This Albion printing press was manufactured by Harrild & Sons of London and exported in 1868 from London to the colonial Western Victoria town of Coleraine, population of 700 at that time. It was installed in the Colerain Albion printing office. It was used to print the first edition of the Coleraine Albion newspaper in 1868 and continued until publication ceased in 1974. The Albion Press is still being used today by a volunteer printer in the “Examiners Office” in the village at Flagstaff Hill. Amongst the items produced are printed paper bags for the Tea Rooms and posters for visitors. ALBION PRINTING PRESS The Albion press was invented and manufactured in London by Richard Whittaker Cope around 1820 and was still being produced in the 1930s. The Albion was manufactured under licence by several companies from the 1850s onwards, one of which was Harrild & Sons of Fleet Works, London. Harrild & Sons describes its business as “printing materials manufacturer”. The business was established in 1807 by Robert Harrild and named R. Harrild & Co. In 1813 he showed that rollers could be used to ink a printing plate instead of inking balls, the method in use at the time. He then established a company to make the rollers. Eventually his company would make other printing materials and equipment. Robert’s sons joined him in the 1830s, when the company was renamed Harrild & Sons, and they continued to run the company after his death in 1853 and up until the mid-1900s. COLERAINE ALBION PRINTING OFFICE The Coleraine Albion Printing Office was established by W.L. Ambler. The first issue of the Coleraine Albion was dated 4th January 1868. Arrangements had been made to receive news from Melbourne, nearby provinces, other colonies and England. The second issue on 18 January 1868 printed articles from many agencies, including the Melbourne Age and the Warrnambool Examiner. The Albion office was sold to William Hatherleigh, formerly of Portland, in October 1868. Thereafter the Albion office had many owners. The last was L. A. & E. Oliver, who took over in January 1972 and was the last to be stated as printers and publishers of the Coleraine Albion. The office was wound up in 1974. The Albion Press and other equipment was distributed to Star printing in Terang. Star Printing donated the Albion press to Flagstaff Hill Maritime Village around 1980 and Stan Philp, owner of Philprint in Warrnambool, transported it to Warrnambool, brought it up to good working order and organised the supply of appropriate printer’s type. The Albion hand operated printing press is significant for producing the first newspaper in Coleraine, Western Victoria and continuing production for over 100 years. The Albion is technologically significant as a working example of a hand operated printer from the mid-19th century. The use of the printer is demonstrated by volunteers at Flagstaff Hill, printing items such as lolly and treat bays for use in the Village. The Albion is socially significant for its role in the isolated provincial colony, providing communication with the outside world, both in Australia and overseas. Newspaper printers were often amongst the first businesses of a small town. Printing press; hand operated Albion Press, Patent 2105. The machine has an upright iron frame at the back that supports the upper press that has a wooden handled metal bar is attached. The frame and legs support a thick metal flatbed. A metal leg supports the front of the press bed. The iron work is painted black with gold highlights. The decorative legs are finished with the golden feet of an animal. The frame above the metal bed includes a crown shaped finial symbol above the maker’s emblem. The maker’s details and the name of the printer are embossed on the upright frame. A plaque with the patent number is below a Lion and Unicorn emblem.Embossed maker’s emblem [A red cross - above a double ring – square inside ring – three banners below ring]. - Inside the double rings “PRINTING MATERIALS MANUFACTURE” - Inside the square, intertwined text “H & S” [representing Harrild & Sons] - Inside the three banners ““FLEET” “WORKS.” “LONDON.E.C.” Embossed across the shoulders “ALBION PRESS / HARRILD & SONS, / MAKERS LONDON.” Emblem above plaque [Lion and Unicorn] Embossed on the plaque “PATENT / 2105” Stamped into upright machine part above the printing bed “2105 / 1866” flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, albion press, printing press, 1866 printing press, printing equipment, communications, coleraine albion printing office, coleraine newspaper, albion newspaper, south west victoria newspapers, harrild and sons london, richard whittaker cope, star printing terang, philprint, coleraine albion, hand operated press

The biscuit locker came from the vessel the "City of Rayville", an American motor-driven freighter constructed in 1920. The ship was the second victim within 24 hours of an extensive minefield laid by German raiders in October 1940, during World War Two and the first American ship to be sunk in world war II. She was under the command of Captain Cronin and bound from Adelaide via Melbourne to New York, carrying a cargo of 1500 tons of lead from Port Pirie along with a cargo of wool and copper from Adelaide, when she struck a mine in the Bass Strait, six miles south of Cape Otway at 7:45 pm on 8th November 1940. The explosion was heard on shore at Apollo Bay; the force of it tore out the foremast and the ship sank within 25 minutes. There was a crew of 38 and all but one survived. A rescue crew of fishermen from Apollo Bay left shore in the dark and picked up the survivors from the dangerous sea taking them back to safety. The US Secretary of State Cordell Hull at the time wrote individual letters of thanks to all the rescuers involved. The biscuit locker is of historical and marine archaeological significance because of its association with the wreck of the City of Rayville. The vessel is listed on the Victorian Heritage Register No VHR S126. Additional significance is that the ship was the first American vessel sunk in the second world war and is still socially significant to the descendants of the City of Rayville crew and the Apollo bay fishermen who took part in the rescue.The external surfaces of the cupboard and the inside of the door are painted brown. The interior is painted blue the door has 2 metal hinges attached on the outside, each with 6 single-slotted screws and a wooden rotating door latch attached to the side of the door. There is a round eyelet on the door near the latch, the cupboard sides are each made from wood joined vertically and sit within a slightly wider, flat base and top. The frame of the cupboard is split with the paint on the outside of the cupboard scratched and chipped revealing a darker paint underneath. There is also a rough slash of white paint from the side of the cupboard going to about the Centre of the door. “PI/298” is hand written in black pen, paint or ink on the inside panel of the door in neat letters. "MS CITY OF RAYVILLE" stamped on back of cupboard in black paintcity of rayville, cupboard, locker, biscuit locker, 1940, world war ii, wwii, cape otway, german mines, american ship, flagstaff hill, warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, rayvill

The paper rack is an example of early 20th-century domestic furniture.Radk; paper or newspaper rack, rectangular wedge-shaped wooden frame, painted brown, with metal loops and wire for hanging against a wall. The front is a "picket fence design".flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, rack, paper rack, handmade, magazine rack, newspaper rack, domestic furnishing, storage, reading material storage

