During the 1890s the Ballarat School of Mines started teaching photography.Handwritten invoice on printed letterhead. The invoice was for chemicals and apparatus for the Ballarat School of Mines, including items for the Chemical Laboratory, Photography Laboratory, Electrical Laboratory and Cyanide.walter cornell, ballarat school of mines, laboratory, chemist, pharmacy, photography electricity, photographic equipment

The Davey Paxman Experimental Steam Engine was purchased as the result of a bequest from Thomas Bath. The 'substantial sum' was used to build an Engineering Laboratory. The Ballarat School of Mines Council minutes of 08 November 1901 record: - Plans for [the] proposed building were submitted ... and ... it was resolved that a temporary building for an Engineering Laboratory be put up.' This laboratory, as an existing building, is first mentioned in the Ballarat School of Mines President's Annual Report of 1901, presented on 28 February 1902, reporting 'the erection of a building 67ft long by 33 ft wide' This report also lists all the equipment that would be accommodated in the Engineering Laboratory, including the experimental steam engine and boiler. The experimental Davey-Paxman steam engine arrived in Ballarat towards the end of 1902. The Engineering Laboratory was opened on 14 August 1903 by His Excellency Sir Sydenham Clarke. This engineering laboratory remained in use till about 1945. By 1944 preparations were under way at the Ballarat School of Mines to expand existing facilities, to be ready for the influx of returned soldiers. A new Heat Engines laboratory was built, this time of brick construction, replacing the previous corrugated-iron shed. In the early stages the steam engine was used to drive an overhead transmission shaft for machinery in the adjacent workshop. Later the steam engine was moved to a space that became the Heat Thermodynamics Laboratory. At the end of 1969 the engine was relocated to the Thermodynamics Laboratory at the then Ballarat Institute of Advanced Education (BIAE) Mt Helen Campus. It was donated to Sovereign Hill in 2006. According to the research of Rohan Lamb in 2001 around five experimental steam engines were made by Davey Paxman, and three of these had similar configuration to the Ballarat School of Mines Steam Engine, however, each of these was also unique with different valve arrangements. The list, which was on a scrap of paper in a folio held in the Essex Archives, confirmed that one was sent to India. The Ballarat steam engine can be dated to late 1901 to early 1902. Zig Plavina was responsible for moving the steam engine to Mount Helen, and worked on it as a technician for many years. He observed the following: * The condenser is driven by the low pressure engine. * The following arrangements are possible: i) the high pressure engine alone, exhausting to atmosphere. Condenser not used, crankshaft flanges not coupled. ii) crankshafts coupled, mains pressure (120 psi) steam supplied to high pressure engine, partially expanded steam delivered to low pressure engine (Tandem operation). Choice available re exhaust steam: either to the condenser or to atmosphere. iii) crankshafts not coupled, reduced pressure steam supplied to low pressure engine. Exhaust steam - either to the condenser or to atmosphere. * Valve arrangement - a choice of Pickering cut-off or throttle governor. On low pressure engine - throttle governor only. Black and white photograph of an experimental steam engine which was produced for the Ballarat School of Mines. It was designed for experimental purposes, such as testing of efficiency, etc. The laboratory which housed the steam engine was lit with gas lighting. davey paxman experimental steam engine, model steam engine, davey paxman, steam, thomas bath, thermodynamics

