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Bendigo Historical Society Inc.
Photograph - HILDA HILL COLLECTION: BLACK AND WHITE PHOTOS, 1918-1919
Hilda Hill Collection. Black & White Photograph Collection Double Sided Card 10 Individual Photographs, Family Life During World War 1. Five Children enjoying day out at Pyramid Mineral Springs in Kyneton 27/09/1918 white gate in background. Female in white coat standing in a garden, Dec 30th 1918 The Ranch. General Pau Bendigo 21/10/1918. Two Gentlemen in a gig at Bendigo's Botanical Gardens Jan 1919. Three ladies in white blouses and black dresses 'The Pines' Jan 1919. Mistress Alma Northcote 1918. Easter Monday 1918 Lieutenant King in uniform at the 'The Ranch'. Small dog standing on white chair in front of a fern. Two men sitting on ground with football goal post in background, one dressed in white clothing with tennis racket at his side and the other man in slightly darker clothing with a hat at his feet. Victorian home, verandah with lacework named the Ranch. The house has lacework below the gutter of the front . Medium light coloured picket fence. Paved footpath with narrow nature strip. Tree on nature strip enclosed by a medium height picket fence.history, australian, world war 1 family life, https://en.wikipedia.org/wiki/paul_pau -
Flagstaff Hill Maritime Museum and Village
Container - Bottle, 1880s to 1910’s
This handmade green glass bottle was made using the turn-moulded or rotated-moulded method, a variation of the mould-blown process. The bottle has the remnants of a cork seal in its mouth. It possibly contained ginger beer, soda or mineral water, flavoured drinks, liquor or wine. The bottle’s shine has been worn from around 3/4 of its body, indicating that it has been resting horizontally on an abrasive surface, perhaps in the ground or on a river or sea bed. TURN-MOULDED BOTTLE production method This bottle was handmade using the ‘turn-moulded’ process, one of a variety of mould-blown processes that followed the earlier mouth-blown method. The maker would add a portion of hot soft glass to the end of his blowpipe then blow air through the pipe while placing the end inside a bottle mould. The mould was then turned and twisted, giving the bottle a round, seamless body, and usually a round indented base. The cooled body of the bottle would then be finished with the addition of an applied top. A small amount of soft glass would be applied to the top of the bottle and a lip would be formed using a tooling implement. A concentric ring would also form below the lip, caused by the rotated lipping tool. The bases of bottles made with the turn-moulded method were generally not embossed but would commonly have a mamelon or ‘dot’ in the centre of the base. SEALING THE BOTTLE After filling this type of bottle with its contents it is then sealed with a straight, cylindrical cork with the aid of a hand operated tool called a bottle corker. The bottle corker compresses the cork as it is driven into the bottle. Once inside the bottle the cork expands evenly into the opening to tightly seal the contents – the denser the cork the better the seal. Brown, brown glass. Handmade turn-moulded bottle with seamless body and tooled lip. Deeply indented base has push-up mark with a ‘mamelon’ nipple-liker bump in the centre. Bottle is straight from base to half height then tapers to a shoulder over the next quarter, than almost straight up to the mouth. Produced in 1880s to 1910’s. flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, brown glass bottle, handmade glass bottle, bottle with indented base, turn-moulded bottle, rotate-moulded bottle, tooled lip on bottle mouth, applied lip bottle, bottle corker, ginger beer bottle -
Flagstaff Hill Maritime Museum and Village
Container - Bottle, 1880s to 1910s
This handmade green glass bottle was made using the turn-moulded or rotated-moulded method, a variation of the mould-blown process. The bottle has the remnants of a cork seal in its mouth. It possibly contained ginger beer, soda or mineral water, flavoured drinks, liquor or wine. The bottle’s shine has been worn from around 3/4 of its body, indicating that it has been resting horizontally on an abrasive surface, perhaps in the ground or on a river or sea bed. TURN-MOULDED BOTTLE production method This bottle was handmade using the ‘turn-moulded’ process, one of a variety of mould-blown processes that followed the earlier mouth-blown method. The maker would add a portion of hot soft glass to the end of his blowpipe then blow air through the pipe while placing the end inside a bottle mould. The mould was then turned and twisted, giving the bottle a round, seamless body, and usually a round indented base. The cooled body of the bottle would then be finished with the addition of an applied top. A small amount of soft glass would be applied to the top of the bottle and a lip would be formed using a tooling implement. A concentric ring would also form below the lip, caused by the rotated lipping tool. The bases of bottles made with the turn-moulded method were generally not embossed but would commonly have a mamelon or ‘dot’ in the centre of the base. SEALING THE BOTTLE After filling this type of bottle with its contents it is then sealed with a straight, cylindrical cork with the aid of a hand operated tool called a bottle corker. The bottle corker compresses the cork as it is driven into the bottle. Once inside the bottle the cork expands evenly into the opening to tightly seal the contents – the denser the cork the better the seal. This turn-moulded glass bottle is made distinctive due to its round seamless body and indented base.Bottle, dark green glass. Handmade turn-moulded bottle with seamless body and tooled lip. Deeply indented base has push-up mark with a ‘mamelon’ bump in the centre. Bottle is straight from base to half height, then tapers to a shoulder over the next quarter, than almost straight up to the mouth. The shine has been worn from three-quarters of the body of the bottle. There are particles adhered to the inside of the bottle. Possibly used for ginger beer. Produced in 1880s to 1910’s. flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, green glass bottle, handmade glass bottle, bottle with indented base, turn-moulded bottle, rotate-moulded bottle, tooled lip on bottle mouth, applied lip bottle, bottle corker -
Flagstaff Hill Maritime Museum and Village
Container - Bottle, 1840s-1870s
This teal coloured bottle (blue-green, non-olive) has been handmade from about the 1840s-1870s. The bottle, possibly used to store soda or mineral water, was found in the coastal waters of Victoria about 100 years from when it was made. It is part of the John Chance Collection. The teal, or blue-green, colour of this bottle’s glass is reasonably rare. The colour is probably the result of a combination of cobalt (blue), iron (yellow-orange) and chromium (green) that may have been in the raw silica, or perhaps added to the glass sand before making the glass. Glassblowers made bottles like this one by blowing air through a long pipe into the molten glass blob at the end of the pipe. The glass was blown out to fit into the shape of the cylindrical dip mould. Once it hardened, the glass was removed from the mould and the glassblower would continue using the pipe to create the neck while carefully using a tool to hold the base. A ponty tool was used to complete the shape of the base. The bottle would be cracked off the end of the glassblower’s pipe and a blob of molten glass would be wrapped around the top of the neck and shaped to finish the lip of the bottle, sometimes using a tool to do this. The seal was usually a cork, often held in place with wax or wire with tape over it to seal the aerated drink inside. The gutter between the upper and lower lip was used to anchor the seal. This style of handmade bottles would often have horizontal bubbles in the applied finish, caused by twisting the glass, and vertical bubbles and diagonal lines in the neck and body from it being blown, and a mark in the base where the ponty tool had been attached. Although the bottle is not linked to a particular shipwreck, it is recognised as being historically significant as an example of handmade, mid-19th century bottles imported for use in Colonial Victoria in the mid-to-late 1800s. The