tennis court). The Angus family was able to afford gardeners, cooks and maids; their home was a popular place for visiting dignitaries to stay whilst visiting Warrnambool. Dr Angus had his own silk worm farm at home in a Mulberry tree. His young daughter used his centrifuge for spinning the silk. Dr Angus was appointed on a part-time basis as Port Medical Officer (Health Officer) in Warrnambool and held this position until the 1940’s when the government no longer required the service of a Port Medical Officer in Warrnambool; he was thus Warrnambool’s last serving Port Medical Officer. (Masters of immigrant ships arriving in port reported incidents of diseases, illness and death and the Port Medical Officer made a decision on whether the ship required Quarantine and for how long, in this way preventing contagious illness from spreading from new immigrants to the residents already in the colony.) Dr Angus was a member of the Australian Medical Association, for 35 years and surgeon at the Warrnambool Base Hospital 1939-1942, He served with the Australian Department of Defence as a Surgeon Captain during WWII 1942-45, in Ballarat, Victoria, and in Bonegilla, N.S.W., completing his service just before the end of the war due to suffering from a heart attack. During his convalescence he carved an intricate and ‘most artistic’ chess set from the material that dentures were made from. He then studied ophthalmology at the Royal Melbourne Eye and Ear Hospital and created cosmetically superior artificial eyes by pioneering using the intrascleral cartilage. Angus received accolades from the Ophthalmological Society of Australasia for this work. He returned to Warrnambool to commence practice as an ophthalmologist, pioneering in artificial eye improvements. He was Honorary Consultant Ophthalmologist to Warrnambool Base Hospital for 31 years. He made monthly visits to Portland as a visiting surgeon, to perform eye surgery. He represented the Victorian South-West subdivision of the Australian Medical Association as its secretary between 1949 and 1956 and as chairman from 1956 to 1958. In 1968 Dr Angus was elected member of Spain’s Barraquer Institute of Barcelona after his research work in Intrasclearal cartilage grafting, becoming one of the few Australian ophthalmologists to receive this honour, and in the following year presented his final paper on Living Intrasclearal Cartilage Implants at the Inaugural Meeting of the Australian College of Ophthalmologists in Melbourne In his personal life Dr Angus was a Presbyterian and treated Sunday as a Sabbath, a day of rest. He would visit 3 or 4 country patients on a Sunday, taking his children along ‘for the ride’ and to visit with him. Sunday evenings he would play the pianola and sing Scottish songs to his family. One of Dr Angus’ patients was Margaret MacKenzie, author of a book on local shipwrecks that she’d seen as an eye witness from the late 1880’s in Peterborough, Victoria. In the early 1950’s Dr Angus, painted a picture of a shipwreck for the cover jacket of Margaret’s book, Shipwrecks and More Shipwrecks. She was blind in later life and her daughter wrote the actual book for her. Dr Angus and his wife Gladys were very involved in Warrnambool’s society with a strong interest in civic affairs. He had an interest in people and the community. They were both involved in the creation of Flagstaff Hill, including the layout of the gardens. After his death (28th March 1970) his family requested his practitioner’s plate, medical instruments and some personal belongings be displayed in the Port Medical Office surgery at Flagstaff Hill Maritime Village, and be called the “W. R. Angus Collection”. The W.R. Angus Collection is significant for still being located at the site it is connected with, Doctor Angus being the last Port Medical Officer in Warrnambool. The collection of medical instruments and other equipment is culturally significant, being an historical example of medicine, administration, household equipment and clothing from late 19th to mid-20th century. Dr Angus assisted Dr Tom Ryan, a pioneer in the use of X-rays and in ocular surgery. Stainless steel catheter with hollow tip from W.R. Angus Collection. Top and end of this instrument screw together. flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, dr w r angus, dr ryan, surgical instrument, t.s.s. largs bay, warrnambool base hospital, nhill base hospital, mira hospital, flying doctor, department of defence australia, australian army, army uniform, medical treatment, medical history, medical education, catheter

This is a SPRA, or Schermuly’s Pistol Rocket Apparatus. The large firearm type pistol would have been used to throw a line between ships, usually in the event of saving lives. The line throwing pistol consists of a long barrel with handle attached, a pistol grip and trigger, which fires a short blank cartridge. Accessories for the pistol included: flares, 12 gauge adaptor (to shoot 12 gauge flares), a wood plunger, and boxes of faked line. The stamp on the handle, Crown over "NP" is a Birmingham Proof House mark that dates the pistol between 1904 and 1954. However Schermuly's line throwing pistol was invented in the 192s and used on British Naval Ships from 1929. The serial number '22507' is only 806 numbers later than one on sale as a British Military WWII issue SRPA '21701'. This pistol appears to be made 125-1945. The apparatus was used as a life saving device for crew and passengers on vessels in distress that were only a few hundred metres from shore, often eliminating the need to launch a boat and risk lives to go out to the vessel in dangerous conditions. It could also be used from ship to ship rescue. The pistol would launch a line from shore to the vessel. The line would be attached to the vessel, then shore crew would send out equipment, including a breeches buoy, in which the stranded people could be pulled to shore. It has saved many lives at sea. The cartridge is loaded into the breech of the pistol and the rocket is inserted into the muzzle. On pulling the trigger, the gases generated by the fired cartridge eject the rocket on its correct line of flight, and at the same time, burst through the waterproof disc and ignite the propellant mixture, which carries the rocket and line on the remainder of the flight. The rocket consists of a weldless steel case filled with propellant mixture sealed in by a waterproof disc. Fixed to the rocket case is a direction bridle, to the end of which a short length of flexible steel wire is attached, this in turn being connected to the end of the line to be thrown. A complete rocket set, or line throwing kit. would include a wood carrying case, two coils of faked line in separate compartments, three rockets and a can of six cartridges. William Schermuly (1857 – 1929) - Founder of the Schermuly business. In 1897 he invented a trough-fired, line throwing apparatus. In 1920 he and his third son, Alfred James Schermuly, invented the pistol rocket apparatus and promoted this overseas during the 1920s. The system was approved by the British Navy in 1929 through an Act of Parliament, which made it compulsory for ships over 500 tons to carry this equipment. The company, Schermuly Pistol Rocket Apparatus Ltd., grew quickly during and after World War II but business eased off during the 1970s before it eventually closed in the 1990s. Saving lives in Warrnambool – The coastline of South West Victoria is the site of over 600 shipwrecks and many lost lives; even in Warrnambool’s Lady Bay there were around 16 known shipwrecks between 1850 and 1905, with eight lives lost. Victoria’s Government responded to the need for lifesaving equipment and, in 1858, the provision of rocket and mortar apparatus was approved for the lifeboat stations. In 1859 the first Government-built lifeboat arrived at Warrnambool Harbour and a shed was soon built for it on the Tramway Jetty, followed by a rocket house in 1864 to safely store the rocket rescue equipment. In 1878 the buildings were moved to the Breakwater (constructed from 1874-1890), and in 1910 the new Lifeboat Warrnambool arrived with its ‘self-righting’ design. For almost a hundred years the lifesaving and rescue crews, mostly local volunteers, trained regularly to rehearse and maintain their rescue skills. They were summoned when needed by alarms, gunshots, ringing bells and foghorns. In July 1873 a brass bell was erected at Flagstaff Hill specifically to call the rescue crew upon news of a shipwreck. Some crew members became local heroes but all served an important role. Rocket apparatus was used as recently as the 1950s. This line-throwing pistol is part of he Rocket Launching Equipment used to perform life-saving rescue at sea from the 1920s. It is significant for its connection with local history, maritime history and marine technology. Lifesaving has been an important part of the services performed from Warrnambool's very early days, supported by State and Local Government, and based on the methods and experience of Great Britain. Hundreds of shipwrecks along the coast are evidence of the rough weather and rugged coastline. Ordinary citizens, the Harbour employees, and the volunteer boat and rescue crew, saved lives in adverse circumstances. Some were recognised as heroes, others went unrecognised. In Lady Bay, Warrnambool, there were around 16 known shipwrecks between 1850 and 1905. Many lives were saved but tragically, eight lives were lost.Pistol, line-throwing, SPRA (Schermuly's Pistol Rocket Apparatus). This line throwing pistol has a wooden pistol grip, brass trigger mechanism, and a long, wide, steel barrel with Bakelite handle attached to the top. Inscriptions are stamped onto the pistol.Stamped on handle: "5" and "[symbol of a Crown] above NP" , "22507", "[within oval] SPRA" Stamped on barrel: "L22507".gun, pistol, flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, flagstaff hill maritime village, great ocean road, line throwing, line throwing pistol, spra, schermuly's pistol rocket apparatus, sea rescue, pyrotechnicks, marine technology, schermuly pistol rocket apparatus ltd., william schermuly, alfred schermuly, pistol line thrower, flagstaff hill maritime museum and village, maritime village, lady bay, warrnambool harbour, port of warrnambool, shipwreck, life-saving, lifesaving, rescue crew, rescue, rocket rescue, rocket crew, beach rescue, line rescue, rescue equipment, rocket firing equipment, rocket rescue equipment, maritime accidents, shipwreck victim, rocket equipment, rescue boat, lifeboat, volunteer lifesavers, volunteer crew, life saving rescue crew, lifesaving rescue crew, rocket apparatus, rocket rescue method, shore to ship, rocket apparatus rescue, stranded vessel, line throwing mortar, rocket rescue apparatus, line thrower, lifeboat warrnambool, rocket machine, rocket head, rocket launcher, rocket line, beach rescue set, rocket set, schermuly, line-firing pistol, line throwing gun, pistol rocket apparatus, line throwing cartridge, line-throwing rocket, firearm, life saving, lsrc