The Davey Paxman Experimental Steam Engine was purchased by the Ballarat School of Mines as the result of a bequest from Thomas Bath.The Davey Paxman Experimental Steam Engine was purchased as the result of a bequest from Thomas Bath. The 'substantial sum' was used to build an Engineering Laboratory. The Ballarat School of Mines Council minutes of 08 November 1901 record: - Plans for [the] proposed building were submitted ... and ... it was resolved that a temporary building for an Engineering Laboratory be put up.' This laboratory, as an existing building, is first mentioned in the Ballarat School of Mines President's Annual Report of 1901, presented on 28 February 1902, reporting 'the erection of a building 67ft long by 33 ft wide' This report also lists all the equipment that would be accommodated in the Engineering Laboratory, including the experimental steam engine and boiler. The experimental Davey-Paxman steam engine arrived in Ballarat towards the end of 1902. The Engineering Laboratory was opened on 14 August 1903 by His Excellency Sir Sydenham Clarke. This engineering laboratory remained in use till about 1945. By 1944 preparations were under way at the Ballarat School of Mines to expand existing facilities, to be ready for the influx of returned soldiers. A new Heat Engines laboratory was built, this time of brick construction, replacing the previous corrugated-iron shed. In the early stages the steam engine was used to drive an overhead transmission shaft for machinery in the adjacent workshop. Later the steam engine was moved to a space that became the Heat Thermodynamics Laboratory. At the end of 1969 the engine was relocated to the Thermodynamics Laboratory at the then Ballarat Institute of Advanced Education (BIAE) Mt Helen Campus. It was donated to Sovereign Hill in 2006. According to the research of Rohan Lamb in 2001 around five experimental steam engines were made by Davey Paxman, and three of these had similar configuration to the Ballarat School of Mines Steam Engine, however, each of these was also unique with different valve arrangements. The list, which was on a scrap of paper in a folio held in the Essex Archives, confirmed that one was sent to India. The Ballarat steam engine can be dated to late 1901 to early 1902. Zig Plavina was responsible for moving the steam engine to Mount Helen, and worked on it as a technician for many years. He observed the following: * The condenser is driven by the low pressure engine. * The following arrangements are possible: i) the high pressure engine alone, exhausting to atmosphere. Condenser not used, crankshaft flanges not coupled. ii) crankshafts coupled, mains pressure (120 psi) steam supplied to high pressure engine, partially expanded steam delivered to low pressure engine (Tandem operation). Choice available re exhaust steam: either to the condenser or to atmosphere. iii) crankshafts not coupled, reduced pressure steam supplied to low pressure engine. Exhaust steam - either to the condenser or to atmosphere. * Valve arrangement - a choice of Pickering cut-off or throttle governor. On low pressure engine - throttle governor only.davey paxman experimental steam engine, model steam engine, steam, thermodynamics laboratory, thomas bath, bequest

Kelvin Company History: The origins of the company lie in the highly successful, if strictly informal, the relationship between William Thomson (1824-1907), Professor of Natural Philosophy at Glasgow University from 1846-1899 and James White, a Glasgow optical maker. James White (1824-1884) founded the firm of James White, who was an optical instrument maker in Glasgow in 1850. He was involved in supplying and mending apparatus for Thomson's university laboratory and working with him on experimental constructions. White was actually declared bankrupt in August 1861 and released several months later. In 1870, White was largely responsible for equipping William Thomson's laboratory in the new University premises at Gilmore hill. From 1876, he was producing accurate compasses for metal ships to Thomson's design during this period and this became an important part of his business in the last years of his life. He was also involved in the production of sophisticated sounding machinery that Thomson had designed to address problems encountered laying cables at sea, helping to make possible the first transatlantic cable connection. At the same time, he continued to make a whole range of more conventional instruments such as telescopes, microscopes and surveying equipment. White's association with Thomson continued until he died. After his death, his business continued under the same name, being administered by Matthew Edwards (until 1891 when he left to set up his own company). Thomson, who became Sir William Thomson and then Baron Kelvin of Largs in 1892, continued to maintain his interest in the business after James White's death in 1884, raising most of the capital needed to construct and equip new workshops in Cambridge Street, Glasgow. At these premises, the company continued to make the compass Thomson had designed during the 1870s and to supply it in some quantity, especially to the Admiralty. At the same time, the firm became increasingly involved in the design, production and sale of electrical apparatus. In 1899, Lord Kelvin resigned from his University chair and became, in 1900, a director in the newly formed limited liability company Kelvin & James White Ltd which had acquired the business of James White. At the same time Kelvin's nephew, James Thomson Bottomley (1845-1926), joined the firm. In 1904, a London branch office was opened which by 1915 had become known as Kelvin, White & Hutton Ltd . Kelvin & James White Ltd underwent a further change of name in 1913, becoming Kelvin Bottomley & Baird Ltd . Hughes Company History: Henry Hughes & Sons was founded in 1838 in London as a maker of chronographic and scientific instruments. The firm was incorporated as Henry Hughes & Sons Ltd in 1903. In 1923, the company produced its first recording echo sounder and in 1935, a controlling interest in the company was acquired by S Smith & Son Ltd resulting in the development and production of marine and aircraft instruments. Following the London office's destruction in the Blitz of 1941, a collaboration was entered into with Kelvin, Bottomley & Baird Ltd resulting in the establishing Marine Instruments Ltd. Following the formal amalgamation of Kelvin, Bottomley & Baird Ltd and Henry Hughes & Sons Ltd in 1947 to form Kelvin & Hughes Ltd., Marine Instruments Ltd then acted as regional agents in the UK for Kelvin & Hughes Ltd who were essentially now a part of Smith's Industries Ltd founded in 1944 and the successors of S Smith & Son Ltd. Kelvin & Hughes Ltd went on to develop various marine radar and echo sounders supplying the Ministry of Transport, and later the Ministry of Defence. The firm was liquidated in 1966 but the name was continued as Kelvin Hughes, a division of the Smiths Group. In 2002, Kelvin Hughes continues to produce and develop marine instruments for commercial and military use. This model compass is a good example of the commercial type of instruments made by Kelvin & Hughes after the world war 2, it was made in numbers for use on various types of shipping after the second world war and is not particularly rare or significant for it's type. Also it was made no earlier than 1947 as the firms of Kelvin, Bottomley & Baird Ltd and Henry Hughes & Sons Ltd who took over from Smith & Sons were not amalgamated until 1947. Given that Smith and Sons is engraved on the compass with Kelvin & Hughes it can be assumed that this compass was made during the company's transitional period to Kelvin & Hughes.Compass, marine or ship's card compass, gimble mounted, with inscriptions. Type is Lord Kelvin 10 inch compass card. Made in Great Britain by Kelvin Hughes Division of S. Smith & Sons (England) Ltd. "LORD KELVIN 10.", "COMPASS GRID", "MANUFACTURED IN GREAT BRITAIN BY", "KELVIN HUGHES DIVISION", "S. Smith & Sons (England) Ltd".flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, marine compass, gimble compass, ship's compass, lord kelvin compass, smith and sons england ltd, henry hughes & son ltd london england, kelvin bottomley & baird ltd glasgow scotland, kelvin & hughes ltd, navigation instrument, scientific instrument, william thomson, james white, baron kelvin of largs