bottle is significant for its rarity, as its teal, blue-green colour is unusual. It is a valuable addition to our collection of 1800s handmade bottles. The bottle is also significant as it was recovered by John Chance, a diver in Victoria’s coastal waters in the late 1960s to early 1970s. Items that come from several wrecks have since been donated to the Flagstaff Hill Maritime Village’s museum collection by his family, illustrating this item’s level of historical value. Bottle; unusual dark teal (blue-green, non-olive) opaque glass, medium size, cork-top style. Handmade with applied double-collar lip with straight side upper and a ring lower. The edge of the mouth is uneven. Neck is slightly bulbous. Body has shoulder seam, then tapers inwards to base, shallow base. Heel is uneven width. Base is shallow with glass of different density. Bubbles in the body and an elongated bubble at base of neck. Sediment inside bottle. Chip in lip. Scratched surface.flagstaff hill, warrnambool, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, shipwreck artefact, john chance, glass bottle, antique bottle, handmade, mouth blown, blown bottle, 19th century bottle, collectable, bottle, green glass, blue-green glass, teal glass, non-olive green glass, dip mould, soda bottle -
Forests Commission Retired Personnel Association (FCRPA)
Fire Beater - Canvas, c 1930s
Bushfire perimeter rather than bushfire area is the main control problem for firefighters on the ground. A conundrum rapidly compounded by spot fires. A small 5 ha fire can be nearly 1 km around the perimeter. That's a long way to build a control line by hand in rough bush. Dry firefighting techniques by hand were mostly confined to “knocking down” or “beating out” the flames, as well as "digging out". Digging or raking a “mineral earth” trail down to bare dirt proved most effective in forest fuels which, unlike grass, tend to retain heat and smoulder. Early tools were whatever happened to be close at hand. They were simple and primitive and included shovels, slashers, axes, hoes, beaters and rakes. A cut branch to beat the flames was often the only thing available. Farming and logging tools, developed over centuries of manual labour, and readily available at local hardware stores came into use, but little thought was given to size, weight, and balance. This canvas hose beater was based on a century-old design which used lengths of canvas fire hose rivetted together and lashed with wire to a broom handle. The hose was be soaked in water to improve its effectiveness. If the flames were more than a metre or so the user was generally not able to get close enough to extinguish the fire It's recommend that users lift no more than above knee height to conserve energy and let the beater to the work. For years foresters experimented with combination tools. In about 1952 fire beaters and other implements were being replaced with Rakuts and later RakehoesEarly firefighting toolBushfire beater - Canvas with wooden handleR P PWD (Public Works Department) The handle has painted markings which indicate which FCV District it belonged to.bushfire -
Ringwood and District Historical Society
Administrative record - Mining Reports, Government Printer, Melbourne, Colony of Victoria quarterly and annual mining reports - 1860s 1870s & 1880s, 1865 - 1883
Colony of Victoria mining reports show any Ringwood mine references under Castlemaine District, St. Andrews Subdivision. Noteworthy for Ringwood: - Death of Pierce Boardman, mining manager at New Ringwood Mining Co., accidentally killed when he lost his footing and fell to a depth of 40 feet on 1st January 1879. - William White injured in truck accident at New Ringwood Antimony Tribute Company, 31st March 1882.Boxed collection of soft and hard bound reports including: 1. Quarterly Colony of Victoria reports of the Mining Surveyors & Registrars, Victoria, 1865-1881 - Summary of gold mining statistics for the quarter - Tables showing the yield of gold from certain parcels of quartz raised during the quarter in some of the deepest mines in Victoria with depth of the deepest shafts, levels, cross-cuts, etc. - Estimated yield of gold and quantity of gold exported during the quarter - Gold received and issued from the Royal Mint during the quarter - Summary of yield of gold from quartz, tailings, etc., crushed during the quarter - Summary of yield of gold from washdirt and cement washed and crushed during quarter - Number and distribution of miners on the goldfields of the colony. 2. 1879-82 Hard bound volume - Chief Inspector of Mines Reports to the Honorable Minister of Mines, Victoria. (Includes fatal and non-fatal accident reports, mining operations, and employment statistcs.) Noteworthy for Ringwood: - Death of Pierce Boardman, mining manager at New Ringwood Mining Co., accidentally killed when he lost his footing and fell to a depth of 40 feet on 1st January 1879. - William White injured in truck accident at New Ringwood Antimony Tribute Company, 31st March 1882. 3. Mineral Statistics for Victoria - annual reports for years 1867, 1871, 1874, 1876, 1877, 1878, & 1879. 4. Handwritten study notes.antimony, boardman, william white -
The Beechworth Burke Museum
Geological specimen - Brown Coal
Brown Coal is typically found as rocks. During formation the Brown Coal starts as peats, which is an acidic brown deposit resembling soil, and over time when subjected to pressure and heat these peats form the Coal. Brown Coal is the lowest rank of coal as it has a low carbon (energy) content, and a high moisture content. This high moisture content makes Brown Coal unsuitable for overseas exports. This particular specimen was recovered from the Yallourn Mine in Latrobe Valley, Victoria as part of the geological survey of Victoria being carried out by Alfred Selwyn. Otherwise known as the 'Yallourn Power Station', the Yallourn Mine is Australia's second largest mine. Yallourn Mine was first built in 1920, and since then it has been providing over 1 billion tonnes of Brown Coal to Australia every year. The Yallourn Mine is responsible for 22% of Victoria's electricity and 8% of Australia's electricity. As of 2021 the mine employs around 500 people. Due to ongoing maintenance issues and Australia's move to cleaner energy, the Yallourn Mine intends to shut down permanently as of 2028. Soon after gold was discovered in 1851, Victoria’s Governor La Trobe wrote to the Colonial Office in London, urging ‘the propriety of selecting and appointing as Mineral Surveyor for this Colony a gentleman possessed of the requisite qualifications and acquaintance with geological science and phenomena’. Alfred Selwyn was appointed geological surveyor in Australia in 1852 which began the Geological Survey of Victoria. In 1853-69 the Geological Survey issued under Selwyn's direction sixty-one geological maps and numerous reports; they were of such high standard that a writer in the Quarterly Journal of the Geological Society of London bracketed the survey with that of the United States of America as the best in the world. During his years spent in Australia, Selwyn collected numerous significant geological specimens, examples of which are held in collections such as the Burke Museum.Brown coal is considered to be an essential rock to Australia's energy consumption. Although plentiful in sources, Brown Coal is not able to be exported overseas due to its high moisture content. As Australia moves towards cleaner energy, Brown Coal is going become less used. This specimen is part of a larger collection of geological and mineral specimens collected from around Australia (and some parts of the world) and donated to the Burke Museum between 1868-1880. A large percentage of these specimens were collected in Victoria as part of the Geological Survey of Victoria that begun in 1852 (in response to the Gold Rush) to study and map the geology of Victoria. Collecting geological specimens was an important part of mapping and understanding the scientific makeup of the earth. Many of these specimens were sent to research and collecting organisations across Australia, including the Burke Museum, to educate and encourage further study.A solid hand-sized sedimentary rock that is a dark shade of brown.13 / BROWN COAL / Showing Woody structure / Locality: Yallourn, Vic. | Label probably / correct but / can't find reference / no. 13 to match in / registers. / C Willman / 15/4/21burke museum, beechworth, indigo shire, beechworth museum, geological, geological specimen, mineralogy, yallourn, yallourn mine, victoria, coal, brown coal, brown coal specimen, alfred selwyn, geological survey of victoria, geological survey, yallourn power station -
