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Parks Victoria - Cape Nelson Lightstation
Furniture - Cabinet
The tall, two‐door cupboard with curved shelves is without a back and is taller than the bench cupboard on the lower lantern room of the lighthouse . The curved shelving suggests that this practical storage cupboard was custom‐built or adapted to serve in this location on the landing level below the lantern room. It is not known when it was provided to the lightstation. It shares the structural features of this furnishing as well as other nineteenth century utilitarian cabinets that were made for Victoria’s lightstations, such as those fitted beside fireplaces in the keepers’ quarters (for example CNLS 0016) or serving as lantern room cupboards. They have doors simply framed and bevelled around central panels. This particular cupboard, which is painted grey with four white panels, is unusual both for its height and the four doors, with the twin top panels taller than those underneath. This panel arrangement repeats the design of the lightstation’s door cases. Further research may reveal more about its manufacture. It is not known whether it is attached to the wall or movable; if attached it is considered to be a fixture and included in the Victorian Heritage Register listing for the lightstation (VHR H1773). Other similar cabinets which have been constructed to fit the curved wall of a lighthouse survive at Cape Schanck, varnished wood benchtop, 2‐door cabinet with brass door knob, no drawers); Point Hicks, benchtop, 2‐door, painted green with silver doors, no drawers) and Gabo Island bench top, 2‐door, no drawers, green paint removed to reveal cedar timber), and Cape Nelson, benchtop, 2‐door, 2‐drawer, partially varnished). Cape Nelson’s tall cupboard with curved shelves and back profile is unusual among the lighthouse furnishings. The cabinet is a unique, original feature of the lighthouse and has first level contributory significance for its historic values and provenance.The tall, two‐door cupboard with curved shelves is without a back and has curved shelving. Painted grey with four white panels, on the four doors, with the twin top panels taller than those underneath. -
Flagstaff Hill Maritime Museum and Village
Tool - Caulking Tool, Ward & Payne Ltd, Late 19th century
Caulking is the traditional technique used on wooden vessels built with butted or clinker-built planks to fill the gaps between these planks while still allowing the wood to flex and move. This involved driving the irons, hammered in with the mallet, deep into the seams to open them up. After this, spun yarn, oakum (hemp) or cotton was driven deep into the gaps. The hemp or cotton was soaked in creosote or pine tar to make the joins watertight. Caulking also played a structural role in tightening up the hull or deck by reducing the longitudinal movement of the neighbouring planks. The subject item was made by Ward & Payne of the Limbrick Works at Hillsborough, Sheffield England manufacturers of hand-forged tools. Their trademark registered in 1850 was a Letter "W" & "P" stamped into the steel. The firm was established by David Ward (1767-1822) in 1803 the company became David Ward & Sons, in 1837 after Ward's son Edward joined the firm. In 1845 Henry Payne the founder's son-in-law became a partner but died in 1850 after which the company reverted to the Ward family. The business then concentrated on making carving tools, chisels and gouges. In 1882 David Ward's grandson David Ward Jr. (1835-1889) purchased land and built a factory at Sheffield North known as the "Limerick Wheel". For a time Wards operated from both 106-114 West Street Sheffield and at Limbrick Road, Hillsborough on the river Loxley. By 1911 they had expanded into making spades, forks, sheep shears and many other types of edged tools including drills and wood planes. In 1967 Wilkinson Sword purchased all the company's share capital and continued to sell Ward & Payne tools until 1970 when a fire burned the factory down and housing development was built on the site. The subject item is significant as it gives a snapshot of the technological development of sailing ships and their operation before steam-powered vessels took over around the world. Tools such as the subject item demonstrate the traditional craftsmanship and skill of the shipwright and the aesthetic quality of the timber ships designs of the time. Caulking tool with square end"WARD Sheffield"flagstaff hill, warrnambool, flagstaff hill maritime museum, shipwreck coast, flagstaff hill maritime village, james s steele, caulking iron, caulking tool, shipwright tools, ward & payne sheffield, forged tools -
Coal Creek Community Park & Museum
Bottle, glass, 1918 - c. 1925
TROVE : The Age (Melbourne, Vic. : 1854 - 1954) Thursday 22 August 1918 p 6 Article 'Doctors and Lodges. Malvern Medical Association. The friendly societies of Malvern have formed a medical association in connection with the Malvern and District U.F.S. Dispensary. This has been registered as the Malvern and District U.F.S. Medical Association and Dispensary. Practically all the societies have joined it. The committee has appointed as medical officer Dr. J Weir, who is now carrying on the work of the institution. Another doctor is to be appointed shortly to assist him. The committee lately purchased a property in Valetta-street, formerly used by the Church of Christ. Structural alterations have been made, and the business will be transferred from High-street to the new building early in September'. TROVE : The Prahran Telegraph (Vic. : 1889 - 1930) Friday 23 January 1925 p 6 Article 'Malvern Dispensary. ANNUAL REPORT AND BALANCE SHEET. The 16th report and balance sheet for the year ending December 31st last of the Malvern and District U.F.S. Medical Association and Dispensary signed by the president (Mr.Chas. A. W. Smith) has been issued. It is the first annual report since the erection of the new hall and dispensary in Valetta street, and discloses a satisfactory state of affairs. Mr. Smith, who is now a past president of the Dispensary, has been commended on. all sides for the active interest He at all times took in the work of the dispensary, and he has every reason to feel pleased and gratified that the erection of the new building was put in hand and completed during his tenure of office. The enterprise is a credit to the district, and shows that, those associated with friendly societies work in Malvern are imbued with a true progressive spirit. The dispensary is assured of a successful and useful future.........................................'. TROVE : Digitised newspaper articles.- The Dispensary Hall in Valetta Street, Malvern was used as a meeting place and dance hall after 1925.Hexagonal clear amber glass bottle, 1/4 full of yellow / brown liquid with cork stopper secured by string. White paper label with red printed text and hand writing. Bottle has 3 plain sides, 2 sides with 'x' stipple pattern either side of a panel with embossed text.Embossed on side of bottle 'NOT TO BE TAKEN', '8'. Embossed on base of bottle '8', followed by an AGM monogram, over one indistinct character and '422M'. On the white paper label printed in red 'POISON' NOT TO BE TAKEN', followed by hand written script in blue ink 'Use on pad as directed. Mr. Williams' , then printed in red, double red lines followed by MALVERN & DISTRICT U.F.S., M.A. & DISPENSARY, VALETTA STREET, MALVERN.poison, friendly societies, amber glass, pharmacist, dispensary, topical medications. -
Australian Gliding Museum
Machine - Glider – Sailplane
Prior to World War II an international competition was held for design of a standard sailplane for use in Olympic competition in 1940 in Finland. The design chosen was the “Meise” from DFS in Germany and its designer Hans Jacob. The 1940 Olympics were cancelled due to the outbreak of war and post war international gliding competition has been organized as World Championships, not as an Olympic event. After the war the Meise was manufactured by firms in Europe and a few were built by amateurs from plans. In 1945, a United Kingdom firm, Chilton Aircraft Limited, revised the plans for the DFS Meise Olympia keeping its aerodynamic shape and prepared new technical drawings for the production of the Chilton Olympia. It engaged Elliotts of Newbury (a firm with aircraft production experience during the war) to built a set of wings for its prototype. The wings were made by Elliotts but it apparently refused to let Chiltons have the jigs required to build more wings. The matter was resolved by Chiltons transferring its production rights and equipment to Elliotts. Elliotts produced several batches of Olympias (the “EON Olympia”) – probably about 150 in total from 1947 including Marks 1, 2 and 3 versions (featuring some structural changes and design improvements). The Australian Gliding Museum’s Olympia is a Mark 2 (actually 2B according to the logbook) which can be distinguished by the built in main wheel and blown Perspex canopy. It was designated as serial number EON/O/34 by Elliotts. It was damaged badly at Bristol, UK, in 1949. The wreckage was acquired by a Melbourne based syndicate including Dave Darbyshire, and imported into Australia. Additional damage occurred in shipping due to the need to shorten the wings to fit them into a crate. The syndicate rebuilt the glider and re-launched it in 1956 (registration number VH-GHR). It was flown by the syndicate and several gliding clubs in Victoria and South Australia until about 1972. A potentially airworthy example of a now rare sailplane of historical importanceSingle seat wooden sailplane, partly restored.australian gliding, glider, sailplane, dfs, hans jacob, meise, olympics, eon olympia, chilton aircraft, elliotts of newbury, dave darbyshire, great eastern gliding club, barossa valley gliding club, murray bridge gliding club -
