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Kiewa Valley Historical SocietyBottle Milk, mid to late 1900's
This glass milk bottle was manufactured and used mid 1800's (1834 Victorian dairy industry was founded) to the time that a cheaper container was invented(plastic bottles and polyethylene plastic lined cardboard cartons). In 1909 the supply of pure bottled milk was required for babies to overcome infant mortality due to unhygienic milk sources (unclean containers and unpasteurized milk). Due to the large volume of milk being processed and hand milking could not keep up with demand, dairy farms introduced milking machines in the late 1930's. The great increases in dairy herds from the average of 18 cows per heard in 1950's to 142 cows per herd in 1996 required milk tankers to pick up the regions milk supply. This bottle was so constructed to be easily moved within the milk processing plants from the delivery vats/holding tanks to the final corking/sealing of the bottles for eventual distribution. From 1958 the milk bottle slowly became phased out of production. At this point in time Melbourne was drawing 160,000 bottles per week from the two major glass bottle works companies, e.g. Melbourne Glass Bottle Works Co.Victoria was the major state supplier of cows milk in the history of Australian milk production from the early 1800's. The Kiewa Valley and its region was a major contributor to meet that demand. Each bottle was "branded" during manufacturing to show the contents (pasteurized milk) and where it originated from (region and supplier). This method of recycling the bottles back to specific dairy farms was a good control method but an uneconomical "on cost" which was replaced by the "throw away" less costly plastic and cardboard containers. Kiewa Valley dairy herds had marked bottles bearing "90/9", "6/18", "6/33", "6/35" and "6/36"This heavy gauged glass milk bottle has a rim and a distinctive head at the top. This head has been manufactured to facilitate the movement of the bottled along the milk production line. The method of pouring milk into the bottle has been part of the "production line". This bottle has a one pint capacity and is made from "light green" coloured glass(a protection against sunlight penetration). There are other milk bottles that do not have a "green" tint in them. This thick glass bottle to contain milk required its thickness because of the extensive handling before final consumption. Milk was delivered by the "milk man" direct to the homes of consumers. During this period delivery to homes in cities and towns was made initially by horse and cart and later by truck.On the bottom end of this bottle a circle within it 6/33 and next to this "ONE PINT" and under this "THIS BOTTLE BELONGS TO MILK BOTTLE RECOVERY LTD" and below this "AND CANNOT BE USED WITHOUT WRITTEN PERMISSION" on the base "M" underneath this "4"glass bottles, commercial milk containers, domestic milk bottles, pasteurized milk bottles -
Kiewa Valley Historical SocietyBottle Milk, circa mid to late 1900's
This glass milk bottle was manufactured and used mid to late 1900's (1834 Victorian dairy industry was founded) up to the time that a cheaper container was invented(plastic bottles and polyethylene plastic lined cardboard cartons). In 1909 the supply of pure bottled milk was required for babies to overcome infant mortality due to unhygienic milk sources (unclean containers and unpasteurized milk). Due to the volume of milk being processed and hand milking could not keep up with demand, dairy farms introduced milking machines in the late 1930's. The great increases in dairy herds from the average of 18 cows per heard in 1950's to 142 cows per herd in 1996 required milk tankers to pick up the regions milk supply. This bottle was so constructed to be easily moved within the milk processing plants from the delivery vats/holding tanks to the final corking/sealing of the bottles for eventual distribution. From 1958 the milk bottle slowly became phased out of production. At this point in time Melbourne was drawing 160,000 bottles per week from the two major glass bottle works companies, e.g. Melbourne Glass Bottle Works Co.Victoria was the major state supplier of cows milk in the history of Australian milk production from the early 1800's. The Kiewa Valley and its region was a major contributor to meet that demand. Each bottle was "branded" during manufacturing to show the contents (pasteurized milk) and where it originated from (region and supplier). This method of recycling the bottles back to specific dairy farms was a good control method but an uneconomical "on cost" which was replaced by the "throw away" less costly plastic and cardboard containers. Kiewa Valley dairy herds had marked bottles bearing "90/9", "6/18", "6/33", "6/35" and "6/36" Found under house at 1 Beauty Ave., Mt Beauty.This heavy gauged glass milk bottle has a rim and a distinctive head at the top. This head was manufactured to facilitate the movement of the bottled along the milk production line. The method of pouring milk into the bottle has been part of the "production line". This bottle has a one pint capacity and is made from "light green" coloured glass(a protection against light penetration). There are other milk bottles that do not have a "green" tint in them. This thick glass bottle which contained milk required its thickness because of the extensive handling before final consumption. Milk was delivered by the "milk man" direct to the homes of consumers. During this period delivery to homes in cities and towns was made initially by horse and cart and later by truck.On the bottom end of this bottle a circle within it "6/18" and next to this "MILK" and opposite "ONE PINT". Below this "THIS BOTTLE BELONGS TO MILK BOTTLE RECOVERY LTD" and below this "AND CANNOT BE USED WITHOUT WRITTEN PERMISSION" on the base "M" underneath this "3"glass bottles, commercial milk containers, domestic milk bottles, pasteurized milk bottles -
Kiewa Valley Historical SocietyBottle Milk, mid to late 1900's
This glass milk bottle was manufactured and used mid to late 1900's (1834 Victorian dairy industry was founded) until the time that a cheaper container was invented(plastic bottles and polyethylene plastic lined cardboard cartons). In 1909 the supply of pure bottled milk was required for babies to overcome infant mortality due to unhygienic milk sources (unclean containers and unpasteurized milk). Due to the volume of milk being processed and hand milking could not keep up with demand, dairy farms introduced milking machines in the late 1930's. The great increases in dairy herds from the average of 18 cows per heard in 1950's to 142 cows per herd in 1996 required milk tankers to pick up the regions milk supply. This bottle was so constructed to be easily moved within the milk processing plants from the delivery vats/holding tanks to the final corking/sealing of the bottles for eventual distribution. From 1958 the milk bottle slowly became phased out of production. At this point in time Melbourne was drawing 160,000 bottles per week from the two major glass bottle works companies, e.g. Melbourne Glass Bottle Works Co.Victoria was the major state supplier of cows milk in the history of Australian milk production from the early 1800's. The Kiewa Valley and its region was a major contributor to meet that demand. Each bottle was "branded" during manufacturing to show the contents (pasteurized milk) and where it originated from (region and supplier). This method of recycling the bottles back to specific dairy farms was a good control method but an uneconomical "on cost" which was replaced by the "throw away" less costly plastic and cardboard containers. Kiewa Valley dairy herds had marked bottles bearing "90/9", "6/18", "6/33", "6/35" and "6/36" Found under house at 1 Beauty Ave., Mt Beauty.This heavy gauged glass milk bottle has a rim and a distinctive head at the top. This head has been manufactured to facilitate the movement of the bottle along the milk production line. The method of pouring milk into the bottle has been part of the "production line". This bottle has a one pint capacity and is made from "light green" coloured glass(a protection against light penetration). There are other milk bottles that do not have a "green" tint in them. This thick glass bottle to contain milk required its thickness because of the extensive handling before final consumption. Milk was delivered by the "milk man" direct to the homes of consumers. During this period delivery to homes in cities and towns was made initially by horse and cart and later by truck.On the bottom end of this bottle a circle within it "6/36" and next to this "MILK" and opposite "ONE PINT". Below this "THIS BOTTLE BELONGS TO MILK BOTTLE RECOVERY LTD" and below this "AND CANNOT BE USED WITHOUT WRITTEN PERMISSION" on the base "M" underneath this "15" glass bottles, commercial milk containers, domestic milk bottles, pasteurized milk bottles -
