Was the stand for a Chance Brothers air & oil containers fitted with pump handle & pressure gauges.This type of installation was once common and relied on the lightkeeper having to pressurise the cylinders manually at regular intervals throughout the hours of darkness. The oil was fed under pressure to the burner mantle. It is all that remains of an air and kerosene oil tank installation, with each rounded side formerly supporting a heavy iron tank. The containers would have been fitted with a pump handle and pressure gauges. An intact assemblage is displayed in the AMSA offices, Canberra with a text that explains ‘This type of installation was once common and relied on the lightkeeper having to pressurise the cylinders manually at regular intervals throughout the hours of darkness’.The system involved vaporising kerosene under pressure and mixing it with air and then burning the vapour to heat an incandescent mantle. The use of kerosene as a fuel to light the lantern became the most common system of illumination from the 1860s after the oil industry in the United States began to develop. The kerosene vapour burner was created in 1901 by British inventor Arthur Kitson (1859-1937) and perfected by Chance Bros for burning a more intense light in their renowned lenses. The lamp had to be watched throughout the night in case a mantle broke, and the tanks needed to be maintained by hand-pumping each hour or so. The Point Hicks lantern was initially lit by a six-wick Trinity house kerosene burner. This was replaced by the more efficient and brighter 55mm vaporised kerosene mantle burner in 1905, and the tank stand is probably original to this apparatus. Electricity eventually replaced kerosene at Point Hicks in 1964 making the tank installation obsolete, and the last kerosene system in an Australian lighthouse was replaced in 1985. Gabo Island Lightstation has a pair of tanks that are not attached to the optical system and are no longer in the lighthouse. They are also missing the pressure gauges that were formerly attached to the top of each cylinder. An intact tank assemblage is displayed at the Cape Schanck Lighthouse Museum it is detached and not original to the lighthouse. Although corroded, the remnant Point Hicks tank stand has first level contributory importance to the lightstation. It is significant for its provenance and historical value as part of the Chance Bros vaporised kerosene burner introduced in 1905 to intensify the light and improve the efficiency of the system. The rusted iron stand rests on four short legs and is shaped like a pair of spectacles.

This photograph is taken in the bedroom of the man's home in the suburbs of Melbourne. It depicts one of the types of nursing care given by Melbourne District Nursing Society (MDNS) Sisters in the community. The Sister is visiting the man's home and is administering an injection which has been ordered by a doctor. Glass syringes were used by the Society until the mid 1960s and were re sterilized for future use. After this time plastic disposable syringes were used.The Trained nurses of the Melbourne District Nursing Society (MDNS), later known as Royal District Nursing Service (RDNS), visited patients in their home and gave best practice care in many fields of nursing and to people of many cultures throughout its 130 years of expansion. Initial visits not only assessed the specific nursing situation but the situation as a whole. Their patients ranged in age from babes, children, adults to the elderly and referrals were taken from Hospitals, General Practitioners and allied Health facilities. Some of the care provided was: – Post-Natal care given to mother and babe, Wound Care following various types of surgery, accidents, burns, cancer, leg ulcers etc. Supervising and teaching Diabetic Care, including teaching and supervising people with Diabetes to administer their own Insulin, and administering Insulin to those unable to give their own injections. Administering other injections and setting up weekly medication boxes. The Sisters performed Catheterizations on adults suffering from conditions such as Quadriplegia, Paraplegia, Multiple Sclerosis (MS), Motor Neurone Disease (MND) and Guillan-Barre Syndrome, and when required at school on children for e.g. those with Spina Bifida. The Sisters visited those requiring Cystic Fibrosis support and care; those requiring Haemo-Oncology care, including visiting children at school; those requiring Home Enteral Feeding care, and those requiring IV therapy at home and home Dialysis. Palliative Care was given including pain relief with the use of syringe drivers, personal care as needed, and advice and support to both patient and family. RDNS provided Stoma management to those needing Urostomy, Ileostomy and Colostomy care and those requiring Continence care. HIV/AIDS nursing care was provided; visits to Homeless Persons were made. Personal care was given to patients ranging in age and with varying mobility problems, such as those with MS, MND, Guillan-Barre Syndrome, Quadriplegia, Paraplegia, Acquired Brain Injury, following a Cerebrovascular Accident (Stroke), those with severe Arthritis and those with a form of Dementia. When necessary the elderly were assisted with personal care and advice given on safety factors with the use of hand rails, bath or shower seats, and hand showers. Rehabilitation with an aim towards independence remained at the forefront of the Sister’s minds and when possible using aids and instruction on safe techniques enabled the person to become fully independent. All care included giving advice and support to the patient and their Carers. The Sisters liaised with the persons Doctor, Hospital and allied Health personal when necessary.On the left of this black and white photograph, is a Melbourne District Nursing Society Sister who is standing side-on and leaning slightly forward as she administers an injection into the right upper arm of a gentleman to her right who is sitting up in bed resting against two white covered pillows. The male patient has short dark hair; is wearing glasses, and is looking up at the Sister. He is wearing a thick grey cardigan over a pale colour pyjama top which has dark piping; the lower part of his body is covered by a dark and light coloured check bed cover. The bed has a solid wooden headrest with a bed lamp attached to its upper right. The Sister who is wearing her uniform grey brimmed hat over her dark short hair, is wearing a white gown over her grey uniform, the collar of which is seen. Three fingers of her left hand are holding back the pushed up sleeve of the man's cardigan and she is holding a white swab between her thumb and first finger. She has a glass syringe resting in her right hand with her thumb and forefinger resting against the lower glass and metal section of the syringe; part of the metal needle is seen, the rest is inserted in the mans upper arm. On the far left of the photograph part of a dressing table mirror can be seen.' Rough Proof' Latrobe Studios Ref No. 59134-8melbourne district nursing service, mdns, royal district nursing service, rdns, rdns - injection

Set of A4 photocopies of 15 years of annual reports of The Electric Supply Company of Victoria Limited from 1920 to 1934. Most of the reports comprise three sheets - Directors Report, left hand side of the Balance Sheet, Trading Account and Profit and Loss Account on the right hand side. Some reports have a statutory declaration by the Manager and Secretary that the reports submitted are a true copy of the report. Items .1 to .12 detail the number of lamps connected, passengers carried and trading account for the last three years. This practice stopped when ESCo sold the company to the SEC but continued to manage it for a further four years. The Directors report from 9/1900 note the forthcoming sale of the company to the British Insulated Wire Company Limited and the problems of finalising the sale. Photocopies from the Public Records Office of Victoria, Company Reports, obtained by Alan Bradley c1995. All three sheets, unless noted otherwise. .1 - 1919 - 1920 .2 - 1920 - 1921 .3 - 1921 - 1922 .4 - 1922 - 1923 .5 - 1923 - 1924 .6 - 1924 - 1925 .7 - 1925 - 1926 - four sheets .8 - 1926 - 1927 .9 - 1927 - 1928 - four sheets .10 - 1928 - 1929 .11 - 1929 - 1930 .12 - 1930 - 1931 - four sheets .13 - 1931 - 1932 - four sheets .14 - 1932 - 1933 .15 - 1933 - 1934 Items separated by yellow coloured A4 sheets.trams, tramways, esco, british insulated wire company, annual reports, directors reports

.1 - Book - 56 pages + grey covers, side stapled, issued by the British Engineering Standards Committee "Electrical Machinery excluding motors for traction purposes", No. 72-1917, September 1917. Has "Commonwealth Engineer" label along the bottom edge. .2 - Book 28 pages - light grey covers, side stapled, issued by the British Engineering Standards Association, "Insulating oils for use in Transformers, oil switches and circuit breakers" No. 148-1923, April 1923. Has a Tait Book Co. stamp along the bottom edge and ESCo date stamp 1 Oct. 1925. Printed by Gaylard & Sons London. .3 - Book 72 pages - light grey covers, side stapled, issued by the British Engineering Standards Association, "Tungsten Filament Electric Lamps" No. 161-1925, August 1927. Has a Tait Book Co. stamp along the bottom edge and ESCo date stamp 15 Feb. 1928. Printed by Waterlow & Sons London. .4 - Book 48 pages - light grey covers, side stapled, issued by the British Standards Institution, "Metal Sheathed paper insulated plain annealed copper conductors for electricity supply including voltage tests" No.1 48-1933, March 1933. Has a Tait Book Co. stamp along the bottom edge and ESCo date stamp 15 Feb. 1928. Printed by Waterlow & Sons London. trams, tramways, power station, standards, materials, electrical systems