Federation University Historical Collection
Booklet, Eugene Kneebone, Explore Discover Apply: University of Ballarat Research Report, 2007, 2007
University of Ballarat is a predecessor institution of Federation University AustraliaPredominantly white and gold soft covered book outlining Research at the University of Ballarat. It includes information on: * Institute for Regional and Rural Research and Innovation * Centre for Regional Innovation and Competitiveness * Teaching to Global Citizenship * Older BLokes and Their Sheds: Community based Men's Sheds in Australia * Education and Re-education in Child Sexual Abuse * Water Demand Management and Climate Change * An Indigenous History of Stonington * Key Drivers of Change in Adult and Community Education * Benchmaking Research * Training for Child Protection * Grabbing a Lifeline to Better Health * Enhancing Nurse Preparation for health care practice * ACT for depression in adolescence * FRom Pokies to Peremptory PErsonal Pleasures * Worksafe Awards * Mineral Sands that are not sinking * Rising Generation Inspired by Trace Elements * Environmental Research from Namibia to Ballarat * Evaluation of VicHealth Sport & Physical Activity Programs * A good Hard Look at Sports Grounds * Preventing Knee Injuries inn Community Australian Football * WIDCORP Beyond the Pipelines *Woodside Energy Ltd Optimizes its Production * Australian Defence Force Seeks Best Fit * Mapping Augmentation Structures Images include: David Battersby, Wayne Robinson, Joel Epstein, Georgina Tsolidis, Barry Golding, Caroline Taylor, Julian Lowe, Laura Kostanski, Ian D. Clark, Jessie Harman, Patrick White, Angela Murphy, Katrina Brown, John McDonald, Robert Watson, Sally Wellard, Louise Hayes, Stephen Cowley, Susan Leggett, Steve Hall, Stafford McKnight, Larissa Koroznikova, Patrick Graz, David Stratton, Andrew Stranieri, John Yearwood widcorp, water in drylands collaborative research project, eugene kneebone -
Flagstaff Hill Maritime Museum and Village
Domestic object - Codd neck bottle, E. Rowlands, 1921
The design of the bottle is called a Codd, sometimes referred to as a marble bottle or "Codd's patent bottle". During the mid-to-late 1800s, there were many inventions to keep the fizz in carbonated drinks such as ginger ale, soda water, and fruit drinks. Hiram Codd, an English engineer invented a successful process that he patented as "Codd's patented globe stopper bottle" in 1872. The Codd-neck bottle (commonly called Codd or marble bottle) is manufactured in two parts. The body of the bottle is cast in two sections. At the time of joining the sections, glass marble and rubber seal are inserted into the neck section. The lip is then applied to the top of the bottle. The Codd bottle is filled upside down as the pressure of the gas from the carbonated liquid holds the marble up and out of the way. When the bottle stands upright the gas pushes the marble up against the washer, creating a firm seal to keep the fizz inside. The bottle is opened by pushing the marble down firmly to allow some of the gas to escape. The marble drops down and is caught in a depression formed in the neck. When the bottle is tilted to pour or drink the liquid the marble rests in a dimple. Two Ballarat miners, Evan Rowland and Robert Lewis started manufacturing mineral and aerated waters, bitters, cordials, and liqueurs in 1854, in a tent on the shores of Lake Wendouree Ballarat. Another 13 firms at that time employed manual operations, whereas they introduced Taylor's No. 1 machine that speeded up the process and laid the foundation for their fortune. Evan Rowland was a pioneer in the aerated water trade in Australia. He was born on August 2, 1826, in North Wales. In 1852, during the gold rush, he emigrated to Melbourne, and in 1854 he went to Ballarat and formed a partnership with Robert Lewis, the firm being called ‘‘Rowlands & Lewis’’. Their next step was to secure a supply of pure water. Using mineral Waters that they found via a natural spring at Warrenheip, Victoria. From the outset, the beverages made from this water gained repute and were in great demand. Their business prospered so well that in 1858 they were able to build a factory at the corner of Sturt and Dawson Streets, Ballarat, and to fit with the most up-to-date machinery then in use. By 1870 their business had increased so much and demand had grown to such an extent that Mr. Rowlands erected another factory, covering over an acre of ground at the corner of Dana and Doveton Streets, costing £13,000. The factory was fitted with the most modern equipment of the time to manufacture cordials and aerated water. In 1873 Rowlands established an agency at 116 Collins St, Melbourne, because the demand for the products of the Melbourne factory became so large. The company expanded to Sydney opening a factory at the corner of Burns & Hay Streets Darling Harbour obtaining spring water to supply this plant from Katoomba in the Blue Mountains. The water was brought to Sydney by rail. In the meantime, the Melbourne concern had progressed so rapidly that in 1888 a magnificent factory embodying all the latest ideas and equipment was built in King Street Melbourne. Robert Lewis was a fellow Welshman born in 1816, and he arrived in Port Phillip in 1853 and became a partner in the early day with Evan Rowland but with lesser and shorter involvement in the firm, from which he retired in 1876. Robert Lewis was perhaps better known as Ballarat's first mayor and a Member of the Legislative Assembly. He was a strong supporter of local charities, president/treasurer of the Eisteddfod Committee, a major force in the development of the Ballarat Hospital, and he was the mayor of Ballarat five times, the first in 1863, (having been a counsellor as early as 1859) and for the last time in 1881. Lewis died in 1884 of a stroke in Ballarat. Rowlands continued in the firm and invented and patented an improved soda water bottle. The water used in Rowlands products was filtered four times but his attempts to use local corks failed on quality grounds. He was a stickler for quality, which was so good that many outside Victoria were prepared to pay the 'premium' imposed by inter-colonial customs duty payable at that time. By the 1890s, Rowlands had factories in Ballarat, Melbourne, Sydney, and Newcastle. He died in 1894 but his company continued until well after the Second World War when it was sold to Schweppes.An early manufacturing process producing the first mineral waters in Australia was invented and developed by an early Welsh migrant to Australia. The Evan Rowlands story gives an insight into the early development of manufacturing industries in Australia that allowed their workers and the towns they were situated in to prosper and develop into what they are today. Bottle; clear glass Codd neck bottle with small marble in top. Once contained soda water or soft drink. Manufactured in 1921 by E. Rowlands of Ballarat, Melbourne, Katoomba and Sydney. The bottle is 'recyclable' - the message on the base says that it remains the property of E. Rowlands Pty Ltd."E. ROWLANDS BALLARAT MELBOURNE KATOOMBA AND SYDNEY". Imprinted into bas "1921" "THIS BOTTLE REMAINS THE PROPERTY OF E. ROWLANDS PTY LTD"flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, bottle, codd bottle, hiram codd, glass marble bottle, e. rowlands bottle manufacturer, soda bottle australia, early recyclable bottle, codd's patent bottle, marble bottle -
City of Moorabbin Historical Society (Operating the Box Cottage Museum)
Containers,Shaving cream, J.B.Williams Co, mid 20thC