Warrandyte artist, Clara Southern, features on the Artists Trail. Published: Nillumbik Now and Then /​ Marguerite Marshall 2008; photographs Alan King with Marguerite Marshall.; p189 Since early in the 20th century this district has attracted artists and other creative people. So much so, that Eltham has been compared to the Left Bank in Paris, New York’s Greenwich Village and London’s Bloomsbury.1 That is until the 1970s when Eltham rapidly expanded into a suburb. However many artists still flourish not only in Montsalvat, Dunmoochin and the Bend of Islands but elsewhere in Nillumbik. Some artists who have worked or lived in Nillumbik are well-known nationally and internationally. Artists are attracted to the hilly district’s subtle colours, unique light and the Yarra River and Diamond Creek. The railway’s extension to Eltham in 1902 brought artists to paint for the day or to camp. Then many settled in Eltham, perhaps also because the poor quality land, far from the city, was cheap. Following World War Two they found they could build houses and studios cheaply by making their own mud-bricks. The flexible material, with its warm tones blending into the bush, also satisfied their aesthetic sensibilities. As early as 1900, Will Longstaff, known for his painting The Ghosts of Menin Gate at the National War Memorial in Canberra, lived at Stanhope in Peter Street, Eltham, later to become the home of intellectuals Clem and Nina Christensen. Members of Australia’s first significant art movement, the Heidelberg School of Artists, painted in Eltham, Warrandyte and Diamond Creek.2 Walter Withers lived at the corner of Bolton and Brougham Street, Eltham and taught Sir Hans Heysen, who for a short while stayed with the Withers family. In Warrandyte were Clara Southern, whom Frederick McCubbin taught at the National Gallery School and Penleigh Boyd, who is represented in all Australian state galleries and the National Collection in Canberra. May Vale, daughter of politician William, lived in Diamond Creek.3 With Jane Price they feature on the Heidelberg School Artists Trail, part of which runs through Nillumbik. The trail includes signs each displaying a reproduction of a painting by an artist and located near where the artist lived or painted. In Nillumbik the trail includes parts of Warrandyte, Eltham in the Alistair Knox Park, Main Road shopping precinct and Wingrove Park, the Research walking track on Main Road and the Diamond Creek Reserve. In 1916 artist William ‘Jock’ Frater lived at the corner of Arthur and Bible Streets, Eltham. Before then, Frater, with other artists including Percy Leason (who moved to Eltham in the mid 1920s) painted in Eltham on weekends. They camped near Bible and Pitt Streets and along the Diamond Creek where the Eltham Retirement Centre now stands.4 In 1921, painter Peter Newbury (father to painter David Newbury, who was born in Eltham) moved to Cromwell Street, Eltham. Max Meldrum, the first Australian painter to formulate a consistent theory of art largely based on tone,5 taught local artists Alan Martin, Clarice Beckett, Peter Glass and Justus Jörgensen. Meldrum visited Eltham then rented a house there for 18 months opposite Wingrove Park. In 1934, artist and architect Justus Jörgensen and his doctor wife Lil and friends built Montsalvat, the artists’ colony. Montsalvat has played an important part in attracting artists to Eltham and its mud-brick, pisé, stone and recycled building materials has had a major influence on Eltham’s built environment. Jörgensen’s students who also helped him build Monstalvat included Arthur Munday, Lesley Sinclair, Helen Lempriere, Joe Hannan, Helen, Sonia and jeweller/sculptor, Matcham Skipper. Among artists who visited Montsalvat were Clifton Pugh and Angry Penguins’ artists Albert Tucker and Arthur Boyd. Some who painted after World War Two were Alan Martin of Eltham and Warrandyte artists Frank Crozier and Harry De Hartog6, one of Melbourne’s first painters influenced by Cubism.This collection of almost 130 photos about places and people within the Shire of Nillumbik, an urban and rural municipality in Melbourne's north, contributes to an understanding of the history of the Shire. Published in 2008 immediately prior to the Black Saturday bushfires of February 7, 2009, it documents sites that were impacted, and in some cases destroyed by the fires. It includes photographs taken especially for the publication, creating a unique time capsule representing the Shire in the early 21st century. It remains the most recent comprehenesive publication devoted to the Shire's history connecting local residents to the past. nillumbik now and then (marshall-king) collection, clara southern, heidelberg artists' trail, main road, research (vic)

Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Baleen, or "Whalebone" The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The "bone" of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as "whalebone." Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070.Whale bone was an important commodity, used in corsets, collar stays, buggy whips, and toys.Whale bone in two pieces. Advanced stage of calcification as indicated by deep pitting. Off white to grey.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whale bones, whale skeleton, whales, whale bone, corsets, toys, whips

Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Baleen, or "Whalebone" The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The "bone" of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as "whalebone." Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070.Whale bone was an important commodity, used in corsets, collar stays, buggy whips, and toys.Whale bone piece. Advanced stage of calcification as indicated by deep pitting. Off white to grey.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whales, whale bone, corsets, toys, whips

Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Baleen, or "Whalebone" The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The "bone" of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as "whalebone." Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070. Whale bone was an important commodity, used in corsets, collar stays, buggy whips, and toys.Whale bone vertebrae. Advanced stage of calcification as indicated by deep pitting. Off white to grey.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whales, whale bone, corsets, toys, whips

Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Baleen, or "Whalebone" The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The "bone" of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as "whalebone." Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070.Whale bone was an important commodity, used in corsets, collar stays, buggy whips, and toys.Whale bone piece. Advanced stage of calcification as indicated by deep pitting. Off white to grey.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whales, whale bone, corsets, toys, whips

Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Baleen, or "Whalebone" The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The "bone" of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as "whalebone." Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070.Whale bone was an important commodity, used in corsets, collar stays, buggy whips, and toys.Whale bone piece. Advanced stage of calcification as indicated by deep pitting. Off white to grey.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whales, whale bone, corsets, toys, whips

Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Baleen, or "Whalebone" The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The "bone" of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as "whalebone." Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070.Whale bone was an important commodity, used in corsets, collar stays, buggy whips, and toys.Whale bone vertebrae. Advanced stage of calcification as indicated by deep pitting. Off white to grey.Noneflagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whales, whale bone, corsets, toys, whips, whalebone

Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Whalebone The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The bone of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as whalebone. Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070.Whale bone during the 17th, 18th, 19th and early 20th centuries was an important industry providing an important commodity. Whales from these times provided everything from lighting & machine oils to using the animal's bones for use in corsets, collar stays, buggy whips, and many other everyday items then in use.Whale bone Vertebrae with advanced stage of calcification as indicated by deep pitting. Off white to grey.None.warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whale bones, whale skeleton, whales, whale bone, corsets, toys, whips, whaleling industry, maritime fishing, whalebone

Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Baleen, or "Whalebone" The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The "bone" of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as "whalebone." Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070.Whale bone during the 17th, 18th, 19th and early 20th centuries was an important industry providing an important commodity. Whales from these times provided everything from lighting & machine oils to using the animal's bones for use in corsets, collar stays, buggy whips, and many other everyday items then in use.Whale jaw bone one side, long & curved with advanced stage of calcification off white to grey.None.warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whale bones, whale skeleton, whales, whale bone, corsets, toys, whips, whaleling industry, maritime fishing, whalebone

Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Baleen, or "Whalebone" The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The "bone" of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as "whalebone." Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070.Whale bone during the 17th, 18th, 19th and early 20th centuries was an important industry providing an important commodity. Whales from these times provided everything from lighting & machine oils to using the animal's bones for use in corsets, collar stays, buggy whips, and many other everyday items then in use.Whale rib bone with advanced stage of calcification as indicated by brittleness. None.warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whale bones, whale skeleton, whales, whale bone, corsets, toys, whips, whaleling industry, maritime fishing, whalebone

1. Musical and linguistic perspectives on Aboriginal song Allan Marett and Linda Barwick Song brings language and music together. Great singers are at once musicians and wordsmiths, who toss rhythm, melody and word against one another in complex cross-play. In this paper we outline some initial findings that are emerging from our interdisciplinary study of the musical traditions of the Cobourg region of western Arnhem Land, a coastal area situated in the far north of the Australian continent 350 kilometres northeast of Darwin. We focus on a set of songs called Jurtbirrk, sung in Iwaidja, a highly endangered language, whose core speaker base is now located in the community of Minjilang on Croker Island. We bring to bear analytical methodologies from both musicology and linguistics to illuminate this hitherto undocumented genre of love songs. 2. Iwaidja Jurtbirrk songs: Bringing language and music together Linda Barwick (University of Sydney), Bruce Birch and Nicholas Evans (University of Melbourne) Song brings language and music together. Great singers are at once musicians and wordsmiths, who toss rhythm, melody and word against one another in complex cross-play. In this paper we outline some initial findings that are emerging from our interdisciplinary study of the musical traditions of the Cobourg region of western Arnhem Land, a coastal area situated in the far north of the Australian continent 350 kilometres northeast of Darwin. We focus on a set of songs called Jurtbirrk, sung in Iwaidja, a highly endangered language, whose core speaker base is now located in the community of Minjilang on Croker Island. We bring to bear analytical methodologies from both musicology and linguistics to illuminate this hitherto undocumented genre of love songs. 3. Morrdjdjanjno ngan-marnbom story nakka, ?songs that turn me into a story teller?: The morrdjdjanjno of western Arnhem Land Murray Garde (University of Melbourne) Morrdjdjanjno is the name of a song genre from the Arnhem Land plateau in the Top End of the Northern Territory and this paper is a first description of this previously undocumented song tradition. Morrdjdjanjno are songs owned neither by individuals or clans, but are handed down as ?open domain? songs with some singers having knowledge of certain songs unknown to others. Many morrdjdjanjno were once performed as part of animal increase rituals and each song is associated with a particular animal species, especially macropods. Sung only by men, they can be accompanied by clap sticks alone or both clap sticks and didjeridu. First investigations reveal that the song texts are not in everyday speech but include, among other things, totemic referential terms for animals which are exclusive to morrdjdjanjno. Translations from song language into ordinary register speech can often be ?worked up? when the song texts are discussed in their cultural and performance context. The transmission of these songs is severely endangered at present as there are only two known singers remaining both of whom are elderly. 4. Sung and spoken: An analysis of two different versions of a Kun-barlang love song Isabel O?Keeffe (nee Bickerdike) (University of Melbourne) In examining a sung version and a spoken version of a Kun-barlang love song text recorded by Alice Moyle in 1962, I outline the context and overall structure of the song, then provide a detailed comparative analysis of the two versions. I draw some preliminary conclusions about the nature of Kun-barlang song language, particularly in relation to the rhythmic setting of words in song texts and the use of vocables as structural markers. 5. Simplifying musical practice in order to enhance local identity: Rhythmic modes in the Walakandha wangga (Wadeye, Northern Territory) Allan Marett (University of Sydney) Around 1982, senior performers of the Walakandha wangga, a repertory of song and dance from the northern Australian community of Wadeye (Port Keats), made a conscious decision to simplify their complex musical and dance practice in order to strengthen the articulation of a group identity in ceremonial performance. Recordings from the period 1972?82 attest to a rich diversity of rhythmic modes, each of which was associated with a different style of dance. By the mid-1980s, however, this complexity had been significantly reduced. I trace the origin of the original complexity, explore the reasons why this was subsequently reduced, and trace the resultant changes in musical practice. 6. ?Too long, that wangga?: Analysing wangga texts over time Lysbeth Ford (University of Sydney) For the past forty or so years, Daly region song-men have joined with musicologists and linguists to document their wangga songs. This work has revealed a corpus of more than one hundred wangga songs composed in five language varieties Within this corpus are a few wangga texts recorded with their prose versions. I compare sung and spoken texts in an attempt to show not only what makes wangga texts consistently different from prose texts, but also how the most recent wangga texts differ from those composed some forty years ago. 7. Flesh with country: Juxtaposition and minimal contrast in the construction and melodic treatment of jadmi song texts Sally Treloyn (University of Sydney) For some time researchers of Centralian-style songs have found that compositional and performance practices that guide the construction and musical treatment of song texts have a broader social function. Most recently, Barwick has identified an ?aesthetics of parataxis or juxtaposition? in the design of Warumungu song texts and musical organisation (as well as visual arts and dances), that mirrors social values (such as the skin system) and forms 'inductive space' in which relationships between distinct classes of being, places, and groups of persons are established. Here I set out how juxtaposition and minimal contrast in the construction and melodic treatment of jadmi-type junba texts from the north and north-central Kimberley region similarly create 'inductive space' within which living performers, ancestral beings, and the country to which they are attached, are drawn into dynamic, contiguous relationships. 8. The poetics of central Australian Aboriginal song Myfany Turpin (University of Sydney) An often cited feature of traditional songs from Central Australia (CA songs) is the obfuscation of meaning. This arises partly from the difficulties of translation and partly from the difficulties in identifying words in song. The latter is the subject of this paper, where I argue it is a by-product of adhering to the requirements of a highly structured art form. Drawing upon a set of songs from the Arandic language group, I describe the CA song as having three independent obligatory components (text, rhythm and melody) and specify how text is set to rhythm within a rhythmic and a phonological constraint. I show how syllable counting, for the purposes of text setting, reflects a feature of the Arandic sound system. The resultant rhythmic text is then set to melody while adhering to a pattern of text alliteration. 9. Budutthun ratja wiyinymirri: Formal flexibility in the Yol?u manikay tradition and the challenge of recording a complete repertoire Aaron Corn (University of Sydney) with Neparr? a Gumbula (University of Sydney) Among the Yol?u (people) of north-eastern Arnhem Land, manikay (song) series serve as records of sacred relationships between humans, country and ancestors. Their formal structures constitute the overarching order of all ceremonial actions, and their lyrics comprise sacred esoteric lexicons held nowhere else in the Yol?u languages. A consummate knowledge of manikay and its interpenetrability with ancestors, country, and parallel canons of sacred y�ku (names), bu?gul (dances) and miny'tji (designs) is an essential prerequisite to traditional leadership in Yol?u society. Drawing on our recordings of the Baripuy manikay series from 2004 and 2005, we explore the aesthetics and functions of formal flexibility in the manikay tradition. We examine the individuation of lyrical realisations among singers, and the role of rhythmic modes in articulating between luku (root) and bu?gul'mirri (ceremonial) components of repertoire. Our findings will contribute significantly to intercultural understandings of manikay theory and aesthetics, and the centrality of manikay to Yol?u intellectual traditions. 10. Australian Aboriginal song language: So many questions, so little to work with Michael Walsh Review of the questions related to the analysis of Aboriginal song language; requirements for morpheme glossing, component package, interpretations, prose and song text comparison, separation of Indigenous and ethnographic explanations, candour about collection methods, limitations and interpretative origins.maps, colour photographs, tablesyolgnu, wadeye, music and culture