Henry Sutton taught Electricity and Magnetism at the Ballarat School of Mines. The first reference to this room was in the 1900 Ballarat School of Mines Annual Report: 'The dynamo has been connected by cables to a switchboard in the new lecture-room ... '. Black and white photograph of the interior of a classroom at the Ballarat School of Mines, including a number of desks, and gas light fittings. The room was the Electricity and Magnetism Classroomballarat school of mines, scientific equipment, electricity, electricity classroom, classroom, henry sutton, laboratory

Probably used in the Ballarat School of Mines Chemisry Laboratories, at that time led by Professor Alfred Mica Smith, with lecturer Daniel Walker. From W. Watson & Sons, Block Arcade, MelbourneAn early model of a flashpoint apparatus, of mainly brass construction, heated by a spirit lamp. Complete with two mercury-in-glass tfermometers (50 degree to 70 degrees celcius x 1 degree, 10 degrees to 50 degrees celcius c 1 degree), and lamp-stand. Serial Number 1786.scientific instruments, chemistry, alfred mica smith, daniel walker, ballarat school of mines, w. watson & sons ltd, thermometer

Large black and white photograph of student using vacuum equipment in a metallurgy laboratory.black and white photography, metallurgy laboratory, metallurgy

Two ceramic funnels with rubber stops used at the Ballarat School of Mines.chemistry, laboratory, scientific instruments, funnel