Shaving cream is a cream applied to the face, or wherever else hair grows, to facilitate shaving. The use of cream achieves three effects: lubricates the cutting process; swells keratin; and de-sensitizes skin. Shaving creams commonly consist of an emulsion of oils, soaps or surfactants, and water. James Baker Williams was born in 1818 in Lebanon, Connecticut USA and, in 1834, began employment with F. and H.C. Woodbridge, a general store located in Manchester. Williams was offered half-interest in the store in 1838, after which its name was changed to Keeny and Williams. Two years later, Williams sold his interest in the store, but retained his share in the drug department. He began experimenting with various soaps to determine which were best for shaving, and eventually developed Williams' Genuine Yankee Soap, the first manufactured soap for use in shaving mugs. In 1847, Williams moved his enterprise to a rented gristmill on William Street in Glastonbury, Connecticut, and his brother, William S. Williams, joined the firm around 1848, when the firm's name was changed to the James B. Williams and Company. William's shaving soaps were sold throughout the United States and Canada and James Williams supervised many aspects of the company until shortly before his death in 1907 at the age of eighty-eight. The Williams family continued to manage the company until it was sold in 1957. By the early 1900s, the company was known throughout the world. In addition to its line of shaving creams, the firm produced talcum powder, toilet soaps, and other toilet preparations. The original 1847 factory is still standing in Glastonbury and, in 1979, was converted into a condominium complex. I In 1983 it was placed on the National Register of Historic Places. 1927 - 1990 Salmond and Spraggon (Australia) Limited , Sydney , New South Wales, was registered as a company on 10 June 1927 following the liquidation of Salmond and Spraggon (Australia) Limited known as the Old Company. The company distributed household cleaning and mineral, metal and chemical wholesaling, pharmaceutical wholesaling throughout Australia on behalf of manufacturers. In 1990 the company was taken over by Alberto Culver, a manufacturer of hair and skin products. A clear glass jar with a screw lid containing 'Williams Shaving Cream' Front Label : J.B WILLIAMS / LUXURY / SHAVING CREAM Back Label : The contents of this jar are guaranteed to be / The J.B.WILLIAMS Luxury Shaving Cream Jar has been changed to meet the Wartime conditions but / the cream is of the same high quality / made in Australia for / J.B. WILLIAMS COMPANY / Glastonbury, Conn. U.S.A. / Vendors / SALMOND & SPRAGGON (AUST.) PTY.LTD. / All Statesshaving equipment, razors, safety razors, cutthroat razors, soap, world war 11 1939-1945, moorabbin, bentleigh, cheltenham, early settlers, shaving cream, williams j.b. company ltd, connecticut usa, glastonbury connecticut usa, salmond & spraggon pty ltd, sydney, new south wales, toiletries, shaving soap, -
Flagstaff Hill Maritime Museum and Village
Furniture - Set of desks & benches, Unknown
The following are the recollections of John Elkins, who started school in February, 1945 at Maryborough in Queensland, Australia. 'I think in Prep 1 that we had some paper to write on with pencils, but my memory of the routine use of slates is much more vivid. Each slate was framed in wood and one side was inscribed with lines to guide the limits for the upper and lower extremities of letters. The slate "pencils" were made of some pale gray mineral softer than slate which had been milled into cylinders some one-eighth of an inch in diameter and inserted into metal holders so that about an inch protruded. Each student was equipped with a small tobacco tin in which was kept a damp sponge or cloth to erase the marks. Sharpening slate pencils was a regular task. We rubbed them on any suitable brick or concrete surface in the school yard. Teachers also kept a good supply of spares, all writing materials and books being provided by the school. It is possible that the retention of slates stemmed from the political imperative that public education should be free. I do recall being given a Copy Book for home practice of letter formation, a typical practice until Grade 6. The tables at which we used to sit in the Infant School were replaced in the primary Grades by long desks seating five or six pupils. These had slots into which the slates could be inserted vertically. When the teacher asked the class to clear their desks, the command issued was "slates away!" This was an occasion for a noisy expression of relief as we dropped the slates producing a sound not unlike a volley of rifle shots, and usually brought a request from the teacher to repeat the process with no noise by holding the frames throughout. Thus, I suspect we may still have used slates in Grade Three, though by then paper, which may have been scarce during the War, seemed to be used more routinely.' The full context of John's account of writing during his primary school days can be found at: https://www.readinghalloffame.org/sites/default/files/history_of_literacy_22slates_away22_penmanship_in_queensland_australia.pdfSchool desks and benches/chairs have been in use in schools since formal group education started.Eight long school desks (five higher three lower), each with four inkwells and groove along length. eight school benches (five higher three lower). Each desk and bench accommodates four children.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village -
National Wool Museum
Textile - Quilt, Rosemary A.O. Cameron, Celebration Quilt, 1990
From Rosemary Cameron - This quilt has been made in 100% wool to celebrate the diversity, durability and beauty of pure wool, especially the lightweight cool wools. The woollen patches were kindly donated by Mr. David Jones, managing Director of Fletcher Jones and Staff which were pre-cut samples of European Fabrics in various weights, textures and colours. I had the task of creating a design around the fabrics available, some of which I only had to sample. I chose to surround my design with dark shades to encompass at the top of the quilt, the lightness of the sky and the trees, in the middle the warmth of summer, the dryness of central Australia and at the bottom the rick tones of Opals, our mineral wealth and the internal heart of earth. To add excitement and texture to this design I chose 31 Australian Wildflowers including all the Australian Floral Emblems, some unusual wildflowers and favourite small wildflowers. Twice life size, these flowers have been made of silk wool and cotton, embroidered, painted and beaded by our creative and talented Hamilton Quilters, their results are fantastic! The brilliance and timeless quality of these Australian Wildflowers intensify and complement the colours of the Wool Quilt. The Quilt was hand pieced and hand quilted at quilting bees. It has a woollen batting, binding and backing which was a delight to work with and very easy to quilt. The flowers were assembled and attached in small working bees. To the fifty-two Hamilton Quilters who have worked on this quilt for six months thank you for you hard work and creativity especially Joan H. Lyons for her time, enthusiasm and knowledge when difficulties arose. Joan M. Lyons has worked with me on various stages of this Quilt, her help and support has been tremendous. To my family who have tolerated scraps of wool and silk, photographs, wildflower books and specimens and drawings which have at times almost taken over our house, a year from ideas to completion, thank you for your support and help in many ways.Multi coloured patchwork quilt with native flowers protruding from centre in a diamond shape.Embroidered on back - "The Celebration Quilt" Made in 1990 by The Hamilton Quilters, Designed by Rosemary A.O. Cameron. Made of Pure Wool. Beryl Anderson, Joan Askew, Bett Basham, Marilyn Baulch, Rau Blaby, Pauline Boyd, Aileen Beckwith, Dorothy Beveridge, Ros Brommell, Rosemary Cameron, Gwen Cook, Anne Cordner, Kaylene Cowland, Elaine Denby, Barbara Dolman, Rosalie Duffield, Helen Fry, Glennys Gardner, Nola Gunning, Margaret Irvine, Bev Jeffrey, Emma Jensen, Betty Lacy, Helen Lampard, Joan H. Lyons, Joan M. Lyons, Elaine McDonald, Carole McEwan, Joy McLeod, Joyce McLeod, Mary May, Joan Mallinson, Susan Mason, Anne Menzel, Val Mills, Betty O’Brien, Di Pettigrew, Therese Read, Sherry Robertson, Lee Rowland, Irene Saddler, Nanette Templeton, Glenys Tindall, Liz Wallis, Ruth Walter, Marion Warburton. Alison Waterman, Pat Wilmot, Nola Malcolm, Ann Nicholls, Margaret Rowe, Jill Hillier.celebration, flowers, hamilton quilters, quilt, native flowers -
Bendigo Historical Society Inc.