This baker’s wagon (or cart) was used to transport and deliver bread and other baked goods in the Warrnambool area. It is currently decorated with signwriting advertising H.H. Smith, Baker who owned and operated his Warrnambool bakery in the late 19th and early 20th century. The design of this baker’s wagon is similar to others dating around the 1930’s and 1940’s and was likely to have been built around that time for Stephenson’s Bakery in Warrnambool. The wagon’s original internal shelves were removed due to it being used in the early days at Flagstaff Hill to give children rides around the Village. BAKERS’ HISTORY There were many bakeries in Warrnambool in the 19th to mid-20th century. Each bread bakery made bread deliveries by horse and wagon in their appointed delivery zone. This wagon has sign writing representing Smith’s bakery although it is most likely the delivery wagon of Stephenson’s bakery. SMITH’S BAKERY – as shown on the wagon’s signage Henry Huntington Smith (1857-1941) was born and educated in Warrnambool. He worked at Davis’ steam biscuit factory in Timor Street before he started his own bakery business in 1885 at a premises near the corner of Fairy and Koroit Streets. A few years later Smith built his new bakery on the corner of Fairy and Lava Street where it still stands today as Monaghan’s Pharmacy. The building was designed by James McLeod in 1892 as a bakehouse, shop and residence for Smith The address was known locally as Smith’s corner. Next door to the bakery, at 136 Fairy Street, were Stables built by Jobbins and McLeod in 1886 for William Cust. A photograph in the archives of the Warrnambool and District Historical Society shows the 1892 building with four fancy horse-drawn wagons on the street with white clad drivers and a promotional stand erected with 5 bakers in uniform and the signage “H H Smith & Co, Pastry Cooks and Confectioners”. One of the wagons appears to have “H H Smith” painted on the side. H.H. Smith & Co. placed an Advertisement in the Weekly Times in December 1896 promoting its business as bakers, confectioners and pastry cooks, praising their shop as an ‘ornament to the town’ with ‘neat appointments’ and ‘dainty decorations’. It also boasted that the business supplied a large number of customers within a twelve mile radius of Warrnambool. In November 1919 The Warrnambool Standard announced the marriage of Henry H Smith, Mayor of Warrnambool, to Jeannie Samson-Goodman in East Adelaide. In the same newspaper was a notice that Frank Crossley was to open as baker and pastry cook in H.H. Smith’s premises. As well as being the proprietor of the H.H. Smith Bakery, Henry Huntington Smith was a Councillor for the Warrnambool Municipality from 1913 – 1937 and Mayer for two terms. In December 1919 during his first term as Mayor he was honoured for the work he had done with returning soldiers after World War I, receiving a document in recognition of this work, presented by the Mothers, Wives and Sisters of returned soldiers. Smith was very interested and involved in the community in many roles, including being the Vice President of the first Warrnambool and District Historical Society. STEPHENSON’S BAKERY – believed to be the past owner of the wagon The last owner of the bakery was Harold Stephenson. Stephenson was enlisted in the A.I.F. and was invalided home in 1943 before the end of the Second World War. He also served as a Councillor 1958-1976, during which time he served six terms as Mayor for the City of Warrnambool (1966-1973) while he had the bakery. He was very involved in many local organisations including the Warrnambool Surf Life Saving Club and the Road Race Committee. He died in 1985, lauded as being one of Warrnambool’s “most distinguished civic leaders”. It has been said that the baker injured in World War II invented a special contraption to enable him to get up into the wagon and that he alerted his customers that he was in their vicinity by blowing a whistle. The customers would come out and choose their own bread from the back of his wagon then pay him for it. However another account is given by a man who once earned pocket money by helping the baker on his rounds. He says that it was Stephenson, the owner and manager of the bakery, and not the delivery baker who received a significant injury during the war, making him unable to climb the stairs of his upstairs accommodation at the bakery, therefore causing him to sleep downstairs. At this time in the early to late 1940’s Stephenson’s bakery had three wagons, one for each of the delivery rounds. The wagons were painted black and yellow. Two of the drivers were Stan Lake and Ali (Alec) Dean who both had wagons with the covered cabin design. The third driver was Bill Lake who had a flat wagon. Stan Lake delivered in the area around Lava and Koroit Streets, Ali Dean had another round and Bill Lake had the Dennington area. Bread continued to be delivered into the 1960’s but by this time the delivery vehicles were motorised. The goods produced at Stephenson’s bakery included breads baked in different shaped tins such as High Tin, Sandwich and Vienna. Some shapes were easily divided into half by breaking them apart, therefore the baker could make two quarter loaves from a half loaf, satisfying different needs. There was the option of white or brown bread, sweet buns, fruit buns and Boston buns. The baker’s assistant was known to take great delight in ‘trimming’ the broken halves of excess bread and crust, enjoying his treat. THE BAKERY PREMISES – South east corner of Fairy and Lava Streets, Warrnambool The building retains the original cast iron veranda. Above the veranda a motif of a wheat sheaf in ornamental plaster can be seen. Inside the building there are still has some of the original fittings. The building was classified by the National Trust in August 1979. After the Second World War an official system of zoning was introduced as a fair way for the baking industry to operate. In 1949 different pricing was introduced by the Government for either delivered or retail purchased bread. Many of the small local bakeries went out of business after the Government banned zoning. The way was made open for the larger bread manufacturers to enter the local market with cheaper prices. Some of those companies were Mc Queens, Tip Top, Twisties, Sunicrust, (Mc Queens ‘new’ bakery building was where the current Toyworld shop now stands, is, in the Ozone carpark.) O’Grady’s Bakery, later changing hands and known as Burkes Bakery, was in Fairy Street near Timor Street intersection, on the North West side. There was also a bakery named Almay. The baker’s wagon is significant because of its association with H.H. Smith’s Bakery in Warrnambool.. The H.H. Smith’s Bakery building on the corner of Fairy and Lava Streets, built in 1892, is classified by the National Trust, August 1979. Smith Street Warrnambool was named after Henry Huntington Smith, who was a Warrnambool Councillor 1913 – 1937 and Mayor 1919 – 1921. Baker’s wagon, often referred to as a baker’s cart. Four wheeled horse-drawn delivery wagon, front wheels smaller than rear wheels. Wagon is clad with metal sheets and lined with varnished timber panels. Wheels have metal rims, wooden spokes and rear wheels have wooden brake pads. Horse shaft is timber with metal fittings. Front has a metal lamp holder, brake lever, metal hand grips and decorative metal foot plates. The wagon has suspension leaves on back and sides and double suspension leaves on the front. Driver’s area at front has a roof, glass side windows and wooden box seat with hinged compartment accessing wagon storage area. Door above back of seat has buckled leather handgrip strap attached, door slides open for access to wagon area. Back of wagon has a wooden step and a split door; top door has ventilation louvers, both doors have metal latches. Wagon is painted cream with brown trim and signage and green step. Remnants of red and green paint are visible; underside of seat panel is painted grey. Wagon advertises H.H. Smith & Co. Baker, a Warrnambool business established in 1885, but is of a more modern design seen around 1930’s and 1940’s and most likely belonging to Stephenson's bakery. Brown signwriting on sides of wagon “H.R. SMITH & CO. / BAKER” Brown signwriting across front of wagon “BAKER” warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, shipwrecked-artefact, great ocean road, baker’s wagon, h.h. smith baker, warrnambool, henry h smith, jeannie samson-goodman, frank crossley, mayor of city of warrnambool, vice president of warrnambool and district historical society, stephenson’s bakery warrnambool, harold stephenson, warrnambool surf life saving club, road race committee, national trust building, stan lake, bill lake, ali dean, 19th and 20th century bakers, davies steam biscuit factory warrnambool, james mcleod building designer, jobbins and mcleod, william cust, h h smith & co, pastry cooks and confectioners, bakery trade, bread delivery wagon