Kiewa Valley Historical SocietyBottle Milk, mid to late 1900's
This glass milk bottle was manufactured and used mid to late1900's (1834 Victorian dairy industry was founded) up until the time that a cheaper container was invented(plastic bottles and polyethylene plastic lined cardboard cartons). In 1909 the supply of pure bottled milk was required for babies to overcome infant mortality due to unhygienic milk sources (unclean containers and unpasteurized milk). Due to the volume of milk being processed and hand milking could not keep up with demand, dairy farms introduced milking machines in the late 1930's. The great increases in dairy herds from the average of 18 cows per heard in 1950's to 142 cows per herd in 1996 required milk tankers to pick up the regions milk supply. This bottle was so constructed to be easily moved within the milk processing plants from the delivery vats/holding tanks to the final corking/sealing of the bottles for eventual distribution. From 1958 the milk bottle slowly became phased out of production. At this point in time Melbourne was drawing 160,000 bottles per week from the two major glass bottle works companies, e.g. Melbourne Glass Bottle Works Co.Victoria was the major state supplier of cows milk in the history of Australian milk production from the early 1800's. The Kiewa Valley and its region was a major contributor to meet that demand. Each bottle was "branded" during manufacturing to show the contents (pasteurized milk) and where it originated from (region and supplier). This method of recycling the bottles back to specific dairy farms was a good control method but an uneconomical "on cost" which was replaced by the "throw away" less costly plastic and cardboard containers. Kiewa Valley dairy herds had marked bottles bearing "90/9", "6/18", "6/33", "6/35" and "6/36" Found under the house at 1 Beauty Ave., Mt BeautyThis heavy gauged glass milk bottle has a rim and a distinctive head at the top. This head has been manufactured to facilitate the movement of the bottled along the milk production line. The method of pouring milk into the bottle has been part of the "production line". This bottle has a one pint capacity and is made from "light green" coloured glass(a protection against light penetration). There are other milk bottles that do not have a "green" tint in them. This thick glass bottle to contain milk required its thickness because of the extensive handling before final consumption. Milk was delivered by the "milk man" direct to the homes of consumers. During this period delivery to homes in cities and towns was made initially by horse and cart and later by truck.On the bottom end of this bottle a circle within it "6/18" and next to this "MILK" and opposite "ONE PINT". Below this "THIS BOTTLE BELONGS TO MILK BOTTLE RECOVERY LTD" and below this "AND CANNOT BE USED WITHOUT WRITTEN PERMISSION" on the base "M" underneath this "4"glass bottles, commercial milk containers, domestic milk bottles, pasteurized milk bottles -
Kiewa Valley Historical SocietyBottle Milk, mid to late 1900's
This glass milk bottle was manufactured and used mid to late 1900's (1834 Victorian dairy industry was founded), until the time that cheaper containers were invented(plastic bottles and polyethylene plastic lined cardboard cartons). In 1909 the supply of pure bottled milk was required for babies to overcome infant mortality due to unhygienic milk sources (unclean containers and unpasteurized milk). Due to the volume of milk being processed and hand milking could not keep up with demand, dairy farms introduced milking machines in the late 1930's. The great increases in dairy herds from the average of 18 cows per heard in 1950's to 142 cows per herd in 1996 required milk tankers to pick up the regions milk supply. This bottle was so constructed to be easily moved within the milk processing plants from the delivery vats/holding tanks to the final corking/sealing of the bottles for eventual distribution. From 1958 the milk bottle slowly became phased out of production. At this point in time Melbourne was drawing 160,000 bottles per week from the two major glass bottle works companies, e.g. Melbourne Glass Bottle Works Co.Victoria was the major state supplier of cows milk in the history of Australian milk production from the early 1800's. The Kiewa Valley and its region was a major contributor to meet that demand. Each bottle was "branded" during manufacturing to show the contents (pasteurized milk) and where it originated from (region and supplier). This method of recycling the bottles back to specific dairy farms was a good control method but an uneconomical "on cost" which was replaced by the "throw away" less costly plastic and cardboard containers. Kiewa Valley dairy herds had marked bottles bearing "90/9", "6/18", "6/33", "6/35" and "6/36" Found under the house at 1 Beauty Ave., Mt BeautyThis heavy gauged glass milk bottle has a rim and a distinctive head at the top. This head has been manufactured to facilitate the movement of the bottled along the milk production line. The method of pouring milk into the bottle has been part of the "production line". This bottle has a one pint capacity and is made from "light green" coloured glass(a protection against light penetration). There are other milk bottles that do not have a "green" tint in them. This thick glass bottle, to contain milk, required its thickness because of the extensive handling (man and machine) before final consumption. Milk was delivered by the "milk man" direct to the homes of consumers. During this period delivery to homes in cities and towns was made initially by horse and cart and later by truck.On the bottom end of this bottle is a circle within it "6/35" and next to this "MILK" and opposite "ONE PINT". Below this "THIS BOTTLE BELONGS TO MILK BOTTLE RECOVERY LTD" and below this "AND CANNOT BE USED WITHOUT WRITTEN PERMISSION" on the base "M" underneath this "20"milk, dairy, glass bottle -
Kiewa Valley Historical SocietyBottle Milk, mid to late 1900's
This glass milk bottle was manufactured and used mid to late 1900's (1834 Victorian dairy industry was founded) up until the time that a cheaper container was invented(plastic bottles and polyethylene plastic lined cardboard cartons). In 1909 the supply of pure bottled milk was required for babies to overcome infant mortality due to unhygienic milk sources (unclean containers and unpasteurized milk). Due to the volume of milk being processed and hand milking could not keep up with demand, dairy farms introduced milking machines in the late 1930's. The great increases in dairy herds from the average of 18 cows per heard in 1950's to 142 cows per herd in 1996 required milk tankers to pick up the regions milk supply. This bottle was so constructed to be easily moved within the milk processing plants from the delivery vats/holding tanks to the final corking/sealing of the bottles for eventual distribution. From 1958 the milk bottle slowly became phased out of production. At this point in time Melbourne was drawing 160,000 bottles per week from the two major glass bottle works companies, e.g. Melbourne Glass Bottle Works Co.Victoria was the major state supplier of cows milk in the history of Australian milk production from the early 1800's. The Kiewa Valley and its region was a major contributor to meet that demand. Each bottle was "branded" during manufacturing to show the contents (pasteurized milk) and where it originated from (region and supplier). This method of recycling the bottles back to specific dairy farms was a good control method but an uneconomical "on cost" which was replaced by the "throw away" less costly plastic and cardboard containers. Kiewa Valley dairy herds had marked bottles bearing "90/9", "6/18", "6/33", "6/35" and "6/36" Found under the house at 1 Beauty Ave., Mt BeautyThis heavy gauged glass milk bottle has a rim and a distinctive head at the top. This head has been manufactured to facilitate the movement of the bottle along the milk production line. The method of pouring milk into the bottle has been part of the "production line". This bottle has a half pint capacity and is made from "clear" glass. There are other milk bottles that have a "green" tint in them and this tint was to protect the contents from sun damage. This thick glass bottle to contain milk required its thickness because of the extensive handling before final consumption. Milk was delivered by the "milk man" direct to the homes of consumers. During this period delivery to homes in cities and towns was made initially by horse and cart and later by truck.On the top half of this bottle is "MILK" and opposite "HALF PINT". Below this "THIS BOTTLE BELONGS TO MILK BOTTLE RECOVERY LTD" and below this "AND CANNOT BE USED WITHOUT WRITTEN PERMISSION" on the base is "2 M" underneath this "8/11" and underneath is "ISM -169"glass bottles, commercial milk containers, domestic milk bottles, pasteurized milk bottles -