William Hutton & Sons were manufacturing silversmiths founded in 1800 in Birmingham with company transferring to Sheffield in 1832. William Hutton had established the firm and with the move to Sheffield, they also became platers having licensed the electroplating technique from the firm of Elkington's. This gave them much early success in the field of electroplating. William's son William Carr Hutton continued the business after his father's death using the same business name until 1864 it was then changed to William Hutton & Son when William Carr's son Herbert Hutton joined him. When William Carr died in 1865, the firm name was again changed to William Hutton & Sons when Herbert's brothers (James & Robert) joined the company. They opened a London showroom in Holborn in 1863 which they moved to Farringdon Road, in 1891 operating until 1918. Hutton's had developed a new nickel alloy that was good for plating and in the late 1800s becoming known as British Plate. They sent their machine-made silver flatware from Sheffield to be hallmarked in London. Hutton's went on to acquire Rupert Favell & Co in 1893 and also registered as a limited company as William Hutton & Sons Ltd in 1902. The Hutton's had also bought Creswick & Co and had started to use their crossed arrows trademark. Hutton's became renowned for the quality of their Arts & Crafts silverware items at the turn of the 19th and 20th centuries. In 1930 Hutton's were taken over by James Dixon & Sons. A significant item that was made around the time electroplating was being developed as a means of producing quality utilitarian items in quantity for domestic use that we're able to be purchased by working-class people.Cruet set of silver plated frame with upright handle protruding from tray base. Holds 5 containers of varying shape and size; 3 have metal lids. Inscription is on the base. Some containers have contents in them.On base "WMH&S" and "01548" etc.flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, cruet set, condiments set, kitchen ware, electroplate, britannia metal, w m hutton

Washboard, wooden framed with ribbed clear glass panel and metal nails.flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, washboard, glass washboard, laundry, clothes washing

This music stand set of shelves is one of many 19th century items of furniture, linen and crockery donated to Flagstaff Hill Maritime Village by, Vera and Aurelin Giles. The items are associated with the Giles Family and are known as the “Giles Collection”. Many of the items of furniture, linen and crockery in the Lighthouse Keeper’s Cottage were donated by Vera and Aurelin Giles and mostly came from the simple home of Vera’s parents-in-law, Henry Giles and his wife Mary Jane (nee Freckleton) whose photos are in the parlour. They married in 1880. Henry, born at Tower Hill in 1858, was a labourer on the construction of the Breakwater before leaving in 1895 to build bridges in N.S.W. for about seven years. Mary Jane was born in 1860 at Cooramook. She attended Mailor’s Flat State School where she was also a student teacher before, as family legend has it, she became a governess at “Injemiara” where her grandfather, Francis Freckleton, once owned land. Henry and Mary’s family of six, some of whom were born at Mailor’s Flat and later children at Wangoom, lived with their parents at Wangoom and Purnim west, where Henry died in 1933 and Mary Jane in 1940. THE SHELVES During the years 1869-1935 there were well over 250 registered bamboo furniture producers in Britain. The earliest recorded firm was Hubert Bill of 14 Little Camden St, London N.W., who claimed to have been established in (1869 the first bamboo furniture maker), while Daniel Jacobs & Sons of Hackney Road, London, were still in business in 1915, after 45 years of production. Design, quality, price and methods of construction were fairly consistent throughout the whole period, but it was the imaginative and often eccentric choice of subject matter that marked the differentiation between the various firms. While most produced standard tables, stands and fire-screens, the more adventurous offered for sale items such as Corner shelve units, charcoal barbecue grills and musical tea tables. Shelves were often covered with embossed leather paper designs, at first imported from Japan and then later produced in England. Some firms incorporated the knobbly roots of the bamboo stems into their designs, generally to form feet. Occasionally handles to drawers and cupboards were made with these roots although they were more commonly carved as imitations. Handles were mostly of cheap metal or brass. The ends of the bamboo canes were capped with stamped metal or turned bone, ivory or wooden discs. Methods of construction fell into three categories. First and most common is that of pegging. Bamboo stems being hollow, thick dowels can easily be glued into the joints. Some firms farmed out this work of `plugging' the ends of the canes to part-time workers at home. The second method, that of pinning, was far less satisfactory as bamboo tends to split lengthwise and therefore the jointed pieces eventually disintegrated. The most efficient method was that patented in 1888 (patent No 2383) by the firm of W. F. Needham in Birmingham. It consisted of metal shoes and covers for all joints which were made by wrapping a metal strip around the stems and soldering the overlapping ends. Some joints were further strengthened by a small pin or screw. Needham was by far the largest and most successful manufacturer and their individual and superior method of construction undoubtedly gained them their reputation. A. Englander & Searle of 34 Gt Eastern St and 31 Mare St, Hackney, London, were a firm particularly concerned with methods of construction. Although they seem to have entered the bamboo furniture market at a comparatively late date, about 1898, they produced inexpensive bamboo, aimed particularly at the export trade. The company stated in their catalogue that bamboo furniture “can be exported in one piece or it can be exported in pieces and put together again. The fixing up is much facilitated by a system of marking and numbering. Further, no glue is required for putting together as the screw system only is applied”. This method of construction best fits the Etagere in the Flagstaff collection and it is believed to have been made by A Englander & Searle, exported in a knock down form to Australia, purchased in kit form from a dealer hear and put together by the owner. The Etagere is a significant item as it highlight furniture fashion of the late Victorian era. This item was highly sort after in its time and although mass produced, not many examples remain, so this example is a valuable addition to the Flagstaff collection. It is believed that the construction method used is by a notable and respected maker of bamboo furniture and that its production was aimed at the export market and probably came to Australia in kit form.Bamboo shelves: decorative free standing Etagere comprising three large shelves and one small shelf. Shelves are made of wood used to store either orange or bacon boxes (as there are no knots in the wood, imported from South America and cheap to recycle). Shelves are covered with embossed leather paper. Frame is made from tortoise shell bamboo (brown lacquer applied to simulate tortoise shell appearance). Ends of bamboo canes are covered with metal shoes and fixed with a pin. Other bamboo joints are fixed with round head steel screws. This item is part of the Giles Collection.Noneflagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, bamboo shelves, bamboo etagere, victorian furniture, furniture, bamboo furniture, embossed leather paper, simulated bamboo, tortise shell, a englander & searle, giles collection, henry giles, tower hill, cooramook, warrnambool breakwater, mailor’s flat, wangoom, 19th century furniture

Ship model Eumeralla steamship with one funnel, two masts portholes in hull, set against a coastal scene with lighthouse. Ship is painted green. Model is in a wooden framed glass case. Split on background scene. Case strengthened by metal brackets at top corners and bottom front corners. flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village