The history of spectacles The earliest form of spectacles are generally agreed to have been invented in Northern Italy in the thirteenth century. Over hundreds of years of innovation and refinement, they have been perfected into the stylish and functional designs you see today worn by millions of people to correct their eyesight. Here's a look at the key moments that defined the history of spectacles. Thirteenth century - Rivet spectacles The earliest form of spectacles was simply two mounted lenses riveted together at the handle ends. They had no sides and were secured to the face by clamping the nose between the rims, some of which had notches which may have been intended to improve the grip. Even then the wearer could only keep them in place by remaining relatively still and would normally support them with the hand. These spectacles contained convex lenses for the correction of presbyopic long-sightedness and were generally suited only to those few who lived beyond their forties and had the ability to read. Sixteenth century - Nose spectacles Nose spectacles were in more common use by the early sixteenth century. These often had a bow-shaped continuous bridge, almost of a modern appearance, that was sometimes flexible depending upon the material, for example leather or whalebone. The bridge was as much an area to be gripped as to rest on the nose. Spectacles were still usually held in place with the hand whilst being used temporarily for a brief period of reading or close inspection. By now the lenses could be used to correct both long and short sight. The general design changed little through the seventeenth century, though certain refinements increased the flexibility and comfort for some wearers. In some localised areas, notably in Spain, people experimented with ear loops made of string. This allowed them to walk around with their spectacles on. Eighteenth century - Temple glasses Only in the eighteenth century did the first modern eyewear, or ‘glasses’ as we would understand them, start to appear. The lenses might be glass, rock crystal or any other transparent mineral substance and were prone to smashing if the spectacles fell off, so there was an impetus to develop frames that could be worn continuously and would stay in place. London optician Edward Scarlett is credited with developing the modern style of spectacles which were kept in place with arms, known as ‘temples’. These were made of iron or steel and gripped the side of the head but did not yet hook over the ears because often the ears were concealed beneath a powdered wig, such as was fashionable at the time. As temples developed they were made with wide ring ends through which the wearer could pass a ribbon, thus tying the spectacles securely to the head. As spectacles were no longer primarily for use in sedentary activities, people began to be noticed out and about in their spectacles and might come to be identified as a ‘spectacle wearer’. By the end of the eighteenth century, people who needed correction for both distance and near could choose bifocals. Nineteenth century - Pince-nez Pince-nez were a nineteenth century innovation that literally translates as ‘pinching the nose’. They had a spring clip to retain the item in place under its own tension. Sometimes this clip was too tight and the wearer struggled to breathe. If it was too loose the pince-nez could fall off so, for safety and security, they were often connected to the wearer's clothing by a cord or a chain to avoid them being dropped or lost. Pince-nez were sometimes chosen by people who felt that large spectacles were too prominent and drew attention to a physical defect. They were also suitable for mounting lenses that could correct astigmatism. Twentieth century spectacles Spectacle wearing continued to become more widespread, key developments being the supply of spectacles to troops in the First World War, cheaper spectacles being subsidised through insurance schemes arranged by friendly societies, and the beginning of the National Health Service in 1948, when free spectacles were made available to all who might benefit from them. This normalised spectacle wearing and led to a significant increase in the scale of production. Entirely separate categories of women’s spectacles and sports eyewear both emerged in the 1930s. The latter half of the twentieth century saw spectacles become more fashionable and stylish as frames with different shapes, materials, and colours became available. Plastics frames, in particular, allowed a greater choice of colours and textured finishes. Plastic lenses were more durable and could be made lighter and thinner than glass, spurring a renewed interest in rimless designs. Designer eyewear bearing popular high-street brand names encouraged patients to regard spectacles as a desirable commodity, even as a fashion accessory, not just a disability aid. https://www.college-optometrists.org/the-british-optical-association-museum/the-history-of-spectacles These spectacles and case were used by Dr. Angus in his surgery in Warrnambool to test patients' eye sight. They were donated to Flagstaff Hill Maritime Village by the family of Doctor William Roy Angus, Surgeon and Oculist. It is part of the “W.R. Angus Collection” that includes historical medical equipment, surgical instruments and material once belonging to Dr Edward Ryan and Dr Thomas Francis Ryan, (both of Nhill, Victoria) as well as Dr Angus’ own belongings. The Collection’s history spans the medical practices of the two Doctors Ryan, from 1885-1926 plus that of Dr Angus, up until 1969. ABOUT THE “W.R.ANGUS COLLECTION” Doctor William Roy Angus M.B., B.S., Adel., 1923, F.R.C.S. Edin.,1928 (also known as Dr Roy Angus) was born in Murrumbeena, Victoria in 1901 and lived until 1970. He qualified as a doctor in 1923 at University of Adelaide, was Resident Medical Officer at the Royal Adelaide Hospital in 1924 and for a period was house surgeon to Sir (then Mr.) Henry Simpson Newland. Dr Angus was briefly an Assistant to Dr Riddell of Kapunda, then commenced private practice at Curramulka, Yorke Peninsula, SA, where he was physician, surgeon and chemist. In 1926, he was appointed as new Medical Assistant to Dr Thomas Francis Ryan (T.F. Ryan, or Tom), in Nhill, Victoria, where his experiences included radiology and pharmacy. In 1927 he was Acting House Surgeon in Dr Tom Ryan’s absence. Dr Angus had become engaged to Gladys Forsyth and they decided he would take time to further his studies overseas in the UK in 1927. He studied at London University College Hospital and at Edinburgh Royal Infirmary and in 1928, was awarded FRCS (Fellow from the Royal College of Surgeons), Edinburgh. He worked his passage back to Australia as a Ship’s Surgeon on the on the Australian Commonwealth Line’s T.S.S. Largs Bay. Dr Angus married Gladys in 1929, in Ballarat. (They went on to have one son (Graham 1932, born in SA) and two daughters (Helen (died 12/07/1996) and Berenice (Berry), both born at Mira, Nhill ) Dr Angus was a ‘flying doctor’ for the A.I.M. (Australian Inland Ministry) Aerial Medical Service in 1928 . The organisation began in South Australia through the Presbyterian Church in that year, with its first station being in the remote town of Oodnadatta, where Dr Angus was stationed. He was locum tenens there on North-South Railway at 21 Mile Camp. He took up this ‘flying doctor’ position in response to a call from Dr John Flynn; the organisation was later known as the Flying Doctor Service, then the Royal Flying Doctor Service. A lot of his work during this time involved dental surgery also. Between 1928-1932 he was surgeon at the Curramulka Hospital, Yorke Peninsula, South Australia. In 1933 Dr Angus returned to Nhill where he’d previously worked as Medical Assistant and purchased a share of the Nelson Street practice and Mira hospital from Dr Les Middleton one of the Middleton Brothers, the current owners of what was once Dr Tom Ryan’s practice. Dr L Middleton was House Surgeon to the Nhill Hospital 1926-1933, when he resigned. [Dr Tom Ryan’s practice had originally belonged to his older brother Dr Edward Ryan, who came to Nhill in 1885. Dr Edward saw patients at his rooms, firstly in Victoria Street and in 1886 in Nelson Street, until 1901. The Nelson Street practice also had a 2 bed ward, called Mira Private Hospital ). Dr Edward Ryan was House Surgeon at the Nhill Hospital 1884-1902 . He also had occasions where he successfully performed veterinary surgery for the local farmers too. Dr Tom Ryan then purchased the practice from his brother in 1901. Both Dr Edward and Dr Tom Ryan work as surgeons included eye surgery. Dr Tom Ryan performed many of his operations in the Mira private hospital on his premises. He too was House Surgeon at the Nhill Hospital 1902-1926. Dr Tom Ryan had one of the only two pieces of radiology equipment in Victoria during his practicing years – The Royal Melbourne Hospital had the other one. Over the years Dr Tom Ryan gradually set up what was effectively a training school for country general-practitioner-surgeons. Each patient was carefully examined, including using the X-ray machine, and any surgery was discussed and planned with Dr Ryan’s assistants several days in advance. Dr Angus gained experience in using the X-ray machine there during his time as assistant to Dr Ryan. Dr Tom Ryan moved from Nhill in 1926. He became a Fellow of the Royal Australasian College of Surgeons in 1927, soon after its formation, a rare accolade for a doctor outside any of the major cities. He remained a bachelor and died suddenly on 7th Dec 1955, aged 91, at his home in Ararat. Scholarships and prizes are still awarded to medical students in the honour of Dr T.F. Ryan and his father, Dr Michael Ryan, and brother, John Patrick Ryan. ] When Dr Angus bought into the Nelson Street premises in Nhill he was also appointed as the Nhill Hospital’s Honorary House Surgeon 1933-1938. His practitioner’s plate from his Nhill surgery states “HOURS Daily, except Tuesdays, Fridays and Saturday afternoons, 9-10am, 2-4pm, 7-8pm. Sundays by appointment”. This plate is now mounted on the doorway to the Port Medical Office at Flagstaff Hill Maritime Village, Warrnambool. Dr Edward Ryan and Dr Tom Ryan had an extensive collection of historical medical equipment and materials spanning 1884-1926 and when Dr Angus took up practice in their old premises he obtained this collection, a large part of which is now on display at the Port Medical Office at Flagstaff Hill Maritime Village in Warrnambool. During his time in Nhill Dr Angus was involved in the merging of the Mira Hospital and Nhill Public Hospital into one public hospital and the property titles passed on to Nhill Hospital in 1939. In 1939 Dr Angus and his family moved to Warrnambool where he purchased “Birchwood,” the 1852 home and medical practice of Dr John Hunter Henderson, at 214 Koroit Street. (This property was sold in1965 to the State Government and is now the site of the Warrnambool Police Station. ). The Angus family was able to afford gardeners, cooks and maids; their home was a popular place for visiting dignitaries to stay whilst visiting Warrnambool. Dr Angus had his own silk worm farm at home in a Mulberry tree. His young daughter used his centrifuge for spinning the silk. Dr Angus was appointed on a part-time basis as Port Medical Officer (Health Officer) in Warrnambool and held this position until the 1940’s when the government no longer required the service of a Port Medical Officer in Warrnambool; he was thus Warrnambool’s last serving Port Medical Officer. (The duties of a Port Medical Officer were outlined by the Colonial Secretary on 21st June, 1839 under the terms of the Quarantine Act. Masters of immigrant ships arriving in port reported incidents of diseases, illness and death and the Port Medical Officer made a decision on whether the ship required Quarantine and for how long, in this way preventing contagious illness from spreading from new immigrants to the residents already in the colony.) Dr Angus was a member of the Australian Medical Association, for 35 years and surgeon at the Warrnambool Base Hospital 1939-1942, He served as a Surgeon Captain during WWII 1941-45, in Ballarat, Victoria, and in Bonegilla, N.S.W., completing his service just before the end of the war due to suffering from a heart attack. During his convalescence he carved an intricate and ‘most artistic’ chess set from the material that dentures were made from. He then studied ophthalmology at the Royal Melbourne Eye and Ear Hospital and created cosmetically superior artificial eyes by pioneering using the intrascleral cartilage. Angus received accolades from the Ophthalmological Society of Australasia for this work. He returned to Warrnambool to commence practice as an ophthalmologist, pioneering in artificial eye improvements. He was Honorary Consultant Ophthalmologist to Warrnambool Base Hospital for 31 years. He made monthly visits to Portland as a visiting surgeon, to perform eye surgery. He represented the Victorian South-West subdivision of the Australian Medical Association as its secretary between 1949 and 1956 and as chairman from 1956 to 1958. In 1968 Dr Angus was elected member of Spain’s Barraquer Institute of Barcelona after his research work in Intrasclearal cartilage grafting, becoming one of the few Australian ophthalmologists to receive this honour, and in the following year presented his final paper on Living Intrasclearal Cartilage Implants at the Inaugural Meeting of the Australian College of Ophthalmologists in Melbourne In his personal life Dr Angus was a Presbyterian and treated Sunday as a Sabbath, a day of rest. He would visit 3 or 4 country patients on a Sunday, taking his children along ‘for the ride’ and to visit with him. Sunday evenings he would play the pianola and sing Scottish songs to his family. One of Dr Angus’ patients was Margaret MacKenzie, author of a book on local shipwrecks that she’d seen as an eye witness from the late 1880’s in Peterborough, Victoria. In the early 1950’s Dr Angus, painted a picture of a shipwreck for the cover jacket of Margaret’s book, Shipwrecks and More Shipwrecks. She was blind in later life and her daughter wrote the actual book for her. Dr Angus and his wife Gladys were very involved in Warrnambool’s society with a strong interest in civic affairs. Their interests included organisations such as Red Cross, Rostrum, Warrnambool and District Historical Society (founding members), Wine and Food Society, Steering Committee for Tertiary Education in Warrnambool, Local National Trust, Good Neighbour Council, Housing Commission Advisory Board, United Services Institute, Legion of Ex-Servicemen, Olympic Pool Committee, Food for Britain Organisation, Warrnambool Hospital, Anti-Cancer Council, Boys’ Club, Charitable Council, National Fitness Council and Air Raid Precautions Group. He was also a member of the Steam Preservation Society and derived much pleasure from a steam traction engine on his farm. He had an interest in people and the community He and his wife Gladys were both involved in the creation of Flagstaff Hill, including the layout of the gardens. After his death (28th March 1970) his family requested his practitioner’s plate, medical instruments and some personal belongings be displayed in the Port Medical Office surgery at Flagstaff Hill Maritime Village, and be called the “W. R. Angus Collection”. The W.R. Angus Collection is significant for still being located at the site it is connected with, Doctor Angus being the last Port Medical Officer in Warrnambool. The collection of medical instruments and other equipment is culturally significant, being an historical example of medicine from late 19th to mid-20th century. Dr Angus assisted Dr Tom Ryan, a pioneer in the use of X-rays and in ocular surgery. Spectacles and case, from the W.R. Angus Collection and used by Dr. Angus for testing the sight of his patients. Black rimmed spectacles in tan, open ended pouch. Inscription is stamped into frame and printed in gold lettering on the case. c. 1969 Inscriptions read on spectacles;“52 (square) 18” and “RODENSTOCK > ELBA < 130“ and printed in gold lettering on the pouch “DOBBIE BROS. / OPTOMETRISTS & OPTICIANS / 173 EXHIBITION ST. MELBOURNE”flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, dr w r angus, dr ryan, surgical instrument, t.s.s. largs bay, warrnambool base hospital, nhill base hospital, mira hospital, flying doctor, medical treatment, spectacles and case, optical testing, optometrist examination, dobbie bros melbourne