Melton City Libraries
Photograph, Melton Railway Bridge, c.1884
"The Melton Viaduct, opened in 1886, is of State heritage significance as a very large and visually distinctive wrought iron, lattice girder trestle bridge over the Werribee River (now Melton Reservoir). It comprises 18.3 and 9.1 metre spans, in a generally alternate arrangement, of total length 375 metres, and standing 38 metres over the Werribee River. Wrought iron small section iron was used to build tension trussed trestle legs, which supported four lines of rivetted wrought-iron deck-type double lattice trusses. It has bluestone abutments and pier bases of coursed rock-faced bluestone with drafted margins. The larger half-piers, now usually submerged in the Melton Reservoir have sharp tapered cutwaters and curved coping at the tops. While designed to carry two rail tracks it has only ever been used as a single track line. Despite several alterations to its deck structure, it remains an outstanding example of a lighter structural design employing open metal trestle supports and metal truss girders. The direct Melbourne to Ballarat railway link of which the Melton viaduct was the major engineering work contributed significantly to the history and development of Victoria. This new link reflected Ballarat’s diversifying economy as well as the commercial and political influence of the metropolis. Construction of the bridge, and the associated large workers camp, were extensively photographed, documenting an important episode in local history. The railway enabled the development of new industries in the Melton area, notably the timber industry and a chaff industry of national importance, greatly facilitated the later transition of the Shire from a pastoral to a farming economy, and struck a major blow to Melton township’s era as a wayside town servicing Ballarat road (especially coach) traffic". Melton Railway Bridge being built across the Werribee Rivertransport -
Eltham District Historical Society Inc
Photograph - Digital Photograph, Alan King, Eltham Living and Learning Centre, 26 January 2008
In 1857, tanner John Pearson purchased three and a half acres of land in Little Eltham, at the western end of Pitt Street, with a 70-foot frontage to Maria Street (Main Road) and stretching down to the Diamond Creek for £100. He contracted Benjamin Oliver Wallis to build house for him. Wallis, a mason by trade who originated from the Cornish village of Newlyn, migrated to Melbourne in 1853 and was shortly engaged by Richard Warren to build the Eltham Hotel, which opened in 1854. When Warren fell into financial difficulty in 1858, Wallis purchased the hotel. That same year, Pearson constructed a tannery below the house with access to the water in the Diamond Creek. When Pearson became bankrupt in 1867, Wallis similarly acquired the house from Pearson’s creditors in 1868 and lived there until his death in 1896. For some of this time the house was in the name of Wallis’s son Richard but following his death in 1888, ownership reverted to his father. It was purchased by retired teacher Richard Gilsenen in 1899. Gilsenen was made acting head teacher at the Eltham State School in 1906 following the sudden death of head teacher John Brown. In the 1950s the house was bought by retired engineer Dr Alfred Fitzpatrick and his wife Claire who made various modifications to house goats and poultry as well as structural modifications to the house. In the early 1970s, Eltham Shire Councillors Frank Maas and Don Maling proposed an extended communities’ activities program be set up and the Commonwealth Grants Commission was approached for financial assistance. In 1974 a $50,000 Commonwealth Grant was received by the Shire Council to acquire the Fitzpatrick property as part of the planning to establish an extended communities’ activities program. The Fitzpatricks moved next door and Claire taught at the new Living and Learning Centre, which began in 1975, one of the first community education centres in Victoria. Covered under Heritage Overlay, Nillumbik Planning Scheme. Published: Nillumbik Now and Then / Marguerite Marshall 2008; photographs Alan King with Marguerite Marshall.; p59This collection of almost 130 photos about places and people within the Shire of Nillumbik, an urban and rural municipality in Melbourne's north, contributes to an understanding of the history of the Shire. Published in 2008 immediately prior to the Black Saturday bushfires of February 7, 2009, it documents sites that were impacted, and in some cases destroyed by the fires. It includes photographs taken especially for the publication, creating a unique time capsule representing the Shire in the early 21st century. It remains the most recent comprehenesive publication devoted to the Shire's history connecting local residents to the past. nillumbik now and then (marshall-king) collection, benjamin oliver wallis, claire fitzpatrick, don maling, dr alfred fitzpatrick, eltham living and learning centre, frank maas, john pearson, richard gilsenen, tannery -
Eltham District Historical Society Inc
Photograph - Digital Photograph, Jim Connor, The Pavillion, Eltham Living and Learning Centre, 739 Main Road, Eltham, 29 November 2016
The Pavillion was an extension to the Eltham Living and Learning Centre which was opened 8 October, 1994 In 1857, tanner John Pearson purchased three and a half acres of land in Little Eltham, at the western end of Pitt Street, with a 70-foot frontage to Maria Street (Main Road) and stretching down to the Diamond Creek for £100. He contracted Benjamin Oliver Wallis to build house for him. Wallis, a mason by trade who originated from the Cornish village of Newlyn, migrated to Melbourne in 1853 and was shortly engaged by Richard Warren to build the Eltham Hotel, which opened in 1854. When Warren fell into financial difficulty in 1858, Wallis purchased the hotel. That same year, Pearson constructed a tannery below the house with access to the water in the Diamond Creek. When Pearson became bankrupt in 1867, Wallis similarly acquired the house from Pearson’s creditors in 1868 and lived there until his death in 1896. For some of this time the house was in the name of Wallis’s son Richard but following his death in 1888, ownership reverted to his father. It was purchased by retired teacher Richard Gilsenen in 1899. Gilsenen was made acting head teacher at the Eltham State School in 1906 following the sudden death of head teacher John Brown. In the 1950s the house was bought by retired engineer Dr Alfred Fitzpatrick and his wife Claire who made various modifications to house goats and poultry as well as structural modifications to the house. In the early 1970s, Eltham Shire Councillors Frank Maas and Don Maling proposed an extended communities’ activities program be set up and the Commonwealth Grants Commission was approached for financial assistance. In 1974 a $50,000 Commonwealth Grant was received by the Shire Council to acquire the Fitzpatrick property as part of the planning to establish an extended communities’ activities program. The Fitzpatricks moved next door and Claire taught at the new Living and Learning Centre, which began in 1975, one of the first community education centres in Victoria.jim connor collection, eltham, eltham living and learning centre, living and learning centre, pavilion -
Flagstaff Hill Maritime Museum and Village
Textile - Plain Sewing Sampler, 1897
A "Plain Sewing Sampler" or "Darning Sampler" was intended to showcase the wide range of sewing techniques and skills a girl or woman had. These skills might include hand sewing techniques such as darning, patching, hemming, mending, structural sewing (making pleats, inserting gussets, joining fabric with seams) making buttonholes and embroidery. Samplers could also be intended for practicing a particular technique. There were several articles printed in Australian newspapers around 1889 referring to the "Plain Sewing Movement". In 1889 a Melbourne branch of the "London Institute for the Advancement of Plain Needlework" was formed by a group of ladies led by Lady Loch and Lady Clarke with the purpose of teaching "plain needlework' to women and girls. "Plain Sewing" included fundamental stitches and techniques that were essential for practical clothing construction and maintenance. Several years later in 1891, another meeting was held at Clivedon (the residence of Lady Clarke) to look into the possibility of improving the teaching of sewing in the state schools. This meeting was attended by several school inspectors and the committee of "the Melbourne Institute for the Advancement of Plain Needlework". This "Plain Sewing Sampler" was donated from the estate of Susan Henry OAM nee Vedmore (1944 - 2021). Susan's family (Harold and Gladys Vedmore) immigrated to Australia from Wales in 1955 and settled in Warrnambool. Susan was well known in the Warrnambool community for her work supporting children and families across the district - particular those with disabilities, or those who were homeless, unemployed or isolated. Susan was the founding trustee of the "Vedmore Foundation" - a Warrnambool philanthropic trust set up to support a range of charitable and not-for-profit causes by providing grant assistance. In 2021, she was awarded a Medal of the Order of Australia for services to the community. It has not been possible to identify the lady (with the initials L. L.) who made this item in 1897 but it was thought to possibly be a female relation in her maternal (or possibly, paternal) grandmother's family. It has many of the same elements and techniques that were taught by the "Plain Sewing Movement" that originated in England at the end of the nineteenth century.This item is a rare example of the handcraft skills learnt by women and girls in the late 1890's to construct and maintain practical clothing for their families.A cream cotton sampler made from three smaller rectangular shapes, displaying a wide variety of plain sewing techniques including hand stitched seams (french, bound and herringboned), inserted patch, buttonhole, button, gathering, a gusset, frills, pintucks, a placket, cross stitch initials and date (L L and 1897) and decorative embroidery.L L/1897flagstaff hill maritime museum and village, warrnambool, shipwreck coast, needlework, textiles, plain sewing sampler, darning sampler, handwork, sewing, great ocean road, susan henry oam, vedmore trust, hand sewing, sewing techniques -