Before the introduction of electricity, irons were heated by combustion, either in a fire or with some internal arrangement. An "electric flatiron" was invented by American Henry Seely White and patented on June 6, 1882. It weighed almost 15 pounds (6.8 kg) and took a long time to heat. The UK Electricity Association is reported to have said that an electric iron with a carbon arc appeared in France in 1880, but this is considered doubtful. Two of the oldest sorts of iron were either containers filled with a burning substance, or solid lumps of metal which could be heated directly. Metal pans filled with hot coals were used for smoothing fabrics in China in the 1st century BC. A later design consisted of an iron box which could be filled with hot coals, which had to be periodically aerated by attaching a bellows. In the late nineteenth and early twentieth centuries, there were many irons in use that were heated by fuels such as kerosene, ethanol, whale oil, natural gas, carbide gas (acetylene, as with carbide lamps), or even gasoline. Some houses were equipped with a system of pipes for distributing natural gas or carbide gas to different rooms in order to operate appliances such as irons, in addition to lights. Despite the risk of fire, liquid-fuel irons were sold in U.S. rural areas up through World War II. In Kerala in India, burning coconut shells were used instead of charcoal, as they have a similar heating capacity. This method is still in use as a backup device, since power outages are frequent. Other box irons had heated metal inserts instead of hot coals. From the 17th century, sadirons or sad irons (from Middle English "sad", meaning "solid", used in English through the 1800s[4]) began to be used. They were thick slabs of cast iron, triangular and with a handle, heated in a fire or on a stove. These were also called flat irons. A laundry worker would employ a cluster of solid irons that were heated from a single source: As the iron currently in use cooled down, it could be quickly replaced by a hot one. https://en.wikipedia.org/wiki/Clothes_ironThis iron is typical of the clothes iron used before electric irons superseded it.Salter iron no. 6, painted black but with rust showing through. Salter iron no. 6.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, iron, clothes, laundry

"Captain Simon Thomas Staughton was the son of Simon Thomas Staughton MLA who had built the mansion Eynesbury on his share of the Exford property inherited from his father Simon Staughton, the original 1840s Werribee River squatter. When the land was sold, Simon’s Exford station extended from Mt Cotterell to the Brisbane Ranges. ST Staughton (senior) was a reputedly the public spirited member of the family in his generation, being a member of the first Roads Board (and Melton Shire President in 1867), a JP, Magistrate and MLA for Bourke from 1883 until his death in 1901, whereupon his son became the MLA for Bourke. Captain ST Staughton had earlier been chosen as a member of a contingent of Victorian Mounted Riflemen sent to England for Queen Victoria’s Diamond Jubilee (1897), and was later a member of King Edward’s coronation escort. In October 1899 he had sailed for South Africa with other Mounted Riflemen from Victorian and NSW to take part in the Boer War. There he was awarded the DSO. He died of peritonitis in 1903, aged 27. He was buried in Boroondara Cemetery after a full military funeral, in which the coffin was borne on a gun carriage drawn by four black horses. All local newspapers reported eloquently on the funeral, and the late Captain’s virtues. The Staughton Memorial Lamp was given to the town by his young widow in 1903. In addition a window in the (former) Christ Church bore the inscription ‘This window is erected by his brother soldiers in loving memory of Captain S Tom Staughton, DSO, ADC, MLA’. The Staughton family had been prominent benefactors of the Church, whose altar rails were also inscribed to the much respected Captain, along with a memorial stone in the new chancel. In the 1970s the memorial was within one of four fenced tree plantations, probably erected and planted in the 1920s or 30s. When High Street and its service roads were redesigned in the 1970s the plantations were completely removed, and the Melton and District Historical Society was successful in having the memorial moved about 50 metres east to its present location". The Weekly Times article about a gift from Tom Staughtonlocal identities

This telescope was amongst various items collected from a sea dive in Port Phillip Bay. The diver was the caretaker of the Port Lonsdale Lighthouse, who dived on various wrecks in the bay during the 1960's. After the caretaker's death, his son sold off many of the shipwreck artefacts. The telescope was purchased from the caretaker's son in the 1990's by a previous owner of the Marine Shop, Queenscliff, Victoria. Many companies were making scientific instruments in Liverpool. Between 1730 up too today, they manufactured spectroscopes, telescopes, microscopes, barometers, photometers, cameras, ophthalmoscopes, and electrical equipment such as electric lamps. Liverpool was a major centre for the production of scientific items rivaling Glasgow and London from 1850 to 1920. This telescope appears to be of quality manufacture but the origins can only be surmised at based on the gold embossing to the leather surrounding the main brass tube as being associated with Liverpool England. There is no maker or owners mark, so again there is no sure way to determine the year of manufacture or maker. There were many opticians and scientific instrument makers working in and around Liverpool from 1730 through too today. Also the possibility the telescope could have been made outside Liverpool overseas should not be overlooked and may have been made as a souvenir item from Liverpool from the mid to late 20th century. The size and type of telescope is a traditional type that was used for many sporting activities in the mid to late 19th century for deer stalking, bird watching, or used generally. I believe the item dates from sometime around the early to late part of the 20th century as the use of the liver bird mark became popular in 1911. It began appearing on many manufactured items of the period up too today, denoting that these items were made by companies operating in or around Liverpool England. If the item had been made by a notable firm it would have been engraved with the makers name city of origin, or owner as was the accepted practice for these items. The writer has been unable to determine if any specific company had had exclusive use of the liver bird logo as it was widely used and was not copyrighted until the Liverpool football club successfully won a court case giving them the sole rights to the trademark in 2012.The item is also an example of the shipwreck artefacts gathered along the southwest coast of Victoria. It is also a sample of scientific instruments used up to the mid 20th century.Victorian style gentleman's three draw brass telescope with machine milling surrounding the end of each tube and around the objective end. The three tube draw has no split and all three cartridges are held within the main brass tube wrapped in leather with rope bindings at both ends 5 cm in length and beginning 7 cm from the objective end. The last 2.8 cm makes up the remainder of the brass tube which has a sliding brass sunshade. The eyepiece is flat and has a protective slide over the lens aperture. Two relay lenses are missing on the ends of the second and third tube. Gold embossed into the leather an inscription “Trade the Liver Mark” also embossed in gold a depiction of the mythical liver bird, associated with the city seal of Liverpool England. flagstaff hill, flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, shipwreck artefact, port phillip bay, port lonsdale lighthouse, wreck, 1960’s diver, queenscliff marine shop, liver bird, scientific instrument, telescope, three drawer telescope, liverpool, liver bird trade mark, trade mark

A small number of heavy cast iron weights and two rods remain at the Point Hicks Lightstation. These weights comprise one rod with a forked top and four circular weights attached to the bottom of the shaft. The weights and rods were part of the original clockwork mechanism that was fitted beneath the lens to keep the kerosene‐fuelled light turning. They were attached to a cable or chains and moved vertically in similar fashion to the way weights move on grandfather clocks. As the weight fell, the optic clock was driven and the lens was turned. To keep the clock turning, the weight needed to be wound back up to the top of its travel. The cables and weights in this lighthouse were visible as they moved through the length of the tower up to the lantern room. It was usual for systems to move inside a tube extending up to the top, but in this case the tower’s cast iron spiral staircase, which is supported on cantilever cast iron brackets set into the concrete wall, spiralled around the space in which they moved. Lighthouse keepers had the arduous job of having to constantly wind the clock to keep the light active, and at least two keepers needed to observe a strict roster of hours. When electric motors were invented, all of this became redundant and the motors were able to turn the optic for as long as there was power to drive them. In December 1964, the original 1890 Chance Bros kerosene‐fuelled light and clockwork mechanism were replaced by small electric motor, and the number of keepers reduced to two. The six circular weights and rods originate from the obsolete system and may have been part of a larger set. Wilsons Promontory retains seven of its original set of ten weights, all of which are detached from the tower’s weight tube. Cape Schanck has a set of fourteen weights remaining in situ as well as another four detached weights, which have inscriptions. One weight is displayed in the lantern room at Cape Otway. The image shows four of the clockwork weights attached to a rod with a forked top. They were part of the original clockwork mechanism that was fitted beneath the lens to keep the kerosene‐fuelled light turning. The Aldis lamp in its case sits on the floor next to the weights. Source: Parks Victoria.The Point Hicks weights have first level contributory significance for the insights they provide into the superseded technology and operations of a late nineteenth century lighthouse. They are well provenanced and are significant for their historic value as part of the lightstation’s Chance Brothers optical system installed in 1890. Four circular metal weights are stored on a metal rod with a forked section at the top. The weights have a cut out section which allows the weights to be removed easily.