A saw is a tool consisting of a tough blade, wire, or chain with a hard-toothed edge. It is used to cut through material, very often wood, though sometimes metal or stone. The cut is made by placing the toothed edge against the material and moving it forcefully forth and less vigorously back or continuously forward. This force may be applied by hand, or powered by steam, water, electricity or other power sources. An abrasive saw has a powered circular blade designed to cut through metal or ceramic. In ancient Egypt, open (unframed) saws made of copper are documented as early as the Early Dynastic Period, circa 3,100–2,686 BC. Many copper saws were found in tombs dating to the 31st century BC. Models of saws have been found in many contexts throughout Egyptian history. As the saw developed, teeth were raked to cut only on the pull stroke and set with the teeth projecting only on one side, rather than in the modern fashion with an alternating set. Saws were also made of bronze and later iron. In the Iron Age, frame saws were developed holding the thin blades in tension. The earliest known sawmill is the Roman Hierapolis sawmill from the third century AD used for cutting stone.The subject item is believed to date from around the mid to late 20th century and is regarded as a modern item. The maker is unknown but the pattern or design and type of wood used indicate it is a tool of modern manufacture.Compass saw with wooden handle and metal blade. Small teeth. flagstaff hill, warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, wood cutting, wood saw, cross cut saw, cabinet makers tools, wood working tools, tool, compass saw

A saw is a tool consisting of a tough blade, wire, or chain with a hard-toothed edge. It is used to cut through material, very often wood, though sometimes metal or stone. The cut is made by placing the toothed edge against the material and moving it forcefully forth and less vigorously back or continuously forward. This force may be applied by hand, or powered by steam, water, electricity or other power sources. An abrasive saw has a powered circular blade designed to cut through metal or ceramic. In ancient Egypt, open (unframed) saws made of copper are documented as early as the Early Dynastic Period, circa 3,100–2,686 BC. Many copper saws were found in tombs dating to the 31st century BC. Models of saws have been found in many contexts throughout Egyptian history. As the saw developed, teeth were raked to cut only on the pull stroke and set with the teeth projecting only on one side, rather than in the modern fashion with an alternating set. Saws were also made of bronze and later iron. In the Iron Age, frame saws were developed holding the thin blades in tension. The earliest known sawmill is the Roman Hierapolis sawmill from the third century AD used for cutting stone.The subject item is believed to date from around the mid to late 20th century and is regarded as a modern item. The maker is unknown but the pattern or design and type of wood used indicate it is a tool of modern manufacture. Compass saw with wooden handle broken and metal blade. Small teeth.Noneflagstaff hill, warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, wood cutting, wood saw, cross cut saw, cabinet makers tools, wood working tools, tool, compass saw

This wall section was part of the original Warrnambool Lighthouse Keeper's Assistant's Quarters built in the late 1800s. The frame was found in 2023, when the non-heritage cabinets built in the 1970s were removed as part of conservation works.The wall section is significant for being part of the original Warrnambool lighthouse keeper's quarters on the western wall. It is an example of the building materials and methods used in the late 19th and early 20 centuries.Wall frame section; a sample of the original inner western wall frame from the Warrnambool Lighthouse Keeper's Residence, Assistant's Quarters. Vertical timber slates of uneven size are fixed with short flat head metal nails to more substantial upper and lower horizontal rails. There are remnants of a sand and clay-like mortar between and in front of the slats. There are two spacers n the rear of one of the rails, made of timber and fixed with thick square handmade nails; the timber of one is rotting.flagstaff hill maritime museum and village, warrnambool, great ocean road, shipwreck coast, warrnambool lighthouse keeper's quarters, 1800s wall lining

The porthole was recovered from the wreck of the clipper ship Schomberg. ABOUT THE SCHOMBERG (October 6 to December 27, 1855)- When the ship Schomberg was launched in 1855, she was considered the most perfect clipper ship ever to be built. James Baines Black Ball Line had commissioned her for their fleet of passenger liners. The Aberdeen builders designed her to sail faster than the clippers designed the three-masted wooden clipper ship to be fast. The timber used for the diagonal planking was British oak with layers of Scottish larch. This luxury emigrant vessel was designed for superior comfort. She had ventilation ducts to provide air to the lower decks and a dining saloon, smoking room, library and bathrooms for the first-class passengers. The master for Schomberg’s maiden voyage was Captain ‘Bully’ Forbes. He drunkenly predicted at her launch that he would make the journey between Liverpool and Melbourne in 60 days. Schomberg departed Liverpool on 6 October 1855 with 430 passengers and 3000 tons of cargo including iron rails and equipment intended the build the Geelong Railway and a bridge over the Yarra from Melbourne to Hawthorn. The poor winds slowed Schomberg’s sail across the equator. She was 78 days out of Liverpool when she ran aground on a sand spit near Peterborough, Victoria, on 27 December; the sand spit and currents were not marked on Forbes’s map. The ship’s Chief Officer spotted the coastal steamer SS Queen at dawn and sent a signal. The master of the SS Queen approached the stranded vessel and all of Schomberg’s passengers safely disembarked. In 1975, 120 years after the Schomberg was wrecked, divers from Flagstaff Hill found an ornate communion set at the wreck site along with many other artefacts. In 1978 a diamond ring was discovered under the concretion in the lid of the communion set, which is currently on display. Former Director of Flagstaff Hill, Peter Ronald, had salvaged most of the artefacts from the wreck. This porthole is significant as an example of an ship's fitting in common use in the mid-19th century. The Schomberg collection as a whole is of historical and archaeological significance at a State level. Flagstaff Hill’s collection of artefacts from the Schomberg is also significant for its association with the Victorian Heritage Registered shipwreck (VHR S 612). The collection is of prime significance because of the relationship between the objects salvaged, as together they help us to interpret the story of the Schomberg. The collection as a whole is historically significant for representing aspects of Victoria's maritime history and its potential to interpret social and historical themes.Porthole frame. Square thick metal plate with formed holes for fixing. Central round opening in the plate is fitted with a hinged round frame with a handle opposite the hinge. Bolts are embedded in the inner frame. The surface is encrusted and the plate is broken near one corner. The frame was recovered from the wreck of the Schomberg.flagstaff hill, flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, schomberg, 1855, clipper ship, black ball line, luxury ship, emigrant ship, captain forbes, bully forbes, ss queen, james baines & co, porthole frame