Flagstaff Hill Maritime Museum and Village
Textile - Plain Sewing Sampler, 1897
A "Plain Sewing Sampler" or "Darning Sampler" was intended to showcase the wide range of sewing techniques and skills a girl or woman had. These skills might include hand sewing techniques such as darning, patching, hemming, mending, structural sewing (making pleats, inserting gussets, joining fabric with seams) making buttonholes and embroidery. Samplers could also be intended for practicing a particular technique. There were several articles printed in Australian newspapers around 1889 referring to the "Plain Sewing Movement". In 1889 a Melbourne branch of the "London Institute for the Advancement of Plain Needlework" was formed by a group of ladies led by Lady Loch and Lady Clarke with the purpose of teaching "plain needlework' to women and girls. "Plain Sewing" included fundamental stitches and techniques that were essential for practical clothing construction and maintenance. Several years later in 1891, another meeting was held at Clivedon (the residence of Lady Clarke) to look into the possibility of improving the teaching of sewing in the state schools. This meeting was attended by several school inspectors and the committee of "the Melbourne Institute for the Advancement of Plain Needlework". This "Plain Sewing Sampler" was donated from the estate of Susan Henry nee Vedmore (1944 - 2021). Susan's family (Harold and Gladys Vedmore) immigrated to Australia from Wales in 1955 and settled in Warrnambool. Susan was well known in the Warrnambool community for her work supporting children and families across the district - particular those with disabilities, or those who were homeless, unemployed or isolated. Susan was the founding trustee of the "Vedmore Foundation" - a Warrnambool philanthropic trust set up to support a range of charitable and not-for-profit causes by providing grant assistance. In 2021, she was awarded a Medal of the Order of Australia for services to the community. It has not been possible to identify the lady (with the initials L. L.) who made this item in 1897 but it was thought to possibly be a female relation in her maternal (or possibly, paternal) grandmother's family. It has many of the same elements and techniques that were taught by the "Plain Sewing Movement" that originated in England at the end of the nineteenth century.This item is a rare example of the handcraft skills needed by women and girls in the late 1890's to construct and maintain practical clothing for their families.A cream flannel sampler made from three smaller rectangular shapes, displaying a wide variety of plain sewing techniques including hand stitched seams (french, bound and herringboned), darned patches, inserted patches, pleats, buttonholes, buttons, a gusset, pintucks, a placket, cross stitch initials and date (L L and 1897) and decorative embroidery.L.L. / ?? Yr 1897flagstaff hill maritime museum and village, great ocean road, warrnambool, sewing, plain sewing, sewing sampler, plain sewing sampler, darning sampler, hand sewing, textiles, susan henry oam, vedmore foundation, sewing techniques -
Surrey Hills Historical Society Collection
Photograph, Surrey Hills Post Office
The post office opened at this location in 1912. It was demolished in 2000. Post office history in the area: Until 1883 when the railway came through to Surrey Hills, this was essentially a rural community of scattered farms. Land subdivisions soon occurred along the railway line and limited postal services followed soon after, although a ‘permanent’ home for the post office was two decades away. George Sim Junior is acknowledged as our first postmaster; he opened a post office on 1 October 1884 in his father’s general store at 619-621 Canterbury Road, a few doors down from the Surrey Hills Hotel on the corner of Union Road. Over the next 20 years, the Surrey Hills Post Office moved several times into temporary, shared accommodation – in 1889 into Woodhead’s Corner Store at 364 Canterbury Road; then in 1895 to No 376, Hansen’s Exchange Building, part of Hansen’s Terrace (demolished) and in 1901 to 109 Union Road, on the corner of Windsor Crescent. Following Federation in 1901, the new Commonwealth Government established the Postmaster-General's Department to provide postal services to the nation. Many of the post offices constructed in the following years reflected a growing sense of Australian pride and nationalism. It was 1914 when building commenced on the ‘purpose-built’ post office at 609 Canterbury Road, Surrey Hills. Described as “a polychromatic Federation Freestyle building”, it served as the local post office for nearly 85 years until sold by the Commonwealth Government in c1999, after which the post office moved to the current, less prominent site at 100 Union Road. For nearly 10 years under private ownership, the building was successfully adapted for use as the base for two businesses, Gargoyles and Dragons and later the Surrey Sculpture Studio, and fortuitously the historic integrity of the building was maintained. However although renovated in the 1990's, structurally sound and of historic significance, it was not protected under local or commonwealth heritage legislation and was demolished soon after sale. This is an early image of a demolished building which should have been protected. In 1991, when the City of Camberwell conducted a heritage study, (which still informs the basis of the City of Boroondara’s heritage guidelines for this part of the municipality,) the post office was owned by the Commonwealth Government. As such, it could not be considered for heritage listing by the local authorities. Some years later, the Commonwealth and Australia Post rather belatedly recognized not only that post offices have heritage and social value, but also that the architecture of post offices as community buildings is important. A heritage management scheme was developed for the buildings they own or control under the Environment Protection and Biodiversity Act 1999. Unfortunately, the Surrey Hills Post Office had been sold and demolished before this was finally enacted in 2004. Black and white image, perhaps from a post card, of Surrey Hills post office at 609 Canterbury Road. The building is flanked by a picket fence. There is a woman, a dog and a man in front of the entrance. The man is in uniform - possibly a postal employee.post offices, canterbury road, businesses, surrey hills post office, surrey sculture studio, gargoyles and dragons -
Melton City Libraries
Drawing, Open Day at Strathtulloh, Unknown
"Strathtulloh, 1402-1600 Greigs Road, Melton South, is significant as an early property in Victoria, retaining different eras of pioneering dwellings, ranging from a ruin to a fine Colonial style homestead. The property has close historical association with the early settlement of the Melton district, and was owned by the Henty family in the 1840s. The Strathtulloh property was alienated by the Crown in 1840 to Charles James Garrard, who sold it in 1848 to Charles and Stephen Henty, whose sister Jane and her husband Samuel Bryan lived there in the late 1840s. In 1853 the property then passed to William Tulloh, after whom the homestead was named. A primitive bluestone ruin of near the Toolern Creek, built of vesicular bluestone and mud mortar, is of unknown origin. It has commonly been assumed to pre-date 1840, and to have belonged to the original holder of the Exford lease, Dr Watton or Port Phillip Association member Dr Cotterill. This is unlikely, as the 1841 census records Dr Watton, and everyone else in the district, as living in a ‘wood’ dwelling. It may instead have been the residence of Garrard, and the Bryans, in the 1840s and an early map names a site near here as ‘Bryan’s outstation’. It is assumed that the two-level stone building that became the kitchen is the earliest intact building on the site, and was the first homestead; it is likely to date to the 1840s or 1850s. The main homestead is a substantial villa constructed of random coursed bluestone, with a verandah facing three sides, attic bedrooms with dormer windows, a fan light over the front door, a hipped roof originally clad in slate, and a large cellar. Although demonstrating characteristics of pioneering construction, such as unworked log beams, pit sawn beams, hand-sawn lintels and colonial door locks, documentary evidence shows that it was built c.1869. The homestead has now been structurally repaired and decoratively restored; a sympathetic new semi-detached rear extension was added in the early years of the 21st century. The former kitchen building has also undergone minor repairs and alterations". Strathtulloh Homestead at 1402-1600 Greigs Road, Melton Southlocal architecture -