Oral history interview with Jock Read (1915- 2010) conducted by Diana Bassett-Smith of Eltham District Historical Society. Peter Bassett-Smith and possibly Gwen Orford also in attendance. The interview includes discussion of Jock's family history and connection to Eltham, including his attendance at Eltham State School starting 1921, childhood memories including games he played, memories of Eltham High School, recreational activities, milking, money earned, local transport, neighbours, effect of the Depression, local shops, involvement with the Church of England and more. Recording contains significant amount of noise. 0:00 Introduction including the clarification of Jock's name as Frances and backstory of his parents being from England 3:15- 5:00 Commences talking about home life and childhood 3:38 Talking about family immigrating to Australia His father immigrated to Australia when he was 6 4:05 Jock was born in and lived with his parents in Brunswick before moving to Eltham during the 1920s 4:55-7:44 Permanently moved to Eltham and started at Eltham Primary School in 1921 Talking about books used at school, and games played at school such as marbles, cricket and football 8:45 Moved into Eltham High School after finishing at Eltham Primary 9:50 Week and weekend activities including: Milking cows and doing milk runs on horseback before school 13:15 Most common mode of transport was using horse drawn vehicles and walking 14:50 Discusses impact of depression on family: Father had previously started a business but the depression had a large impact on that 16:10-18:00 Facilities that Jock had • Used hurricane lamps and candles- no electricity • Woodfire • Milk and bread were delivered • Greengrocer- George Bird? 25:22 Left Eltham high school in 1930 26:00 Begins discussing involvement with the church of England 31:46 Electricity did not come to Eltham until 1926 Jock described it as an exciting event 33:00-34:00 Describing the rented house, he was living in- small wooden cottage 35:00 Discussion around starting a mail run round areas of Eltham 38:40-42:35 Enlisted in the navy during WW2 • Navel cadets in 1934 • HMAS Vampire • Served as a seaman gunner Audio Compact Cassette Tape ACME C90 XHG Converted to MP3 file; 55.1MB, 0:42:35audio cassette, audio recording, diana bassett-smith, eltham, jock read, oral history, read family, elham primary school, eltham high school, eltham primary school, 1920s, brunswick, depression, church, st margaret's church, housing, ww2, second world war

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

2971.1 - Photocopy of the cover of the State Electricity Commission of Victoria Magazine, Contact, Vol 3, No. 3, Nov 1938 . Features Miss Winifred Gurr of the Queenscliff office, as the Good Fairy, Electricity at the Geelong Centenary Celebrations. Has the SEC logo or motif on the top of the cover. 2971.2 - Photocopy of an article in the State Electricity Commission of Victoria Magazine, Contact, Vol 3, No. 3, Nov. 1938 titled "The Development of Ballarat's Electricity Supply". One A3 sheet and one A4 sheet. The article details the SEC's part in the celebration of Geelong's Centenary Celebrations in October 1938. Opened by Mayor, Alderman C. N. Brown. Details the lighting needs for the celebrations, 400kW, the large motor traffic who came to see them, damage due to Gales, public buildings illuminated and the procession. Includes details of the decorated trams - 1500 paper floors and 400 lamps. Has photos of Moorabool St, a decorated Pengelly tram and Power Station. On page 4 is a letter from an American visitor, Dorothy Bradner congratulating the tramways. Record revised 3/4/2019 to add digital images with those from Andrew Cook CD. Images added of pages 22 and 37 Page 22 - image 12 - titled "The Provincial Big Three" - photos of the Managers of the Ballarat, Geelong and Bendigo Regions - Mr. T. A. Farr, Mr. H.N. Hornabrook and T.H. McNaught. Page 37 - image 11 - Staff movements of General Interest - records the retirement of W. White Tramways Inspector Geelong, and appointments - W. J. McKinnon appointed as Tramway Inspector and Mr. C. S. Ball, appointed Senior Traffic Inspector. Each item had a thin strip of paper attached by staple to the top left hand corner, giving the Vol. No. details. trams, tramways, sec, geelong, geelong centenary, power station, decorated trams, letters

This Post Office Receiving Pillar was restored in 1980 and is now a fully operational Australia Post mailbox. In early August 1980 Prime Minister Mr. Fraser posted Warrnambool’s first commemorative envelope into this restored Post Office Receiving Pillar at Flagstaff Hill Maritime Village. The special limited edition envelopes are numbered 1 – 7000. When posted, the envelopes would have the Flagstaff Hill Logo and Flagstaff Hill Maritime Village’s own postmark of a ship’s steering wheel surrounding a lighthouse and a sailing ship, and were dated August 3 on the First Day Cover. Amongst Flagstaff Hill’s collection is that very first letter posted by Prime Minister Fraser. HISTORY OF POST OFFICE RECEIVING PILLARS In 1851 ‘pillar boxes’ were installed at roadside locations in the island of Jersey, England; they had already been successful in several European countries. The use of new prepaid, adhesive postage stamps as well as the roadside pillar boxes meant there was no need for the public to take a trip to the Post Office just to post a letter. By 1855 London had installed its first six Pillar Boxes. In 1856 the pillar boxes were first introduced in Sydney. These were circular with a crown on the dome, supported by leaves. Early Victoria Mail was originally collected by ‘letter carriers’, first appointed in Melbourne in 1841, equipped with leather bag and hand bell. He wore a red coat with brass buttons and a black top hat! In 1844 two wooden receiving boxes were erected in Melbourne. The first cast iron boxes were installed in South Melbourne (Emerald Hill) and were still in service until 1967. They were a fluted circular design and made in England. In the early 1860’s the ‘low door round’ design posting box was introduced, being circular and surrounded by a crown, with two broad embossed bands around its circumference. The clearance door was in front of the box and low down. These were made in Australia. In the early 1870’s square boxes with a tapering top were being used. These too were made in Australia by different manufacturers with slight variations on style such as the orientation and number of slots. Next came the circular boxes again, similar to the ‘low door round’ but with the clearance door extending to just below the posting slot, often referred to as ‘high door round’. These boxes did not have embossed bands. In 1887 small cast iron boxes were introduced, attached to posts and poles and called ‘lamp post receivers’. Around 1930 a ‘London’ model was used in Victoria. It was copied from the flat-domed type in London but made in Tasmania. [References: Flagstaff Hill Maritime Village records, The Warrnambool Standard, August 1st, 1980, “Stamps.Au” http://www.stampsau.com, 4th April 2011 (Extracted from “Australian Street Posting Boxes” by Ken Sparks – out of print)] Post Office Receiving Pillar, or letterbox.1885 “High Door Round” design. Tall cast iron cylinder with decorative dome cap with crown on top. Side has a slot and a hinged door with handle shaped as a fist. Painted red with gold trim. “POST OFFICE / RECEIVING PILLAR” lettering cast into cylinder. Restored in 1980 and once again operating as an Australia Post mailbox. Commemorative plague on pillar.“POST OFFICE / RECEIVING PILLAR” lettering cast into cylinder. Flagstaff Hill Maritime Museum – Port of Warrnambool. This letter receiver was officially commissioned on 3rd August 1980 by the Prime Minister of Australia, the Right Honourable Malcolm Fraser M.P. on completion of 25 years’ service as the Federal Minister for Wannon.”flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, post office receiving pillar, letterbox, mailbox, australia post