The history of spectacles The earliest form of spectacles are generally agreed to have been invented in Northern Italy in the thirteenth century. Over hundreds of years of innovation and refinement, they have been perfected into the stylish and functional designs you see today worn by millions of people to correct their eyesight. Here's a look at the key moments that defined the history of spectacles. Thirteenth century - Rivet spectacles The earliest form of spectacles was simply two mounted lenses riveted together at the handle ends. They had no sides and were secured to the face by clamping the nose between the rims, some of which had notches which may have been intended to improve the grip. Even then the wearer could only keep them in place by remaining relatively still and would normally support them with the hand. These spectacles contained convex lenses for the correction of presbyopic long-sightedness and were generally suited only to those few who lived beyond their forties and had the ability to read. Sixteenth century - Nose spectacles Nose spectacles were in more common use by the early sixteenth century. These often had a bow-shaped continuous bridge, almost of a modern appearance, that was sometimes flexible depending upon the material, for example leather or whalebone. The bridge was as much an area to be gripped as to rest on the nose. Spectacles were still usually held in place with the hand whilst being used temporarily for a brief period of reading or close inspection. By now the lenses could be used to correct both long and short sight. The general design changed little through the seventeenth century, though certain refinements increased the flexibility and comfort for some wearers. In some localised areas, notably in Spain, people experimented with ear loops made of string. This allowed them to walk around with their spectacles on. Eighteenth century - Temple glasses Only in the eighteenth century did the first modern eyewear, or ‘glasses’ as we would understand them, start to appear. The lenses might be glass, rock crystal or any other transparent mineral substance and were prone to smashing if the spectacles fell off, so there was an impetus to develop frames that could be worn continuously and would stay in place. London optician Edward Scarlett is credited with developing the modern style of spectacles which were kept in place with arms, known as ‘temples’. These were made of iron or steel and gripped the side of the head but did not yet hook over the ears because often the ears were concealed beneath a powdered wig, such as was fashionable at the time. As temples developed they were made with wide ring ends through which the wearer could pass a ribbon, thus tying the spectacles securely to the head. As spectacles were no longer primarily for use in sedentary activities, people began to be noticed out and about in their spectacles and might come to be identified as a ‘spectacle wearer’. By the end of the eighteenth century, people who needed correction for both distance and near could choose bifocals. Nineteenth century - Pince-nez Pince-nez were a nineteenth century innovation that literally translates as ‘pinching the nose’. They had a spring clip to retain the item in place under its own tension. Sometimes this clip was too tight and the wearer struggled to breathe. If it was too loose the pince-nez could fall off so, for safety and security, they were often connected to the wearer's clothing by a cord or a chain to avoid them being dropped or lost. Pince-nez were sometimes chosen by people who felt that large spectacles were too prominent and drew attention to a physical defect. They were also suitable for mounting lenses that could correct astigmatism. Twentieth century spectacles Spectacle wearing continued to become more widespread, key developments being the supply of spectacles to troops in the First World War, cheaper spectacles being subsidised through insurance schemes arranged by friendly societies, and the beginning of the National Health Service in 1948, when free spectacles were made available to all who might benefit from them. This normalised spectacle wearing and led to a significant increase in the scale of production. Entirely separate categories of women’s spectacles and sports eyewear both emerged in the 1930s. The latter half of the twentieth century saw spectacles become more fashionable and stylish as frames with different shapes, materials, and colours became available. Plastics frames, in particular, allowed a greater choice of colours and textured finishes. Plastic lenses were more durable and could be made lighter and thinner than glass, spurring a renewed interest in rimless designs. Designer eyewear bearing popular high-street brand names encouraged patients to regard spectacles as a desirable commodity, even as a fashion accessory, not just a disability aid. https://www.college-optometrists.org/the-british-optical-association-museum/the-history-of-spectacles The company Optical Prescription Spectacle Makers (OPSM ) was formed in Sydney in 1932 and publically listed in 1953. These spectacles and case were used by Dr. Angus when testing patients' eyes. The spectacles and case were donated to Flagstaff Hill Maritime Village by the family of Doctor William Roy Angus, Surgeon and Oculist. It is part of the “W.R. Angus Collection” that includes historical medical equipment, surgical instruments and material once belonging to Dr Edward Ryan and Dr Thomas Francis Ryan, (both of Nhill, Victoria) as well as Dr Angus’ own belongings. The Collection’s history spans the medical practices of the two Doctors Ryan, from 1885-1926 plus that of Dr Angus, up until 1969. ABOUT THE “W.R.ANGUS COLLECTION” Doctor William Roy Angus M.B., B.S., Adel., 1923, F.R.C.S. Edin.,1928 (also known as Dr Roy Angus) was born in Murrumbeena, Victoria in 1901 and lived until 1970. He qualified as a doctor in 1923 at University of Adelaide, was Resident Medical Officer at the Royal Adelaide Hospital in 1924 and for a period was house surgeon to Sir (then Mr.) Henry Simpson Newland. Dr Angus was briefly an Assistant to Dr Riddell of Kapunda, then commenced private practice at Curramulka, Yorke Peninsula, SA, where he was physician, surgeon and chemist. In 1926, he was appointed as new Medical Assistant to Dr Thomas Francis Ryan (T.F. Ryan, or Tom), in Nhill, Victoria, where his experiences included radiology and pharmacy. In 1927 he was Acting House Surgeon in Dr Tom Ryan’s absence. Dr Angus had become engaged to Gladys Forsyth and they decided he would take time to further his studies overseas in the UK in 1927. He studied at London University College Hospital and at Edinburgh Royal Infirmary and in 1928, was awarded FRCS (Fellow from the Royal College of Surgeons), Edinburgh. He worked his passage back to Australia as a Ship’s Surgeon on the on the Australian Commonwealth Line’s T.S.S. Largs Bay. Dr Angus married Gladys in 1929, in Ballarat. (They went on to have one son (Graham 1932, born in SA) and two daughters (Helen (died 12/07/1996) and Berenice (Berry), both born at Mira, Nhill ) Dr Angus was a ‘flying doctor’ for the A.I.M. (Australian Inland Ministry) Aerial Medical Service in 1928 . The organisation began in South Australia through the Presbyterian Church in that year, with its first station being in the remote town of Oodnadatta, where Dr Angus was stationed. He was locum tenens there on North-South Railway at 21 Mile Camp. He took up this ‘flying doctor’ position in response to a call from Dr John Flynn; the organisation was later known as the Flying Doctor Service, then the Royal Flying Doctor Service. A lot of his work during this time involved dental surgery also. Between 1928-1932 he was surgeon at the Curramulka Hospital, Yorke Peninsula, South Australia. In 1933 Dr Angus returned to Nhill where he’d previously worked as Medical Assistant and purchased a share of the Nelson Street practice and Mira hospital from Dr Les Middleton one of the Middleton Brothers, the current owners of what was once Dr Tom Ryan’s practice. Dr L Middleton was House Surgeon to the Nhill Hospital 1926-1933, when he resigned. [Dr Tom Ryan’s practice had originally belonged to his older brother Dr Edward Ryan, who came to Nhill in 1885. Dr Edward saw patients at his rooms, firstly in Victoria Street and in 1886 in Nelson Street, until 1901. The Nelson Street practice also had a 2 bed ward, called Mira Private Hospital ). Dr Edward Ryan was House Surgeon at the Nhill Hospital 1884-1902 . He also had occasions where he successfully performed veterinary surgery for the local farmers too. Dr Tom Ryan then purchased the practice from his brother in 1901. Both Dr Edward and Dr Tom Ryan work as surgeons included eye surgery. Dr Tom Ryan performed many of his operations in the Mira private hospital on his premises. He too was House Surgeon at the Nhill Hospital 1902-1926. Dr Tom Ryan had one of the only two pieces of radiology equipment in Victoria during his practicing years – The Royal Melbourne Hospital had the other one. Over the years Dr Tom Ryan gradually set up what was effectively a training school for country general-practitioner-surgeons. Each patient was carefully examined, including using the X-ray machine, and any surgery was discussed and planned with Dr Ryan’s assistants several days in advance. Dr Angus gained experience in using the X-ray machine there during his time as assistant to Dr Ryan. Dr Tom Ryan moved from Nhill in 1926. He became a Fellow of the Royal Australasian College of Surgeons in 1927, soon after its formation, a rare accolade for a doctor outside any of the major cities. He remained a bachelor and died suddenly on 7th Dec 1955, aged 91, at his home in Ararat. Scholarships and prizes are still awarded to medical students in the honour of Dr T.F. Ryan and his father, Dr Michael Ryan, and brother, John Patrick Ryan. ] When Dr Angus bought into the Nelson Street premises in Nhill he was also appointed as the Nhill Hospital’s Honorary House Surgeon 1933-1938. His practitioner’s plate from his Nhill surgery states “HOURS Daily, except Tuesdays, Fridays and Saturday afternoons, 9-10am, 2-4pm, 7-8pm. Sundays by appointment”. This plate is now mounted on the doorway to the Port Medical Office at Flagstaff Hill Maritime Village, Warrnambool. Dr Edward Ryan and Dr Tom Ryan had an extensive collection of historical medical equipment and materials spanning 1884-1926 and when Dr Angus took up practice in their old premises he obtained this collection, a large part of which is now on display at the Port Medical Office at Flagstaff Hill Maritime Village in Warrnambool. During his time in Nhill Dr Angus was involved in the merging of the Mira Hospital and Nhill Public Hospital into one public hospital and the property titles passed on to Nhill Hospital in 1939. In 1939 Dr Angus and his family moved to Warrnambool where he purchased “Birchwood,” the 1852 home and medical practice of Dr John Hunter Henderson, at 214 Koroit Street. (This property was sold in1965 to the State Government and is now the site of the Warrnambool Police Station. ). The Angus family was able to afford gardeners, cooks and maids; their home was a popular place for visiting dignitaries to stay whilst visiting Warrnambool. Dr Angus had his own silk worm farm at home in a Mulberry tree. His young daughter used his centrifuge for spinning the silk. Dr Angus was appointed on a part-time basis as Port Medical Officer (Health Officer) in Warrnambool and held this position until the 1940’s when the government no longer required the service of a Port Medical Officer in Warrnambool; he was thus Warrnambool’s last serving Port Medical Officer. (The duties of a Port Medical Officer were outlined by the Colonial Secretary on 21st June, 1839 under the terms of the Quarantine Act. Masters of immigrant ships arriving in port reported incidents of diseases, illness and death and the Port Medical Officer made a decision on whether the ship required Quarantine and for how long, in this way preventing contagious illness from spreading from new immigrants to the residents already in the colony.) Dr Angus was a member of the Australian Medical Association, for 35 years and surgeon at the Warrnambool Base Hospital 1939-1942, He served as a Surgeon Captain during WWII 1941-45, in Ballarat, Victoria, and in Bonegilla, N.S.W., completing his service just before the end of the war due to suffering from a heart attack. During his convalescence he carved an intricate and ‘most artistic’ chess set from the material that dentures were made from. He then studied ophthalmology at the Royal Melbourne Eye and Ear Hospital and created cosmetically superior artificial eyes by pioneering using the intrascleral cartilage. Angus received accolades from the Ophthalmological Society of Australasia for this work. He returned to Warrnambool to commence practice as an ophthalmologist, pioneering in artificial eye improvements. He was Honorary Consultant Ophthalmologist to Warrnambool Base Hospital for 31 years. He made monthly visits to Portland as a visiting surgeon, to perform eye surgery. He represented the Victorian South-West subdivision of the Australian Medical Association as its secretary between 1949 and 1956 and as chairman from 1956 to 1958. In 1968 Dr Angus was elected member of Spain’s Barraquer Institute of Barcelona after his research work in Intrasclearal cartilage grafting, becoming one of the few Australian ophthalmologists to receive this honour, and in the following year presented his final paper on Living Intrasclearal Cartilage Implants at the Inaugural Meeting of the Australian College of Ophthalmologists in Melbourne In his personal life Dr Angus was a Presbyterian and treated Sunday as a Sabbath, a day of rest. He would visit 3 or 4 country patients on a Sunday, taking his children along ‘for the ride’ and to visit with him. Sunday evenings he would play the pianola and sing Scottish songs to his family. One of Dr Angus’ patients was Margaret MacKenzie, author of a book on local shipwrecks that she’d seen as an eye witness from the late 1880’s in Peterborough, Victoria. In the early 1950’s Dr Angus, painted a picture of a shipwreck for the cover jacket of Margaret’s book, Shipwrecks and More Shipwrecks. She was blind in later life and her daughter wrote the actual book for her. Dr Angus and his wife Gladys were very involved in Warrnambool’s society with a strong interest in civic affairs. Their interests included organisations such as Red Cross, Rostrum, Warrnambool and District Historical Society (founding members), Wine and Food Society, Steering Committee for Tertiary Education in Warrnambool, Local National Trust, Good Neighbour Council, Housing Commission Advisory Board, United Services Institute, Legion of Ex-Servicemen, Olympic Pool Committee, Food for Britain Organisation, Warrnambool Hospital, Anti-Cancer Council, Boys’ Club, Charitable Council, National Fitness Council and Air Raid Precautions Group. He was also a member of the Steam Preservation Society and derived much pleasure from a steam traction engine on his farm. He had an interest in people and the community He and his wife Gladys were both involved in the creation of Flagstaff Hill, including the layout of the gardens. After his death (28th March 1970) his family requested his practitioner’s plate, medical instruments and some personal belongings be displayed in the Port Medical Office surgery at Flagstaff Hill Maritime Village, and be called the “W. R. Angus Collection”. The W.R. Angus Collection is significant for still being located at the site it is connected with, Doctor Angus being the last Port Medical Officer in Warrnambool. The collection of medical instruments and other equipment is culturally significant, being an historical example of medicine from late 19th to mid-20th century. Dr Angus assisted Dr Tom Ryan, a pioneer in the use of X-rays and in ocular surgery. Spectacles and case, from the W.R. Angus Collection and used by Dr. Angus testing the sight of his patients. Metal case covered in red leather, black velvet lining. Tan rimmed spectacles. Maker is OPSM. Inscriptions on case, inside case and on spectacle rim.Inscribed on spectacle arms “CONTORA”. Inscription on case in gold print “OPSM Optical Prescription Spectacle Makers Pty Ltd”. Inscription on white oval label inside case is illegible. flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, dr w r angus, spectacles and case, optical testing, optometrist examination, opsm optical prescription spectacle makers