The Beechworth Burke Museum
Photograph, 1960s
This photo was taken in the 1960s from a northeast position looking down towards Lake Sambell, the caravan park, and the surrounding area. This photo was taken during a period of rejuvenation for the lake area including the opening of the caravan park in 1959 and the swimming pool area in 1961 (this pool is just visible in the centre of the photo). The popularity of caravanning in Australia exploded during this post-war period of the late 1950s and 1960’s. This popularity was driven by multiple factors, including: the stopping of fuel rations, the accessibility of car ownership through the manufacturing of affordable cars, technological developments in caravan design, and the increase in prosperity and leisure time for many Australians. Lake Sambell is an artificial lake that was developed on the previous site of the Rocky Mountain Mining Company workings and was officially opened by Minister for Lands, Mr Baily, on October 5, 1928. The disused and unattractive remains of the mine were converted into a recreational area intended for swimming, boating, and fishing. The lake is named after Mr L.H. Sambell, shire engineer and secretary of the Forward Beechworth Committee, who advocated for the enhancement of Beechworth into a tourist destination and was central to the planning and establishment of the lake. Funding for the project was raised by both competition funds and donations. Since the construction in 1928 several engineering issues have arisen. In 1939 the water levels were low, and the lake was considered both an eyesore and ‘mudhole’, Beechworth Shire Council sort funding to raise the height of the lake six feet to improve the quality of water. Throughout the 1940s the Beechworth Swimming Club tried to raise awareness and funds to address the structural engineering issues and improve swimming facilities at the lake. R.E. Carter, similar to L.H. Sambell, was a shire engineer who advocated the importance of positioning Beechworth as a tourist destination. Carter held the position from 1954-63 and organised many improvements to the Lake Sambell area including the caravan park in 1959, the lake swimming pool in 1961, water skiing and boating facilities, and increased the lake surface are in 1964. These improvements were financed mainly by grants from the Tourist Development Authority. This photograph is of historical significance as it documents Lake Sambell and the surrounding area in the 1960s after a phase of enhancements to improve the appearance and usability for both the people of Beechworth and tourists. It is also of social significance in providing an insight into the increase in leisure time and access to travel during a period of post-war prosperity.Black and white rectangle photograph printed on matte photographic paper and unmounted.Reverse: 1 / [logo KODAK/ VELOX/ PAPER] / C798 / 3535lake sambell, lake sambell caravan park, lake sambell swimming pool, caravan park, caravanning 1960s, rocky mountain mining company, l.h. sambell, r.e. carter, beechworth swimming club, forward beechworth committee, minister of lands, tourist development authority, lake swimming, swimming, boating, fishing, water skiing, beechworth 1960s, lake sambell fishing, lake sambell boating -
Parks Victoria - Point Hicks Lightstation
Corbel
In architecture a corbel serves a decorative as well as structural function as a solid piece of stone, wood or metal that is built into a wall and juts out like a bracket to carry a weight. The smoothly shaped corbel was formerly built into the external wall of the lighthouse facing the sea. It consists of two cupped, rounded forms, one bigger than the other, which are attached to a damaged flat base. Made of cast concrete, it is the same fabric as the lighthouse and shows evidence of white paint on its surface. An early architectural drawing of the tower shows the corbel as a projecting, decorative moulding underpinning the balcony floor associated with the auxiliary light. It indicates the original corbel was a much larger architectural feature which started as a solid rectangular block and terminated with a smaller block and then two tapering, rounded forms. Prepared in mid-1888, the architectural drawings for the lighthouse by Victorian Public Works Department architect, Frederick Hynes, were amended in 1888-89 to provide for an auxiliary light, which comprised an arched opening and door in the tower wall below the lantern room and small balcony. In the late nineteenth century all of Victoria’s lightstations installed a red auxiliary light to serve as a danger warning to mariners sailing too close to shoare. Existing lightstations, like Cape Otway, built a pavilion below their lighthouse facing out to sea, but newly constructed towers like Point Hicks and Split Point incorporated them into their designs. The efficacy of auxiliary lights became a controversial issue and all were discontinued on 1 January 1913. The Point Hicks balcony was removed from the face of the tower in 1971 after it was found to be badly rusted. This resulted in the complete removal of the corbel, from which the rounded moulding and part of the base survives. The auxiliary light and door were subsequently removed in 1975 and glass blocks now fill the opening. Cape Schanck Lightstation retains four cast iron brackets from its auxiliary light balcony which are currently stored in the lighthouse on the ground floor. No other architectural fabric associated with the auxiliary light has been identified at Point Hicks Lightstation. The fragment of corbel has first level contributory significance for its historic and architectural values as a relic of the auxiliary light and as an original moulding from the fabric of Victoria’s first concrete lighthouse.A masonary corbel. -
Flagstaff Hill Maritime Museum and Village
Tool - Caulking Tool, William Marple & Sons, Early 20th century
Caulking is the traditional technique used on wooden vessels built with butted or clinker-built planks to fill the gaps between these planks while still allowing the wood to flex and move. This involved driving the irons, hammered in with the mallet, deep into the seams to open them up. After this, spun yarn, oakum (hemp) or cotton was driven deep into the gaps. The hemp or cotton was soaked in creosote or pine tar to make the joins watertight. Caulking also played a structural role in tightening up the hull or deck by reducing the longitudinal movement of the neighbouring planks. William Marples junior joined his father's joinery making business in 1821. In 1860 William's sons joined him and the firm became William Marples and sons. Over the years they acquired John Moseley & Sons a London plane maker and Thomas Ibbotson & Co a Sheffield edge tool maker. Growing to become the most prolific and best known Sheffield tool maker. Their large factory was known as the Hibernia Works. Their trademark was a shamrock that appeared on some of their tools, in 1961 they had about 400 employees. In 1962 the record Tool Company and William Ridgway acquired a fifty percent interest in the company and in 1972 the companies merged with several others to form Ridgway Tools Ltd. After 116 years at its Hibernia Works, the company was moved to Dronfield. A 1982 takeover by A G Bahco of Sweden was short-lived and in 1985 Record Ridgway returned to British ownership first as Record Marples Woodworking Tools Ltd. In 1988 then as Record Holdings PLC in 1993. In 1998 the company accepted a bid from American Tool Corporation, subsequently trading as Record Irwin. The Irwin company itself was acquired by Newell Rubbermaid in 2002 and renamed Irwin Industrial Tool Co. Both the Marples and Record names were re-branded "Irwin" However the name has since been resurrected as Irwin/Marples and applied to wood chisels and table saw blades now made at their new facility in Udine, Italy. As a footnote, William Marples was the uncle of Robert Marples and Joseph Marples, both of whom established competing tool making businesses in Sheffield. The Robert Marples firm disappeared early in the 20th century. After several changes in the company's ownership tools are now made under the Ridgway name but in China. A tool made by a company with a long family history of tool making in Sheffield England, with a member of the Marples family, Joseph Marples establishing a competing tool company which continues today to manufacture quality products for the joinery and shipwrights trades.Caulking tool straight wide blade, Stamped "W Marples & Sons" & James S Steele tool box.flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, caulking tool, caulking iron, james s steele -
Flagstaff Hill Maritime Museum and Village
Functional object - Gas Fitting, Before 1878
