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

Extract from The Spectator of June 12, 1946: "From the Queensland 'Methodist Times'. Dreams do come true. At any rate, that is what the Rev. Cliff Lanham believes, who after the lapse of several years finds that his early dream of a Flying Patrol for the Inland is now an actuality. The Methodist Inland Mission Board has purchased from the Disposals Commission of the R.A.A.F. a De Haviland Fox Moth Biplane. Indeed, two machines have been bought, but one will be broken up for spare parts. This 'new angel of the air' is fitted with a 130 h.p. engine and possesses a cruising speed of 100 miles per hour. The petrol consumption is only that of a big six-cylinder car—18 miles per gallon. In addition to the pilot there is room for three passengers, and a stretcher is installed whereby urgent cases of sickness or accident can be flown to the nearest hospital. In this machine, Mr Lanham proposes to cover the whole of S. W. Queensland and a portion of the Northern Territory from his headquarters at Mt Isa. It takes little imagination to realise what a boon the 'flying parson' will be to those of the great outback." …. "Before [Mr Lanham] inaugurated the scheme [the idea of a flying parson] he spent his first furlough from inland mission work (and incidentally £60) learning to fly. 'In a month,' he says whimsically, 'I was a pilot of sorts.' Mr Lanham is a son of the Church. His parents were staunch Methodists, and their home offered generous hospitality to mininsters and preachers. His brother, the Rev. Percy Lanham, M.A., died in Libya when on active service as a chaplain. His widowed mother must be proud of her tall, stalwart son, whom the Church now sends forth on his flying mission for the Lord. May he ever be wafted through inland skies on two wings and a prayer." It is of interest to note that although Cliff Lanham's brother, Percy, is listed in the Methodist Church of Australasia's Ministerial Index (9th Edition, Revised to 1961) Cliff Lanham himself is not listed as either active or deceased.Three B&W identical photographs of Lanham standing next to a Methodist Inland Mission bi-plane. Lanham and an unidentified man are holding a stretcher between them with a boy of about 10-11 on it. They seem to be exiting the plane. The original photograph F69-1 is a 110x65 mm Kodak print; the other two are 195x145 mm enlargements. Lanham is wearing a white shirt and grey trousers, the other person is wearing a safari helmet.All three photos identify "Rev. Cliff Lanham" on the back. They seem to have been originally used or intended for use by The Spectator.lanham, cliff, queensland, methodist inland mission, flying parson

Comprises a collection of metal, wooden and plastic toys which would possibly date back to the 1920s to 1940sThis collection came from the Warton / Baker families from Tawonga and Redbank in the Kiewa Valley.Collection of metal toys: 1. x2 Train Locomotives 2. Red tractor - mechanical with key 3. Man using grinder - mechanical with key 4. Two birds with worm - mechanical with key 5. Green trailer - mechanical with key 6. Small tank - mechanical with key 7. Aeroplane 8. Metal top 9. Home-made push-along wheels 10. Home made top 11. Cap gun 12. Cookie Cutters 13. Small tin puncture Kit - empty 14. Metal fox whistle 15. Tin trumpet 16. Large metal pump top 17. Plastic & metal mechancal toy in cardboard box- Jolly Skipper Other: 1. Monkey puppet with paper legs 2. Small plastic bells 3. Plastic boy on bike 4. Plastic green car 5. Plastic small trains 6. Soldier dog 8. Two half coconut shells (hollow) 9. Cylinder of wooden mechano tinker toy 10. Plastic Mr & Mrs Funny Face in box 11. Trip to New York game in box 12. Wooden Modelcraft - Build-ees in box 13. Wooden ring 14. Jig-saw toys, puzzles, wooden mechano, mechanical toys, recreation, children