Stevenson screens were first introduced in Australia in the 1880s and were widely installed by 1910. The screens have been used to shelter and protect thermometers and other meteorological instruments from rain and direct heat while the holes and double-louvre walls allowed air to flow around them. Sometimes other meteorological instruments were included in the weather stations, so there were different Stevenson Screen sizes. This authentic, original Stevenson screen was previously owned by the Australian Bureau of Meteorology and was used for many years for weather readings at the Cape Otway Light Station in southwest Victoria. The Lighthouse Keepers recorded the readings for minimum and maximum temperatures at 9 a.m. every day from January 1865 until April 1994. The equipment was sheltered in a Stevenson Screen from 1902 until April 15 1994, when the mercury thermometer was replaced by a platinum resistance probe within an Automatic Weather Station (AWS). This Stevenson screen is one of the two screens that then became redundant. The other Stevenson screen was kept to display to visitors. Lightkeepers were no longer required at the Cape Otway Light station either, due to the automated system. The meteorological instruments donated with the screen were used for measuring temperature and humidity. They are mounted on a metal bracket that fits across the screw holes on the screen’s internal frame. The glass-covered Relative Humidity (RH) sensor was made by the renowned precision instrument maker, Rotronic AG of Switzerland, which was founded in 1965. The firm made its first electronic temperature and humidity instrument in 1967. Meteorological records have been collected in Australia from the 1800s. The records were collated, published and used as a basis for weather forecasts. Many sectors, such as maritime and agriculture industries, have relied on these figures for making important decisions. The quality and placement of the meteorological instruments used to measure temperature and humidity are of utmost importance for accuracy. In early colonial times, there were no national standards for meteorological instruments that would allow for accurate figures and comparisons. Once the Bureau of Meteorology was established (around 1908 to 1910) the department installed Stevenson screens throughout Australia, many at lighthouses and light stations, and the measuring instruments were standardised. The Stevenson Screen was named after its inventor, Scottish Civil Engineer Thomas Stevenson (1818-1887) who was also the father of Robert Louis Stevenson, author. Stevenson developed the small thermometer screen around 1867. It had double-louvred walls around the sides and a top of two asbestos sheets with an air space between them and was thickly painted with a white coating that reflected the sun’s rays. This design was modified in 1884 by Edward Mawley of the Royal Meteorological Society. Standards were set for the locations of the screens and instruments, including their distance above ground level and the direction the door faced.Stevenson screens played a significant part in providing a standardised shelter for all meteorological instruments used by the Australian Bureau of Meteorology from about 1910 until 1994. The readings from the instruments gave the meteorological statistics on which weather forecasts throughout Australia were based. This Stevenson screen was used locally at Cape Otway, along the Great Ocean Road in southwest Victoria, so contributed towards our local forecasts and weather warnings.Stevenson screen, original, from the Australian Bureau of Meteorology’s weather station at the Cape Otway Lighthouse. The screen is a white wooden cupboard with a slanted cover raised above the top. The top has ten drilled ventilation holes, and the sides and door are made of downward-slanting double louvres. Two brass hinges join the door to the lower edge of the screen and a metal fitting at the top edge allows for a padlock closure. The screen is supported on four short legs, each with a hole drilled from side to side for fitting to a frame. Inside the screen are two wooden frames fitted with hooks and screws. The floor has three boards; one across the back and one across the front at the same level, and a board wider than the space between these boards is fitted higher, overlapping them slightly. Inside the screen, a pair of electronic instruments with short electric cables is mounted on a metal bracket with drilled holes in it. One of the instruments is a Relative Humidity (RH) probe. It is 26 cm long and is a glass tube with a filter on one end and an electrical connection on the other. It has inscriptions on its label, showing that was made by Rotronic AG, Switzerland. The other instrument is a Resistance Temperature Device (RTD) thermometer. It is 22.5 cm long and has a narrow metal probe joined to a hexagonal metal fitting. A brass plate on the front of the screen has impressed inscriptions. The screen is Serial Number 01/C0032, Catalogue Number 235862.Stamped into brass plate "CAT. NO. / 253862 / SERIAL NO. 01/C0032" On instrument’s electrical fitting; “CD2” [within oval ‘+’ above S] “Serie693 op65 / 220/380V~16A” On instrument’s glass; “rotronic ag” “SWISS MADE” “CE / CH-8303 / Bassersdorf” Symbol for [BARCODE] “ART NO MP 101A_T4-W4W” “POWER 4.8.30VDC“ “OP. RANGE: 0-100%RH/-40+60° C” “OUT H 0-100% 0-1V” “OUT T -40+60°C -0.4..+0.6V” “SERIE NO 19522 009”flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, cotton region shelter, instrument shelter, thermometer shelter, thermoscreen, thermometer screen, measuring instruments, meteorological instrument, weather recording, weather station, lighthouse equipment, light station equipment, stevenson screen, marine instruments, mercury thermometer, platinum resistance probe, aws, automatic weather station, rotronic ag, swiss made, meteorological device, weather forecast, weather prediction, weather records, meteorological forecast, meteorological record, australian bureau of meteorology, bureau of meteorology, bureau, bom, relative humidity, rh, relative humidity probe, resistance temperature device, rtd, thermometer, temperature, humidity, cape otway, cape otway lighthouse, cape otway light station, rotronic, switzerland, swiss instrument, thomas stevenson, double-louvered walls, edward mawley, royal meteorological society, 01/c0032, serial number, cat. no. 235862, serial no. 01/c00323

Restored by Tony Newstead. Played by Dr Phil Law during the 1930s, "for dances and other functions, while teaching at Clunes, Talbot, Creswick, Learmonth, Newtown, Smeaton, and while teaching at Elwood (at Eltham, Gisborne and Sunbury." including on many of his expeditions to the Antarctic. Phil Law was a dedicated jazz reed player and band leader in his early years as a country school teacher. His brothers also played. Gift of Dr Phil Law - 1999. Dr Law died in Melbourne on 28 February 2010 at the age of 97.Owned and played by Dr Phillip Garth (Phil) Law AC, CBE, for dances and other functions, while teaching during the 1930s, and on many of his 28 expeditions to the Antarctic. Metal Silver B flat soprano saxophone made by V. Kohlert and Sons, Graslitz, Czechoslovakia. Circa 1920s. Mother of pearl keys, slight denting. Additional mouth piece. On bell of saxophone "Kohlert Sons / Graslitz / Czechoslovakia" framed by flower and leaf motifdr phil law, dr phillip law, soprano saxophone, kohlert and sons, kohlert sons, antarctic explorer, b flat soprano saxophone, silver instrument, reed instrument

Cambridge Instrument Co Ltd, England operated from 1924 to 1967. They were makers of measuring instruments (electrical) and scientific instruments.Timber framed electrical instrument with interior metal conductor. Brass knobs that screw are at one end labelled 1.5 volts and 15 amps. Plates each end labelledscientific instrument, cambridge instruments, electricity, scientific objects, scientific instruments

Used by Ballarat School of Mines Geology Department. Probably a second generation purchase by SMB Geology department. Earlier references to "Petrological microscope", SMB Calendar for 1908-9, p 35Boxed optical microscope - Petrographic type. It has a rigid (upright) frame and twin objective lens turret and a black enameled frame with brass-finish components. Stored in blonde finished wooden box. Manufacturers certificate inside box door dated "1. ii. 1912" Three other objectives in metal casesEye piece - "Reichert Wien" Microscope - E.Leitz Wetzlar No140283 Made for Kilpatrick & Co Melbourne Objective x 2 R & J BECK. LTD, Objective H. Crouch. London ballarat school of mines, geology, petrography, microscope, leitz, scientific instruments, brass, lens, r & j beck, reichert