The artefact is a short cross-section of part of a functional part of a brass fitting that suspended a gas lamp, providing structural support, and internally, supplying the gas for its ignition. It combines elegant design with the elements required for safe and efficient delivery of gas. It was recovered from the LOCH ARD shipwreck site. There are similar artefacts in the Flagstaff Hill collection. The LOCH ARD left Gravesend (London) on 2 March 1878, bound for Melbourne, with a crew of 37, 17 passengers, and a diverse and valuable cargo of manufactured goods, luxury items, and refined metal. Some of the cargo was intended for Melbourne’s first International Exhibition to be held in 1880. At 3 am, 1 June 1878, the ship was wrecked against the high limestone cliffs of Mutton Bird Island on Victoria’s south west coast near Port Campbell. Only two people survived the disaster — Tom Pearce, a male crew member, and Eva Carmichael, a female passenger. The cargo proved too difficult to salvage in the vessel’s exposed condition and was largely written off. The manifest of goods in the LOCH ARD’s holds included “Fittings gas (4 cases)”. The gas lighting of streets, public buildings, and the dwellings of wealthier private citizens, was already well advanced in the cities and major towns of the Australian colonies. In 1841 Sydney was the first to be gas lit with 23 street lamps, 106 hotel lamps, and 200 private residences connected to the Darlinghurst “gasometer” by an underground network of metal pipes. “The dim days of oil and tallow are gone by!” pronounced one newspaper, flushed with civic pride. The 1850s Gold Rush promoted a similar attitude of confidence and affluence in the Colony of Victoria. In 1855 Melbourne was connected to its own system of subterranean gas pipes despite the same high rates of 25 shillings per 1000 cubic feet being charged, (reduced to 15 shillings in 1865 with cheaper sources of coal). By1858 Kyneton had its own gasworks to light the town (fuelled by eucalyptus leaves) and Geelong followed suit in 1860. Had the LOCH ARD reached its intended destination in 1878, it is probable that the 4 cases of brass gas light fittings on board would have found a ready market.The gas fitting is significant for its association with the LOCH ARD shipwreck, which is of State significance and is listed on the Victorian Heritage Register S417. The fitting is an example of a late 19th-century plumbing and light fitting.A pressed brass gas light fitting, recovered from the wreck of the LOCH ARD. The elegant and functional fitting extends from an ornate 8cm diameter ceiling flange, and comprises two short lengths of fluted column pipe with a brass joiner that are severed (cut off) at the end. Within this decorative outer layer of 3cm diameter is a full length brass tube liner, which is in turn protecting a narrow 0.75cm copper gas pipe that also runs full length. The artefact is generally unrestored with reddish/cream sandstone concretion, but is in good condition.warrnambool, shipwreck coast, flagstaff hill, shipwrecked coast, flagstaff hill maritime village, flagstaff hill maritime museum, shipwreck artefact, maritime museum, gas lamps, gas lighting, gas works, brass fittings, gas pipes, loch ard, 1878 shipwreck, victorian affluence, colonial gas lighting -
Eltham District Historical Society Inc
Photograph, VR Commissioner's Special train, steam locomotive D3-639 crossing the Echuca-Moama Road Rail Bridge over the Murray River from Moama, NSW to Echuca, Victoria, 1962
VR Commissioner's Special train, steam locomotive D3-639 crossing the Echuca-Moama Road Rail Bridge over the Murray River from Moama, NSW to Echuca, Victoria. Commissioner Edgar Henry Brownbill on footplate, 1962. Commissioner Edgar Henry Brownbill was in office 1957 to 1967. George Coop advises - "The train on the Eltham/Moama bridge is actually the Commissioner’s Special on one of its inspection tours of the VR rail system. This was a very grand special train with accommodation for the Commissioner and staff in carriages also used once for the Royal Train and other State purposes. You can just see the Commissioner of the day, dressed in his suit and wearing engine drivers gloves, standing in the loco cab doorway. A good ‘hands on’ impression is created amongst local staff if can be seen that the boss is no ‘desk jockjey’. The observation car on the back was originally made for the ’Spirit of Progress’. I climbed up onto the bridge iron plate work to get this view. It was safe enough as the cantilevered pedestrian walkway was still on the east side at the time." "I was resident in Echuca from Jan. ’59 to approx. May ’64. At that time the single Echuca/Moama bridge was a combined road/rail bridge. The rail gauge was 5’3” and still is, I believe, on the new bridge that sits just upstream of the old one. This rail line into NSW has always been 5’3" gauge because it has no connection with any NSW tracks. The old Echuca/Moama bridge, locally called the ‘Iron Bridge’ has, over years, undergone some structural changes. The two lattice iron hoops arcing over the roadway have been raised and lowered and changed design. Presently a pedestrian walkway is cantilevered off the west (or downstream) side of the bridge. It used to be on the eastern side. Guess changes went in when new rail bridge only was built on the eastern side as well." Image dated as c.1963 based on same image in Port of Echuca collection (possibly frame 32 of film) (print 19.5 x 24.5cm) On reverse in pencil: "Brown card" in black pen: "Commissioners special. F. Brown on Footplate. George C.L. Coop c1963". https://victoriancollections.net.au/items/59d575b921ea6e1278d78042 However based on frame no. 10, date set as 1962Digital TIFF file Scan of 35mm Ilford FP3 black and white negative transparencyd3-639, d3-class steam locomotive, echuca-moama road rail bridge, edgar henry brownbill, george coop collection, murray river, vr commissioner's special train -
Robin Boyd Foundation
Article, Japan Interior Design, An Architect's House in Melbourne, Australia. Architect: Robin Boyd, Feb-62
This Japanese journal features a photographic article on Boyd's Walsh Street home. It was written by a Japanese architecture student who visited Walsh Street with a group of 6 such students in 1961. A translation of the text follows. ________________________________________________________ "An Architect’s House in Melbourne, Australia Author: Tamon Okubo This house was built by architect Robin Boyd as an experimental work. Although in a residential area of Melbourne, the site is a 40 x 126 ft rectangle in a corner of a former park with high rise buildings on either side. Due to its location, the design focuses on protecting the privacy of the house from the outside and on the composition of the interior space, creating a somehow introverted plan. However, the interior is not completely closed from the outside; it is cleverly designed to provide both views of the rooves of nearby houses as well as the mountains in the distance. Firstly, the couple’s room and the children’s rooms are in separate buildings. These two independent structures are connected by a courtyard. The ceiling of the courtyard is partly open, so one can look out from the second-floor terrace of the couple’s room. The walls on both sides of the courtyard are of opaque glass to ensure privacy from outside. In both buildings brick walls with three-inch steel pipe inserted into the brick cavities form the structure and separate each room. The roof is connected to pairs of 3/4-inch thick cables, spaced four feet apart, attached to the brick walls of both buildings and supported by wooden posts that separate the glass panels in the rooms. The cables are not tightly strung together but are loosely suspended from the front structure, where the entrance is, to the rear one. The upper cable in the courtyard is covered with vine. The materials used are insulation board for the roof, raw timber for the structural materials, native jarrah for the timber sections of the interior walls and white eucalyptus for the joints. Robin Boyd – A Brief Personal History 1919 Born in Melbourne, Australia 1947 As an architect, was the first director of the Small Homes Service, a public housing research institute established to provide homes for needy Australians. 1960 Wins the American Institute Architects Prize (the Japanese architect, Kenzo Tange, was awarded the same prize in 1959). In the same year he was elected an honorary member of the Institute. Mr Robin Boyd is currently writing a book on the history of Australian architecture, The Walls Around Us, as well as a book on Kenzo Tange. He is a frequent visitor to Japan to exchange ideas with Japanese architects and is quite a Japanophile. " This is a photocopy of the article from Japan Interior Design No 17. Pages 4-5 are glued together, and pages 6-7 are glued together, p8 p9, p10 are separate. There is writing on it (not Robin Boyd's hand). Geoffrey Serle, Robin Boyd's biographer, may have given it to Patricia Boyd.walsh st library -
Federation University Historical Collection
Programme, The Opening of Civic Hall, 1956, 1956