The history of spectacles The earliest form of spectacles are generally agreed to have been invented in Northern Italy in the thirteenth century. Over hundreds of years of innovation and refinement, they have been perfected into the stylish and functional designs you see today worn by millions of people to correct their eyesight. Here's a look at the key moments that defined the history of spectacles. Thirteenth century - Rivet spectacles The earliest form of spectacles was simply two mounted lenses riveted together at the handle ends. They had no sides and were secured to the face by clamping the nose between the rims, some of which had notches which may have been intended to improve the grip. Even then the wearer could only keep them in place by remaining relatively still and would normally support them with the hand. These spectacles contained convex lenses for the correction of presbyopic long-sightedness and were generally suited only to those few who lived beyond their forties and had the ability to read. Sixteenth century - Nose spectacles Nose spectacles were in more common use by the early sixteenth century. These often had a bow-shaped continuous bridge, almost of a modern appearance, that was sometimes flexible depending upon the material, for example leather or whalebone. The bridge was as much an area to be gripped as to rest on the nose. Spectacles were still usually held in place with the hand whilst being used temporarily for a brief period of reading or close inspection. By now the lenses could be used to correct both long and short sight. The general design changed little through the seventeenth century, though certain refinements increased the flexibility and comfort for some wearers. In some localised areas, notably in Spain, people experimented with ear loops made of string. This allowed them to walk around with their spectacles on. Eighteenth century - Temple glasses Only in the eighteenth century did the first modern eyewear, or ‘glasses’ as we would understand them, start to appear. The lenses might be glass, rock crystal or any other transparent mineral substance and were prone to smashing if the spectacles fell off, so there was an impetus to develop frames that could be worn continuously and would stay in place. London optician Edward Scarlett is credited with developing the modern style of spectacles which were kept in place with arms, known as ‘temples’. These were made of iron or steel and gripped the side of the head but did not yet hook over the ears because often the ears were concealed beneath a powdered wig, such as was fashionable at the time. As temples developed they were made with wide ring ends through which the wearer could pass a ribbon, thus tying the spectacles securely to the head. As spectacles were no longer primarily for use in sedentary activities, people began to be noticed out and about in their spectacles and might come to be identified as a ‘spectacle wearer’. By the end of the eighteenth century, people who needed correction for both distance and near could choose bifocals. Nineteenth century - Pince-nez Pince-nez were a nineteenth century innovation that literally translates as ‘pinching the nose’. They had a spring clip to retain the item in place under its own tension. Sometimes this clip was too tight and the wearer struggled to breathe. If it was too loose the pince-nez could fall off so, for safety and security, they were often connected to the wearer's clothing by a cord or a chain to avoid them being dropped or lost. Pince-nez were sometimes chosen by people who felt that large spectacles were too prominent and drew attention to a physical defect. They were also suitable for mounting lenses that could correct astigmatism. Twentieth century spectacles Spectacle wearing continued to become more widespread, key developments being the supply of spectacles to troops in the First World War, cheaper spectacles being subsidised through insurance schemes arranged by friendly societies, and the beginning of the National Health Service in 1948, when free spectacles were made available to all who might benefit from them. This normalised spectacle wearing and led to a significant increase in the scale of production. Entirely separate categories of women’s spectacles and sports eyewear both emerged in the 1930s. The latter half of the twentieth century saw spectacles become more fashionable and stylish as frames with different shapes, materials, and colours became available. Plastics frames, in particular, allowed a greater choice of colours and textured finishes. Plastic lenses were more durable and could be made lighter and thinner than glass, spurring a renewed interest in rimless designs. Designer eyewear bearing popular high-street brand names encouraged patients to regard spectacles as a desirable commodity, even as a fashion accessory, not just a disability aid. https://www.college-optometrists.org/the-british-optical-association-museum/the-history-of-spectacles These spectacles and case from F.G. and R.G. Bennett of Warrnambool were used by Dr. Angus to test his patients' eye sight. They were donated to Flagstaff Hill Maritime Village by the family of Doctor William Roy Angus, Surgeon and Oculist. It is part of the “W.R. Angus Collection” that includes historical medical equipment, surgical instruments and material once belonging to Dr Edward Ryan and Dr Thomas Francis Ryan, (both of Nhill, Victoria) as well as Dr Angus’ own belongings. The Collection’s history spans the medical practices of the two Doctors Ryan, from 1885-1926 plus that of Dr Angus, up until 1969. ABOUT THE “W.R.ANGUS COLLECTION” Doctor William Roy Angus M.B., B.S., Adel., 1923, F.R.C.S. Edin.,1928 (also known as Dr Roy Angus) was born in Murrumbeena, Victoria in 1901 and lived until 1970. He qualified as a doctor in 1923 at University of Adelaide, was Resident Medical Officer at the Royal Adelaide Hospital in 1924 and for a period was house surgeon to Sir (then Mr.) Henry Simpson Newland. Dr Angus was briefly an Assistant to Dr Riddell of Kapunda, then commenced private practice at Curramulka, Yorke Peninsula, SA, where he was physician, surgeon and chemist. In 1926, he was appointed as new Medical Assistant to Dr Thomas Francis Ryan (T.F. Ryan, or Tom), in Nhill, Victoria, where his experiences included radiology and pharmacy. In 1927 he was Acting House Surgeon in Dr Tom Ryan’s absence. Dr Angus had become engaged to Gladys Forsyth and they decided he would take time to further his studies overseas in the UK in 1927. He studied at London University College Hospital and at Edinburgh Royal Infirmary and in 1928, was awarded FRCS (Fellow from the Royal College of Surgeons), Edinburgh. He worked his passage back to Australia as a Ship’s Surgeon on the on the Australian Commonwealth Line’s T.S.S. Largs Bay. Dr Angus married Gladys in 1929, in Ballarat. (They went on to have one son (Graham 1932, born in SA) and two daughters (Helen (died 12/07/1996) and Berenice (Berry), both born at Mira, Nhill ) Dr Angus was a ‘flying doctor’ for the A.I.M. (Australian Inland Ministry) Aerial Medical Service in 1928 . The organisation began in South Australia through the Presbyterian Church in that year, with its first station being in the remote town of Oodnadatta, where Dr Angus was stationed. He was locum tenens there on North-South Railway at 21 Mile Camp. He took up this ‘flying doctor’ position in response to a call from Dr John Flynn; the organisation was later known as the Flying Doctor Service, then the Royal Flying Doctor Service. A lot of his work during this time involved dental surgery also. Between 1928-1932 he was surgeon at the Curramulka Hospital, Yorke Peninsula, South Australia. In 1933 Dr Angus returned to Nhill where he’d previously worked as Medical Assistant and purchased a share of the Nelson Street practice and Mira hospital from Dr Les Middleton one of the Middleton Brothers, the current owners of what was once Dr Tom Ryan’s practice. Dr L Middleton was House Surgeon to the Nhill Hospital 1926-1933, when he resigned. [Dr Tom Ryan’s practice had originally belonged to his older brother Dr Edward Ryan, who came to Nhill in 1885. Dr Edward saw patients at his rooms, firstly in Victoria Street and in 1886 in Nelson Street, until 1901. The Nelson Street practice also had a 2 bed ward, called Mira Private Hospital ). Dr Edward Ryan was House Surgeon at the Nhill Hospital 1884-1902 . He also had occasions where he successfully performed veterinary surgery for the local farmers too. Dr Tom Ryan then purchased the practice from his brother in 1901. Both Dr Edward and Dr Tom Ryan work as surgeons included eye surgery. Dr Tom Ryan performed many of his operations in the Mira private hospital on his premises. He too was House Surgeon at the Nhill Hospital 1902-1926. Dr Tom Ryan had one of the only two pieces of radiology equipment in Victoria during his practicing years – The Royal Melbourne Hospital had the other one. Over the years Dr Tom Ryan gradually set up what was effectively a training school for country general-practitioner-surgeons. Each patient was carefully examined, including using the X-ray machine, and any surgery was discussed and planned with Dr Ryan’s assistants several days in advance. Dr Angus gained experience in using the X-ray machine there during his time as assistant to Dr Ryan. Dr Tom Ryan moved from Nhill in 1926. He became a Fellow of the Royal Australasian College of Surgeons in 1927, soon after its formation, a rare accolade for a doctor outside any of the major cities. He remained a bachelor and died suddenly on 7th Dec 1955, aged 91, at his home in Ararat. Scholarships and prizes are still awarded to medical students in the honour of Dr T.F. Ryan and his father, Dr Michael Ryan, and brother, John Patrick Ryan. ] When Dr Angus bought into the Nelson Street premises in Nhill he was also appointed as the Nhill Hospital’s Honorary House Surgeon 1933-1938. His practitioner’s plate from his Nhill surgery states “HOURS Daily, except Tuesdays, Fridays and Saturday afternoons, 9-10am, 2-4pm, 7-8pm. Sundays by appointment”. This plate is now mounted on the doorway to the Port Medical Office at Flagstaff Hill Maritime Village, Warrnambool. Dr Edward Ryan and Dr Tom Ryan had an extensive collection of historical medical equipment and materials spanning 1884-1926 and when Dr Angus took up practice in their old premises he obtained this collection, a large part of which is now on display at the Port Medical Office at Flagstaff Hill Maritime Village in Warrnambool. During his time in Nhill Dr Angus was involved in the merging of the Mira Hospital and Nhill Public Hospital into one public hospital and the property titles passed on to Nhill Hospital in 1939. In 1939 Dr Angus and his family moved to Warrnambool where he purchased “Birchwood,” the 1852 home and medical practice of Dr John Hunter Henderson, at 214 Koroit Street. (This property was sold in1965 to the State Government and is now the site of the Warrnambool Police Station. ). The Angus family was able to afford gardeners, cooks and maids; their home was a popular place for visiting dignitaries to stay whilst visiting Warrnambool. Dr Angus had his own silk worm farm at home in a Mulberry tree. His young daughter used his centrifuge for spinning the silk. Dr Angus was appointed on a part-time basis as Port Medical Officer (Health Officer) in Warrnambool and held this position until the 1940’s when the government no longer required the service of a Port Medical Officer in Warrnambool; he was thus Warrnambool’s last serving Port Medical Officer. (The duties of a Port Medical Officer were outlined by the Colonial Secretary on 21st June, 1839 under the terms of the Quarantine Act. Masters of immigrant ships arriving in port reported incidents of diseases, illness and death and the Port Medical Officer made a decision on whether the ship required Quarantine and for how long, in this way preventing contagious illness from spreading from new immigrants to the residents already in the colony.) Dr Angus was a member of the Australian Medical Association, for 35 years and surgeon at the Warrnambool Base Hospital 1939-1942, He served as a Surgeon Captain during WWII 1941-45, in Ballarat, Victoria, and in Bonegilla, N.S.W., completing his service just before the end of the war due to suffering from a heart attack. During his convalescence he carved an intricate and ‘most artistic’ chess set from the material that dentures were made from. He then studied ophthalmology at the Royal Melbourne Eye and Ear Hospital and created cosmetically superior artificial eyes by pioneering using the intrascleral cartilage. Angus received accolades from the Ophthalmological Society of Australasia for this work. He returned to Warrnambool to commence practice as an ophthalmologist, pioneering in artificial eye improvements. He was Honorary Consultant Ophthalmologist to Warrnambool Base Hospital for 31 years. He made monthly visits to Portland as a visiting surgeon, to perform eye surgery. He represented the Victorian South-West subdivision of the Australian Medical Association as its secretary between 1949 and 1956 and as chairman from 1956 to 1958. In 1968 Dr Angus was elected member of Spain’s Barraquer Institute of Barcelona after his research work in Intrasclearal cartilage grafting, becoming one of the few Australian ophthalmologists to receive this honour, and in the following year presented his final paper on Living Intrasclearal Cartilage Implants at the Inaugural Meeting of the Australian College of Ophthalmologists in Melbourne In his personal life Dr Angus was a Presbyterian and treated Sunday as a Sabbath, a day of rest. He would visit 3 or 4 country patients on a Sunday, taking his children along ‘for the ride’ and to visit with him. Sunday evenings he would play the pianola and sing Scottish songs to his family. One of Dr Angus’ patients was Margaret MacKenzie, author of a book on local shipwrecks that she’d seen as an eye witness from the late 1880’s in Peterborough, Victoria. In the early 1950’s Dr Angus, painted a picture of a shipwreck for the cover jacket of Margaret’s book, Shipwrecks and More Shipwrecks. She was blind in later life and her daughter wrote the actual book for her. Dr Angus and his wife Gladys were very involved in Warrnambool’s society with a strong interest in civic affairs. Their interests included organisations such as Red Cross, Rostrum, Warrnambool and District Historical Society (founding members), Wine and Food Society, Steering Committee for Tertiary Education in Warrnambool, Local National Trust, Good Neighbour Council, Housing Commission Advisory Board, United Services Institute, Legion of Ex-Servicemen, Olympic Pool Committee, Food for Britain Organisation, Warrnambool Hospital, Anti-Cancer Council, Boys’ Club, Charitable Council, National Fitness Council and Air Raid Precautions Group. He was also a member of the Steam Preservation Society and derived much pleasure from a steam traction engine on his farm. He had an interest in people and the community He and his wife Gladys were both involved in the creation of Flagstaff Hill, including the layout of the gardens. After his death (28th March 1970) his family requested his practitioner’s plate, medical instruments and some personal belongings be displayed in the Port Medical Office surgery at Flagstaff Hill Maritime Village, and be called the “W. R. Angus Collection”. The W.R. Angus Collection is significant for still being located at the site it is connected with, Doctor Angus being the last Port Medical Officer in Warrnambool. The collection of medical instruments and other equipment is culturally significant, being an historical example of medicine from late 19th to mid-20th century. Dr Angus assisted Dr Tom Ryan, a pioneer in the use of X-rays and in ocular surgery. Spectacles and case, from the W.R. Angus Collection and used by Dr. Angus testing the sight of his patients. Metal case covered in blue leather, blue velvet lining. Orange/yellow rimmed spectacles, one lens covered with cardboard. White oval label inside case. Inscription on case with maker’s details in gold print.Inscription on case reads “F. G. & R. G. BENNETT / WARRNAMBOOL”. flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, dr w r angus, spectacles and case, optical testing, optometrist examination, f.g. and r.g. bennett of warrnambool