Photograph - HILDA HILL COLLECTION: BLACK AND WHITE PHOTOS, 1923-1925
Series of Black & White Photos Hill Family & Friends. Hanging Rock Victoria Australia News Years Day 1925 Doreen, wearing all white dress and hat and holding dark coloured bag in right hand, Nora, also in all white outfit with large pockets and hat with dark coloured handbag held by her right hand and hat, Wal, dressed in grey suit white shirt and dark tie and dark hat, Jonah wearing white outfit with bands around the bottom and dark hat, & Elma skirt with circular bands and white blouse dark hat and paper in her left hand. Gentleman standing to the right wearing a dark suit and hat. Nora in white outfit and hat with dark bag in her left hand, Bill trench coat and light coloured hat, Elma wears a white dress with circular pattern and dark hat, Rob white trench coat over a dark suit white shirt and dark tie & Mev (not very clear) is wearing a white dress with a multi coloured jacket and dark hat, standing in front of a wooden tree enclosure, trees in distant background, January 1, 1923 Unknown Location. Kyneton Mineral Springs, five men and five women picnicking at Springs, fifth girls is taking the photo, January 1, 1923. girl sitting on the beach, wearing white clothing and a white hat, Down The Coast. Bunt and friend both dressed in dark trousers and white shirts, one with a striped tie, tree and house in background, rectangular open top tin also in background, 1924..australia, history, post war life -
Flagstaff Hill Maritime Museum and Village
Functional object - Crucible, The Patent Plumbago Crucible Company, circa 1873
This crucible was raised from the wreck of the Loch Ard. It is one of six similar relics, in a range of sizes, now in the Flagstaff Hill collection. All were manufactured by the Morgan brothers who founded the Patent Plumbago Crucible Company in 1856, making crucibles in a small factory in Battersea London. A crucible is a container used for purifying and melting metals so that they can be cast in a mold to a predetermined shape and use. They must withstand extremely high temperatures, abrupt cooling, and shed their contents with minimal adherence. The addition of graphite to the traditional firing clays greatly enhanced the durability of industrial crucibles this technique was pioneered by the Morgan Bros thereby making a significant technological advance in foundry technology and metallurgy. The Morgans first noticed the advantages of graphite crucibles at the Great Exhibition held in London in 1851. Initially, they contracted to be sole selling agents for the American-made products of Joseph Dixon and Co. from New Jersey, but in 1856 they obtained that firm's manufacturing rights and began producing their graphite crucibles from the South London site. The Morgans imported crystalline graphite in 4-5 cwt casks from the British colony of Ceylon (now Sri Lanka) and mixed it with conventional English (Stourbridge) clays to be fired in kilns. Their products were purchased by the Royal Mints in London and India and exported to official mints in France and Germany. They were successful exhibitors of their crucibles and furnaces at the London Exhibition held in 1861 (Class 1, Mining, quarrying, metallurgy and mineral products, Exhibit 265, Patent Plumbago Crucible Co). The range of sizes represented by the six crucibles retrieved from the Loch Ard suggests they may have been part of a sample shipment intended for similar promotion in the Australian colonies or at Melbourne's International Exhibition to be held in 1880. A newspaper account of an 1864 tour of the Morgan brothers' 'Black Potteries' at Battersea indicates: "All the pots were numbered according to their contents, each number standing for one kilogram, or a little over two pounds; a No. 2 crucible contains two kilograms; a No. 3, three kilograms, and so on." These numbers are obscured by marine sediment on three of the crucibles in the Flagstaff Hill collection, but those legible on the remaining three are 5, 6, and 8. None of the six is of the same size. (For more information on the Loch Ard wreck see note sec this document) The shipwreck of the Loch Ard is of significance for Victoria and is registered on the Victorian Heritage Register ( S 417). Flagstaff Hill has a varied collection of artefacts from Loch Ard and its collection is significant for being one of the largest accumulation of artefacts from this notable Victorian shipwreck of which the crucible is a small part. The collections objects give us a snapshot of how we can interpret the story of this tragic event. The collection is also archaeologically significant as it represents aspects of Victoria's shipping history that allows us to interpret Victoria's social and historical themes of the time. Through is associated with the worst and best-known shipwreck in Victoria's history.A medium size crucible, or fluxing pot, for heating and pouring molten metal. The container rises in a slight curve from a smaller flat base to a wider open top with a lip for pouring. It was recovered from the wreck of the LOCH ARD. The crucible has a coating of sediment that obscures its numerical specifications of size and capacity. The markings that remain visible indicate it is a Morgan’s crucible, made with graphite to prevent cracking and provide a smooth non-adhesive inner surface. .On base: “…ORGAN’S …ENT”flagstaff hill, warrnambool, flagstaff-hill-maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, graphite crucible, plumbago crucible, morgan's crucible company, loch ard, morgan potteries, crucible, fluxing pot -
Forests Commission Retired Personnel Association (FCRPA)
Rakehoe, McLeod Tool
Bushfire perimeter rather than bushfire area is the main control problem for firefighters on the ground. A conundrum rapidly compounded by spot fires. A small 5 ha fire can be nearly 1 km around the perimeter. That's a long way to build a control line by hand in rough bush. Dry firefighting techniques by hand were mostly confined to “knocking down” or “beating out” the flames, as well as "digging out". Digging or raking a “mineral earth” trail down to bare dirt proved most effective in forest fuels which, unlike grass, tend to retain heat and smoulder. Early tools were whatever happened to be close at hand. They were simple and primitive and included shovels, slashers, axes, hoes, beaters and rakes. A cut branch to beat the flames was often the only thing available. Farming and logging tools, developed over centuries of manual labour, and readily available at local hardware stores came into use, but little thought was given to size, weight, and balance. For years foresters experimented with combination tools. In about 1952 fire beaters and other implements were being replaced with Rakuts. However, its believed the now common Rakehoe is an Australian variation of the American McLeod Tool which was developed in 1905 by forest ranger Malcolm McLeod of the Sierra National Forest. The late Athol Hodgson advised that predecessors, Reg Torbet who had been the Chief Fire Officer for the Forests Commission from 1948-1956, along with his QLD counterpart Clive Price, went in late 1951 as Australian delegates on a 10 week fire study tour of Nth America organised by the United Nations. They came back with a couple of McLeod tools from Canada. Cam MacLeod (different spelling) had been the Head of Fire Research for the Canadian Forest Service at the time and had supplied them. The tools were ideal for deciduous forests in the eastern provinces and Clive arranged to have them manufactured in QLD. The Rakho, as it was then spelled, was first issued to FCV crews 65 years ago in 1955-56. The American Pulaski had been trialled, but never found favour with Australian firefighters.First used in 1955Rakehoebushfire -
Flagstaff Hill Maritime Museum and Village
Functional object - Crucible, The Patent Plumbago Crucible Company, circa 1878