A hacksaw is a fine-tooth saw with a blade held under tension by a frame. It is used for cutting materials such as metal or plastics. Hand-held hacksaws consist of a metal arch with a handle, usually a pistol grip, and pins for attaching a narrow disposable blade. A screw or other mechanism is used to put the thin blade under tension. The blade can be mounted with the teeth facing toward or away from the handle, resulting in cutting action on either the push or pull stroke. On the push stroke, the arch flexes slightly, decreasing the tension on the blade.Steel frame for blade. adjustment lever in handle.Dimpled feature on curved sectionhacksaw, tool, ballarat school of mines, trade, cutting, metal, plastics

This brass bell bracket has been carefully shaped to fit around the shape of a bell. Its fitting allows it to swing freely. The bracket allows the bell to be fixed to a horizontal surface such as a s wooden frame, post or base. It may have been portable or fixed to a counter, desk or table. The bell may have been used to sound the time, to draw attention to an event such as a church surface, to signal a time to start or stop, or even as a percussion instrument.This metal bell bracket appears to be handmade and may have been used as a portable signal for a school or public meeting. It could have been used on a ship to signal the watch or the time.Bell bracket; the brass, bracket is bell-shaped with a removable hinged section across the top where the bell swung. The base is composed of a curved and shaped base stand. flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, bell bracket, bell stand, bell frame, swinging bell, portable bell, bell ringing, signal

A design for a Trade and Art Workshop at the Ballarat School of Mines was prepared by Ewan Jones and Associates on the Albert Street boundary around 1984. The M.B. John Building (Building K), a three storey, face red brick, restrained Late Twentieth Century International styled building with an elongated, cuboid form (defined by the parapeted facades) that is offset by projecting exposed concrete framed, round‐arched entrance and stair wells on the east (Albert Street) elevation (the centrally located entrance breaking the brick façade with glazing). The facades are also characterised by banks of aluminium framed, horizontal ribbon windows, which wrap around the building corners. Metal shades project beyond the windows, while post‐supported bullnosed verandahs and hoods and projecting concrete stairs are other features. On the west elevation, the cuboid façade is punctuated by projecting curved concrete and glazed, elongated bays at first floor level. (David Rowe/Wendy Jacobs) The M.B. John Trade–Art building of SMB was officially opened by the Hon. John Cain, Premier of Victoria, in the presence of Morgan B. John. Programs include 3 Dimensional Art, Painting & Decorating, and Engineering Trades. (SMB Institutional Plan 1989)Black and white photograph of a sketch for the proposed Trade Workshops at the Ballarat School of Mines, from the Albert Street vantage point. This building is known as the M.B. John Building on the SMB Campus.ballarat school of mines, trade workshops, flecknoe, m.b. john, ewan jones and associates pty ltd, albert street, morgan b. john, ewan jones and associates

The M.B. John Trade–Art building (Albert Street front) of SMB was officially opened by the Hon. John Cain, Premier of Victoria, in the presence of Morgan B. John. Programs include 3 Dimensional Art, Painting & Decorating, and Engineering Trades. (SMB Institutional Plan 1989) The M.B. John Building (Building K), a three storey, face red brick, restrained Late Twentieth Century International styled building with an elongated, cuboid form (defined by the parapeted facades) that is offset by projecting exposed concrete framed, round‐arched entrance and stair wells on the east (Albert Street) elevation (the centrally located entrance breaking the brick façade with glazing). The facades are also characterised by banks of aluminium framed, horizontal ribbon windows, which wrap around the building corners. Metal shades project beyond the windows, while post‐supported bullnosed verandahs and hoods and projecting concrete stairs are other features. On the west elevation, the cuboid façade is punctuated by projecting curved concrete and glazed, elongated bays at first floor level. (David Rowe/Wendy Jacobs)Image of a multi-storey brick building on the Ballarat School of Mines campus. The building is known as the M.B. John Building.ballarat school of mines, m.b. john building, morgan b. john, albert street, m.b. john

The M.B. John Building (Building K), a three storey, face red brick, restrained Late Twentieth Century International styled building with an elongated, cuboid form (defined by the parapeted facades) that is offset by projecting exposed concrete framed, round‐arched entrance and stair wells on the east (Albert Street) elevation (the centrally located entrance breaking the brick façade with glazing). The facades are also characterised by banks of aluminium framed, horizontal ribbon windows, which wrap around the building corners. Metal shades project beyond the windows, while post‐supported bullnosed verandahs and hoods and projecting concrete stairs are other features. On the west elevation, the cuboid façade is punctuated by projecting curved concrete and glazed, elongated bays at first floor level. (David Rowe/Wendy Jacobs)Colour photograph of a red brick building on Albert Street. It was build to house trade workshops and Ceramics at the Ballarat School of Mines. m.b. john, m.b. john building, ballarat school of mines

A mass produced utilitarian item made for domestic decorative use. No history or manufacturing provenance currently available.The subject item at this time cannot be associated with an historical event, person or place, provenance is unknown. The item is assessed as a collection asset as it is believed to have been produced after 1910 and before 1950.Container of pressed metal. The container has a broad, thin lip, and its round body flares outwards towards base, then tapers inwards to a short heel. A loop holding a metal ring is attached to the side, near the top. A decorative geometrical transfer pattern in blue and cream covers the body and inside of the lip. In the centre of one side is a round frame with the portrait of an Egyptian woman within.warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, flower vase, decorative object, tin vase

A washboard is a tool designed for hand washing clothing. With mechanized cleaning of clothing becoming more common by the end of the 20th century. The traditional washboard is usually constructed with a rectangular wooden frame in which are mounted a series of ridges or corrugations for the clothing to be rubbed upon. For 19th-century washboards, the ridges were often of wood; by the 20th century, ridges of metal were more common. A "fluted" metal washboard was patented in the United States by Stephen Rust in 1833. Zinc washboards were manufactured in the United States from the middle of the 19th century. In the late 20th century and early 21st century, ridges of galvanized steel are most common. Clothes are soaked in hot soapy water in a wash tub or sink, then squeezed and rubbed against the ridged surface of the washboard to force the cleaning fluid through the cloth to carry away dirt. A significant item for cleaning clothes still in use today in many countries giving a snapshot into the domestic life of a housewife.Washboard wooden rectangular with wood grid and 2 legsNoneflagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill-maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, clothes washing, cleaning, 19th century washing appliances, scrub board, washboard