The City of Ballarat unanimously resolved to erect a Civic Hall in Mair Street in 1951. The architects, Gordon Murphy, of Melbourne, and H.L. and L.J. Coburn, of Ballarat, were commissioned in 1952. The Council constructed the foundations and footings for the building under the supervision of the former City engineer, Mr L.H. Finch, in 1953. These footings are of massed concrete. The design for the building took advantage of the cross fall of the land, providing for the Small Hall to be entered from the Doveton Street frontage through a foyer under the Main Stage, the structure is steel with brick panels, with accommodation for 1,592 persons in the Main Hall and 440 persons in the Lower Hall. The front facade faces Mair Street, set back from the building line to provide for the entrance drive-ways and kerbed gardens. Tenders were invited on a firm price basis. A young Ballarat master Builter, Walter Benbow Trahar was the successful tenderer, the contract price being 139,841 pounds. the work was commenced in 1953 and has proceeded in spite of material and labour difficulties until its completion. The following statistics are of interest:- * The foundations contained 200 cubic yards of concrete. * The constructional steel work weighs approximately 270 tons. * The reinforcing steel 47 tons. * Reinforced concrete in the structure, 1,100 cubic yards. * The approximate number of bricks in the building, 580,000. * The flooring is of selected kiln-dried hard wood and totals 40,000 lineal feet. * The dimensions of the Main Auditorium, 100ft by 86 ft, including the side promenades each 82ft by 13ft. *The Main stage, of reinforced concret with parquette finish measures 62 ft by 40ft. *The floor area of the Lower Hall is 74 ft by 38 ft, and has a stage dimensions of 40ft by 20 ft. * Each hall has independent heating and ventillating systems. Where possible the material in the building was furnished from local business houses. The public address installation, which provided for additional microphones, is on the main Stage. There is inter-communication throughout the building connecting the front office, with the bioscope box, the stages in both the large and lower halls, and the Hallkeeper's residence. Local craftsmen have completed the painting, plaster work, and the electrical installation; local produced materials being used in the construction of the buildings with the exception of the timber for the Main Floor, the roofing and the structural steel. The City of Ballarat Councillors in 1956 were Councillors N. T. Callow, F.J. Cutts, K.C. Webb, W.E. Roff, O.W. Curnow, F.T. Woodward, Allan C. Pittard, A.W. Nicholson, J.A. Chisholm, G.L. Scott, F.W. Oliver, A.D. Mason. The Town clerk was H.R. Maddern and the City Engineer was G. Murrowood. A City of Ballarat Council meeting of 25 September 2013 voted to demolish the Ballarat Civic Hall. The Council heard from nearly 50 members of the public during a marathon six-hour meeting. Councilors John Birt, Des Hudson, Amy Johnson, Josh Morris, Peter Innes, John Philips supported the motion to demolish Civic Hall. Councillors Samantha McIntosh, Vicki Coltman and Belinda Coates voted against the motion.Six page souvenir Program of citizens' entertainment on the occasion of the Opening of Ballarat Civic Hall on in August 1956. The front cover features the City of Ballarat Coat of Arms. The programme starts with a message from the Mayor, Cr Neil T. Carrow. It includes the Concert Programme directed by James H. Davey, an asrtist's impression of the Civic Hall from Mair Street, and information relative to the New Civic Hall. The programme features images of the City of Ballarat Coat of Arms, Cr N.T. Callow, , James H, Davey, and an artist's impression of the Ballarat Civic Hall. Mayor Neil Callow's Message: "To-day, our citizens witness the fulfilment of the most extensive Municipal undertaking in the City's period of recent prosperity and development. Their Hall now fills a requirement of which they have been deprived since the Coliseum building was destroyed by fire over 20 years ago. The building has been designed as an all purpose structure and I am hopeful the citizens will use it and enjoy it to its fullest extent. Your Council and its Architects have planned as broadly as possible for the benefit of all to-day and for years to come. We are proud of the work executed by a Ballaarat Master Builder whose work is a monument to the City's craftsmen. I feel I should also remind this assembly that the women of Ballaarat, back in 1951, provided funds which have been applied in the purchase of a Grand Piano and two Upright Pianos which are now installed in this building. The sincere hope of myself and your Councillors is that this Hall and its amenities will prove of immense value to the development of the cultural and artistic tastes of this community and that it will be freely used for these and many other purposes. From now on this magnificent building and its furnishings and equipment will be available to all. I strongly exhort you to use and protect it. My hope is that the citizens will, for many years to come, enjoy the amenities which it has to offer. ballarat civic hall, civic hall, architecture, finch, art deco, city of ballarat, coat of arms, city of ballarat coat of arms, callow, shugg, lemke, oates, gullan, tuuri, john, robertson, sorrell, antonio, gordon murphy, walter benbow trahar, trahar, coburn, h.l. coburn, l.j. coburn, n.t. callow -
Flagstaff Hill Maritime Museum and Village
Ceramic - Stoneware Bottle, Henry Kennedy Pottery, Late 1800s to early 1900s
This bottle was made in Scotland and recovered decades later from a shipwreck along the coast of Victoria. It may have been amongst the ship's cargo, its provisions or amongst a passenger's personal luggage. It is now part of the John Chance collection. Stoneware bottles similar to this one were in common use during the mid-to-late 19th century. They were used to store and transport. The bottles were handmade using either a potter's wheel or in moulds such as a plaster mould, which gave the bottles uniformity in size and shape. The bottle would then be fired and glazed in a hot kiln. Makers often identified their bottles with the impression of a small symbol or adding a colour to the mouth. The manufacturer usually stamped their bottles with their name and logo, and sometimes a message that the bottle remained their property and should be returned to them. The bottles could then be cleaned and refilled. The Barrowfield pottery was founded in 1866 by Henry Kennedy, an Irish native, in the Camlachie district east of Glasgow, close to the Campbellfield and Mount Blue potteries. It is believed that Kennedy started with just one kiln but by 1871 was employing forty men and six boys and such was the success of the enterprise that by 1880, no less than eight kilns were in operation and a year later one hundred and the pottery was employing eighteen people. Stoneware bottle production was a mainstay of the pottery and over “1500 dozen” were being turned out daily along with other wares, including 30-gallon ironstone containers. With so many kilns in operation, six hundred saggars were required every week but, unlike some potteries, these were made on the premises from Garnkirk and Glenboig fire clays. Pottery production reaches a high scale which presented a high risk of fire and Barrowfield was no exception. In April 1884 heat from a kiln set fire to the roof resulting in significant structural damage, the loss of unfinished wares alone amounting to £10,000 a very substantial sum in 1884. The pottery recovered from this reverse but then Henry Kennedy died in July 1890. The terms of his will indicated that he and his sons John and Joseph were partners and this was reflected in a change of title in the 1891-92 Post Office Directory to Henry Kennedy & Sons. Despite the growth of the business there was still space enough, however, to allow china, earthenware and glass retailers Daniel and John McDougall to commence production of their Nautilus wares there in 1894, the success of which allowed them to soon move to permanent quarters at the empty Saracen Pottery, Possil. In around 1900 John Kennedy left to resurrect the liquidated Cleland Pottery and although Barrowfield remained listed as Henry Kennedy & Sons, brother Joseph was in control. In 1911 Henry Kennedy & Sons Ltd was formed, with two of the four directors being the Kennedy brothers. The pottery’s growth to this point was reflected in the eighteen kilns the largest pottery kilns then recorded in Scotland. However, the disruption of the First World War and the combined effects of subsequent economic depression, US prohibition, hygiene regulations and competition from alternative materials posed severe challenges for stoneware potteries in the post-war years as they competed with each other for diminishing markets. Competitors such as Eagle and Caledonian Potteries fell by the wayside and finally, Barrowfield closed in 1929. This stoneware bottle is historically significant for its manufacture and use in the late 19th to the early 20th century. The bottle is also significant as it was recovered by John Chance, a diver, from a wreck on the coast of Victoria in the 1960s-70s. Items that come from several wrecks along Victoria's coast have since been donated to the Flagstaff Hill Maritime Village’s museum collection by his family, illustrating this item’s level of historical value. Stoneware was produced at Barrowfield pottery for the domestic and export markets, with South America being a large market. Barrowfield stoneware can be found throughout the world. Its longevity and abundant production makes the subject item a significant addition to the Flagstaff Hill Maritime Museum collection.Bottle, salt glazed stoneware, beige, some discolouration above base. Chip on base and on neck. Inscriptions stamped near base.Makers lozenge stamped, H Kennedy Barrowfield Pottery GLASGOW at base.flagstaff hill, warrnambool, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, john chance, h kennedy pottery, stoneware, ironstone, pottery, barrowfield glasgow -
Eltham District Historical Society Inc
Photograph, Woodburn residence, mudbrick adobe (1949), Eltham Heritage Tour, 24 May 1992, 24/05/1992