This water standpipe is believed to be the only one of its kind in working order. It was originally located in Warrnambool, on the hillside at the corner of Mickle Crescent and Banyan Street, providing water for the Chinese Market Gardens below, on the flats. It was removed from this location on May 2nd, 1979, with the intention to relocate it at the new Flagstaff Hill Maritime Museum & Village. The standpipe lay in storage for years until the Warrnambool Company, Chemblast, offered to restore it for use as a working display. The display was officially opened on March 31, 2014. The water from the adjacent lake is drawn out with a hand operated water pump, and goes up into the standpipe, where flows through the canvas hose and into the top of the Furphy Farm Water Cart. The display is a visual acknowledgement of the years served by Flagstaff Hill volunteer and Friends of Flagstaff Hill Chairperson, Bob Crossman. Warrnambool’s early settlers had no water supply prior to the mid-1850s. They relied on rain water tanks, domestic wells and springs. The town experienced a huge, destructive fire in William Bateman Jnr. & Co.’s large produce store in November 1856, which highlighted the need for both a fire brigade and a good supply of water. In 1863 a volunteer fire brigade was established. In August 1880 the town celebrated the installation of its first water standpipe on the corner of Liebig and Timor streets. The water was pumped from springs at Cannon Hill through the connected pipeline to the standpipe, then distributed to households via horse and cart. Each of the licenced cart drivers were compelled by Council regulations to keep their carts full from sunset to sunrise, ready to cart water to outbreaks of fire. They received a fee for this service. In 1893 the town installed a water supply, sourced from the Merri River, stored in a reservoir basin and tower in north Liebig Street, and distributed throughout the town in a system of pipes. By late 1939 a reticulated supply was installed, with the water piped in under the Otway Scheme. Standpipes are still used in modern times in rural and remote areas for homes, farms, stock, agriculture and firefighting. Many commercial or government owned standpipes are metered, charging a fee for the quantities of water supplied. This water standpipe was made by Langlands Foundry Co. Limited, Melbourne, which was establish in 1842. It was Melbourne’s first foundry and iron shipbuilder, and one of the largest employers in Victoria at the time. Langlands was known for its high quality workmanship and wide range of goods for mining, engineering, marine, railway and other industrial uses. The company made the first cast bell, the first lamp posts in the colony, and the boiler for the first Australian train. In the 1860s it produced cast iron pipes for the Board of Works, which laid the pipes for Melbourne’s first reticulated water supply. The firm was bought by Austral Otis Co. in 1897.This water standpipe is significant historically as it is believed to be the only one of its type in working condition. The standpipe is significant for being manufactured by early colonial firm Langlands Foundry of Melbourne, which was known for high quality, cast iron products. The firm made the boiler for the first Australian train, assembled the first Australian paddle steamer and made the first Australian cast bell and lamp posts. Langlands was one of the largest employers in Victoria at the time. The standpipe is significant historically as it represents the evolution of water supply services in Australia. Standpipe; vertical cast iron water pipe, painted crimson, fixed in position, tapering inward from the round base to the rectangular joint near the finial on top. A hexagonal pipe extends at right angles from the joint, with an outlet fitting and flow-controlling wheel on the end. A length of canvas hose hangs from the outlet fitting. Inscriptions are on one face of the joint. The standpipe was made by Langlands Foundry Company of Melbourne. Embossed “LANGLANDS FOUNDRY CO. / LIMITED / ENGINEERS / MELBOURNE”warrnambool, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, flagstaff hill, standpipe, stand-pipe, water standpipe, fire standpipe, firefighting equipment, water supply equipment, chinese market gardens, banyan street, liebig street, water tower, bateman’s fire, working display, water supply, town water, rural water, reticulated water, cannon hill spring, merri river, otway water, water carters, horse and cart water supply, volunteer fire brigade, langlands foundry, early melbourne, iron works, bob crossman, late 19th century water supply

Post Office Receiving Pillar was Collected from Warrnambool City Council’s Scott Street Depot and transported to Flagstaff Hill, stored in the Barracks area Friends of Flagstaff Hill began the project of restoring the Post Office Receiving Pillar in early 2011. The replacement dome required a pattern to be made from paper, then timber, then someone to manufacture it. The cast iron body required sand blasting and undercoating. The pillar was installed in Flagstaff Hill Maritime Village in March 2014. A specialist visited the Village and painted the pillar with 7 coats of ‘post office red’ then completed the job with gold paint on the details. In 2015 an information plate of brass was fitted to the Pillar in the position that would have originally announced the clearing times. It was originally manufactured by G Couch, Engineer, Alliance Iron Works, Melbourne. Gordon Couch passed away in June 1896 and his Works were offered for auction in November 1897. HISTORY OF POST OFFICE RECEIVING PILLARS In 1851 ‘pillar boxes’ were installed at roadside locations in the island of Jersey, England; they had already been successful in several European countries. The use of new prepaid, adhesive postage stamps as well as the roadside pillar boxes meant there was no need for the public to take a trip to the Post Office just to post a letter. By 1855 London had installed its first six Pillar Boxes. In 1856 the pillar boxes were first introduced in Sydney. These were circular with a crown on the dome, supported by leaves. Early Victoria Mail was originally collected by ‘letter carriers’, first appointed in Melbourne in 1841, equipped with leather bag and hand bell. He wore a red coat with brass buttons and a black top hat! In 1844 two wooden receiving boxes were erected in Melbourne. The first cast iron boxes were installed in South Melbourne (Emerald Hill) and were still in service until 1967. They were a fluted circular design and made in England. In the early 1860’s the ‘low door round’ design posting box was introduced, being circular and surrounded by a crown, with two broad embossed bands around its circumference. The clearance door was in front of the box and low down. These were made in Australia. In the early 1870’s square boxes with a tapering top were being used. These too were made in Australia by different manufacturers with slight variations on style such as the orientation and number of slots. Next came the circular boxes again, similar to the ‘low door round’ but with the clearance door extending to just below the posting slot, often referred to as ‘high door round’. These boxes did not have embossed bands. In 1887 small cast iron boxes were introduced, attached to posts and poles and called ‘lamp post receivers’. Around 1930 a ‘London’ model was used in Victoria. It was copied from the flat-domed type in London but made in Tasmania. … [References: Flagstaff Hill Maritime Village records, The Argus, 11th April, 1890, The Argus, 2nd July, 1896, The Argus, 30th Nov. 1897, “Stamps.Au” http://www.stampsau.com, 4th April 2011 (Extracted from “Australian Street Posting Boxes” by Ken Sparks – out of print)] Post Office Receiving Pillar, or letterbox.1885 "High Door Round" design, restored 2014 Tall cast iron sylinder with decorative dome cap, slot in side, hinged door with handle shaped as a fist. Painted red with gold trip..Reconditioned barrel, reconstructed dome. Restored by Friends of Flagstaff Hill, 2014. Now a working letterbox. Made in Melbourne.Oval maker's plate “ - G. COUCH - / ENGINEER / ALLIANCE IRON / WORKS / MELBOURNE”flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, post office receiving pillar, letterbox, mailbox, australia post

This telescope was amongst various items collected from a sea dive in Port Phillip Bay. The diver was the caretaker of the Port Lonsdale Lighthouse, who dived on various wrecks in the bay during the 1960's. After the caretaker's death, his son sold off many of the shipwreck artefacts. The telescope was purchased from the caretaker's son in the 1990's by a previous owner of the Marine Shop, Queenscliff, Victoria. John Browning was particularly well known for his scientific advances in the fields of spectroscopy, astronomy, and optometry. Between 1856 and 1872, Browning acquired provisional patents for designs of numerous scientific instruments. He was also the recipient of an award at the 1862 International Exhibition held in London. Also recognised for his temperature-compensated aneroid barometer. Browning's scientific instruments were used in physics, chemistry, and biology. The products he designed and manufactured included spectroscopes, telescopes, microscopes, barometers, photometers, cameras, ophthalmologist, and electrical equipment such as electric lamps. John Browning was born around 1831 in Kent, England. His father, William Spencer Browning, was a maker of nautical instruments. John Browning's great-grandfather was also an instrument maker as well as John’s brother Samuel Browning of the firms Spencer & Browning and Spencer, Browning & Rust, who also manufactured navigational instruments. The latter firm was in operation in London from 1784 to 1840 and was succeeded by the firm of Spencer, Browning & Co. John Browning initially intended to follow the medical profession and entered Guy's Hospital, a teaching hospital and a school of medicine. Despite having passed the required examinations, however, he abandoned his plans. Instead, he apprenticed with his father, William Spencer Browning. At the same time, in the late 1840s, he was a student attending the Royal College of Chemistry several days per week. By the early 1870s, practical optics had become John Browning's primary interest, and he listed his occupation as an optician on the census records from 1871 to 1901. He was well known among London's ophthalmic surgeons for his various ophthalmic instruments. He had a large part in reforming the art of crafting spectacles. Other achievements were as an author of the book, How to Use Our Eyes and How to Preserve them by the Aid of Spectacles. Published in 1883, the book included thirty-seven illustrations, including a diagram demonstrating the anatomy of the eye. In 1895, he was one of the founders of the "British Ophthalmology" the first professional organisation for optometry. He was not only its first president but also registered as its first member so many considered him to be the first professional optometrist. Other professional organisations he belonged too was as a member of “The Aeronautical Society of Great Britain”. In 1871 constructing the first wind tunnel located at Greenwich Marine Engineering Works. He was also a member of other scientific organisations, such as the “Microscopical Society of London”, the “Meteorological Society”, and the “Royal”. Then in 1908 the company of W. Watson & Son, opticians and camera makers, took over John Browning's company since 1901 John Browning had been semi-retired but in 1908 he fully retired and moved to Bournemouth in Hampshire. He died in Cheltenham, Gloucestershire in 1925.The telescope is significant for its association with one of the world’s leading scientific instrument makers and inventor of the 19th and early 20th century. It is believed the donation came off a wreck either in Port Philip Bay or between Point Lonsdale and the Nepean Heads making it a significant maritime historical artefact. Its provenance is good given it was taken off a wreck in this area by the Point Lonsdale lighthouse caretaker. Examples of John Browning's telescopes because of their scientific and historical importance are highly valued by collectors.Marine style single draw brass telescope with a sunshade. The single draw has no split and the second cartridge is held in a long brass tube within the single draw, mounted from the objective end. The eyepiece is flat and at the end of the first draw in a very faded engraving that is believed to read "John Browning, 63 Strand, and should read London under the word strand but this is hard to establish given the engravings condition. This interpretation of the engraving has been arrived at by examination of other John Browning telescope engraving examples."John Browning, engraved to the first tube in copper plate style "63 STRAND" Engraved under in capital textflagstaff hill, flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, shipwreck artefact, port phillip bay, port lonsdale lighthouse, wreck, 1960’s diver, queenscliff marine shop, john browning, telescope, spectroscopy, optometry, scientific instruments, william spencer browning, optician, navigational instrument, microscopical society of london, aeronautical society, marine technology