A saw is a tool consisting of a tough blade, wire, or chain with a hard-toothed edge. It is used to cut through material, very often wood, though sometimes metal or stone. The cut is made by placing the toothed edge against the material and moving it forcefully forth and less vigorously back or continuously forward. This force may be applied by hand, or powered by steam, water, electricity or other power sources. An abrasive saw has a powered circular blade designed to cut through metal or ceramic. In ancient Egypt, open (unframed) saws made of copper are documented as early as the Early Dynastic Period, circa 3,100–2,686 BC. Many copper saws were found in tombs dating to the 31st century BC. Models of saws have been found in many contexts throughout Egyptian history. As the saw developed, teeth were raked to cut only on the pull stroke and set with the teeth projecting only on one side, rather than in the modern fashion with an alternating set. Saws were also made of bronze and later iron. In the Iron Age, frame saws were developed holding the thin blades in tension. The earliest known sawmill is the Roman Hierapolis sawmill from the third century AD used for cutting stone. The subject item at this time cannot be associated with an historical event, person or place, provenance is unknown, as the maker is unknown but the pattern or design and type of wood used indicate it is a tool of modern manufacture around the mid to late 20th century.Wood hand saw with wooden handle attached to saw by 4 rivets. No blade markings Noneflagstaff hill, warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, handsaw, wood saw, carpenders tools, cabinet makers tools, wood cutting

The following are the recollections of John Elkins, who started school in February, 1945 at Maryborough in Queensland, Australia. 'I think in Prep 1 that we had some paper to write on with pencils, but my memory of the routine use of slates is much more vivid. Each slate was framed in wood and one side was inscribed with lines to guide the limits for the upper and lower extremities of letters. The slate "pencils" were made of some pale gray mineral softer than slate which had been milled into cylinders some one-eighth of an inch in diameter and inserted into metal holders so that about an inch protruded. Each student was equipped with a small tobacco tin in which was kept a damp sponge or cloth to erase the marks. Sharpening slate pencils was a regular task. We rubbed them on any suitable brick or concrete surface in the school yard. Teachers also kept a good supply of spares, all writing materials and books being provided by the school. It is possible that the retention of slates stemmed from the political imperative that public education should be free. I do recall being given a Copy Book for home practice of letter formation, a typical practice until Grade 6. The tables at which we used to sit in the Infant School were replaced in the primary Grades by long desks seating five or six pupils. These had slots into which the slates could be inserted vertically. When the teacher asked the class to clear their desks, the command issued was "slates away!" This was an occasion for a noisy expression of relief as we dropped the slates producing a sound not unlike a volley of rifle shots, and usually brought a request from the teacher to repeat the process with no noise by holding the frames throughout. Thus, I suspect we may still have used slates in Grade Three, though by then paper, which may have been scarce during the War, seemed to be used more routinely.' The full context of John's account of writing during his primary school days can be found at: https://www.readinghalloffame.org/sites/default/files/history_of_literacy_22slates_away22_penmanship_in_queensland_australia.pdfSchool desks and benches/chairs have been in use in schools since formal group education started.Eight long school desks (five higher three lower), each with four inkwells and groove along length. eight school benches (five higher three lower). Each desk and bench accommodates four children.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village

This copper nail, sometimes known as a ‘Dumpy Bolt’ or spike, was salvaged from the hull of the wreck of the “George III”. It dates back to at least 1810. It was found by an abalone diver on the south east coast of Tasmania. The nail would have been used to hold the layers of the ship’s keel frame and the planking together. The nail has been passed from the abalone diver to an interested business man on a trip to the south of Hobart, on again to the business man’s close friend who then donated it to Flagstaff Hill Maritime Village. The metal of nails such as this one, after being in the sea for a long time, become affected by the natural reaction of the sea water, causing it to degenerate and thin, and the stress from the force of the sea over the years alters its shape. Iron nails had been used on ships previously, but they quickly corroded in the salt; ships needed regular, costly and time-consuming maintenance to replace the iron nails. Towards the end of the 18th century the British Navy trialled the use of copper nails, finding them to be very successful. Merchant ships began to adopt this process in the early 19th century, although it made ship building very expensive and was more often used for ships such as the “George III” that sailed on long voyages. The three masted sailing ship “George III” was a convict transport ship built in Deptford, England, in 1810. On 14th December 1834 she left Woolwich, England, bound for Hobart Town, Van Diemen’s Land (Tasmania), under Captain William Hall Moxey. She was carrying 220 male convicts plus crew, guards and their families, totalling 294 persons (another 2 were during the voyage). Amongst the cargo were military stores including several copper drums of gun powder. On 27th January 1835 the “George III” was near the Equator, about half way into her journey. A fire broke out and the gun powder was in danger of explosion, threatening the whole ship. Two convicts braved the heat and smoke, entered the store and seized the gun powder drums, suffering burns for their efforts but saving a probable disaster. The fire destroyed some of the provisions and food was scarce. Many became ill with scurvy and some died during the journey. Nearing the end of their journey on 10th April 1835 the “George III” was headed through the D'Entrecasteaux Channel, south east Tasmania, between the mainland and Bruny Island. She was sailing in the moonlit night to hasten her arrival in port due to the great number of sick on board. She struck uncharted rocks, known only to the local whalers, between Actaeon Reef and Southport Lagoon and within hours began to break up. The ship’s boats were used to first rescue the women and children. Firearms were used to help quell the panic of the convicts below decks and some were killed by the shots. Many convicts, including the sick, were drowned. In all, 133 lives were lost including 5 of the crew, guards and their families. It was the third worst shipping disaster in Tasmanian waters. A monument in honour of the prisoners who perished in the “George III” has been erected, noting the date of the wreck as “Friday 10th April 1835.” (NOTE: there are a few differences between sources regarding dates of the shipwreck, some saying March and others April 1835. There are also differences in the figures of those on board and the number of lives lost.) The copper nail is significant as an example of sailing ship construction; fasteners used in the early 19th century on ships carrying convicts to Australia. The nail is also significant for its association with the ship “George III”. The “George III” is registered on the Australian National Shipwreck Database, ID 7195 as an Historic Shipwreck. She is the third worst shipwreck in Tasmanian waters. She is also associated with Early Australian History and the transportation of convicts to Australia. The incident of the fire on board and the bravery of the convicts in making the gun powder safe is an example of the social character of the people in early Tasmanian colonisation. Copper nail (also called a Dumpy bolt or spike) from the convict ship George III, wrecked in 1835. Nail is long, bent in an ‘L’ shape about 3/5ths along, tapering from both ends to the bend. Both ends are flat and do not taper to a point, nor have a thread. The shorter end has been polished, showing bright copper. There is pitting along the nail and virdigris is evident on the longer, unpolished end. The nail is displayed with the longer section resting on a wooden board between two ‘U’ shaped uprights, the shorter section upright. flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, george iii, ship construction, ship nail, 1835 shipwreck, 19th century shipwreck, william moxey, d'entrecasteaux channel, convict transportation, copper nail, dumpy bolt, spike, keel nail