The University of Ballarat in 1998 comprised the Mt Helen Campus, SMB (Ballarat School of Mines) Campus and the Horsham Campus. It's current name is Federation University Australia. In 1998 Everyone@UB was a monthly staff newsletter edited by Peter Baird in consultation with Don Moconachie.A series of monthly bulletins covering all University of Ballarat campuses. .1) University merger, John Bailey, Michael Adermann, Vice-Chancellor, Jenny Nemeth, Katherine Birkin, Rowena Coutts, Ballarat Technology Park, Ron Wild .2) Chancellor appointment, Chancellor retirement, Geoffrey Blainey tribute, David Caro, Katherine Birkin, Arno Besse, George Murdoch, Bullarook, Stephen Kemmus, Neville French, ceramics, Tristan Smith, Horsham, Arnhem Land film, Ararat, Kerry Cox, anorexia, salary packages, University of Ballarat Brass Band, Natalie Radomski, becoming a university. Images: Geoffrey Blainey, David Caro, David James, Katherine Birkin, Arno Besse, George Murdoch, Geoffrey Blainey, Stephen Kemmis, Neville French, John Ackland, Richard Jardine, Glen Auld, Dennis Arne, Andrew Kotsonis, Kerry Cox, Suzanne McLaren, Marcia Pope, Rosemary Green, Leonie Otago, Natalie Rodomski .5) October 1998 - Carolyn Taylor, misogyny, Horsham campus building under construction, David Caro, Miranda Kerr, Martin Westbrook, Iain Reid, virtual monitors, teaching practice, Joanne Knight, John Pidgeon, Sally Buckland, arsenic, Ian Rae, Bob Allan, Patricia Cartwright, Matthew Baker, Sundru Sivamalai, Janine Smith, Pat Mann, International Student Market Research, Steve Mennen, Copyright, internet to the outback, Charters Towers, Engineering students, Darryl Dyason, Andrew McDougall, Dianne Jacono, Ross Morgan, Keith Boast, Cranbrook Academy of Art (Detroit), Helmut Stenzel, Mt Helen vegetation, Jan Bedggood, Ann-Maree Haintz, Kathleen Lakey, Adrienne Ryan, Fiona Schmidt. .11) Phil Candy, flexible learning, strategic planning. .12) diving, Reconciliation, Learning City, Student residence, Alex Rubinov, Graduate Centre, Ceramics, horse, Wimmera, tree regeneration, student poverty, UB museum, David Manterfeild, Heather Hatfeild. Redundancy, video conferencing Images: Steve Matthews, Craig Holloway, Peter Pilven, Sneha Kirubakaran, Phil Honeywood, Kerry Cox, David Manterfield, Martin Westbrooke, Ram Karan, Barry Jones, Gael Ramsay, Jenny Hargave, Heather Hatfield. .16) Jeff Kennett, Honorary Doctorate, Technology Park, Mary Atkinson, Ian Wright, Internet, Disability Action Plan, Robert Munt obituary, Sandra Stepcich obituary, Virginia Fenwlon, East Timor, Centre for Environmental Management, Wayne Jolly, 130th anniversary, Craig Hurley, Barry Wemyss, John Murray, Tori Power, Grant Curnow. Images: Vivienne Witwer, Claire Hetherington, Ian Wright, Virginia Fenelin .17) Broadband, AARNet, David James Retirement, wetlands, Debbie Eagles, Centre for Rural and Regional Health, numeracy, nursing, Sue Turale, Max Palmer, Camp Street, Arts Academy, library, SMB scholarship, Landcare, Mallee pipeline, Verna Barry, Alice Mills, Marian Brown, .18) Fiji, Texans, Greenhill, Robert Whitson, Ian Clark, Abororiginal history, Yuille St, Peter Baird, Martin Westrbrook, Robert Allen, Arts Academy, John McGrath, Phil Ruglen, 3BBB, John Ferrier .21) Beverley. Lassiter, Vice-ChAncellor appointment, Kerry Cox, Craig Hurley, Barry Wemyss, Ceramics, Bill Pryor, University Games, Olympics, Broken Hill, Alex Rubinov, Jonathan Halls, Dare to be different, Wayne Muir, Student Union Refit. Images: Wayne Muir, Alex Ruminov, Kerry Cox .22) December 2000 - nursing, David James, Phil Candy, John McLean, Debbie Eagles, brewery, brewing, Meredith Sussex, Lyn Faneco, TAFE,Joy Nunn, ARC, mosaics, Timor, Alfredo Pires, Centre for Rural and Regional Health, diabetes, kangaroos, Murray-Darling, Leagher Homestead, David Welch, Joy Nunn, Jill Blee, Maryanne Coutts, positive discrimination, Theresa Saunders, Imelda Crebbin .23) March 2001 - Nancy Lange, Paul Lambeth, Yvonne Button, Don Pennell, Natalie Radomski, Marcia Pope, McKinnon Walker, Marc Brodie, TAFE, WorldSkills, Horticulture, Ararat, Website, library, Leeanne Pitman, Liz Hartmann, nursing, Miranda Walker, Ciaran Pier, Anxiety Disorders, volcano, brewing, beer, Peter Aldred, Rob Greig, Jeremy Smith, Alice Mills, Geoff Burgess, .24) May 2001 - Graduations, Talia Venn, Stephen Carthew, Honory Doctorate, Steve Monaghetti, Heather Moore, Brendan O'Brien, Bill Pryr, Terry O'Brien, Carole Wilson, Carolyn Taylor, rape law reform, Federation at the Ballarat School of Mines, Work Skills, Debbie Eagles, Sue Purtle, Longerenong, Mohair, Early Childhood, Horsham, Kerry Cox, Willy Hobbs, David Firth, Kim Durban, BAPA, maryanne Coutts, Ewen McDonald, butterflys, Fukuoaka INstitute of Technology, Jane Wilkinson .25) Wayne Robinson, Neil McAdam retirement, Anne Beggs Sunter, nursing, Eileen Sellers, Hannelore Best, international nursing, Francis Adams, copyright, Roy Taylor, Wendy Bolger, unplugged, Horsham, Robert Irvine, Horsham graduations, Anxiety Clinic, Carole Wilson, Heart Mat, University of Ballarat Mission, Diabetes, Emelia Martinez-Brawley. Images include Wayne Robinson, Anne Beggs Sunter, Eileen Sellers, Hannelore Best, Phil Candy. Meg Tasker, Roy Taylor, Wendy Bolger, Robert Irvine, Angus McLachlan, Roger Castleman, Stephen Roberts, Philip Smith, Bob Allen, Rob Greig, Dennis Jeandet, Carole Wilson, Doug Lloyduniversity of ballarat, ballarat school of mines, wetland, broadband, david janes, smb, kennett, leadership, eagles, centre for rural and regional health, microwave, turale, arts academy, camp street, library, landcare, mallee, mallee pipeline, barry, verna barry, mills, brown, palmer, caro, geoffrey blainey, blainey, birkin, besse, kemmis, adermann, ackland, jardine, auld, mclaren, pope, green, otago, radomski, honorary doctorate, munt, stepcich, wemyss, rubinov, muir, everyone@ub, robinson, horsham, stawell, ararat, fukuoaka, taylor, moneghetti, coutt, hatfeild, westbrooke, karan, bailey, james, nemeth, wild, de bono, texas, sharpam, fiji, clark, ruyg, kropp, sugget, baird, allen, westbrook, rural health, stacpoole, mcgrath, ruglen, ferrier, manterfield, pilven, michael adermann, tafe, mount helen vegetation, dennis arne