The Federation University Historical Collection holds a full range of Victoria Education Gazette and Teachers' Aid from 1900-1968.Ten black hard covered volumes with red tape spine, covering 1900 to 1910. The gazettes include Education Department appointments, transfers, resignations and retirements, notices, queries, notices of books, examination papers, original articles, lesson plans, suggestions for lessons, drawing, obituaries, notes on nature study, mathematics, music, sloyd woodwork, English grammar, Victorian State School Swimming Clubs, Geography, penmanship, science, History, Latin, Geography; The School Garden - Shean's Creek .1) Arbour Day (pg 135) Images: Melbourne Teachers' College 1888 Building (p.8); Union Jack (p. 80); Gasometer (p. 132) .2) Plant Life lesson plans, The Antarctic in 1910, Model Nature Lesson - what plants live on , Superannuation Fund, Saluting the Flag, A.N.A. School Children's Competitions, school garden awards, Teacher Training College, Nature Study - A page from a Teacher's Diary, A Mushroom, Mrs Bush's Kindergarten Christmas Images: Dookie Agricultural College, George R. Button, training college students attending the university, Sloyd teachers, Staff at the Summer School, Outside Wilson Hall, Watt's River Weir, Fungi .3) Images: Walhalla State School; Francis W. Parker (p. 18); Freearm Drawing- Sale State School (p.71) .5) Images: Map of Australia (p.33); Formalin lamps for disinfecting rooms (p. 80); Melbourne Teachers Training College (p. 167) .6) Werribee Gorge Supplement (p. 3, 4, 11, 12, 13) .7) First Exhibition of Women's Work (p. 7, 73-76) .8) Images: Franco-British Exhibition; Memorial to William H. Nichols (p. 191) .9) Temperance Teaching; Birds native to Australia (p.4) Images: Royal Agricultural Show State Schools Exhibit (p. 5-18); Leonard's Hill School; Visit of the American Fleet .10) Funeral of Edward VII Images: Portsea Quarantine Station (p. 33-35)w.o. ryan, f. thomas, a.a. tipping, t.n. considine, w.c. fordyce, e.e. bull, h.w. byrne, j.t. flynn, r.t. smith, a.w. steane, james bagge, theo fink, frank tate, siede, nature, garden, education, school, teacher, teaching, arbor day, arbour day

Looking south along Main Road from the south side of the intersection of Bridge Street with Main Road. Anne Hunniford's Post Office and Burgoyne's store on left. Miss Harriet (Minnie) Williams's Cash Drapery Mart (est. 1902 and enlarged in 1906), also known as Eltham House on the right. Harriet (Minnie) Williams was born London, 1857, the daughter of George John Williams (1812-1895) and Jane Mansfield (1812-1895). In September 1885 she was operating Williams’s Drapery Establishment in premises on Main Road owned by R. Wallis who advertised them to let in September 1885. In 1902 she opened Williams’s Cash Drapery Mart at the southwest corner of Bridge Street and Main Road (opposite the Post Office), owned by W.J. Taylor. In 1906 she bought the premises and one quarter acre of land and expanded the business with a re-opening in April 1906. Harriet was also well-known and esteemed as an active worker in Methodist circles and also Superintendent of the Sunday School. Harriet fell ill in August 1907 and died 15 August. She is buried in Eltham Cemetery with her good friend Ada Ford. Note also the gas street lamp on right. Watson's Hotel on corner of Pitt Street visible in distance. The CBA bank building is hidden behind trees, the chimney and part roof visible. The photo was possibly taken by John Henry Clark of Clark Bros Photographers who operated from 25 Thompson Street, Windsor near Prahan 1894-1914. Evelyn Observer and Bourke East Record (Vic. : 1902 - 1917), Friday 30 March 1906, page 5 ________________________________________ ELTHAM. (FROM OUR OWN CORRESPONDENT.) For over three years Miss Williams has carried on a drapery business in very small and inconvenient premises opposite the Eltham post-office. Recently she bought the building and a quarter-acre of land from Mr. W. J. Taylor. Thus having a free hand, she at once matured plans to enlarge and improve the premises to make them suitable for her growing business. The result being that she consulted Mr Roach, contractor, of Heidelberg, put the matter in his hands, and now he has completed in a very satisfactory manner and up-to-date style extensive improvements. A large addition, of very neat and attractive design, with three large windows, has been built right along the front of the old building, and the counters and inside fittings are very neat and convenient, harmonizing well with the attractive outside appearance. Miss Williams has now got in a large now stock of goods, and is making extensive arrangements for a “reopening week," commencing 2nd April, during which time she will make 10 per cent reduction on all cash purchases in the form of gifts of that value. Miss Williams has gone to considerable expense and liability both, in the enlargement and improvement of the premises and in purchasing additional stock. We therefore trust that the public will stand by her by heartily and en masse patronizing her re-opening effort to show their appreciation of pluck in this advance movement. Google Street View Feb 2017: https://www.google.com.au/maps/@-37.7191341,145.1462046,3a,50.5y,191.91h,88.27t/data=!3m6!1e1!3m4!1sARwwqEQfMSfH9oTWWapPgQ!2e0!7i13312!8i6656 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 '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 (x2) 4 x 5 inch B&W Neg B&W Print 16 x 25 cmsepp, shire of eltham pioneers photograph collection, eltham, main road, anne jane hunniford, burgoyne store, christopher watson, commercial bank of australia, drapery store, eltham house, gas lamp, harriet (minnie) williams, post office, street lamp, watson's hotel, williams's cash drapery mart, clark bros. photo