The design of this and other similar treadle powered dental engine (or dentist drill) was in common use by dentists from the 1870’s into the 1920's. When electricity became accessible to most communities the electrically powered dental engines began to take over from the treadle power. Over the ages teeth were extracted using picks and scissors and other gouging instruments. Bow drills, hand drills and even a "bur thimble" drill were later used to prepare cavities for filling. Some drills were made bendable by attaching flexible shanks between the metal bur and the handle, giving access to the teeth at the back of the mouth. Other mechanical devices were introduced along the way, such as clockwork drills, but they were hard to handle and inefficient. Over the centuries “dentistry has been performed by priests, monks and other healers. This was followed by barbers; the barber’s chair may well have been the precursor to the dental chair. “(SA Medical Heritage Society Inc.) In 1871 James Morrison patented the first commercially manufactured 'foot treadle dental engine', the first practica dental engine although others had been introduced as early as 1790 (by John Greenwood). Handmade steel burs or drills were introduced for dental handpieces, taking advantage of the significant increase in the speed of the drill. In 1891 the first machine-made steel burs were in use. The treadle drill reduced the time to prepare a cavity from hours to less than ten minutes. In 1876 the Samuel S. White Catalogue of Dentist Instruments listed a 12 ½ inch wheel diameter dental engine, with 14 bright steel parts, for sale at US $55 In today’s market, this is the equivalent to US $1200 approx. The specifications of that dental engine are very similar to the this one in our Flagstaff Hill Maritime Village’s collection. It is interesting to note that workings of a similar treadle dentist drill were used and modified to power a treadle spinning wheel of one of the volunteer spinners at Flagstaff Hill Maritime Village. The foot treadle dental engine was a milestone in dental history. “Historic importance of treadle powered machines; they made use of human power in an optimal way” (Lowtech Magazine “Short history of early pedal powered machines”) The invention of a machine to speed up the process of excavation of a tooth lead to the invention of new burs and drills for the handpieces, improving speed and the surgical process of dentistry. They were the fore-runner of today’s electrically powered dental engines. This treadle-powered dentist drill, or dentist engine, is made of iron and steel and provides power for a mechanical dental hand-piece that would be fitted with a dental tool. The drill has a three footed cast iron base, one foot being longer than the other two. A vertical C shaped frame is joined into the centre of the base, holding an axle that has a driving-wheel (or flywheel) and connecting to a crank. A slender, shoulder height post, made from telescoping pipes, joins into the top of this frame and is height adjusted by a hand tightened screw with a round knob. On the post just above the frame is a short metal, horizontal bar (to hold the hand-piece when it is not in use). A narrow tubular arm is attached to the top of the stand at a right angle and can move up and down. At the end of the arm is a firmly fixed, flexible rubber hose protected for a short distance by a sheath of thin metal. At the end of the hose there is a fitting where the drill’s hand-piece would be attached; a small, silver coloured alligator clip is also at the end. A treadle, or foot pedal, is hinged to the heel to the long foot of the base, and joined at the toe to the crank that turns the driving-wheel. There is a spring under the toe of the treadle. The metal driving-wheel has a wide rim. Touching the inside of the rim are four tubular rings that bulge towards the outside of the driving-wheel, away from the pole, and all meet at the hub of the axle. The axle is bulbous between the inside of the driving-wheel and the frame then passes through the frame and is attached on the other side. The driving-wheel has a groove around which a belt would sit. The belt would also fit around a pulley on the arm, at the top of the post. The pulley is joined to a rod inside the arm and this spins the drill's hand-piece and dental tool holder. The two shorter feet of the base are made from a long metal bar that has been curved outwards, and its centre is bolted to the base of the pole. Under the ends of the curved legs of the base are wedge shaped feet. The driving-wheel is decorated in light coloured paint on both sides, each side having three sets of floral decals evenly spaced around them, and each about a sixth of the wheel's circumference. Similar decoration is along the sides of the frame. The foot pedal has decorative cutout patterns in the centre of the foot and at the toe. On the long foot of the stand is some lettering with a fine, light coloured border around it. The lettering is hard to read, being a dark colour and flaking off. There are also remnants of fine, light coloured flourishes. The foot pedal has lettering of the maker’s trade mark cast into the metal at the ball of the foot. Lettering on the base is peeling and difficult to read. The foot pedal has a trade mark cast into it that looks like a combination of ‘C’ , ‘S’ , ‘A’, ‘R’. flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, dentist, teeth, dental drill, dental engine, treadle drill, foot powered drill, treadle engine, orthodontics, dental surgery, james morrison

The design of this and other similar treadle powered dental engine (or dentist drill) was in common use by dentists from the 1870’s into the 1920's. When electricity became accessible to most communities the electrically powered dental engines began to take over from the treadle power. Over the ages teeth were extracted using picks and scissors and other gouging instruments. Bow drills, hand drills and even a "bur thimble" drill were later used to prepare cavities for filling. Some drills were made bendable by attaching flexible shanks between the metal bur and the handle, giving access to the teeth at the back of the mouth. Other mechanical devices were introduced along the way, such as clockwork drills, but they were hard to handle and inefficient. Over the centuries “dentistry has been performed by priests, monks and other healers. This was followed by barbers; the barber’s chair may well have been the precursor to the dental chair. “(SA Medical Heritage Society Inc.) In 1871 James Morrison patented the first commercially manufactured 'foot treadle dental engine', the first practica dental engine although others had been introduced as early as 1790 (by John Greenwood). Handmade steel burs or drills were introduced for dental handpieces, taking advantage of the significant increase in the speed of the drill. In 1891 the first machine-made steel burs were in use. The treadle drill reduced the time to prepare a cavity from hours to less than ten minutes. In 1876 the Samuel S. White Catalogue of Dentist Instruments listed a 12 ½ inch wheel diameter dental engine, with 14 bright steel parts, for sale at US $55 In today’s market, this is the equivalent to US $1200 approx. The specifications of that dental engine are very similar to the this one in our Flagstaff Hill Maritime Village’s collection. It is interesting to note that workings of a similar treadle dentist drill were used and modified to power a treadle spinning wheel of one of the volunteer spinners at Flagstaff Hill Maritime Village. The foot treadle dental engine was a milestone in dental history. “Historic importance of treadle powered machines; they made use of human power in an optimal way” (Lowtech Magazine “Short history of early pedal powered machines”) The invention of a machine to speed up the process of excavation of a tooth lead to the invention of new burs and drills for the handpieces, improving speed and the surgical process of dentistry. They were the fore-runner of today’s electrically powered dental engines. This treadle-powered dentist drill, or dentist engine, is made of iron and steel and provides power for a mechanical dental handpiece that would be fitted with a dental tool. On the foot is painted lettering naming it "The Brentfield" and there is a fine line of light coloured paint creating a border around the name. The paint under the lettering is peeling off. The drill has a Y-shaped, three footed cast iron base, one foot being longer than the other two. A vertical frame is joined into the centre of the base, holding an axle that has a driving-wheel (or flywheel) and connecting to a crank. A slender, shoulder height post, made from adjustable telescoping pipes, joins into the top of this frame. On the post just above the frame is a short metal, horizontal bar (to hold the hand-piece when it is not in use). A narrow tubular arm is attached to the top of the stand at a right angle and can move up, down and around. There is a pulley each side of the joint of the arm and a short way along the arm is fitted a short metal pipe. A little further along the arm a frayed-ended cord hangs down from a hole. At the end of the arm is another pulley and a joint from which hangs a long, thin metal pipe with two pulleys and a fitting on the end. A treadle, or foot pedal, is joined to the long foot of the base, and joined at the toe to the crank that turns the driving-wheel. The metal driving-wheel has a wide rim. Touching the inside of the rim are four tubular rings that bulge towards the outside of the driving-wheel, away from the pole, and all meet at the hub of the axle. The axle fits between the inside of the driving-wheel and the frame then passes through the frame and is attached on the other side. The driving-wheel has a groove around which a belt would sit. The belt would also fit around a pulley on the arm, at the top of the post. The pulley is joined to a rod inside the arm and this spins the drill's hand-piece and dental tool holder. The foot pedal has a cross-hatch pattern on the heel and the ball of the foot has tread lines across it. The end of the toe and the instep areas have cut-out pattern in them. "The ____/ Brentfield / __ DE IN L___" (Made in London) painted on the long foot of the base. Marked on the drill connection is “Richter De Trey, Germany”flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, dentist, teeth, dental drill, dental engine, treadle drill, foot powered drill, treadle engine, orthodontics, dental surgery, james morrison, the brentfield, richter de trey, german dental fitting, london dental drill