Kiewa Valley Historical SocietyBottle Milk, Circa mid to late 1900's
This glass milk bottle was manufactured and used mid to late 1900's (1834 Victorian dairy industry was founded) up to the time that a cheaper container was invented(plastic bottles and polyethylene plastic lined cardboard cartons) and produced. In 1909 the supply of pure bottled milk was required for babies to overcome infant mortality due to unhygienic milk sources (unclean containers and unpasteurized milk). Due to the volume of milk being processed and hand milking could not keep up with demand, dairy farms introduced milking machines in the late 1930's. The great increases in dairy herds from the average of 18 cows per heard in 1950's to 142 cows per herd in 1996 required milk tankers to pick up the regions milk supply. This bottle was so constructed to be easily moved within the milk processing plants from the delivery vats/holding tanks to the final corking/sealing of the bottles for eventual distribution. From 1958 the milk bottle slowly became phased out of production. At this point in time Melbourne was drawing 160,000 bottles per week from the two major glass bottle works companies, e.g. Melbourne Glass Bottle Works Co. Victoria was the major state supplier of cows milk in the history of Australian milk production from the early 1800's. The Kiewa Valley and its region was a major contributor to meet that demand. Each bottle was "branded" during manufacturing to show the contents (pasteurized milk) and where it originated from (region and supplier). This method of recycling the bottles back to specific dairy farms was a good control method but an uneconomical "on cost" which was replaced by the "throw away" less costly plastic and cardboard containers. Kiewa Valley dairy herds had marked bottles bearing "90/9", "6/18", "6/33", "6/35" and "6/36" This particular one has "7/14".This heavy gauged glass milk bottle has a rim and a distinctive head at the top. This head has been manufactured to facilitate the movement of the bottled along the milk production line. The method of pouring milk into the bottle has been part of the "production line". This bottle has a one Imperial pint capacity and is made from "clear" glass. There are other milk bottles that have a "green" tint in them. Around the bottom side of the bottle and blown into the glass "ONE IMPERIAL PINT". Below these markings and stenciled is "KIEWA" (in freehand style and underlined) underneath is "PASTEURISED FULL CREAM MILK" underneath this ,in freehand stiyle is "USE" next to this in block style "KIEWA BUTTER, CREAM, AND ICE CREAM MIX" to the left of this ,and barely readable is stenciled "THIS BOTTLE ALWAYS REMAINS/ THE PROPERTY OF/ NORTH EASTERN DAIRY Co. Ltd". On the base of the bottle is molded a big "2". with a smaller "m". An identification mark of "7" over "14" is within a circled boundary. Below this is moulded "RM - 15". glass bottles, commercial milk containers, domestic milk bottles, pasteurized milk bottles -
Rutherglen Historical SocietyPhotograph - Image, 1970s
Greatly relieved by his son’s safe return from war, John Richard Stanton (1872-1955) buys a parcel of productive farming land for his son John Charles “Jack” Stanton (1895-1989) to give him a “good start in life”. Jack’s wife Ethel Capper, devised the name “Gracerray” for the property to honour her sister Grace and the nearby Murray River. After the First World War, fourth generation Jack Stanton (1895-1989) with the help of his father started building a new winery (at the current site of the winery and cellar door) called ‘Gracerray’ named after his wife’s sister Grace and the Murray River. It is pronounced “Grah-sair-ray”. Jack built Gracerray around some existing cement open top vats from a winery that was demolished after phylloxera ravaged the region in the late 1890s. He used second hand materials from the defunct Great Southern gold mine and propped up the roof with huge tree trunks. Jack only made fortified wine up until the 1960s when he and his son-in-law Norman Killeen started making red wine to meet changing Australian tastes.Black and white portrait photograph of a mature man in suit and tie.On back of photo: "145% [upper case E in small circle] J.C. Stanton" wineries, north east victoria, wine industry, j c stanton, stanton & killeen winery, jack stanton -
Bendigo Historical Society Inc.Document - DOCUMENTS: RELATING TO BENDIGO COGNAC DISTILLERY AND 'THUNDER' BREWERY
Documents relating to Bendigo Cognac Distillery and 'Thunder' Brewery - a. Text of article ''It slowly fades away'' - previously catalogued, see Mosaic # 6548 and #2860. Relates to demolition of house at 45 Lucan Street. One handwritten annotation - the word ''rafters'' has ''bearers'' written above it; b. page (no author or date) with seven dates 1859 - 1908 with the names of different firms operating from site - mention of Glasgow and Thunder, Thunder & Co. Lucan St Brewery, Thunders Sandhurst Brewery, Thunder A & Co., Tankard Malting Co., Bendigo Cognac Distillery, Alpine Brewing Co., (latter note has names of some proprietors); c. handwritten three-page letter/note from Cyril Michelsen to ''John'' relating to ''an excellent story'' with some ''added facts'' - the distillery operated back in 1858; quarry for the stone used in the building - a ''stadium' of the North Bendigo State School; old home named ''Stoneleigh'; d. three paged handwritten article/note titled ''The World of the Past and Present'' Feb. 1967 (no author) - description of the site with details of the vats and walls as existing at that time.Mr Cyril Michelsonbuildings, commercial, thunders brewery -
City of Moorabbin Historical Society (Operating the Box Cottage Museum)Kitchen Equipment, cutlery butter knife, c1930
Rodd's was established by George & Ernest Rodd in Melbourne in 1919.They were manufacturers and wholesalers of precious metal jewellery. Later they began to manufacture high quality silver plated cutlery under the brand name “Rodd”. They then expanded into holloware when they took over Platers Pty. Ltd. who produced a very high quality range of silver plated Sheffield Reproduction Silverware, under the brand name “Hecworth”. Rodd’s established a large factory at 150 Barkly St., St. Kilda, Melbourne. During WW2 with a staff some 200, the factory produced ordnance components to help with the war effort. Rodd’s established sales offices in the main city centres of all States. The company prospered. In December, 1960, Rodd [Australia] Ltd. was merged with Mytton’s Ltd., Melbourne, and became part of the newly formed company Mytton Rodd [Australia] Ltd. Mytton’s were also producers of silver plated cutlery under the brand name “Grosvenor” and were strong competitors to the Rodd brand of cutlery Australia wide. It was a friendly take over and the Directors of Rodd [Aust.] Ltd. were appointed to the board of Mytton Rodd [Aust.] Ltd., and some to the Holding Company Mytton’s Ltd. Mytton’s were heavy manufacturing engineers producing a large range of stainless steel products including: kitchen sinks of various design, beer barrels [9 and 18 gallon kegs] for the breweries, milk vats for cooling and storing milk on dairy farms, a large range of dairy and industrial vessels, road transport tanks, LPG tanks, low pressure pre-mix vessels for the soft drink industry. They also produced a range of domestic bathes, steel railway sleepers, using their 3000 ton hydraulic presses. Mytton’s also had their own non ferrous foundry and rolling mill which produced nickel silver sheet used in the manufacturer of their silver plated cutlery. They also produced copper sheet for their own and industrial use. Mytton’s had factories in York St., South Melbourne and Port Melbourne. Rodd [Aust.] Ltd. set up a manufacturing, distribution plant in Auckland, New Zealand, circa 1960. This company began producing precious metal jewellery in a rented space in the premises of Matthey Garret Ltd., Bullion Merchants, in Drake St., Auckland. Later they moved into their own building in Sale St., Auckland. The company prospered and purchased land and built a factory at 121 Apirana Ave. Glen Innes, Auckland, circa 1964. ( B. McCulloch Rodd Pty Ltd)A butter knife with stainless steel blade and bone handle c1930on blade; RODD / STAINLESScutlery, stainless steel, cheltenham, moorabbin, bentleigh, early settlers, rodd aust ltd, mytton rodd pty ltd, aukland, port melbourne -