Gasometers resulted from complex engineering design evolving from primitive gasholders first used in 1824 in England to power street lights. The 20th century gasometer, (as used at the Highett Gasworks), was comprised of a series of large interconnected, telescopic, cylindrical vessels or lifts, which rose and fell depending on the volume of gas stored. The gasholder operated on a basic principle of a gas-filled floating vessel, rising and falling in a seal of water. The Highett Gasworks had its beginning in 1939 but its beginnings commenced sixty-two years earlier when the privately owned Brighton Gas Company was floated in 1877. By 1880 the company was performing well and making excellent profits. The company was welcomed by residents wanting to replace the shadowy light of a kerosene lamp with the bright luminescence of "modern" gas lamps. The land developers of the day were also keen supporters. But by 1884 people became disgrunted because either the gas had not reached them yet or because the quality of the supply had diminished due to the increasing use. In 1885 a second private gas company, the Central Brighton and Moorabbin Gas Co, Chaired by "Tommy" Bent was floated and for many years the two gas companies enjoyed a shared monopoly in supplying gas from their New Street Works. In the 1930s the company expanded its gas production facilities to Highett where it had purchased 45 acres of land adjacent to the Melbourne-Frankston railway line. A gasholder with a capacity of 750,000 cubic feet was erected on the Highett land in 1927 and connected with high pressure mains to the Brighton works. Three years later the company directors decided to proceed with the construction of a vertical retort house and coal store. Following a "lull" during the Great Depression work recommenced in 1936 and by 1939 the first complete gas-making plant was completed, and gas making commenced. Over the next twenty one years other significant extensions occurred, including an amenities block to accomodate 100 workers. In 1969 Esso commenced the introduction of natural gas to residents homes and the gradual decommissioning of the Highett Gasworks commenced. Part of the old Highett Gasworks site is now a council owned parkThe photos of the Higett Gasworks, now demolished, recall their long history, that originated in the 1800s with the production of gas to supply homes with a new, much improved light source, and later it's other applications such as for stoves etc. The arrival of gas in the Shire of Moorabbin was a huge step forward that encouraged further building and development in the area.Three Photographs of the Highett Gasworks. Two are coloured photos taken in 1974, and one is black and white taken in the 1960s. All are in good conditionOn the back of the two coloured photographs "Highett Gasworks 1974" No inscription on the black and white aerial photograph.brighton, moorabbin, highett, bent thomas, gasometer, highett gasworks, engineering design, brighton gas company, central brighton and moorabbin gas company, great depression, lamp kerosene

Yields information about the reconstruction of the depot trackwork during 1935/1936 and the condition of the rails, types of rails and methodsSet of 5 Black and white photo prints from collected negatives of the relaying of the depot fan at the SEC Ballarat depot building, during refurbishment by the SEC during 1935 or 1936. 1351.1 - Wendouree Parade depot junction, track - relaying the 2nd set of points. One track was still useable at the time. Note fences and tools lying around the work area. 1351.2 - laying out the trackwork for two and three roads, note machines and cylinders in background. 1351.3 - looking along No. 2 road out of the depot doors, not connected, possibly taken some time after 1351.2, as the area appears to be cleaned up. 1351.4 - Photo showing the various rail weights for possibly the western rail on No. 3 road and how the fishplates were at the time of the photograph. Not known whether this was the final arrangement, taken looking towards the depot building. 1351.5 - ditto but from the other end - note the damaged flangeway on the depot end rail - horse tram rail? Copy 2 - of all above photos - large format prints (203H x 253W) - added 28/7/2007, ex Alan Bradley holding of prints, received 5/2007. See also Reg Item 3901 for a mounted set of these photographs along with those of Reg Item. 1352. Negatives scanned at high res and images updated 14/5/2020. tramways, trams, wendouree parade, sec depot, rehabilitation, trackwork

The invention of the Coolgardie Safe is credited to Arthur Patrick McCormick, a contractor in Coolgardie, and later the Mayor of Narrogin. Coolgardie is in the Eastern Goldfields region of Western Australia. Gold was first discovered there in 1892; the townsite became a municipality in 1894, and by 1898 its population of 15,000 made it the third largest town in Western Australia after Perth and Fremantle. In the last decade of the 19th century, Coolgardie was the capital of the West Australian goldfields. Being 180 kilometres from the nearest civilisation, food supplies were initially scarce and expensive. As fresh food was a valuable commodity there was incentive to preserve it, and keep it out of reach of scavengers such as birds, dingos, dogs, ants, and flies. It was in an effort to do this, in the extreme heat of the Australian Interior, that McCormick came up with his design for the Coolgardie Safe. McCormick noticed that a wet bag placed over a bottle cooled its contents. He further noted that if this bottle was placed in a breeze, the bag would dry out more quickly, but the bottle would get colder. What McCormick had discovered was the principle of evaporation: ‘to change any liquid into a gaseous state requires energy. This energy is taken in the form of heat from its surroundings.’ Employing this principle, McCormick made a box for his provisions which he covered with a wet hessian bag. He then placed a tray on top, into which he poured water twice daily. He hung strips of flannel from the tray so that water would drip down onto the hessian bag, keeping it damp. As the water evaporated, the heat dissipated, keeping the food stored inside cool and fresh. The success of McCormick’s invention would not have worked without a steady supply of water. Fresh water was scarce in the eastern goldfields at this time but the demand for water from a steadily growing population encouraged innovation. The solution was to condense salt water. Heating salt water in tanks produced steam that was condensed in tall cylinders, cooled and then collected in catchment trays. By 1898 there were six companies supplying condensed water to the goldfields, the largest company producing 100,000 gallons of water a day. In the early 20th century, Coolgardie Safes were also manufactured commercially. These safes incorporated shelving and a door, had metal or wooden frames and hessian bodies. The feet of the safe were usually placed in a tray of water to keep ants away. (MAV website) The early settlers of Moorabbin Shire depended on this type of Food Safe to protect their food from flies and vermin as they established market gardens in the fertile area around the notorious Elster Creek A metal framed, 4 sided structure standing on 4 legs with 2 hinged doors on one side, a metal tray at base of food safe and a metal cover over top. Ridges on which to rest trays carrying food are inside safe. The Safe is enclosed by fly-wire mesh.'...IN.....GEELONG' A manufacturer's oval metal plate is embossed on one side of Safe but it is illegible.elster creek, moorabbin, brighton, dendy's special survey 1841, market gardens, infant mortality, disease, cemeteries, fruit, vegetables, pioneers, coolgardie safe, mccormick arthur patrick, dendy henry, vaccination, jones martha, jones ethel may