Mullard Limited was a British manufacturer of electronic components. The Mullard Radio Valve Co. Ltd. of Southfields, London, was founded in 1920 by Captain Stanley R. Mullard, who had previously designed valves for the Admiralty before becoming managing director of the Z Electric Lamp Co. The company soon moved to Hammersmith, London and then in 1923 to Balham, London. The head office in later years was Mullard House in Torrington Place, Bloomsbury, now part of University College London. In 1923, in order to meet the technical demands of the newly formed BBC, Mullard formed a partnership with the Dutch manufacturer Philips. The valves (US vacuum tube) produced in this period were named with the prefix PM, for Philips-Mullard, beginning with the PM3 and PM4 in 1926. Mullard finally sold all its shares to Philips in 1927. In 1928 the company introduced the first pentode valve to the British market. Mullard opened a new manufacturing plant at Mitcham, Surrey in 1929 and in late 1930s Mullard opened a new plant in Blackburn, Lancashire. By 1949 Mullard had produced a number of television sets, such as the MTS-521 and MTS-684 and in 1951 Mullard was producing the LSD series of photographic flash tubes. In the early 1980s, Mullard manufactured the SAA5050, some of the earliest teletext decoding modules made in the UK. In 1957 Philips-Mullard helped to set up the Mullard Radio Astronomy Observatory (MRAO) at the University of Cambridge. Philips continued to use the brand name "Mullard" in the UK until 1988. Mullard Research Laboratories in Redhill, Surrey then became Philips Research Laboratories. As of 2007, the Mullard brand has been revived by Sovtek, producing a variant of the ECC83 and EL34. The Z Electric Lamp Co. continued business into the 1970s operating from premises in Thornton Heath, south London, manufacturing lamps of specialised design but it closed due to the recession in the mid 1970s. Sovtek is a brand of vacuum tube owned by Mike Matthews's New Sensor Corporation and manufactured in Saratov, Russia. They are often used in guitar amplificationA box with a 'Mullard' valve for a radioTop of box : MULLARD / ELECTRONIC VALVE / Side of box; GAURANTEED ELECTRONIC / VALVE / MULLARD ( in a shield) : mullard radio valve co. ltd., london, mullard captain stanley, electronic equipment, moorabbin, bentleigh, cheltenham, early settlers

A Gramophone / Phonogram is a device for the mechanical recording and reproduction of sound. The phonograph was invented in 1877 by Thomas Edison. in USA and Alexander Graham Bell's Volta Laboratory made several improvements in the 1880s and introduced the graphophone, This Edison was donated to CMHs by the family of John Box 1841-1913This gramophone belonged to John Box 1841-1913 an early settler in the area of Henry Dendy's Special Survey Brighton 1841A wooden cabinet with a lift up lid enclosing a turntable , record , trumpet and handle . This cabinet stands on another storage cabinet with shelf and doorEDISONmanufactured objects, music, musical records, long playing records, gramophone, phonogram, wireless, edison thomas, edison pty ltd, electric lights;

Two red covered auction catalogues with black printing for a sale on the 6th, 7th & 8th March 1984 at the Australian National Animal Health Laboratory, Geelong, Vic. For sale were Transportable Site Buildings, Main Office, Main Store, Fitters, Carpenters & Test Workshops, Construction Materials, General and Electrical Equipment, Fork Lifts, Motor Vehicles, Tip Trucks, Bobcat, Scaffolding and Large Quantities Brass, Copper & Black Pipe Fittings. J. H. Curnow & Son Pty. Ltd. Were the auctioneers.business, auctioneers, j h curnow & son pty ltd, ian dyett collection - auction catalogue - australian national animal health laboratory, john holland, j h curnow & son pty ltd, f c dyett, i m dyett, n f dyett, bolton bros pty ltd print

Dark red covered auction catalogue with black printing for a sale on the 5th and 6th July 1983 at the Australian National Animal Health Laboratory, Geelong, Vic. For sale was Construction Materials, Equipment, Scaffolding, Transportable Site Buildings, G.F.C. False Work, and Large Quantity Piping Stainless Steel and Copper Fittings. J. H. Curnow & Son Pty. Ltd. Were the auctioneers.business, auctioneers, j h curnow & son pty ltd, ian dyett collection - auction catalogue - australian national animal health laboratory, john holland, j h curnow & son pty ltd, f c dyett, i m dyett, n f dyett, bolton bros pty ltd print

Khaki cylinder containing camouflage face paint of light green and sand colours.FSN 8510/161/6202; paint , face, camouflage, stick form.camouflage, sas

Khaki cylinder containing camouflage face paint of light green and sand colourFSN 8510/161/6202camouflage, sas