Federation University Historical CollectionLetter - Correspondence, Letter on Bendigo United Pyrites Company Letterhead, 1898, 1898
"The United Pyrites Company's Works are situated about three quarters of a mile from Spargo Brothers, and are on the northern side of the Marong road, in Pinch-gut Gully. Two processes are followed at these works, viz., the amalgamating process and the treatment by means of chlorine gas. The latter is called the Newbery-Vautin system, and the mode pursued is that laid down by Mr. Cosmo Newbery and Mr Vautin, whose names have been given to the process. Mr. Edwards manages these works. Three reverbatory furnaces are used to roast the pyrites, which is weighed in the truck before being put into the furnaces. At this weighbridge a sample of each lot is kept, and if the yield is not equal to expectation, the works are carefully gone over to see where the fault occurs. Care is taken at the furnace to regulate the heat, otherwise the pyrites might slag instead of roasting evenly right through. An immense revolving furnace (made of boiler iron) was used at these works. It was found to be suitable for treating blanket sand, but was not a success for roasting coarse pyrites. The process of amalgamating by means of Chilian mills is the same in these works as at the Western Works, but the United Works are on a larger scale, and eleven mills are utilised. It is the chlorine gas process which is most interesting here. The gas is made from sulphuric acid, black oxide of manganese, and common salt, and the gas is introduced into huge vats, where it works its way through a filter of pieces of quartz and then through the bed of roasted pyrites lying above. The action of the gas transforms the gold into chloride of gold. This is easily dissolved in water, and in that form is drawn off into huge delf jars, where the use of sulphate of iron precipitates the gold to the bottom. A small battery—eight head of stamps in two boxes—is in use here to crush small consignments of stone sent for trial. Test crushings come from all the Australasian colonies, and even from India. The jars used are manufactured at Epsom, and some of the salt used is also of home manufacture, from the Salt Lakes on the Northern plains. Mr. Edwards took us over a new building in course of erection, and in which the chlorine gas is to be generated in the midst of the pyrites— a still further advancement in the new process. There is some very good machinery in this new building, and the tailings from the ordinary pyrites works will also be treated by this chlorine gas system, which has been found to work well at Mount Morgan, in Queensland. The purest of gold is obtained by this process, the gold passing in solution into a charcoal filter, from which it emerges in the shape of metallic gold. We saw some nice cakes of retorted gold at the works. One of 26oz. was from some New Zealand pyrites (2½ tons), and assayed over 23 carats. There were also cakes of Avoca gold, of silver, and of the tremulous amalgam." (The Argus, 4 February 1887)Two handwritten letters to the Ballarat School of Mines on Bendigo United Pyrites Company Letterhead.bendigo united pyrites company, pyrites, ballarat school of mines, j.j. deeble, joel deeble, joel james deeble, a.m. dean, fred j. martell, martell, s.h. cowan, letterhead -
Puffing Billy RailwayEquipment - Victorian Railways Carriage Foot Warmer
During prestige, long distance train journeys some carriages had air-conditioning, and the majority of passengers had to brave unheated carriages. To offer some comfort during the winter months, the non-air-conditioned carriages were provided with footwarmers. These were metal containers roughly 100 mm thick and 300 mm wide, and about 750 mm long, which were filled with salt crystals (concentrated crystalline hydrated sodium acetate). The footwarmers were covered by sleeves of thick canvas, and two footwarmers were usually placed in each compartment of non-air-conditioned carriages. To activate the chemicals, the footwarmers were heated almost to boiling point. This was done by removing the canvas sleeves and placing the footwarmers in a large bath of very hot water. After they had been heated, they were removed from the bath and the sleeves refitted. They were then ready to be placed in the carriages. The McLaren patent foot warmer was used on railways in New South Wales, Queensland, Victoria and South Australia as well as South Africa and New Zealand. It was during the 1901 royal visit by the Duke and Duchess of Cornwall that these foot warmers were first used in New Zealand in the royal carriage. Before railway carriage heating was introduced, McLaren patent foot warmers were placed on the floor of New South Wales government railway carriages from 1891 to provide a little passenger comfort. The rectangular steel container worked a bit like a hot water bottle but instead of water contained six and a half kilograms of loosely-packed salt crystals, (concentrated crystalline hydrated sodium acetate). This was permanently sealed inside the container with a soldered cap. After the foot warmer was heated in vat of boiling water for about one and a quarter hours the crystals became a hot liquid. (The melting point for sodium acetate is 58 degrees). There was a whole infrastructure of special furnaces set up at stations for the daily heating of foot warmers. By 1914 the Victorian railways had 4,000 foot warmers in service and by 1935 there were 33 furnaces at principal stations to heat them. After about 10 hours the container was picked up by the handle and given a good vertical shake which helped the cooled liquid reform into a solid mass of hot crystals. Staff or sometimes passengers shook them en route when the foot warmers began to get cold. However, as they were heavy this was only possible by fit and agile passengers. At the end of the journey the containers were boiled again for reuse on the next trip. Sodium acetate railway foot warmers were introduced in Victoria in 1889, Adelaide to Melbourne express in 1899. "Shaking up" on this service took place at Murray Bridge and Stawell on the tip to Melbourne and at Ballarat and Serviceton on the trip to Adelaide. The use of foot warmers began to decline in New South Wales from the 1930s with the first trial of carriage air-conditioning in 1936, steam heating from 1948 ad LP gas heating from 1961. By the early 1960s the main services using foot warmers were the overnight mail trains. info from : http://www.powerhousemuseum.com/collection/database/?irn=67564#ixzz4UBNzVf6t Under Creative Commons License: Attribution Non-Commercial There was a whole infrastructure set up at stations for the daily heating of foot warmers in special furnaces. In Victoria alone in 1935 there were 33 heating works.Historic - Victorian Railways - Carriage Heater - Foot warmerA rectangular-shaped stainless steel casing with a welded seam down the back and welded ends. There is a handle at one end for carrying and shaking. Inside the foot warmer are two baffle plates and three trays to contain the sodium acetate. There was a cast-iron ball in each internal compartment. puffing billy, victorian railways, carriage haeter, foot warmer, passenger comfort, station furnace, railway ephemera, early heating methods -
Eltham District Historical Society IncPhotograph - Digital Photograph, Marguerite Marshall, Former home of Alistair and Margot Knox, King Street, Eltham, 16 January 2006