This lead ingot was donated to Flagstaff Hill Maritime Village in January 2015 by local residents who discovered the ingot in their garden after they purchased the property about 12 months ago The LOCH ARD cargo manifest lists “Pig lead 50 tons” comprising “944 pig and 37 rolls”. Subsequent classification has rendered this section of cargo as “Lead Ballast”. This could be true. The international price per ton of lead ore plunged from a high point of £17 in 1853 to a low of £8 in 1882. The cheaper price of lead at the time of the vessel’s loading in early 1878 may have meant it was considered as an alternative to other ballast material (traditionally stone) for the journey to Melbourne. Loch Line ships generally returned to Britain laden with Australian wool. Even though wool bales were “screwed in” to the hold to less than half their “pressed weight”, they still made an awkwardly light cargo for the passage around the Horn. The concentrated weight of lead pigs along the keel line would help steady and centre the ship, and perhaps the artefacts in this case were to be retained for this purpose, rather than being sold on to the ready colonial market. However this is conjecture. Demand for building materials in the gold and wool rich Colony of Victoria was high in the 1870s, and much of the LOCH ARD cargo was intended for the Melbourne International Exhibition in 1880, which was another example of buoyant economic conditions. In the nineteenth century lead was valued for its density (high ratio of weight to volume), flexibility (relative softness for working into shape), and durability (corrosion resistant and waterproofing properties). It was used for pipes and water tanks, roof flashing and guttering, window sealing and internal plumbing. Many large private residences and new public buildings were at planning or construction stage in the colony during this period. The LOCH ARD lead ingots could equally have been destined for this ready market. HISTORY OF THE LOCH ARD The LOCH ARD belonged to the famous Loch Line which sailed many ships from England to Australia. Built in Glasgow by Barclay, Curdle and Co. in 1873, the LOCH ARD was a three-masted square rigged iron sailing ship. The ship measured 262ft 7" (79.87m) in length, 38ft (11.58m) in width, 23ft (7m) in depth and had a gross tonnage of 1693 tons. The LOCH ARD's main mast measured a massive 150ft (45.7m) in height. LOCH ARD made three trips to Australia and one trip to Calcutta before its final voyage. LOCH ARD left England on March 2, 1878, under the command of Captain Gibbs, a newly married, 29 year old. She was bound for Melbourne with a crew of 37, plus 17 passengers and a load of cargo. The general cargo reflected the affluence of Melbourne at the time. On board were straw hats, umbrella, perfumes, clay pipes, pianos, clocks, confectionary, linen and candles, as well as a heavier load of railway irons, cement, lead and copper. There were items included that intended for display in the Melbourne International Exhibition in 1880. The voyage to Port Phillip was long but uneventful. At 3am on June 1, 1878, Captain Gibbs was expecting to see land and the passengers were becoming excited as they prepared to view their new homeland in the early morning. But LOCH ARD was running into a fog which greatly reduced visibility. Captain Gibbs was becoming anxious as there was no sign of land or the Cape Otway lighthouse. At 4am the fog lifted. A man aloft announced that he could see breakers. The sheer cliffs of Victoria's west coast came into view, and Captain Gibbs realised that the ship was much closer to them than expected. He ordered as much sail to be set as time would permit and then attempted to steer the vessel out to sea. On coming head on into the wind, the ship lost momentum, the sails fell limp and LOCH ARD's bow swung back. Gibbs then ordered the anchors to be released in an attempt to hold its position. The anchors sank some 50 fathoms - but did not hold. By this time LOCH ARD was among the breakers and the tall cliffs of Mutton Bird Island rose behind the ship. Just half a mile from the coast, the ship's bow was suddenly pulled around by the anchor. The captain tried to tack out to sea, but the ship struck a reef at the base of Mutton Bird Island, near Port Campbell. Waves broke over the ship and the top deck was loosened from the hull. The masts and rigging came crashing down knocking passengers and crew overboard. When a lifeboat was finally launched, it crashed into the side of LOCH ARD and capsized. Tom Pearce, who had launched the boat, managed to cling to its overturned hull and shelter beneath it. He drifted out to sea and then on the flood tide came into what is now known as LOCH ARD Gorge. He swam to shore, bruised and dazed, and found a cave in which to shelter. Some of the crew stayed below deck to shelter from the falling rigging but drowned when the ship slipped off the reef into deeper water. Eva Carmichael had raced onto deck to find out what was happening only to be confronted by towering cliffs looming above the stricken ship. In all the chaos, Captain Gibbs grabbed Eva and said, "If you are saved Eva, let my dear wife know that I died like a sailor". That was the last Eva Carmichael saw of the captain. She was swept off the ship by a huge wave. Eva saw Tom Pearce on a small rocky beach and yelled to attract his attention. He dived in and swam to the exhausted woman and dragged her to shore. He took her to the cave and broke open case of brandy which had washed up on the beach. He opened a bottle to revive the unconscious woman. A few hours later Tom scaled a cliff in search of help. He followed hoof prints and came by chance upon two men from nearby Glenample Station three and a half miles away. In a state of exhaustion, he told the men of the tragedy. Tom returned to the gorge while the two men rode back to the station to get help. By the time they reached LOCH ARD Gorge, it was cold and dark. The two shipwreck survivors were taken to Glenample Station to recover. Eva stayed at the station for six weeks before returning to Ireland, this time by steamship. In Melbourne, Tom Pearce received a hero's welcome. He was presented with the first gold medal of the Royal Humane Society of Victoria and a £1000 cheque from the Victorian Government. Concerts were performed to honour the young man's bravery and to raise money for those who lost family in the LOCH ARD disaster. Of the 54 crew members and passengers on board, only two survived: the apprentice, Tom Pearce and the young woman passenger, Eva Carmichael, who lost all of her family in the tragedy. Ten days after the LOCH ARD tragedy, salvage rights to the wreck were sold at auction for £2,120. Cargo valued at £3,000 was salvaged and placed on the beach, but most washed back into the sea when another storm developed. The wreck of LOCH ARD still lies at the base of Mutton Bird Island. Much of the cargo has now been salvaged and some was washed up into what is now known as LOCH ARD Gorge. Cargo and artefacts have also been illegally salvaged over many years before protective legislation was introduced. One of the most unlikely pieces of cargo to have survived the shipwreck was a Minton porcelain peacock - one of only nine in the world. The peacock was destined for the Melbourne International Exhibition in 1880. It had been well packed, which gave it adequate protection during the violent storm. Today, the Minton peacock can be seen at the Flagstaff Hill Maritime Museum in Warrnambool. From Australia's most dramatic shipwreck it has now become Australia's most valuable shipwreck artefact and is one of very few 'objects' on the Victorian State Heritage Register. The shipwreck of the LOCH ARD is of State significance ― Victorian Heritage Register S417 Flagstaff Hill’s collection of artefacts from LOCH ARD is significant for being one of the largest collections of artefacts from this shipwreck in Victoria. It is significant for its association with the shipwreck, which is on the Victorian Heritage Register (VHR S417). The collection is significant because of the relationship between the objects, as together they have a high potential to interpret the story of the LOCH ARD. The LOCH ARD collection is archaeologically significant as the remains of a large international passenger and cargo ship. The LOCH ARD collection is historically significant for representing aspects of Victoria’s shipping history and its potential to interpret sub-theme 1.5 of Victoria’s Framework of Historical Themes (living with natural processes). The collection is also historically significant for its association with the LOCH ARD, which was one of the worst and best known shipwrecks in Victoria’s history. Lead ingots (sometimes referred to as ‘lead ballast’ or ‘lead pigs), salvaged from the wreck of the LOCH ARD. Grey metal bars with flat base, rising in a curved moulded shape to form a smooth rounded upper face. The imprint of the maker runs along the upper surface in clearly legible capital lettering (height 3cm). Durable and heavy, with some marine staining, but in good condition. Stamped along curved surface, within oval border, "PONTIFEX & WOOD LONDON."flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, loch line, loch ard, captain gibbs, eva carmichael, tom pearce, glenample station, mutton bird island, loch ard gorge, lead pigs, lead ingots, lead ballast, pontifex and wood, london, lead smelters