ELTHAM HERITAGE TOUR The Society excursion on 24th May 1992 was arranged by David Bick, leader of the team carrying out the Shire's heritage study. David selected a number of sites or buildings identified in the study, some of them lesser known components of the Shire's heritage. The tour commenced at the Eltham Shire Office at 10.00 am. Travel was by private car and mini-bus with stops at about twelve locations for commentary by David.It included a short walk in Hurstbridge and lunch at Kinglake. Highlights of the tour included: - 10 am Leave from Shire Offices - 3 Important Trees - A Physical Link to Eltham's First Settlers - Toorak Mansion Gates - A Surviving Farm House - An Intact Circa 1900 Main Street - First Settlers - Gold Miners, and Timber-getters - An Early Hotel - A Pioneering Homestead - Changing Eltham Shire - 20th Century - 4 pm Afternoon Tea and Finish Tour Extract from ELTHAM CULTURAL HERITAGE TOUR (Newsletter No. 85, July 1992, by Bettina Woodburn) "In some respects Eltham is a 'back-water' and it has its own distinctive flavour. On the outskirts the homes date from the 1960's, 70's and 80s with a sprinkling of 'earth homes', mud-brick or pise, rammed dirt. Crossing Main Road into Beddoe Street and Thompson Crescent a very pleasant drive past pines and old fence lines, front lawns unfenced, the occasional ·old farm building, we eventually looked down on a huge circular roof of a 1992 adobe home. Other distinctive places included the Pauline Toner Butterfly Reserve, Gordon Ford's splendid garden at Fulling in Pitt Street, cypress hedges and old houses in Bridge Street and in every direction Eltham's special feature - a totally treed horizon. We were now in the part of the Shire closest to Melbourne - Montmorency - not on the way to anywhere, with no through road going across it, developed in the 1950's and 1960's with conventional gardens, now converted to native plants. The rail looped between Greensborough and Eltham and a shopping street (Were Street) served the area, growing up the hill from the station. It was a typical outer Melbourne suburb with lawns and roses with patches of originality. The shopping precinct still has 1950 characteristics - walls which sloped back, projecting roofs, the original shop fronts are nearly all tiled below the old windows. There's an air of past times about the School, the Dairy, the Butcher's (now a milk bar) and the Castlemaine stone face of the Commonwealth Bank. The final stop for the tour was at the mud-brick Woodburn residence, adobe of 1949 with additions. After War Service, Bill Woodburn had commenced an Architecture course at Melbourne University and after second year in the Christmas vacation, with his wife, Betti, built the two bedroom house - with amazing saving of costs. In the three and a half months they made over 3000 bricks (external walls 18" x 12" x 4", internal walls 12" x 9" x 4"), sifted top soil for mortar and laid them, on concrete foundations and slab floor, made all the structural window frames, door frames and roof members to carry 'super six' asbestos sheets, laboured for the electrician and plumber, did all the glazing and, still without electricity, moved in in March 1949. Rooms have been added, at first with glass walls, later using concrete blocks, to accommodate three daughters and a son. The house not only grew from the earth, but also with the family."Record of the Society's history and activities and highlighting various aspects of the Heritage Study undertaken by David Bick used to create the future heritage overlay for the Shire of Eltham and later Nillumbik Shire.Roll of 35mm colour negative film, 4 stripsKodak Gold 100 5095shire of eltham historical society, activities, heritage tour, woodburn house -
National Wool Museum
Clothing - 35 Life, Canwen Zhao, 2022
Canwen Zhao was awarded the $10,000 We The Makers Acquisitive Prize for '35 Life' in 2023. Artist Statement: "35life" is a sustainable fashion project that transforms second-hand clothing materials into urban street outdoor-style products. Highlighting prominent Chinese classic red and green colours not only conveys eastern aesthetics but also adds a sense of unity to the clothing collection. The high-saturation and high-brightness full-colour palette keeps the clothing consistently "fresh," allowing any trendy colours to seamlessly integrate into the project's designs, thus extending the lifespan of the garments. Additionally, all clothing items can quickly transform into a stylish bag for convenient daily carrying and home storage. These bags are made from leftover fabric generated during the production process and serve as original packaging for sale. This approach not only reduces excessive packaging but also enhances the chances of resale in the second-hand market. The project draws inspiration from the traditional Chinese cultural concept of "huo feng ding," meaning "exchange the old for the new." it's also influenced by the designer's personal experience with health issues, making the designs suitable for individuals who can't be exposed to sunlight for extended periods, adapting to the changing urban lifestyle. 35life aims to provide visually pleasing and comfortable dressing experiences for urban dwellers who are busy with work and experience high levels of stress. Unlike traditional design patterns, this project adopts a unique design approach. It selects 3-5 pieces of raw materials based on their colours, and then disassembles them through structural lines. While retaining most of their functionality, these materials are rearranged and assembled on a flat surface before being shaped on a dress form. Subsequently, various ways of creating storage bags are derived from the initial clothing prototypes. After refining the designs, the final products are developed, and similar materials are used to create samples. Therefore, under this design methodology, even for the same garment, it is impossible to produce two identical pieces of clothing. Each garment is truly one-of-a-kind, which enhances its rarity and contributes to the longevity of the fashion pieces. The project includes various types of clothing, each with unique storage methods. This yellow look, named "elegant beach sunscreen monarch," draws its fashion inspiration from traditional Han Chinese attire and its storage concept from the Chinese cultural concept of "jiu jiu gui yi." the design employs flat pattern cutting, utilizing materials from the second-hand market such as beach towels, children's waterproof clothing, and women's dresses. Similar colours and patterns are reassembled through cutting and combining. For the sleeves, quick-drying, sun-protective sport fabric forms the base, overlaid with discarded silk fabric dyed with turmeric and plant dyes. This not only ensures functionality but also adds a sense of elegance. The length can be adjusted using drawstrings. Artist Bio: Zhao Canwen is a multidisciplinary fashion designer with a strong passion for integrating art, history, culture, and sustainable design. With over 15 years of experience in painting, she draws inspiration from ancient Chinese philosophy and aesthetics, which gives her a unique sense of beauty. After 8 years of fashion and art training, she possesses a keen insight into current trends and tends to combine art with commercial needs. Zhao's design style is diverse, characterized by a multidimensional approach, a focus on colour application, and storytelling through details.Outfit consisting of six pieces: - Orange plastic eye wear with green paint - Pair of red and green metal clip on earrings - Red beaded phone case with attached beads on string - Pair of red and green painted running shoes - Yellow and green hooded garment with red piping and zips - Brown bag with green beaded handlessustainable, fashion, we the makers, art, culture, design, chinese philosophy, prize -
Puffing Billy Railway
V. R. Krupp 1888. IV. Rail, 1888
60lbs rail that was used throughout the Victorian rail network. In 1887 Gibbs, Bright and Co. had a contract with Victorian Railways for railway and canal construction and supply of Krupp Rails. Gibbs, Bright and Co were merchant bankers and shipping agents and merchants who where also Directors of the GWR ( Great Western Railway ) and the Ship The "Great Britain" in England Gibbs, Bright and Company had principally been involved in shipping and trading, mainly in the West Indies, but following the discovery of gold in Victoria they established an office in Melbourne and soon became one of the leading shipping agents and merchants in the Colony. They expanded into passenger shipping and soon established offices in Brisbane, Sydney, Newcastle, Adelaide and Perth as well as launching passenger services between England, Mauritius and New Zealand. Gibbs, Bright also held a number of financial agencies from British mortgage, finance and investment companies as well as representing several British insurance companies in Australia. In addition they conducted a growing import business as well as an export business that included livestock, dairy produce, wool and flour. Also the company played a substantial part in the development of Australia's mineral resources, starting with lead in 1895, and later venturing into tin, gold, copper, cement and super phosphates. In Australia, after WWI, many of the larger companies were managing their own import and export so Gibbs, Bright and Company tended to focus its Agency business on smaller companies while expanding their interest into other markets such as timber, wire netting, zinc, stevedoring, road transport, marine salvage, gold mining as well as mechanical, structural, electrical and marine engineering. The