Copper intrauterine devices (IUDs), first marketed in the early 1970s, represent an important contraceptive option for 150 million women worldwide. The method is safe, rapidly reversible, inexpensive, highly effective, long-acting (up to 20 years for some products [1]), and non-hormonal; these attributes make it unique and desirable for many users. However, increased bleeding and pain cause up to 15% of users to have the device removed within the first year [2]; still higher percentages tolerate some level of these side effects yet retain use of the method. In one study, 67% of women using the TCu380A complained about menstrual side effects within the first year of use [3]. (Hubacher et al, 'Side effects from the copper IUD: do they decrease over time?', 2009)This is one of a collection of items received from the practice of Dr Lachlan Hardy-Wilson, FRCOG, Launceston, Tasmania.Sealed Gravigard IUD in original box. IUD and inserter are sealed inside a sterile plastic pocket. The box is made of cardboard and has an orange top panel with white sides. Text printed on the front of the box reads '1 Sterile Pack/Gravigard*/contraceptive/copper/contraceptive/FRAGILE/Do not bend or crush/SEARLE'. Text printed on side of box reads 'Made in England Supplied by Searle Laboratories, Division of Searle Australia Pty. Ltd., Sydney, Australia'.intrauterine device

Copper intrauterine devices (IUDs), first marketed in the early 1970s, represent an important contraceptive option for 150 million women worldwide. The method is safe, rapidly reversible, inexpensive, highly effective, long-acting (up to 20 years for some products [1]), and non-hormonal; these attributes make it unique and desirable for many users. However, increased bleeding and pain cause up to 15% of users to have the device removed within the first year [2]; still higher percentages tolerate some level of these side effects yet retain use of the method. In one study, 67% of women using the TCu380A complained about menstrual side effects within the first year of use [3]. (Hubacher et al, 'Side effects from the copper IUD: do they decrease over time?', 2009)This is one of a collection of items received from the practice of Dr Lachlan Hardy-Wilson, FRCOG, Launceston, Tasmania.Two sealed Gravigard IUDs. IUD and inserter are sealed inside a sterile plastic pocket. Manufacturer information is printed on a cardboard insert which holds each IUD inside the pocket.intrauterine device

Used to measure the depth/distance of the uterus. Uterine sounds are particularly useful for ensuring safe and accurate IUD placement.This is one of a collection of items received from the practice of Dr Lachlan Hardy-Wilson, FRCOG, Launceston, Tasmania.Disposable uterine sound in sterile sealed packaging. Label inside packaging reads 'Mark-7 brand of disposable uterine sound/ONE STERILE UNIT/NO. 154'. Label also includes manufacturer information, a sterile packaging warning, and a caution about sale of the item being restricted to physicians.intrauterine device

In 1937, the engineer Holger Hesse founded Testa Laboratory, which later became Ambu. Hesse developed products that made a difference to patients and doctors. The real breakthrough came in 1956 when the Ambu ventilation bag reached the market, developed together with anaesthetist Henning Ruben. It was the world’s first self-inflating resuscitator and a major milestone in emergency medical equipment. The Ambu bag became a permanent part of hospital and emergency services product ranges. Brown rubber bag with a round metal filter at one end and a connector tube at the other. There is a blue plastic connector between the rubber bag and the metal tube.Moulded into blue plastic connector: AMBU-INTERNATIONAL / Ruben-Resuscitator Stamped into filter: Ambu logo - large capital A with AUER inside the legs of the Aambu, ruben, self-inflating, resuscitator, emergency, henning, ruben

After the 1939 bushfires, the Forests Commission invested heavily in a radically new communications network. After suffering some inevitable delays due to the War, radio VL3AA switched into full operation in October 1945 proudly beaming out 200 watts across the State. The communication systems were regarded at the time to be more technically advanced than the police and the military. These pioneering efforts were directed by Geoff Weste, and later technical experts like Rex Philpot, John Whitehead, Charlie Reisinger and many others who designed, built and repaired most of the radio equipment. There was a dedicated radio laboratory at Surrey Hills in Melbourne.Radio setManufactured by McLeod Electric - Derrinallumradios

After the 1939 bushfires, the Forests Commission invested heavily in a radically new communications network. After suffering some inevitable delays due to the War, radio VL3AA switched into full operation in October 1945 proudly beaming out 200 watts across the State. The communication systems were regarded at the time to be more technically advanced than the police and the military. These pioneering efforts were directed by Geoff Weste, and later technical experts like Rex Philpot, John Whitehead, Charlie Reisinger and many others who designed, built and repaired most of the radio equipment. There was a dedicated radio laboratory at Surrey Hills in Melbourne.Radio setSTC Star Radio Telephone Type FR5.1.25-STradios