Situated in King Street, Eltham, Alistair Knox built his home and office in 1962-1963 with mud-bricks made from the local soil and recycled materials blending the house with bush around it. Knox popularised the Eltham earth building movement, begun by Montsalvat founder, Justus Jorgensen. Alistair Knox (1912-1986) was also an Eltham Shire Councillor 1971-1975 and Shire President in 1975. Knox established the inaugural Eltham Community Festival in 1975. Covered under Heritage Overlay, Nillumbik Planning Scheme. Published: Nillumbik Now and Then / Marguerite Marshall 2008; photographs Alan King with Marguerite Marshall.; p145 Lack of money was a strong incentive for Alistair Knox to do what he did best when he built his house and office at King Street, Eltham in 1962-63. He used mud-bricks from local soil and recycled materials, characteristically blending the house with the bush around it. The result was a work of art. Knox popularised the Eltham earth building movement,1 begun by Montsalvat founder Justus Jörgensen. He was also an Eltham Shire Councillor from 1971 to 1975 and Shire President in 1975. For Knox mud-brick building was not just a building style, but a spiritual experience and a way of relating with nature. At 40 he rediscovered God and his building reflected his theological, political, philosophical and particularly environmental world view, which was far ahead of its time.2 He also contributed to building development in his use of concrete slab foundations when stumps and bearers were the norm. Knox was introduced to mud-brick construction in 1940 by Jörgensen, then shortly after, Knox joined the Navy. In 1946 Knox studied Building Practice and Theory at Melbourne Technical College (now RMIT University). There he befriended fellow student and artist Matcham Skipper who belonged to what was then called the Jörgensen Artists’ Colony. Knox decided to build an earth building in Eltham, partly because the post-war huge building demands resulted in expensive and scarce building materials. He asked artist Sonia Skipper for help who, with Matcham, had constructed mud-brick buildings at the Artists’ Colony. The simple rectangular low-lying house at King Street is framed by native plants and a 3.6 metres wide pergola surrounds the building. Wedded to the landscape, a door in every room at the perimeter, opens outside. The property also includes a forge, a small hut built by son Macgregor at 15, and a mud-brick tower for chickens. Building materials were foraged from a wide variety of sources. Some of the joinery material came from old whisky vats. When the Oregon of the highest quality ‘was put through the wood-working machines, it gave off a deep smell of whisky that made the whole atmosphere exotic and heady’.3 Amateur builders, including schoolboys from Knox’s Presbyterian Church, made some of the mud-bricks. But the building was finished with the professional help of Yorkshire builder, Eric Hirst. Inside, the light is subdued with the mud-brick, beamed timber ceilings and floors of slate, timber or orange-brown tiles. Skylights, with rich blue and red leadlighting, illuminate one entrance area and this feature is repeated as edging on the door. The centre of the house is like a covered courtyard, with rooms built around it. The central room, 11 metres x 7 metres, was built in the same proportions as Knox’s mud-bricks. Clerestory windows on four sides infuse the room with a soft light. A huge brick fireplace extends beyond one corner and opposite is a small one where timber can only be placed vertically. The slate for the floor was discarded from the Malthouse Brewery now used as a theatre in Southbank. In the middle is a large refectory table and benches that seat 18. Like much of the house, it is rugged, yet beautiful. Made of Western Australian Jarrah by Macgregor with a chain saw and an adze, it retains knot and nail holes. Each wall has an opening, 2.4 metres at the ends and 3.6 metres at the sides. Only one has doors and these concertina doors are made of the backs of old church pews. The main bedroom has an ensuite with a marble hand basin discarded from the Victorian Parliament building; and a dressing room, where two wardrobes of polished timber recovered from a tip are attached to the walls. Separate from the house is the strikingly original circular-shaped office made of bluestone sourced from the original Army campsite at Broadmeadows.This collection of almost 130 photos about places and people within the Shire of Nillumbik, an urban and rural municipality in Melbourne's north, contributes to an understanding of the history of the Shire. Published in 2008 immediately prior to the Black Saturday bushfires of February 7, 2009, it documents sites that were impacted, and in some cases destroyed by the fires. It includes photographs taken especially for the publication, creating a unique time capsule representing the Shire in the early 21st century. It remains the most recent comprehenesive publication devoted to the Shire's history connecting local residents to the past. nillumbik now and then (marshall-king) collection, alistair and margot knox house, alistair knox design, mudbrick construction, eltham, king street -
Flagstaff Hill Maritime Museum and VillageAnimal 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 VillageAnimal 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 VillageAnimal 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 VillageAnimal 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 VillageAnimal 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 VillageAnimal 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 VillageAnimal specimen - Whale Vertebrae, Undetermined
Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Whalebone The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The bone of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as whalebone. Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070.Whale bone during the 17th, 18th, 19th and early 20th centuries was an important industry providing an important commodity. Whales from these times provided everything from lighting & machine oils to using the animal's bones for use in corsets, collar stays, buggy whips, and many other everyday items then in use.Whale bone Vertebrae with advanced stage of calcification as indicated by deep pitting. Off white to grey.None.warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whale bones, whale skeleton, whales, whale bone, corsets, toys, whips, whaleling industry, maritime fishing, whalebone -
Flagstaff Hill Maritime Museum and VillageAnimal specimen - Whale Jaw Bone, Undetermined
Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Baleen, or "Whalebone" The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The "bone" of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as "whalebone." Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070.Whale bone during the 17th, 18th, 19th and early 20th centuries was an important industry providing an important commodity. Whales from these times provided everything from lighting & machine oils to using the animal's bones for use in corsets, collar stays, buggy whips, and many other everyday items then in use.Whale jaw bone one side, long & curved with advanced stage of calcification off white to grey.None.warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whale bones, whale skeleton, whales, whale bone, corsets, toys, whips, whaleling industry, maritime fishing, whalebone -
Flagstaff Hill Maritime Museum and VillageAnimal specimen - Whale Rib Bone, Undetermined
Prior to carrying out a detailed condition report of the cetacean skeletons, it is useful to have an understanding of the materials we are likely to encounter, in terms of structure and chemistry. This entry invites you to join in learning about the composition of whale bone and oil. Whale bone (Cetacean) bone is comprised of a composite structure of both an inorganic matrix of mainly hydroxylapatite (a calcium phosphate mineral), providing strength and rigidity, as well as an organic protein ‘scaffolding’ of mainly collagen, facilitating growth and repair (O’Connor 2008, CCI 2010). Collagen is also the structural protein component in cartilage between the whale vertebrae and attached to the fins of both the Killer Whale and the Dolphin. Relative proportions in the bone composition (affecting density), are linked with the feeding habits and mechanical stresses typically endured by bones of particular whale types. A Sperm Whale (Physeter macrocephalus Linnaeus, 1758) skeleton (toothed) thus has a higher mineral value (~67%) than a Fin Whale (Balaenoptera physalus Linnaeus, 1758) (baleen) (~60%) (Turner Walker 2012). The internal structure of bone can be divided into compact and cancellous bone. In whales, load-bearing structures such as mandibles and upper limb bones (e.g. humerus, sternum) are largely composed of compact bone (Turner Walker 2012). This consists of lamella concentrically deposited around the longitudinal axis and is permeated by fluid carrying channels (O’Connor 2008). Cancellous (spongy) bone, with a highly porous angular network of trabeculae, is less stiff and thus found in whale ribs and vertebrae (Turner Walker 2012). Whale oil Whales not only carry a thick layer of fat (blubber) in the soft tissue of their body for heat insulation and as a food store while they are alive, but also hold large oil (lipid) reserves in their porous bones. Following maceration of the whale skeleton after death to remove the soft tissue, the bones retain a high lipid content (Higgs et. al 2010). Particularly