Company's shipping interests continued to grow as well and still formed a major part of its business. In 1948 the parent company in England took the major step from tradition when they changed the business from a partnership into a private limited company. The name was the same, Antony Gibbs and Sons Limited, and in practice the effect of the change was very little. Some of the firm's branches and departments had already become limited companies and the formation of a parent company simplified the structure. The Australian operation was in time changed to Gibbs Bright & Co Pty Ltd in 1963. In 1848 Alfred Krupp becomes the sole proprietor of the company which from 1850 experiences its first major growth surge. In 1849 his equally talented brother Hermann (1814 - 1879) takes over the hardware factory Metallwarenfabrik in Berndorf near Vienna, which Krupp had established together with Alexander Schöller six years earlier. The factory manufactures cutlery in a rolling process developed by the brothers. Krupp's main products are machinery and machine components made of high-quality cast steel, especially equipment for the railroads, most notably the seamless wheel tire, and from 1859 to an increased extent artillery. To secure raw materials and feedstock for his production, Krupp acquires ore deposits, coal mines and iron works. On Alfred Krupp's death in 1887 the company employs 20,200 people. His great business success is based on the quality of the products, systematic measures to secure sales, the use of new cost-effective steel-making techniques, good organization within the company, and the cultivation of a loyal and highly qualified workforce among other things through an extensive company welfare system. From 1878 August Thyssen starts to get involved in processing the products manufactured by Thyssen & Co., including the fabrication of pipes for gas lines. In 1882 he starts rolling sheet at Styrum, for which two years later he sets up a galvanizing shop. The foundation stone for Maschinenfabrik Thyssen & Co. is laid in 1883 with the purchase of a neighboring mechanical engineering company. In 1891 August Thyssen takes the first step toward creating a vertical company at the Gewerkschaft Deutscher Kaiser coal mine in [Duisburg-]Hamborn, which he expands to an integrated iron and steelmaking plant on the River Rhine. Just before the First World War he starts to expand his group internationally (Netherlands, UK, France, Russia, Mediterranean region, Argentina). info from The company thyssenkrupp - History https://www.thyssenkrupp.com/en/company/history/the-founding-families/alfred-krupp.htmlHistoric - Victorian Railways - Track Rail - made by Krupp in 1888Section of VR Krupp 1888 Rail mounted on a piece of varnished wood. Rail made of ironpuffing billy, krupp, rail, victorian railways -
Flagstaff Hill Maritime Museum and Village
Tool - Caulking Tool, A Mathieson and Son, Early 20th century
Caulking is the traditional technique used on wooden vessels built with butted or clinker-built planks to fill the gaps between these planks while still allowing the wood to flex and move. This involved driving the irons, hammered in with the mallet, deep into the seams to open them up. After this, spun yarn, oakum (hemp) or cotton was driven deep into the gaps. The hemp or cotton was soaked in creosote or pine tar to make the joins watertight. Caulking also played a structural role in tightening up the hull or deck by reducing the longitudinal movement of the neighbouring planks. The subject item was made by Alexander Mathieson & Sons but the company was established in 1792 when John Manners had set up a workshop making woodworking planes at 14 Saracens Lane Glasgow. He also employed an apprentice Alexander Mathieson (1773-1851). But in the following year at Saracen's Lane, the 1841 census describes Alexander Mathieson as a master plane-maker now at 38 Saracen Lane with his son Thomas Adam working with him as a journeyman plane-maker. Presumably, Alexander must have taken over the premises and business of John Manners. Now that the business had Thomas Adam Mathieson working with his father it gradually grew and became more diversified, and it is recorded at the time by the Post-Office Glasgow Annual Directory that by 1847-1848 Alexander Mathieson was a “plane, brace, bit, auger & edge tool maker”. In 1849 the firm of James & William Stewart at 65 Nicolson Street, Edinburgh was taken over by Mathieson and Thomas was put in charge of the business, trading under the name Thomas A. Mathieson & Co. as plane and edge-tool makers. Thomas's company went on to acquire the Edinburgh edge-tool makers “Charles & Hugh McPherson” and took over their premises in Gilmore Street. In the Edinburgh directory of 1856/7, the business is recorded as being Alexander Mathieson & Son, plane and edge-tool makers at 48 Nicolson Street and Paul's Work, Gilmore Street Edinburgh. In the 1851 census, Alexander is recorded as working as a tool and plane-maker employing eight men. Later that year Alexander died and his son Thomas took over the business. Under the heading of an edge-tool maker in the 1852/3 Post-Office Glasgow Annual Directory the firm is now listed as Alexander Mathieson & Son, with further entries as "turning-lathe and vice manufacturers". By the early 1850s, the business had moved to 24 Saracen Lane. The directory for 1857/8 records that the firm had moved again only a few years later to East Campbell Street, off the Gallowgate area, and that through further diversification was also manufacturing coopers' and tinmen's tools. The ten-yearly censuses report the firm's growth in 1861 stating that Thomas was a tool manufacturer employing 95 men and 30 boys; in 1871 he had 200 men working for him and in 1881 300 men. By 1899 the firm had been incorporated as Alexander Mathieson & Sons Ltd, even though only Alexander's son Thomas appears ever to have joined the firm so the company was still in his father's name. In September 1868 Thomas Mathieson put a notice in the newspapers of the Sheffield & Rotherham Independent and the Sheffield Daily Telegraph stating that his firm had used the trade-mark of a crescent and star "for some time" and that "using or imitating the Mark would be proceeded against for infringement". The firm had acquired its interest in the crescent-and-star mark from the heirs of Charles Pickslay, the Sheffield cutler who had registered it with the Cutlers' Company in 1833 and had died in 1852. The year 1868 seems also to be the one in which the name Saracen Tool Works was first adopted; not only does it figure at the foot of the notice in the Sheffield press, but it also makes its first appearance in the firm's entry in the Post-Office Glasgow Annual Directory in the 1868/9 edition. As Thomas Mathieson's business grew, so too did his involvement in local public life and philanthropy. One of the representatives of the third ward on the town council of Glasgow, he became a river bailie in 1868, a magistrate in 1870 and a preceptor of Hutcheson's Hospital in 1878. He had a passion for books and was an "ardent Ruskinian". He served on the committee handling the bequest for the setting up of the Mitchell Library in Glasgow. When he died at Coulter Maynes near Biggar in 1899, he left an estate worth £142,764. In the Company's later years both Thomas's sons, James Harper and Thomas Ogilvie were involved in the continuing life of the firm. James followed in his father's footsteps in becoming a local public figure. He was appointed Deputy Lieutenant of the County of the City of Glasgow and was made a deacon of the Incorporation of the Hammermen of Glasgow in 1919. His brother Thomas Ogilvie was recorded as a tool manufacturer and employer in the 1911 census. Thomas Ogilvie's son Thomas Alastair Sutherland Ogilvie Mathieson was born in 1908 and took a rather different approach to engineer, however, by becoming a racing driver. In 1947 he wed the French film actress Mila Parély. The firm had won many awards at world fairs for their goods. At the Great Exhibition, London, 1851. Prize medal for joiners' tools in the class of Cutlery & Edge Tools, Great London Exposition, 1862. Prize medal honoris causa. International Exhibition, Melbourne, 1880. Gold medal International Exhibition of Industry, Science and Art, Edinburgh, 1886. Prize medalThe firm Alexander Mathieson & Sons were one of the leading makers of hand tools in Scotland. Its success went hand in hand with the growth of the shipbuilding industries on the Firth of Clyde in the nineteenth century and the emergence of Glasgow as the "second city of the Empire". It also reflected the firm's skill in responding to an unprecedented demand for quality tools by shipyards, cooperages and other industries, both locally and far and wide. The subject item is of further significance as it gives a snapshot of the technological development of sailing ships and their operation before steam-powered vessels took over around the world. Tools such as the subject item demonstrate the traditional craftsmanship and skill of the shipwright and the aesthetic quality of the timber ships designs of the time. Caulking tool Off-set. Stamped on blade "Mathieson & Son Glasgow" also stamped in handle, James S Steele tool box.flagstaff hill, warrnambool, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, james s steele, caulking iron, caulking tool, offset caulking tool, alexander mathieson & sons, shipwrights tools, ship building, clinker hull caulking, sailing ships -
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