Langlands Company History: Langlands foundry was Melbourne's first foundry and iron shipbuilder established in 1842, only 8 years after the founding of the Victorian colony by two Scottish immigrants, Robert Langlands and Thomas Fulton, who had formed a partnership before emigrating (1813–1859). The business was known as the 'Langlands Foundry Co'. Henry Langlands (1794-1863), left Scotland in 1846 with his wife Christian, née Thoms, and five surviving children to join his brother Robert. By the time he arrived in early January of 1847 the partnership of Robert Langlands and Fulton had dissolved as Fulton had gone off to establish his own works. It was at this time that the two brothers took over ownership of Langlands foundry. Several years later Robert retired and Henry became sole the proprietor. The foundry was originally located on Flinders Lane between King and Spencer streets. Their sole machine tool, when they commenced as a business, was a small slide rest lathe turned by foot. In about 1865 they moved to the south side of the Yarra River, to the Yarra bank near the Spencer Street Bridge and then in about 1886 they moved to Grant Street, South Melbourne. The works employed as many as 350 workers manufacturing a wide range of marine, mining, civil engineering, railway and general manufacturing components including engines and boilers. The foundry prospered despite high wages and the lack of raw materials. It became known for high-quality products that competed successfully with any imported articles. By the time Henry retired, the foundry was one of the largest employers in Victoria and was responsible for casting the first bell and lamp-posts in the colony. The business was carried on by his sons after Henry's death. The company was responsible for fabricating the boiler for the first railway locomotive to operate in Australia, built-in 1854 by Robertson, Martin & Smith for the Melbourne and Hobson's Bay Railway Company. Also in the 1860s, they commenced manufacture of cast iron pipes for the Board of Works, which was then laying the first reticulated water supply system in Melbourne. Langlands was well known for its gold mining equipment, being the first company in Victoria to take up the manufacture of mining machinery, and it played an important role in equipping Victoria's and Australia's first mineral boom in the 1850s and 1860s. Langlands Foundry was an incubator for several engineers including Herbert Austin (1866–1941) who worked as a fitter at Langlands and went on to work on the Wolesely Shearing machine. He also founded the Austin Motor Company in 1905. Around the 1890s Langlands Foundry Co. declined and was bought up by the Austral Otis Co. in about 1893. History for Grimoldi: John Baptist Grimoldi was born in London UK. His Father was Domeneck Grimoldi, who was born in Amsterdam with an Italian Father and Dutch mother. Domeneck was also a scientific instrument maker. John B Grimoldi had served his apprenticeship to his older brother Henry Grimoldi in Brooke Street, Holburn, London and had emigrated from England to Australia to start his own meteorological and scientific instrument makers business at 81 Queens St Melbourne. He operated his business in 1862 until 1883 when it was brought by William Samuel and Charles Frederick, also well known scientific instrument makers who had emigrated to Melbourne in 1875. John Grimoldi became successful and made a number of high quality measuring instruments for the Meteorological Observatory in Melbourne. The barometer was installed at Warrnambool's old jetty and then the Breakwater as part of the Victorian Government's insistence that barometers be placed at all major Victorian ports. This coastal barometer is representative of barometers that were installed through this government scheme that began in 1866. The collecting of meteorological data was an important aspect of the Melbourne Observatory's work from its inception. Just as astronomy had an important practical role to play in navigation, timekeeping and surveying, so the meteorological service provided up to date weather information and forecasts that were essential for shipping and agriculture. As a result, instruments made by the early instrument makers of Australia was of significant importance to the development and safe trading of companies operating during the Victorian colonies early days. The provenance of this artefact is well documented and demonstrates, in particular, the importance of the barometer to the local fishermen and mariners of Warrnambool. This barometer is historically significant for its association with Langlands’ Foundry which pioneered technology in the developing colony by establishing the first ironworks in Melbourne founded in 1842. Also, it is significant for its connection to John B Grimoldi who made the barometer and thermometer housed in the cast iron case. Grimoldi, a successful meteorological and scientific instrument maker, arrived in the colony from England and established his business in 1862 becoming an instrument maker to the Melbourne Observatory. Additional significance is its completeness and for its rarity, as it is believed to be one of only two extant barometers of this type and in 1986 it was moved to Flagstaff Hill Maritime Village as part of its museum collection. Coast Barometer No. 8 is a tall, red painted cast iron pillar containing a vertical combined barometer and thermometer. Half way down in the cast iron framed glass door is a keyhole. Inside is a wooden case containing a mercury barometer at the top with a thermometer attached underneath, each with a separate glass window and a silver coloured metal backing plate. Just below the barometer, on the right-hand side, is a brass disc with a hole for a gauge key in the centre. The barometer has a silvered tin backing plate with a scale, in inches, of "27 to 31" on the right side and includes a Vernier with finer markings, which is set by turning the gauge key. The thermometer has a silvered tin backing plate with a scale on the left side of "30 to 140". Each of the scales has markings showing the units between the numbers.Inscription at the top front of the pillar reads "COAST BAROMETER" Inscribed on the bottom of the pillar is "No 8". and "LANGLANDS BROS & CO ENGINEERS MELBOURNE " The barometer backing plate is inscribed "COAST BAROMETER NO. 8, VICTORIA" and printed on the left of the scale, has "J GRIMOLDI" on the top and left of the scale, inscribed "Maker, MELBOURNE". There is an inscription on the bottom right-hand side of the thermometer scale, just above the 30 mark "FREEZING" Etched into the timber inside the case are the Roman numerals "VIII" (the number 8)flagstaff hill, warrnambool, maritime village, maritime museum, flagstaff hill maritime museum & village, shipwreck coast, great ocean road, warrnambool breakwater, coast barometer, coastal barometer, barometer, weather warning, ports and harbours, fishery barometer, sea coast barometer, austral otis co, coast barometer no. 8, henry grimoldi, henry langlands, john baptist grimoldi, langlands foundry co, meteorological instrument maker, robert langlands, scientific instrument maker, thermometer, thomas fulton

This framed document titled "The Victorian Missions to Seamen, St Nicholas Seamen's Church Williamstown" shows a list of donors of significant items to the St Nicholas Missions to Seamen's Church in Williamstown when the new building opened in 1944. The organisation ceased in 1966 and the furnishings were later donated to Flagstaff Hill Maritime Village in Warrnambool by the Missions to Seamen Victoria. The transcription of the document is as follows: The Victoria Missions to Seamen, St Nicholas Seamen's Church, Williamstown To the Glory of God List of Gifts Altar - Mrs. and Miss J.R. Schutt Cross - Mrs. R.J. Ewart Chalice and Paten - Mr. and Mrs. Percy Taylor 1 Pair Altar Lights - Mrs. R.J. Ewart 1 Pair Altar Lights - Mrs. M. Jackson Sanctuary Lamp - Miss C. Roberts Rerebos - Miss. M. Breaks, in memoriam Miss. L.A. Breaks Sanctuary Window - Victoria Missions to Seamen Lightkeepers' Auxiliary Missal - Mrs. R.J. Ewart Missal Desk - Mrs. R. Hodgkiss Altar Vases - Mrs. R. Kaybould Bible - Mrs. R.J. Ewart Sanctuary Chairs - Mr. and Mrs. F.H. Twist Credence Table - Mrs. F. Clark Altar Dish – Mrs L. Clark Font - Mr. and Mrs. C.V. Dyble Prayer Desk - H.M.H.S. "Centaur" Reed Organ - "Joy Club for Fighters" Collection Plates - Mr. D. MacKae Hymn Board - St. David's Musical Society, Brighton Pews, Carpet and Hangings - Williamstown Lightkeepers' Auxiliary Bell - Mrs. A.L. Feenes THE MISSIONS TO SEAMEN (Brief History: for more, see our Reg. No. 611, Set of Pews) The Missions to Seamen, an Anglican charity, has served seafarers of the world since 1856 in Great Britain. It symbol is a Flying Angel, inspired by a Bible verse. Today there are centr4es in over 200 ports world-wide where seamen of all backgrounds are offered a warm welcome and provided with a wide range of facilities. In Victoria the orgainsation began in Williamstown in 1857. It was as a Sailors’ Church, also known as ‘Bethel’ or the ‘Floating Church’. Its location was an old hulk floating in Hobson’s Bay, Port of Melbourne. It soon became part of the Missions to Seamen, Victoria. In the year 2000 the organisation, now named Mission to Seafarers, still operated locally in Melbourne, Portland, Geelong and Hastings. The Ladies’ Harbour Lights Guild was formed in 1906 to support the Missions to Seamen in Melbourne and other centres such as Williamstown. Two of the most significant ladies of the Guild were founder Ethel Augusta Godfrey and foundation member Alice Sibthorpe Tracy (who established a branch of the Guild in Warrnambool in 1920). The Guild continued its work until the 1960s. In 1943 a former Williamstown bank was purchased for the Missions to Seaman Club. The chapel was named St Nicholas’ Seamen’s Church and was supported by the Ladies’ Harbour Lights Guild, the Williamstown Lightkeepers’ Auxiliary and the League of Soldiers’ and Sailors’ Friends. It ceased operation in 1966. A Missions to Seamen Chapel and Recreation Room was a significant feature of ports during the late 1800s and into the 1900s. It seemed appropriate for Flagstaff Hill to include such a representation within the new Maritime Village, so the Melbourne Board of Management of Missions to Seamen Victoria gave its permission on 21st May 1979 for the entire furnishings of the Williamstown chapel to be transferred to Flagstaff Hill. The St Nicholas Seamen’s Church was officially opened on October 11, 1981 and closely resembles the Williamstown chapel. This document is significant through its association with the St Nicholas' Mission to Seamen Church in Williamstown, Melbourne, established in 1857. The document is socially significant as it connects the community of Williamstown with the St Nicholas' Missions to Seamen and represents the importance of the church to the community. The items in our collection from the Missions to Seamen in Williamstown, Victoria, have historical and social significance. They show that people of the 1800s and 1900s cared about the seafarers’ religious, moral, and social welfare, no matter what the religion, social status or nationality. It had its origins in Bristol, England when a Seamen's Mission was formed in 1837. The first Australian branch was started in 1856 by the Rev. Kerr Johnston, a Church of England clergyman, and operated from a hulk moored in Hobson's Bay; later the Mission occupied buildings in Williamstown and Port Melbourne. Document titled "The Victorian Missions to Seamen, St Nicholas Seamen's Church Williamstown". The document is a list of gifts originally given to the St Nicholas Seaman's Church in Williamstown, Victoria. The document is mounted in a decorative wooden frame with glass cover. This is one of the original items in our ‘St Nicholas Seamen's Church Williamstown Collection’.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, framed document, donations to st nicholas seamen's church williamstown, 139 nelson place williamstown, religion, religious service, sailors rest, bethel sailors’ church, bethel floating church, ladies harbour light guild, mission to seafarers, st nicholas seaman’s church williamstown, mission to seamen williamstown, st nicholas seamen’s church flagstaff hill, flying angel club, mrs. and miss j.r. schutt, mrs. r.j. ewart, mr. and mrs. percy taylor, mrs. m. jackson, miss c. roberts, miss. l.a. breaks, miss. m. breaks, victoria missions to seamen lightkeepers' auxiliary, mrs. r. hodgkiss, mrs. r. kaybould, mr. and mrs. f.h. twist, mrs. f. clark, mrs l. clark, mr. and mrs. c.v. dyble, h.m.h.s. "centaur", "joy club for fighters", mr. d. mackae, williamstown lightkeepers' auxiliary, mrs. a.l. feenes, st. david's musical society brighton