After the 1939 bushfires, the Forests Commission invested heavily in a radically new communications network. After suffering some inevitable delays due to the War, radio VL3AA switched into full operation in October 1945 proudly beaming out 200 watts across the State. The communication systems were regarded at the time to be more technically advanced than the police and the military. These pioneering efforts were directed by Geoff Weste, and later technical experts like Rex Philpot, John Whitehead, Charlie Reisinger and many others who designed, built and repaired most of the radio equipment. There was a dedicated radio laboratory at Surrey Hills in Melbourne. Little is known about this particular radio handsetField radio telephone with handset.radios

After the 1939 bushfires, the Forests Commission invested heavily in a radically new communications network. After suffering some inevitable delays due to the War, radio VL3AA switched into full operation in October 1945 proudly beaming out 200 watts across the State. The communication systems were regarded at the time to be more technically advanced than the police and the military. These pioneering efforts were directed by Geoff Weste, and later technical experts like Rex Philpot, John Whitehead, Charlie Reisinger and many others who designed, built and repaired most of the radio equipment. There was a dedicated radio laboratory at Surrey Hills in Melbourne. The purpose and operation of this particular instrument is unknown.FCV testing meterMade in the radio laboratory of the Forests Commission Victoriaradio

Two glass display cabinets used at the School in both the Laboratory and the MuseumGlass display cases

Heating unit.Labec Selbys Scientific Instruments Chemicals Laboratory Apparatus Melbourne-Sydney-Brisbane-Perth-Adelaide Made by Lsboratory Equipment Pty. Ltd. Sydney Volts 240 Serial 4798 Watts 1200

Example of C 1950's medical equipment.See aboveGlass medicinal bottle containing Acriflavine antiseptic.I.F.A.S, Industrial First Aid, poison, Acriflavine IFAS Laboratories, Sydney & Melbourneantiseptic c1950's

Two red covered auction catalogues with black printing for a sale on the 5th and 6th July 1983 for the Australian National Animal Health Laboratory, Geelong, Vic. For sale were construction materials, equipment, extensive scaffolding, transportable site buildings, G.F.C. False Work, large quantity piping stainless steel and copper fittings. Account: John Holland (Constructions) Pty. Ltd. J. H. Curnow & Son Pty. Ltd. Were the auctioneers.business, auctioneers, j h curnow & son pty ltd, ian dyett collection - auction catalogue - australian national animal health laboratory - geelong, john holland (constructions) pty ltd, j h curnow & son pty ltd, f c dyett, i m dyett, n f dyett, bolton bros pty ltd print

Auction catalogue with bright yellow front page with brown tape binding. Sale is due to the completion of works on the Australian National Animal Health Laboratory (A.N.A.H.L.), John Holland (Constructions) Pty. Ltd. They sold surplus Construction Equipment and Site Buildings. Auctioneers were J. H. Curnow & Son Pty. Ltd.business, auctioneers, j h curnow & son pty ltd, ian dyett collection - auction catalogue, john holland (const) pty ltd, australian national animal health laboratory, j h curnow & son pty ltd

This slide is part of a collection of visual resources used by Stuart Ascough while conducting training, seminars, conferences and lectures in China, Australia, India, Russia and Taiwan. This item is part of a collection of books, manuals, photographs, letters and clothing relating to the working life of Stuart Ascough. Stuart's career in the wool industry spanned over 43 years from 1960 to 2003 in various roles including Topmaking Plant Manager at Courtaulds Ltd. in Spennymore, U.K., Operations Manager at Port Phillip Mills in Williamstown Victoria, Marketing Executive, Early Stage Wool Processing at the International Wool Secretariat Melbourne, Australia and General Manager of Victoria Wool Processors Pty. Ltd. in Laverton North, Victoria. Throughout his career Stuart travelled extensively, and in the 1990s worked at many topmaking mills in China on quality improvement projects. He also provided technical advice and training at mills in India, Ukraine, Lithuania, Kyrgyzstan, Russia, Latvia, Byelorussia and other parts of Europe and Asia.35mm colour transparency mounted in plastic slide mount showing interior view of scientific equipment in a laboratory.wool, industry, australia, australian wool board international wool secretariat, topmaking, carding, factory, training, gill box