Before the introduction of electricity, lighthouses had a clockwork mechanism that caused the lens to rotate with a light source inside that was either powered by Kerosene or Colza oil. The mechanism consisted of a large weight attached by a cable through the centre of the lighthouse to the top where the cable wrapped around a barrel, drum or wheels that controlled the speed of the lights rotation by a clockwork mechanism. The keeper would crank the clockwork mechanism, which would lift the weight ready for the next cycle similar to an old grandfather clock mechanism. Once the weight lifted to its apex at the bottom of the first landing, the keeper would let it fall, which would pull on the cable, which would, in turn, operate a series of gears activating the rotation of the Fresnel optical lens, which would then rotate to create the lighthouse’s unique light speed of rotation characteristic. Creating a specific characteristic required a way to regulate the speed of the rotation, and was important as sailors could identify a particular light by its speed and time between flashes. The weight had to fall at a certain rate to create the proper rotation speed of the lens and a regulator within the mechanism accomplished this. History: From 1851, Chance Brothers became a major lighthouse engineering company, producing optical components, machinery, and other equipment for lighthouses around the world. James Timmins Chance pioneered placing lighthouse lamps inside a cage surrounded by Fresnel lenses to increase the available light output these cages, are known as optics and they revolutionised lighthouse design. Another important innovation from Chance Brothers was the introduction of rotating optics, allowing adjacent lighthouses to be distinguished from each other by the number of times per revolution the light flashes. The noted English physicist and engineer, John Hopkins invented this system while employed at Chance Brothers. Chance Brothers and Company was a glass works and originally based in Spon Lane, Smethwick, West Midlands England. The company became a leading glass manufacturer and a pioneer of British glass making technology. The Chance family originated in Bromsgrove as farmers and craftsmen before setting up a business in Smethwick near Birmingham in 1824. They took advantage of the skilled workers, canals and many other industrial advances taking place in the West Midlands at the time. Robert Lucas Chance (1782–1865), known as 'Lucas', bought the British Crown Glass Company's works in Spon Lane in 1824. The company specialised in making crown window glass, the company ran into difficulty and its survival was guaranteed in 1832 by investment from Chance's brother, William (1788 – 1856). William owned an iron factoring business in Great Charles Street, Birmingham. After a previous partnership that Lucas had dissolved in 1836, Lucas and William Chance became partners in the business which was renamed, Chance Brothers and Company. Chance Brothers invented many innovative processes and became known as the greatest glass manufacturer in Britain. In 1848 under the supervision of Georges Bontemps, a French glass maker from Choosy-le-Roi, a new plant was set up to manufacture crown and flint glass for lighthouse optics, telescopes and cameras. Bontemps agreed to share his processes that up to then had been secret with the Chance Brothers and stayed in England to collaborate with them for six years. In 1900 a baronetcy was created for James Timmins Chance (1814–1902), a grandson of William Chance, who had started the family business in 1771 with his brother Robert. Roberts grandson, James became head of Chance Brothers until his retirement in 1889 when the company became a public company and its name changed to Chance Brothers & Co. Ltd. Additional information: Lighthouses are equipped with unique light characteristic or flashing pattern that sailors can use to identify specific lighthouses during the night. Lighthouses can achieve distinctive light characteristics in a few different ways. A lighthouse can flash, which is when brief periods of light interrupt longer moments of darkness. The light can occult, which is when brief periods of darkness interrupt longer moments of light. The light can be fixed, which is when the light never goes dark. A lighthouse can use a combination of flashing, oscillating, or being fixed in a variety of combinations and intervals to create individual light characteristics. It is a common misconception that a lighthouse's light source changes the intensity to create a light characteristic. The light source remains constant and the rotating Fresnel lens creates the various changes in appearance. Some Fresnel lenses have "bulls-eye" panels create beams of light that, when rotated between the light and the observer, make the light appear to flash. Conversely, some lenses have metal panels that, when rotated between the light and the observer, make the light appear to go dark. This Dioptric clockwork apparatus used to turn a lighthouse optical lens is very significant as it is integral to a lighthouses operation, we can also look at the social aspect of lighthouses as being traditionally rich with symbolism and conceptual meanings. Lighthouses illustrate social concepts such as danger, risk, adversity, challenge and vigilance but they also offers guidance, salvation and safety. The glowing lamp reminds sailors that security and home are well within reach, they also symbolize the way forward and help in navigating our way through rough waters not just on the oceans of the world but in our personal lives be it financial, personal, business or spiritual in nature. Nothing else speaks of safety and security in the face of adversity and challenge quite the way a lighthouse does. Revolving dioptric clockwork apparatus used to turn a Fresnel optical lighthouse lens. A cylindrical cast metal pillar and cabinet painted green with 3 glass doors enclosing the top section. Inside the pillar/cabinet is a large clockwork mechanism used to turn and regulate a lighthouse light by means of weights and a chain attached to same. One door has the name "Adams Mare" in metallic dots similar to "Braille" to the inside edge of door frame.shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, flagstaff hill, maritime-museum, shipwreck-coast, warrnambool, flagstaff-hill-maritime-village, revolving dioptric mechanism, dioptric mechanism for lighthouse, lighthouse clockwork timing mechanism, acetylene lighthouse light mechanism, 19th century lighthouse mechanism, kerosene light, fresnel lenses, colza oil, chance brothers

Inhaler for chloroform, metal, chrome plated, with hinged frame, Schimmel Busch type. Small.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village