G42 Garratt Steam Locomotive Traffic and train loadings on Victoria's narrow gauge railways reached their peak during the 1920s. To assist in handling the longer, heavier trains, the Victorian Railways ordered two larger, more powerful Beyer Garratt locomotives. These were delivered in 1926 and were numbered G41 and G42. They were sent to work on the Colac–Beech Forest–Crowes line and the Moe–Walhalla line respectively. After the line from Moe closed in 1954, G42 was sent to Colac, where it worked with its mate, G41, until closure of that line in mid-1962. G41 had been in poor condition and was scrapped, whereas a brighter future awaited G42. The Victorian Railways offered G42 to the Puffing Billy Preservation Society, for display as a static exhibit in the Menzies Creek Museum. Over time, a plan evolved to restore G42 to operation, a goal that was eventually achieved by the launch of G42 back into traffic in April 2004. G42 now continues to operate as a restored member of the Puffing Billy Railway's locomotive fleet. No. originally constructed: 2 No. in service: 1 (No. 42) Boiler pressure: (lb/sq. in) 180 Boiler heating surface: 1268 sq ft (117.8 m2) Tractive effort: (85%) 26,860 lbs (12.18 t) Driving wheel diameter: 36" (91.44 cm) Max axle load: 9t 5cwt Length Overall: 51' 7" (15.72m) Height Overall: 10' 8" (3.28m) Date of manufacture: 1926 Manufacturer: Beyer Peacock Place of manufacture: Manchester UK Locomotive Type: Garratt Coal capacity: 70 cwt Cylinder diameter: 13" (33.02 cm) Cylinder stroke: 18" (45.72 cm) Wheel arrangement: 2-6-0+0-6-2 Roadworthy weight: 69t Water capacity: 1680 gal (7,637.43 l) Beyer Peacock - Garratt Locomotives Register Works Number - 6268 / 1926 Gauge/Railway/Class - 2'6"/Victorian Government Rlys/G Type - 2-6-0+0-6-2 No. G42 Notes - Australia G42 Built in 1926 and painted all-over black, this Garratt locomotive was issued to the Moe to Walhalla line where it remained—other than for overhauls—until the line closed in 1954. After an overhaul at Newport Workshops, it was issued to the Colac to Crowes line and remained there until that line closed in 1962 when it was returned to Newport Workshops for storage. In 1964 it was sold to the Puffing Billy Preservation Society and removed from the V.R. register 3 months later. It arrived at Belgrave in 1968 and was hauled to Menzies Creek for static display in the museum. 1986 saw the commencement of restoration the Belgrave workshops and has been restored to its 1946 to 1954 condition with raised cab roof, raised marker lamps, steel cow-catchers and all-over black livery. It was returned to service on April 18, 2004. Service History : Jun 1926 - Moe - initial allocation of a new locomotive Jun 1926 - Oct 1954 Moe Oct 1954 - Jan 1955 Workshops Jun 1955 - May 1962 Colac Jul 1962 - Dec 1965 Workshops - Stored Jan 1968 - Feb 1968 Belgrave - Stored Feb 1968 - 1982 - Menzies Creek Steam Museum 1982 - 2004 - Under restoration Apr 2004 - Belgrave - In active service at Puffing Billy Railway BelgraveHistoric - Victorian Railways - Narrow Gauge - Garratt Steam Locomotive - G42 Victorian Heritage Register (VHR) Number H2187 G42 Garratt Steam Locomotive made of steel, iron and wrought iron with brass fittings - the Locomotive is in Active Service - Belgrave Station G42puffing billy, narrow gauge, garratt, g42, steam locomotive, beyer peacock, victorian railways

This is a set of 23 photographs of cartographic, aero-triangulation and lithographic equipment, and personnel at the Army Survey Regiment, Fortuna, Bendigo circa 1979. Photos .8P to .23P were taken in Lithographic Squadron’s printing, Camera, proofing rooms and external buildings. Cartographic Squadron’s SGT Jim McDonald operated the Editwriter type setting machine, as shown in photo .2P for a couple years in a room on the top floor of Fortuna Villa. This is a set of 23 photographs of cartographic, aero-triangulation and lithographic equipment, and personnel at the Army Survey Regiment, Fortuna, Bendigo, c1979. Black and white photos are on photographic paper and mounted on manilla card. They were scanned at 300 dpi. .1) - Photo, black & white, c1979, Typesetting machine, ‘Editwriter’ Model 7500, SGT Jim McDonald. .2) - Photo, black & white, c1979, Processor Model ACP101 & dual disk module (attached to Editwriter). .3) - Photo, black & white, c1979, Duplicating machine, stencil process electric ‘Gestetner’. .4) - Photo, black & white, c1979, Comparator photogrammetric stecometer, modified ‘Carl Zeiss’, CPL Jack Elverd. .5) - Photo, black & white, c1979, Point transfer device ‘Wild PUG IV. .6) - Photo, black & white, c1979, Zoom transfer scope, stereo ‘Bausch & Lomb’ .7) - Photo, black & white, c1979, Stereoplotter analytical automatic, ‘APC/3-1’. .8) - Photo, black & white, c1979, Prophylaxis unit, ‘Densply/Cavtron’ .9) - Photo, black & white, c1979, Machine punch register (made by Bendigo Ordnance Factory). .10) - Photo, black & white, c1979, Plan printer 122cm (48”) wide. ‘Admel Bruning’ Model - 5003A. .11) - Photo, black & white, c1979, Metal halide printing lamp. ‘Violight 5000 HV’ .12) - Photo, black & white, c1979, Densitometer transmission or reflection, ‘Macbeth’ Model – TR 524 MD. .13) - Photo, black & white, c1979, Machine whirling vertical type ‘Payne VLW’. .14) - Photo, black & white, c1979, Densitometer reflection, ‘Macbeth’ Model – RD917. .15) - Photo, black & white, c1979, Densitometer reflection, 240V ‘Cosar’ .16) - Photo, black & white, c1979, Printer contact ‘Hohlux’ Model RP-II, LCPL Martin Van der Maele. .17) - Photo, black & white, c1979, Frame printing vacuum vertical. .18) - Photo, black & white, c1979, Frame printing vacuum flip top 91cm x 117cm. .19) - Photo, black & white, c1979, Printer reduction stereo plotter diapositive ‘Wild’ Model – U3A modified and U4A modified to U4A plus. .20) - Photo, black & white, c1979, Printing press offset rotary lithographic 3 colour ‘Ultra-MAN-III’ .21) to. 23) - Photo, black & white, c1979, Camera cartographic consolidated super 100 32” x 32”The three personnel appearing in this set are identified. Most items have a full description, NSN, serial number, and the Repairer’s name, address and phone details and contact name. Just the full description is documented.royal australian survey corps, rasvy, army survey regiment, army svy regt, fortuna, asr