bones with a spongy (porous) structure have a high capacity to hold oil-rich marrow. Comparative data of various whale species suggests the skull, particularly the cranium and mandible bones are particularly oil rich. Along the vertebral column, the lipid content is reduced, particularly in the thoracic vertebrae (~10-25%), yet greatly increases from the lumbar to the caudal vertebrae (~40-55%). The chest area (scapula, sternum and ribs) show a mid-range lipid content (~15-30%), with vertically orientated ribs being more heavily soaked lower down (Turner Walker 2012, Higgs et. al 2010). Whale oil is largely composed of triglycerides (molecules of fatty acids attached to a glycerol molecule). In Arctic whales a higher proportion of unsaturated, versus saturated fatty acids make up the lipid. Unsaturated fatty acids (with double or triple carbon bonds causing chain kinks, preventing close packing (solidifying) of molecules), are more likely to be liquid (oil), versus solid (fat) at room temperature (Smith and March 2007). Objects Made From the Whaling Industry We all know that men set forth in sailing ships and risked their lives to harpoon whales on the open seas throughout the 1800s. And while Moby Dick and other tales have made whaling stories immortal, people today generally don't appreciate that the whalers were part of a well-organized industry. The ships that set out from ports in New England roamed as far as the Pacific in hunt of specific species of whales. Adventure may have been the draw for some whalers, but for the captains who owned whaling ships, and the investors which financed voyages, there was a considerable monetary payoff. The gigantic carcasses of whales were chopped and boiled down and turned into products such as the fine oil needed to lubricate increasing advanced machine tools. And beyond the oil derived from whales, even their bones, in an era before the invention of plastic, was used to make a wide variety of consumer goods. In short, whales were a valuable natural resource the same as wood, minerals, or petroleum we now pump from the ground. Oil From Whale’s Blubber Oil was the main product sought from whales, and it was used to lubricate machinery and to provide illumination by burning it in lamps. When a whale was killed, it was towed to the ship and its blubber, the thick insulating fat under its skin, would be peeled and cut from its carcass in a process known as “flensing.” The blubber was minced into chunks and boiled in large vats on board the whaling ship, producing oil. The oil taken from whale blubber was packaged in casks and transported back to the whaling ship’s home port (such as New Bedford, Massachusetts, the busiest American whaling port in the mid-1800s). From the ports it would be sold and transported across the country and would find its way into a huge variety of products. Whale oil, in addition to be used for lubrication and illumination, was also used to manufacture soaps, paint, and varnish. Whale oil was also utilized in some processes used to manufacture textiles and rope. Spermaceti, a Highly Regarded Oil A peculiar oil found in the head of the sperm whale, spermaceti, was highly prized. The oil was waxy, and was commonly used in making candles. In fact, candles made of spermaceti were considered the best in the world, producing a bright clear flame without an excess of smoke. Spermaceti was also used, distilled in liquid form, as an oil to fuel lamps. The main American whaling port, New Bedford, Massachusetts, was thus known as "The City That Lit the World." When John Adams was the ambassador to Great Britain before serving as president he recorded in his diary a conversation about spermaceti he had with the British Prime Minister William Pitt. Adams, keen to promote the New England whaling industry, was trying to convince the British to import spermaceti sold by American whalers, which the British could use to fuel street lamps. The British were not interested. In his diary, Adams wrote that he told Pitt, “the fat of the spermaceti whale gives the clearest and most beautiful flame of any substance that is known in nature, and we are surprised you prefer darkness, and consequent robberies, burglaries, and murders in your streets to receiving as a remittance our spermaceti oil.” Despite the failed sales pitch John Adams made in the late 1700s, the American whaling industry boomed in the early to mid-1800s. And spermaceti was a major component of that success. Spermaceti could be refined into a lubricant that was ideal for precision machinery. The machine tools that made the growth of industry possible in the United States were lubricated, and essentially made possible, by oil derived from spermaceti. Baleen, or "Whalebone" The bones and teeth of various species of whales were used in a number of products, many of them common implements in a 19th century household. Whales are said to have produced “the plastic of the 1800s.” The "bone" of the whale which was most commonly used wasn’t technically a bone, it was baleen, a hard material arrayed in large plates, like gigantic combs, in the mouths of some species of whales. The purpose of the baleen is to act as a sieve, catching tiny organisms in sea water, which the whale consumes as food. As baleen was tough yet flexible, it could be used in a number of practical applications. And it became commonly known as "whalebone." Perhaps the most common use of whalebone was in the manufacture of corsets, which fashionable ladies in the 1800s wore to compress their waistlines. One typical corset advertisement from the 1800s proudly proclaims, “Real Whalebone Only Used.” Whalebone was also used for collar stays, buggy whips, and toys. Its remarkable flexibility even caused it to be used as the springs in early typewriters. The comparison to plastic is apt. Think of common items which today might be made of plastic, and it's likely that similar items in the 1800s would have been made of whalebone. Baleen whales do not have teeth. But the teeth of other whales, such as the sperm whale, would be used as ivory in such products as chess pieces, piano keys, or the handles of walking sticks. Pieces of scrimshaw, or carved whale's teeth, would probably be the best remembered use of whale's teeth. However, the carved teeth were created to pass the time on whaling voyages and were never a mass production item. Their relative rarity, of course, is why genuine pieces of 19th century scrimshaw are considered to be valuable collectibles today. Reference: McNamara, Robert. "Objects Made From the Whaling Industry." ThoughtCo, Jul. 31, 2021, thoughtco.com/products-produced-from-whales-1774070.Whale bone during the 17th, 18th, 19th and early 20th centuries was an important industry providing an important commodity. Whales from these times provided everything from lighting & machine oils to using the animal's bones for use in corsets, collar stays, buggy whips, and many other everyday items then in use.Whale rib bone with advanced stage of calcification as indicated by brittleness. None.warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, whale bones, whale skeleton, whales, whale bone, corsets, toys, whips, whaleling industry, maritime fishing, whalebone -
Stawell Historical Society IncPhotograph, Whitehall Property Greens Creek
Hutchings family 1. Wimmera River in flood below Whitehall running a banker c. 1920. Ted & Col Hutchings in foreground. 2. Wimmera River in flood looking downstream. No date but possibly same time as no. 1. from same place. 3. Looking over the Wimmera River to Island paddock towards Greens Creek 4. Wimmera River half a banker at Whitehall 5. Wimmera River in flood upstream from carpenter's shop looking towards engine house at Whitehall 5a. Wimmera River in flood. Left to right - blacksmith shop and carpenters' shop. 5b. Taken from the same spot with Emily & Ada Hole, E G (Ted) & Col Hutchings. Blacksmith shop & carpenters' shop, Whitehall. 5c. Wimmera River upstream from the carpenters' shop. Foreground is possibly Belladonna lilies which were all over the river bank in 1992. Whitehall. 5d. Looking downstream towards the loose boxes, Whitehall. 5e. Blacksmiths' shop and carpenters' shop from the pumping station. Wimmera River, Whitehall. 6. Wimmera River in flood at Whitehall. 7. Wimmera River half a banker in front of old hut at Whitehall. 8. Wimmera River Emily Hayes, Edward G (Ted) Hutchings & Colin J Hutchings. 9. Morrl-Morrl - Greens Creek Road opposite back paddock. Whitehall. Black Ford in distance. c. 1919 10. Whitehall woolshed north east aspect, Drive to the right of photo 11. Whitehall woolshed - north east aspect showing the drive to the right 11a. Whitehall woolshed - north aspect 11b. Same tree near woolshed 11c. Same tree again in centre, other trees came up after the 23 flood. Woolshed to the right out of photo. 