This crucible was raised from the wreck of the LOCH ARD. It is one of six similar relics, in a range of sizes, now in the Flagstaff Hill collection. All bear markings to indicate their manufacture by the Morgan brothers of Battersea, trading as the Patent Plumbago Crucible Co. A crucible is a container used for purifying and melting metals so that they can be cast in a mould to a predetermined shape and use. They must withstand extremely high temperatures, abrupt cooling, and shed their contents with minimal adherence. The addition of graphite to the traditional firing clays greatly enhanced the durability of industrial crucibles in mid-Victorian Britain, a significant technological advance at a time of great activity in foundries and expansion of demand for refined metals. The Morgans first noticed the advantages of graphite crucibles at the Great Exhibition held in London in 1851. Initially they contracted to be sole selling agents for the American-made products of Joseph Dixon and Co. from New Jersey, but in 1856 they obtained that firm’s manufacturing rights and began producing their own graphite crucibles from the South London site. The Morgans imported crystalline graphite in 4-5 cwt casks from the British colony of Ceylon (now Sri Lanka) and mixed it with conventional English (Stourbridge) clays to be fired in kilns. Their products were purchased by the Royal Mints in London and India, and exported to official mints in France and Germany. They were successful exhibitors of their crucibles and furnaces at the London Exhibition held in 1861 (Class 1, Mining, quarrying, metallurgy and mineral products, Exhibit 265, Patent Plumbago Crucible Co). The range of sizes represented by the six crucibles retrieved from the LOCH ARD, suggest they may have been part of a sample shipment intended for similar promotion in the Australian colonies ― at Melbourne’s International Exhibition to be held in 1880. The summary of cargo manifest, by Don Charlwood in ‘Wrecks and Reputations’ does not mention any crucibles, implying that they were not a large consignment of uniform items. A newspaper account of an 1864 tour of the Morgan brothers’ ‘Black Potteries’ at Battersea indicates: “All the pots were numbered according to their contents, each number standing for one kilogram, or a little over two pounds; a No. 2 crucible contains two kilogrammes; a No. 3, three kilogrammes, and so on.” These numbers are obscured by marine sediment on three of the crucibles in the Flagstaff Hill collection, but those legible on the remaining three are 5, 6, and 8. None of the six are of the same size from a visual appraisal.The shipwreck of the LOCH ARD is of State significance ― Victorian Heritage Register S417A large crucible, or fluxing pot, for heating and pouring molten metal. It was recovered from the wreck of the LOCH ARD. The clay fired vessel rises from circular flat base to a larger rim with pouring lip. It is stained a rust colour and bears some sedimentary accretion. Half of its loose fitting lid with central knob has also survived. Markings on the artefact indicate it is a Morgan’s crucible, made with graphite to prevent cracking in the furnace and provide a smooth (non-adhesive) inner surface. On base: “…RGAN’S PATENT CRUCIBLE”. On rim: “MORGAN’S PATENT P…” Below top edge "BAK"flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, graphite crucible, plumbago crucible, morgans crucible company, loch ard, fluxing pot, crucible -
Flagstaff Hill Maritime Museum and Village
Functional object - Crucible, The Patent Plumbago Crucible Company, circa 1878
This crucible was raised from the wreck of the LOCH ARD. It is one of six similar relics, in a range of sizes, now in the Flagstaff Hill collection. All bear markings to indicate their manufacture by the Morgan brothers of Battersea, trading as the Patent Plumbago Crucible Co. A crucible is a container used for purifying and melting metals so that they can be cast in a mould to a predetermined shape and use. They must withstand extremely high temperatures, abrupt cooling, and shed their contents with minimal adherence. The addition of graphite to the traditional firing clays greatly enhanced the durability of industrial crucibles in mid-Victorian Britain, a significant technological advance at a time of great activity and expansion in foundries and demand for refined metals. The Morgans first noticed the advantages of graphite crucibles at the Great Exhibition held in London in 1851. Initially they contracted to be sole selling agents for the American-made products of Joseph Dixon and Co. from New Jersey, but in 1856 they obtained that firm’s manufacturing rights and began producing their own graphite crucibles from the South London site. The Morgans imported crystalline graphite in 4-5 cwt casks from the British colony of Ceylon (now Sri Lanka) and mixed it with conventional English (Stourbridge) clays to be fired in kilns. Their products were purchased by the Royal Mints in London and India, and exported to official mints in France and Germany. They were successful exhibitors of their crucibles and furnaces at the London Exhibition held in 1861 (Class 1, Mining, quarrying, metallurgy and mineral products, Exhibit 265, Patent Plumbago Crucible Co). The range of sizes represented by the six crucibles retrieved from the LOCH ARD, suggest they may have been part of a sample shipment intended for similar promotion in the Australian colonies ― at Melbourne’s International Exhibition to be held in 1880. A summary of the LOCH ARD cargo manifest, by Don Charlwood in ‘Wrecks and Reputations’ does not mention any crucibles, implying that they were not part of a larger consignment of uniform items. A newspaper account of an 1864 tour of the Morgan brothers’ ‘Black Potteries’ at Battersea indicates: “All the pots were numbered according to their contents, each number standing for one kilogram, or a little over two pounds; a No. 2 crucible contains two kilogrammes; a No. 3, three kilogrammes, and so on.” These numbers are obscured by marine sediment on three of the crucibles in the Flagstaff Hill collection, but those legible on the remaining three are 5, 6, and 8. None of the six are of the same size from a visual appraisal. The shipwreck of the LOCH ARD is of State significance ― Victorian Heritage Register S417A No. 6 size Morgan’s graphite crucible (i.e. 6kgs capacity). The crucible rises in a slight curve from a smaller flat base up to a wider top with a (chipped) pouring lip. It was recovered from the wreck of the LOCH ARD. The artefact is largely accretion free despite its long period of submersion at the wreck site. It has a number of visible maker’s markings which identify the manufacturer and the smelting capacity of the pot. The graphite crucible is in fair and stable condition. The number “6” which is framed in a square. The letters “THE PATENT PLUMBAGO CRUCIBLE COMPANY” and “BATTERSEA WORKS COMPANY”. Below rim "... GNS"flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, graphite crucible, plumbago crucible, morgan's crucible company, loch ard, crucible, fluxing pot -
The Beechworth Burke Museum
Geological specimen - Coorongite
Coorongite is a dark, rubber-like, highly resilient structureless algal deposit. In the Coorong district of South Australia it occurs in moderate quantities associated with the coastal swamps and sand dunes which extend for a considerable distance east of the mouth of the Murray. This particular specimen was recovered from the south of the Coorong River, South Australia. A type of sediment rich in organic matter, Coorongite is the unlithified end-member of the sapropelic coal series. The members of the sapropelic coal series can be ranked in order as sapropel (the unlithified form), sapropelic-lignite, and sapropelic-coal (the lithified forms) based on increasing carbon content and decreasing volatile content. Sapropel (Coorongite) is an unlithified dark, pulpy, fine organic mud containing concentrations of algae and miospores that are more or less identifiable. Coorongite is typically found as an algae like substance, that can be found in irregular size pieces. Coorongite was believed to be dried up oil due to its rubber-like texture. The Coorongite is also soft to the point where it can be cut into with a knife or it can be broken and torn by hand. Otherwise known as 'Kurangk', the Coorong River is home to the Ngarrindjeri people, which acts as both a place for gathering food and a spiritual place. In 1852 the first sight of Coorongite was found along the Coorong River. The finders mistook the Coorongite for dried up oil, which lead to the belief that there were oil reserves under the Coorong River. Between the 1860s and the 1930s the Coorong River became a place where mining oil and Coorongite became precedent. Nowadays, the local council and the South Australian Government are working together with the Ngarrindjeri people to sustain and preserve the Coorong River and the culture that is with it. Soon after gold was discovered in 1851, Victoria’s Governor La Trobe wrote to the Colonial Office in London, urging ‘the propriety of selecting and appointing