A black plastic folder containing a set of 38 General Electric Data Sheets for MMTB and tramway trust equipment, dated July 8 1924. Contained in folder with flexible clips. Pages have been punched with four holes. Copy of document made for BTM Feb 1998 by Doug Prosser. For scan of list - see btm780sheet.pdf General Electric Data for Car Equipment Maintenance Contents For scan see btm780d1 (5 pages) Title sheet Data contents summary sheet showing manual prepared for Melbourne & Metropolitan Tramways Board Including Footscray Tramway Trust Hawthorne Tramways Trust Melbourne, Brunswick and Coburg Tramway Trust Prahran and Malvern Tramways Trust. 2 sheets dated July 8, 1924 giving equipment schedules for the various operators, and diagrams. - hard to read the background sheet information. Does not reference the tramcars. For scan see btm780d2 (54 sheets - items 1 to 27) 1. Methods of Removing the Armature from Box Frame Railway Motors Dated 9/1924, 7 pages 2. Instructions for order Magnet Frames for Railways and Mine Haulage Motors 2 pages, not dated 3 Winter Covers for Ventilated Railway Motors - 2 pages 4 Better Commutation for Railway Motors - 1 page 5 Commutator Grooving Machines - 1 page 6 Railway Motor Armature Coils - 2 pages 7 Carbon Brushes for Railway motors - including brush pressure adjustment - 2 pages 8 Renewable Carbon-Way Brush holders for Railway Motors - 2 pages 9 Commutator Grooving Machines (2nd version) - 2 pages 10 The Repair of Railway Motor Commutators - 3 pages 11 Dimensions of Electrical Apparatus used with 600-volv Type PC railway control equipment, (Sheet 15380, dated 2/1/1924) - 1 sheet including · US-13-E Trolley Base, · MS-118-A main switch, · MA-13-F Fuse Box, · MD3 - lightning Arrester, · BJ-386-B Distributing Box, · Type BG Railway Resistors. 12 Connections of Type KM-63-BR Railway Controllers and Equipment - Drawing 15257, 1 page, dated 1/3/1921 with dimension details on rear of type K-63-BR railway controller equipment including: · SG Resister, · BK-13-A Insulator, · MR11 - Circuit breaker, · MD3 - Lightning Arrester box, · K63-BR Controller, · US15C Trolley Base. 13 Method of Supporting Railway Resistors using Porcelain Bolt insulators for 600 and 1500 Volt Work. Drawing dated 1/11/1923, No. 15249B - 1 page 14 Dimensions of Electrical Apparatus used with 600-volv Type M railway control equipment, (Sheet 15381, dated 2/1/1924) - 1 sheet including · US-13-E Trolley Base, · MS-118-A main switch, · MA-13-F Fuse Box, · MD3 - lightning Arrester, · BJ-386-B Distributing Box, · Type BG Railway Resistors. 15 Dimensions of Electrical Apparatus used with 600Volt, Type PC Railway Control Equipment. Drawing No. 15382, dated 2/1/1924. Includes: · C129-A Master Controller, · DA82C Coupler sockets, · MS-14-G switch, · MS-46-H switch. 16 Dimensions of Electrical Apparatus used with 600-volv Type M railway control equipment, (Sheet 15383, dated 2/1/1924) - 1 sheet including · C-169-A Controller · DA-69-B Coupler Socket and DC-66-C Coupler Plug · MS-14-G Switch · MS-46-H-Switch 17 Method of Making Tap Connections for Car Cables -= SD 15468, 1/11/1924, 1 page 18 The Repair of 600 Volt Railway Motor Armatures, 64408, 9/2/1924, 4 pages 19 Proper Method of Mounting and Dismounting Railway Motor Pinions. - 2 pages 20 Pinion Pullers for Railway Motors - 2 pages, dated 8/1/1924. 21 The Care of Railway Motor Bearings - 4 pages 22 Oil Scraper Rings for Air Compressors - 64590 - May 1924 - 1 page 23 Finger Bases for type K 63 controller 1 page 24 Adjustment of Drum Controller fingers - 29/1/1924, 64600A - 1 page 25 Star Wheels for Type K Controllers - 64603 - 1 page 26 Soldering Aluminium Controller Cylinder Castings - 2 pages 27 Porcelain Bolt Insulators for Railway Service - and drawing on rear showing mounting arrangement of resistor Grids - 2 pages. For scan see btm780d3 (13 pages) 28 Connections of Armature and Field Winding for GE-201-F and GE 263A railway motors. DS37869 29 Connections of Armature and Field Winding for GE-201-I railway motors. K1629303 30 Connections of Armature and Field Winding for GE-202 motor, DS 10472 31 Connections of Armature and Field Winding for GE-203 A and GE 226 railway motors. DS23869. 32 Connections of Armature and Field Winding for GE-241 motors - K1629077 33 Connections of Armature and Field Winding for CP25A Air compressor 34 Connections of Armature and Field Winding for CP27A Air compressor 35 Connections of Armature and Field Winding for GE-258 and GE 264 railway motors. K1629343. 36A- Dimensions of Type K-63-BR Railway Controller Equipment 36 US-13-E Trolley Base for Railway Service - 3/1/1923, 64823 - 2 pages 37 Copy of M&MTB (Eastern System) Certificate of Competency as Motorman. 38 Photocopies of a series of four photos of 22E trucks under an SEC tramcar. For scan see btm780d4 (40 pages) 39 Sprague G-E Multiple Unit Control, Type PC, Instruction Book 84772 - Oct. 1922 - 40 Pages. Images of sheets added 2-11-15 trams, tramways, general electric, motors, controllers, trolley pole bases