12. Whitehall woolshed - south aspect, sheep entrance end 13. Whitehall. left to right, Stackyard, stables in the centre and the Wimmera River behind following the trees. 14. Whitehall horse paddock c. 1920. left to right, Machinery shed, stable in the centre. Homestead to the right in distance. There is no windmill. 15. Load of wool from Whitehall woolshed to right. 16. Whitehall c. 1920 before the windmill. left to right, garage and mens' hut. Wimmera river runs along the tree line. 16a. Stables, garage and mens' hut after the construction of the windmill. River behind. 17. Whitehall c. 1922. Note windmill addition. Garage to left, Mens' Hut to right. Jack Donnelly & Edward G (Ted) Hutchings with pet lambs. River behind trees. 18. Whitehall gardens. Summer house to the right, pine tree lined drive in the centre background. Ted & Col Hutchings on the lawn. C. 1920 19. Edward G. (Ted) & Colin J. Hutchings in Whitehall garden. Wimmera River in the background. The building behind the fence is the carpenters' shop which the family lived in while house was rebuilt after fire 15 Jan 1877 20. Whitehall c. 1920. left to right, cattle yard, killing house, Wimmera river behind the fence, and the loose box on the right. Black Orpington chooks in foreground. 21. Bay window (original blinds) in the master bedroom. Whitehall 20 Sep 1992 22. Master bedroom (original wallpaper) Joyce & Col Hutchings, Moyu, Ben & Rebecca Roe 20 Sep 1992 23. Col & Ted's bedroom (original) Marble mantlepiece had been removed. Whitehall. 20 Sep 1992 24. Whitehall kitchen. Large yellow meat oven to left of stove, bread oven far left, extreme right is oven where milk heated to skim cream. Chimney was a central one shared with meat oven. Bread oven chimney separate. 20 Sep 1992 25. Whitehall dairy, made of natural stone with dried brick corners. Entrance behind creeper which is over trellis. 20 Sep 1992. This building still remains in 1 Jun 2023 26. Inside charcoal lined meat cellar. Bottom right is concrete vat for pickling meat in brine. Top of brickwork slightly above ground level. Whitehall 20 Sep 1992 27. Fire foreground was stable flooring which was to left of photo. Machinery shed (thatch roof). 4 posts far left remains of cowshed. Large post in centre foreground is the gate post of corral. River to right. 20 Sep 1992 28. Whitehall machinery shed. Posts on far right are cow shed. Over the river is the island paddock. Wimmera river runs behind machinery shed. 20 Sep 1992 29. Posts of 10 sided corral. Killing house by side of gum tree in centre of photo on far side of corral. To left is one of the bales of the cowshed. Whitehall. 20 Sep 1992 29a. Similar photo in the 1920's. To the right is horsebreaking corral, then cow shed, loose box, haystacks and stable on left. Whitehall. 30. Dining room fire place put in the open fire of the mens' hut, only the chimney remains. To the left is the drive & river. Rebecca Roe, Col Hutchings granddaughter. 20 Sep 1992 30a. Looking down the Whitehall Drive. Mens' Hut (Jack Donnelly in doorway) and garage far left. 1920's 30b. The Drive, Whitehall taken from in front of the mens' hut. Wimmera River on the left. Gum tree on left still there 20 Sep 1992. 30c. Reverse from 30a. Whitehall drive from the front gate looking towards the mens' hut and garage. c. 1926 30d. Curly Donohue leaving for Warracknabeal. Ex mail contractor Omeo to Bright Victoria. C. 1926 30e. Looking down the drive towards front gate. Mens' hut on the right, river on the left. 31. Whitehall from the side. Building in centre behind David is separater room. 2 roomed hut to left of separater room and remains of mens' hut chimney. Photo 16 taken from similar spot. 20 Sep 1992 32. Benjamin Roe (Col Hutchings grandson) in the Carpenters' shop. The family lived in this building after the fire in the 1870's. Whitehall 20 Sep 1992 33. Ford across the Wimmera River at Whitehall (River abt. 5 feet higher than normal) 20 Sep 1992 33a. Wimmera River, Whitehall 34. Site of old bridge before Col Hutchings time. Tree in foreground to right still has bolt from bridge work protuding. A large post was in the centre of photo to make equal distance. 20 Sep 1992 35. Entrance to the old ford. Colin J Hutchings & his daughter, Moyu Roe. Wimmera River, Whitehall 20 Sep 1992 36. Summer house at Whitehall 20 Sep 1992 looking down to the orchard, dark green trees in distance old fruit trees. 36a. Edward & Colin Hutchings in front of the Summer house, Whitehall c. 1921 36b. Summer house looking towards front gate. Whitehall. 36c. Grey thrush in nest box which can be seen in previous photo with summer house in the background. Whitehall. 36d. Summer house from the orchard side. Whitehall. 37a. South side of Whitehall. First window Edith Sutherland's room, 2nd window, Ted & Col's room, bay window master bedroom 38. Taken in middle of front path looking towards front gate. Edith Sutherland in garden. Date palm in centre, cotton palm to left. Whitehall c. 1920's 38a. Garden at Whitehall taken from near the cotton palm. 39. Whitehall 20 Sep 1992 Bay window-master bed, small window to r. of bay-Colin Hutchings born in, front door, window to right-dining room, round the corner- drawing room, window on right, spare bed, verandah on left is spare bed. 39a. Whitehall c. 1920's Date palm on the right. 39b. Win, Colin T & Colin J Hutchings. Date palm in background. Whitehall 1943 39c. Edward George, Colin Thomas, Elizabeth Ambler & Colin James Hutchings wearing RAAF uniform. Date Palm in background. Whitehall c. 1943 39c. Front garden of Whitehall looking from the front right side of the house towards the drive & Wimmera River. Date palm on right, cotton palm on left 20 Sep 1992 40. Taken from bottom left corner of front garden looking towards the summer house. Cotton palm on right. River to the left. 41. Elizabeth A Hutchings beside master bedroom window. Whitehall c. 1920 42. Whitehall (photo of a painting by Wallace) owned by Colin T Hutchings 1982. 42a. Whitehall painting by Wallace after restoration now owned by Nick Hutchings 2021 42b. Whitehall c. 1923 42c. Taken from the side garden looking towards the right side of house. Front door is to the left out of photo. The cotton palm is to the left. c. 1923 43. Signpost showing Whitehall 20 Sep 1992, All ground up to the tree line behind the signpost was Whitehall property. 44. Colin T. Hutchings age 9 mths. Mar 1943 Whitehall 45. Colin James, Elizabeth Ambler & Edward George Hutchings. Front garden by the date palm, Whitehall c. 1939-40 45a. Colin James, Edward George, Edward Thomas Hutchings & E. Winifred May & Barney (dog) Whitehall. c. 1939-40. 45b. Colin James & Colin Thomas Hutchings during drought & World War ll c. 1944-45 in front of cotton palm, date palm to right. 46. Garden at Whitehall. Jack Donnelly on the hand mower. Cotton palm on left, date palm behind Jack and roof of carpenters shop to right. 47. Colin J Hutchings on tractor, E. Tom Hutchings behind. Whitehall, c. 1933 48. Jack Donnelly (Tad) & Colin J. Hutchings. Cotton palm to right. Whitehall c. 1917-18 49. Edward G (Ted) & Colin J Hutchings with cockatoo outside the dairy in rear garden. Whitehall c. 1923 50. Taken from the windmill looking across the roof of the mens' hut to the garden, orchard and drive in Winter time. House is behind the trees to right, Wimmera River to the left out of picture. Whitehall. 50a. Not labelled by Col Hutchings. It is an aerial shot looking towards the house in the trees & seems to be taken from the top of a tree...on the river side. 51. E. Tom Hutchings & George Chambers dam sinking. Whitehall. 51a. Tom Hutchings & George Chambers dam sinking. Whitehall. 51b. E. Tom Hutchings dam sinking. 52. Emily Hayes & Ada Hole (sisters) with Tom, Col & Ted Hutchings at the woolshed. 53. E T (Tom) Hutchings on reaper & binder. Whitehall. 54. Orchard looking towards the house. Carpenters' shop and river on the right. Whitehall. 54a. Orchard looking from the house, dark trees in background form part of the drive. 55. Grasshopper plague, Christmas Day 1933. Whitehall 56. Frost on the front lawn, Whitehall. 57. Little red hen & chicks with the river in the background 58. Edward (Ted) G. Hutchings muscovy ducks, hay shed and trees along the river in the background. 58a. Edward (Ted) G Hutchings muscovy ducks. 59. Swimming in the Wimmera River, either Ted or Col Hutchings in the foreground. 60. Looking towards the fowl house and pigsty, Whitehall. 