as Mineral Surveyor for this Colony a gentleman possessed of the requisite qualifications and acquaintance with geological science and phenomena’. Alfred Selwyn was appointed geological surveyor in Australia in 1852 which began the Geological Survey of Victoria. Selwyn went on to collect geological samples and catalogue thousands of specimens around Australia. In 1853-69 the Geological Survey issued under Selwyn's direction sixty-one geological maps and numerous reports; they were of such high standard that a writer in the Quarterly Journal of the Geological Society of London bracketed the survey with that of the United States of America as the best in the world. During his years spent in Australia, Selwyn collected numerous significant geological specimens, examples of which are held in collections such as the Burke Museum.Coorongite is considered to be a mineral with a unique texture, where it can be both hard and soft. Coorongite can also be considered to be a rare mineral, as it is only located along the Coorong River and due to the mining of it, has left very few sources. It was believed at one point that Coorongite could be used to replace oil. This specimen is part of a larger collection of geological and mineral specimens collected from around Australia (and some parts of the world) and donated to the Burke Museum between 1868-1880. A large percentage of these specimens were collected in Victoria as part of the Geological Survey of Victoria that begun in 1852 (in response to the Gold Rush) to study and map the geology of Victoria. Collecting geological specimens was an important part of mapping and understanding the scientific makeup of the earth. Many of these specimens were sent to research and collecting organisations across Australia, including the Burke Museum, to educate and encourage further study.Three solid varyingly hand-sized pieces of wooden appearing organic matter derived from the river in the Coorong District in South Australia. A rubber-like, highly resilient structureless algal deposit.Specimen 245 page 69 / in Descriptive Register / "Elcestic Bitumen, / Coorangite" South of / Coorung River, South Australia . / C. WIllman / 15/4/21burke museum, beechwoth, indigo shire, beechworth museum, geological, geological specimen, mineraology, coorong, coorong river, kurangk, ngarrindjeri, south australia, coorongite, coorongite specimen -
City of Moorabbin Historical Society (Operating the Box Cottage Museum)
Manufactured Glass, bottle 'Kruse's Magnesia', 20thC
Johann August (John) Kruse was instrumental in the development of the pharmaceutical industry and pharmacy training in Victoria. He was a driving force behind the creation of the Pharmaceutical Society of Victoria and was appointed a founding member of the Society's inaugural council in 1857. He manufactured many pharmaceuticals and health products such as mineral waters and 'Kruse's Fluid Magnesia' (1863) which is still in use today. He later went on to produce insecticides and dynamite, then established his own analytical chemistry service. In 1878 Kruse established Victoria's first pharmacy training facility - the Melbourne School of Pharmacy. There pharmacy apprentices were taught chemistry, botany, materia medica and Latin, while country students could study by correspondence. The School was endorsed and monitored by the Pharmacy Board of Victoria to which Kruse was appointed in 1880. Kruse's pharmacy school was the forerunner of the Victorian College of Pharmacy, Monash University, which remains Victoria's only pharmacy training institute. In 1853, shortly after qualifying as pharmacist at the University of Göttingen, Johann August (John) Kruse, moved to London. The medical practitioner Dr S. Weil sent Kruse to Victoria, Australia to manage a new pharmacy and tobacconist's shop which he was having built at 136 Bridge Rd in Richmond. In 1856 Kruse opened a second pharmacy 'John Kruse and Company Chemists and Druggists' at 207 Bourke Street. 1857 the Richmond shop was destroyed by fire, so all pharmaceutical production was moved to the Bourke St premises and later to his new location at 184 Bourke St.. Kruse was forced to sell his business in 1868 to Felton Grimwade and Company and work for them as manager of their chemical works. By the early 1870s he had regained financial independence so left the company to establish his own businesses again. He opened up a pharmacy at 31 Swanston St and in c1874 leased Victoria's premier natural springs, Clifton Springs, on the northern side of the Bellarine Peninsula, where he established a bottling plant. Suspensions of magnesium hydroxide in water, often called Milk of Magnesia, are used as an antacid to neutralize stomach acid, and as a laxative. Milk of magnesia is sold for medical use as chewable tablets, capsules, and as liquids having various added flavours Kruses Fluid Magnesia 300ml Extralife Kruse’s Fluid Magnesia, Magnesium supplement. Rapidly absorbed, easily digested. Improves general well being, corrects magnesium deficiency. Helps relieve indigestion, when due to acidity. In 1878 Kruse established Victoria's first pharmacy training facility - the Melbourne School of Pharmacy, the forerunner of the Victorian College of Pharmacy, Monash University, which remains Victoria's only pharmacy training institute. A glass bottle containing ‘Kruse’s’ Magnesia’ medicineKRUSE’S / PRIZE MEDAL / MAGNESIA/ K / FELTON-GRIMWADE & CO. MELBOURNE Directions for use ......glass works, pharmaceutical glass, pharmacy, kruse johann august (john), dr weil s, ., victorian college of pharmacy, monash university, university of göttingen, felton grimwade and company, magnesium bicarbonate, magnesium oxide -
Federation University Historical Collection
Letter - Correspondence, Margaret Malone, Letter regarding gold assay from Mount Egerton Mine, 10/02/2014
Margaret Malone was associated with a kaolin mine at Mount Egerton. WOMAN WHO MANAGES A MINE Works With A Vision (By a Special Corespondent) BALLARAT, August 22.—Like a Heroine in a Bret Harte story of the Soaring: Forties Miss Margaret Malone, the only woman mine manager in Australia, has lived most of her life in an atmosphere where hope springs eternal in the gold-seeking breast. Forty years ago her father gave up farming to seek the elusive mineral near Ballarat. "One day my mother went for a walk along the Gordon-Egerton road and picked up a pebble with a few specks of gold in it," she told an interviewer yesterday, recounting the early history of the nine she now runs at Egerton. "Dad said, There must be more where that came from,' and hopefully sank a shaft. Our hopes were dashed, however, when he found only white clay. No one realised then the value of the disappointing looking white stuff which was all that Dad could find from every shaft he sank. At last be gave up the search, and the kaolin remained untouched." Later an Englishman from a pottery town in the old country urged Mr. Malone to try and sell his clay, and he sent some to the Bendigo potteries, but nothing came of it, and it was left to Miss Malone, after her father's death, to start on her unusual career by finding purchasers in Sydney and Melbourne for her clay, and herself working the mine. Strenuous Work "Mine managing is strenuous work in more ways than one," she admitted. "I have, to go down my mine daily, ad sometimes have to descend perpendicular ladders for about 150 ft. to reach areas being worked. I have to be my own manager, she explained, "because it is necessary to teach the men I employ the methods of grading clays." A New Cure She is convinced that a number of uses for kaolin, apart from pottery, soap and drugs, are yet to be discovered. "One of my employees has already found a new use for it," she said, "although scarcely one to be generally recommended, perhaps. By chewing a small piece of the clay he firmly believes that he "cured himself of heart burn." "All That Glistens" There is more in Miss Malone's mining than meets the eye, however. The actual working of the field and the substantial profit she makes on it do not fill her days. Always before her - dangles the compelling vision that caused her father, in his day, to give up farming to seek for gold. "All the time I am getting my clay dug," she confessed, "1 am watching for the colour of gold. One of these days I may strike it." WOMAN WHO MANAGES A MINE Works With A Vision (By a Special Corespondent) BALLARAT, August 22.