61. Snake on the path, Whitehall. c. 1923 61a. E. Tom Hutchings killing a snake, Whitehall. c. 1923 61b. E. Tom Hutchings killing a snake, Whitehall. c. 1923 62. Notice of clearing sale, Stawell News & Pleasant Creek Chronicle on 5 Apr 1916 where the stock & whole of the household furniture was to be sold by James Hutchings widow. 63. Back to Greens Creek 7 Jun 1987 Colin J Hutchings left and Belle Kindred centre looking at photo 64. Back to Greens Creek 7 Jun 1987 Colin J Hutchings centre, Graham Stewart holding photograph on the right. 65. Colin J Hutchings & Bill Walker. Back to Greens Creek 7 Jun 1987 66. Colin J Hutchings delivering a speech before the plaque unveiling. Back to Greens Creek 7 Jun 1987 67. Graeme Williamson & Colin J Hutchings (2 'old boys') Greens Creek School Site 7 Jun 1987 68. Graeme Williamson talking to Moyu Roe (Hutchings) in background is May Williamson. Back to Greens Creek 7 Jun 1987 69. Greens Creek SS, Edward (Ted) & Colin J Hutchings attended. 70. Original students of first Greens Creek School 7 Jun 1987 Back row left 1. Kindred 3. Colin J Hutchings 4,5,6 not known 7. Graeme Williamson Sitting left 1. Not an original 2,3,4, not known 5. Belle Kindred 71. Terrier at Greens Creek State School 72. The new school students Back to Greens Creek 7 Jun 1987. Perry twins standing in centre and the teacher kneeling front left. 73. Will Rees water colour 1925 signature 74. Will Rees water colour 1925 75. Shearing at Kirkellar. Allen Simpson's 76. Back to Greens Creek 7 Jun 1987 Colin J Hutchings left and Belle Kindred centre looking at photo 77. Back to Greens Creek 7 Jun 1987 Colin J Hutchings centre, Graham Stewart holding photograph on the right. 78. Colin J Hutchings & Bill Walker. Back to Greens Creek 7 Jun 1987 79. Colin J Hutchings delivering a speech before the plaque unveiling. Back to Greens Creek 7 Jun 1987 80. Graeme Williamson & Colin J Hutchings (2 'old boys') Greens Creek School Site 7 Jun 1987 81. Graeme Williamson talking to Moyu Roe (Hutchings) in background is May Williamson. Back to Greens Creek 7 Jun 1987 82. Greens Creek SS, Edward (Ted) & Colin J Hutchings attended. 83. Original students of first Greens Creek School 7 Jun 1987 Back row left 1. Kindred 3. Colin J Hutchings 4,5,6 not known 7. Graeme Williamson Sitting left 1. Not an original 2,3,4, not known 5. Belle Kindred 84. Shearing at Kirkellar. Allen Simpson's 85. Terrier at Greens Creek State School 86. The new school students Back to Greens Creek 7 Jun 1987. Perry twins standing in centre and the teacher kneeling front left. Digital Copy of Parish Maps Kara Karahomestead -
Kiewa Valley Historical SocietyBag Whitening Agent Reckitts, circa early 1900s
This little bag of "whitener" additive for the washing of white clothes was manufactured in Hull in the United Kingdom mid and later 1900's. The Manufacturer, Ricketts, was one of the first manufacturers to employ women in equal proportions with males (a rarity before 1914). This product was used to improve the appearance of white fabrics. This ability to use a product that would "whiten" clothes chemically rather than the "hard boiling" of clothes was a time saver and a lot easier on the fabrics. This is a boon to rural families where time was of the essence (boiling took time). The blue coloring was introduced because the white colour perception is enhanced by the blue (fadeable and not permanent). The "washing machine industry" of the late 1900's emphasised "whitening" agents that were not so haphazard in producing blue stains, and allowed a "gentle" washing action. This item is very significant in detailing the early 1900's rural household domestic "chore" of washing white clothes to a "social" standard of cleanliness. White shirts were the mark cleanliness that those outside of the family judged the family unit by. The best clothes were worn to church on Sundays. Hard and mostly rural activities/work in the Kiewa Valley encompassing farming, crop cultivation, cattle/sheep and "field work" to do with the SEC Vic Hydro Scheme involved provided a stain prone environment. As appearances, of clothing, was on the whole not significant it was a different scenario at social and religious scenes. The ability to attain "brilliant" white shirts, dresses and bonnets by a less drastic method to that of "boiling" of clothes in vats, was a boon of that "era". The anti establishment revolt came later in the 1950's onward took longer to migrate from the cities and larger rural townships to eventually sneak into the Kiewa valley.This "blue bag" is a whitening agent wrapped in flannel or muslin, or sold ready bagged (1 ounce).It was used in the final rinse to "whiten white coloured clothes" The string was used to facilitate finger grip onto the "bag" after the wash had finished for easy removal to stop the hand and other surfaces from being stained by the blue colour residue drips.domestic and commercial laundries, starch and whitening additive, washing brightener -
Federation University Historical Collection
Booklet, Ballarat School of Mines Annual Report, 1901, 1901
In 1901 Andrew Anderson was President of the Ballarat School of Mines. At the height of its world wide fame the annual report states: 'That the public recognises and appreciates the importance of the School, is evident by the large additions to the class rolls - (many of the students have come long distances, from England, India, South Africa, new South Wales, Queensland, West Australia, South Australia and Tasmania,) which give ample proof, if such were necessary, of the wide spread reputation of the School.'8 page booklet relating to the Ballarat School of Mines in the year 1901. It includes information on: Alfred Johnston's death during the Boer War, Thomas Bath's bequest to the Ballarat School of Mines, resignation of Theophilus Williams from the School Council, appointment of Richard Maddern and Isaiah Pearce to the School Council, Associateship courses, New mining metallurgical laboratory and a statement of receipts and expenditure ballarat school of mines, andrew anderson, thomas bath, alfred gresham johnston, boer war, rhenoster kop, south africa, richard maddern, isaiah pearce, salariesmining laboratory, metallurgical laboratory, wynne tables, tregurtha tables, halley's percussioina tables, wilfley concentrator, spitzkasten, jig, linkenback table, chilian mill, amalgamator, model agitation plant, slime vats, alfred mica smith, william gurr, thomas hart, museum, fees, mining plant, model mine, allendale excursion, daylesford excursion, botanical excursion, geological excursion, melbourne excursion, itonworkers' association -
Ballaarat Mechanics' Institute (BMI Ballarat)FC Pring Cyanide Vat Builder
This photograph is from the Max Harris Collection held by the Ballaraat Mechanics' Institute. Please contact BMI for all print and usage inquiries.ballarat, pring, cyanide vat builder, steam, cooperage, 1854 -
Tatura Irrigation & Wartime Camps MuseumBook - Book - Childrens, E. O. Plauen, Vater Und Sohn (Father and Son), 1940's
Book brought from Jaffa, Palestine in 1941 by the Drescher family, internees at Camp 3, Tatura.Soft yellow coloured card covered book with black and white comic like illustrations. Cover shows man lying down with fee in air, small boy looking down at him. Title in handwriting- German gothic script.Peter Dreschercamp 3, drescher, children's books, peter drescher, vater und sohn, father and son -
Tatura Irrigation & Wartime Camps MuseumBook - Book - Childrens, Vater Und Sohn (Father and Son), 1940's
Book brought from Jaffa, Palestine in 1941 by the Drescher family, internees at Camp 3, Tatura.Soft red coloured card covered book with black and white comic like illustrations. Cover shows man sitting on a swing with a young boy holding a Winnie the pooh toy. Title in German Gothic script.Peter Dreschercamp 3, children's books, peter drescher, german internees in camp 3 -
Tatura Irrigation & Wartime Camps MuseumBook - Childrens, E. O. Plauen, Vater Und Sohn (Father and Son), 1940's
Book brought from Jaffa, Palestine in 1941 by the Drescher family, internees at Camp 3, Tatura.Soft yellow coloured card covered book with black and white comic like illustrations. Cover shows man lying down with fee in air, small boy looking down at him. Title in handwriting- German gothic script.Peter Dreschercamp 3, drescher, children's books -
Federation University Historical Collection
Letter, Specifications for taking down , carting and re-erecting engine gear puddlers
Taking down of equipment of the Berry Consols Gold Mining Company No.1 Mine. Handwritten specifications.engine, gear, air pipes, surface horizontal gear, machine horses, sluice deck, tram roads, step ladders, engine house, balance weights, sludge vat