—Like a Heroine in a Bret Harte story of the Soaring: Forties Miss Margaret Malone, the only woman mine manager in Australia, has lived most of her life in an atmosphere where hope springs eternal in the gold-seeking breast. Forty years ago her father gave up farming to seek the elusive mineral near Ballarat. "One day my mother went for a walk along the Gordon-Egerton road and picked up a pebble with a few specks of gold in it," she told an interviewer yesterday, recounting the early history of the nine she now runs at Egerton. "Dad said, There must be more where that came from,' and hopefully sank a shaft. Our hopes were dashed, however, when he found only white clay. No one realised then the value of the disappointing looking white stuff which was all that Dad could find from every shaft he sank. At last be gave up the search, and the kaolin remained untouched." Later an Englishman from a pottery town in the old country urged Mr. Malone to try and sell his clay, and he sent some to the Bendigo potteries, but nothing came of it, and it was left to Miss Malone, after her father's death, to start on her unusual career by finding purchasers in Sydney and Melbourne for her clay, and herself working the mine. Strenuous Work "Mine managing is strenuous work in more ways than one," she admitted. "I have, to go down my mine daily, ad sometimes have to descend perpendicular ladders for about 150 ft. to reach areas being worked. I have to be my own manager, she explained, "because it is necessary to teach the men I employ the methods of grading clays." A New Cure She is convinced that a number of uses for kaolin, apart from pottery, soap and drugs, are yet to be discovered. "One of my employees has already found a new use for it," she said, "although scarcely one to be generally recommended, perhaps. By chewing a small piece of the clay he firmly believes that he "cured himself of heart burn." "All That Glistens" There is more in Miss Malone's mining than meets the eye, however. The actual working of the field and the substantial profit she makes on it do not fill her days. Always before her - dangles the compelling vision that caused her father, in his day, to give up farming to seek for gold. "All the time I am getting my clay dug," she confessed, "1 am watching for the colour of gold. One of these days I may strike it." (WOMAN WHO MANAGES A MINE Works With A Vision (By a Special Corespondent) BALLARAT, August 22.—Like a Heroine in a Bret Harte story of the Soaring: Forties Miss Margaret Malone, the only woman mine manager in Australia, has lived most of her life in an atmosphere where hope springs eternal in the gold-seeking breast. Forty years ago her father gave up farming to seek the elusive mineral near Ballarat. "One day my mother went for a walk along the Gordon-Egerton road and picked up a pebble with a few specks of gold in it," she told an interviewer yesterday, recounting the early history of the nine she now runs at Egerton. "Dad said, There must be more where that came from,' and hopefully sank a shaft. Our hopes were dashed, however, when he found only white clay. No one realised then the value of the disappointing looking white stuff which was all that Dad could find from every shaft he sank. At last be gave up the search, and the kaolin remained untouched." Later an Englishman from a pottery town in the old country urged Mr. Malone to try and sell his clay, and he sent some to the Bendigo potteries, but nothing came of it, and it was left to Miss Malone, after her father's death, to start on her unusual career by finding purchasers in Sydney and Melbourne for her clay, and herself working the mine. Strenuous Work "Mine managing is strenuous work in more ways than one," she admitted. "I have, to go down my mine daily, ad sometimes have to descend perpendicular ladders for about 150 ft. to reach areas being worked. I have to be my own manager, she explained, "because it is necessary to teach the men I employ the methods of grading clays." A New Cure She is convinced that a number of uses for kaolin, apart from pottery, soap and drugs, are yet to be discovered. "One of my employees has already found a new use for it," she said, "although scarcely one to be generally recommended, perhaps. By chewing a small piece of the clay he firmly believes that he "cured himself of heart burn." "All That Glistens" There is more in Miss Malone's mining than meets the eye, however. The actual working of the field and the substantial profit she makes on it do not fill her days. Always before her - dangles the compelling vision that caused her father, in his day, to give up farming to seek for gold. "All the time I am getting my clay dug," she confessed, "1 am watching for the colour of gold. One of these days I may strike it." (Adelaide Observer, 31 August 1929.)Hand written letter from Margaret Malone of the Mount Egerton Mine.Mount Egerton Mine February 10/14 The Manager Mining Dept Dear Sir, Last Monday week, I left with Mr Martell, a parcel of stone to be treated, requesting that cost of treatment, be deducted from some and balance of gold be forwarded me to above address. I was informed, this would occupy about a day or so, but not having received any communication so far, I shall be glad to hear from you are same. Yours faithfully Margaret Malonemargaret malone, female mine manager, kaolin, mount egerton, women -
Flagstaff Hill Maritime Museum and Village
Animal specimen - Whale bone, Undetermined
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 -
Flagstaff Hill Maritime Museum and Village
Animal specimen - Whale bone, Undetermined
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 -
Flagstaff Hill Maritime Museum and Village
Animal specimen - Whale bone, Undetermined
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 -
Flagstaff Hill Maritime Museum and Village
Animal specimen - Whale bone, Undetermined
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 -
Flagstaff Hill Maritime Museum and Village
Animal specimen - Whale bone, Undetermined
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 -
Flagstaff Hill Maritime Museum and Village
Animal specimen - Whale bone, Undetermined
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 -
Flagstaff Hill Maritime Museum and Village
Animal specimen - Whale Vertebrae, Undetermined
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 -
Flagstaff Hill Maritime Museum and Village
Animal specimen - Whale Jaw Bone, Undetermined
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 -
Flagstaff Hill Maritime Museum and Village
Animal specimen - Whale Rib Bone, Undetermined
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 -
Bendigo Historical Society Inc.
Photograph - HILDA HILL COLLECTION: BLACK AND WHITE PHOTOS, 1917-1918
Series of Black & White Photos Hill Family & Friends Life During The Final Years of The First World War. Hilda Hill and another, seated on steps , background building weatherboard construction and glass windows,girl at rear wearing dark dress with check scarf around her neck, girl at front wearing a lighter colour dress and white blouse, and medal on ribbon around her neck, S.H.L.C. November 1917. Jack & Frank, both dressed in dark suits white shirts and dark ties, man standing outside of vehicle with right arm resting on the car and one foot on the running board, with the family car, dark colour with wooden spoke wheels. Francie, wearing dark skirt and white blouse & the dog, kneeling in front of a netting fence with top rail, background is corrugated iron shed wall. Easter 1918. Man in dark suit white shirt and dark tie holding a tennis racquet over his head, brick wall to left and doorway, on the verandah of 'The Ranche' property. Horse & Gig, man and boy seated on the gig and boy standing behind all dressed dark clothing, man wearing a hat, boy at rear wearing shorts and long socks with boots, to right gable roof shed, 'Durvol' property Kyneton Victoria Australia. Frank & Sweep the dog up a ladder, high paling fence in right background. Six young ladies , three standing and three seated on a white wooden railing fence, all dressed in lightly coloured outer wear, some showing white blouses Kyneton Mineral Springs 27th September 1918. Group of four young ladies all dressed in white and wearing broad brimmed hats, two men one sitting and one lying on the ground, man at rear white shirt and dark tie with broad brimmed hat, man at front, dark trousers and white shirt with dark waistcoat, no person has been identified in this photo, In the shade Hanging Rock?Hilda Hill Personal Colllectionaustralia, history, post war life