The locomotive was supplied new by Decauville to the Metropolitan Gas Company Ltd, Melbourne, for use at their gasworks in West Melbourne, where it was named Carbon suppied in 1889 (Couillet builder's number 986, Decauville serial number 90). It was named Carbon. The West Melbourne gas works sourced its coal from Maitland, New South Wales, and the coal was brought by ship to a wharf adjacent to the West Melbourne gas plant. John Benn and Carbon were used to haul the coal over a 762 mm (2 ft 6 in) gauge railway from the wharf to the gasworks, a distance of about 450 metres (500 yards). West Melbourne Gas Works No. "Carbon" Wheels: 0-4-0T Builder: Couillet Build Date: 1890 Construction No.: 986 Empty Weight: Unknown Weight on Drivers: Unknown Driver Diameter: Unknown Tractive Effort: Unknown Boiler Pressure: Unknown Cylinders: Unknown Fuel: Coal Gauge: 30 Decauville locomotives The firm Société Anonyme Decauville located at Petit Bourg, France, was founded to manufacture light railways pioneered by French farmer Paul Decauville to transport crops from the field in 1875. Decauville began designing their own locomotives in 1882, although initially manufacture was contracted out to other builders, notably the Belgian firm Hainault at Couillet Although not well known in Australia, in Europe Couillet was a significant builder of steam locomotives of many different gauges and sizes over a long period of time. The locomotive was supplied new by Decauville to the Metropolitan Gas Company Ltd, Melbourne, for use at their gasworks in West Melbourne, where it was named Carbon (986) . Carbon ( 986 ) The locomotive weighs approximately seven tons. It has the Couillet builder's number 986. of 1889 It was built for Decauville & Cie. of Paris, suppliers of portable and industrial railway equipment, and has their serial number of 90 of 1890. Built in 1889 for the West Melbourne site of the Metropolitan Gas Company, it is a four-wheel tank locomotive and was named “Carbon”. It was withdrawn from service in the 1930s and stored until sold privately in 1962. For a few years in the 1960s it was used on a circle of track at Walhalla, before going to the Whistle Stop Amusement Park in Frankston. Although a number of similar locomotives still exist, as far as is known Carbon is the only one still operating in its original condition. Historic - Industrial railways - Metropolitan Gas Company Ltd, Melbourne Steam Locomotive Small Decauville Couillet Steam locomotive. - Iron & wrought iron framesCouillet builder's number 986, Decauville serial number 90puffing billy, narrow gauge, industrial narrow gauge railway, couillet 986, decauville 90, steam locomotive, metropolitan gas company, carbon

This photograph shows a piece of gold mining equipment identified as a mine winch, possibly an air winch cylinder of 1870s RG Ford's Patent design. Throughout the history of mining for gold and other precious materials, the windlass or winch (pictured) was used to bring up buckets full of soil from the bottom of a mine. This soil was then searched for gold/metals before being relocated to a different area. Due to the size and complexity of this particular piece of equipment, this winch may have been used to raise and lower mine carts to the entrance of the mine (often used in coal mining) and could have been used in raising cages up and down (acting as elevators) containing miners if the mine was particularly deep. The actual use of this particular item in the Beechworth locality is undocumented but these are some possibilities based on the use of these pieces of equipment in other mining locations. Mining can have a largely detrimental impact to the environment and therefore, the study of machinery like the one depicted in this photograph can help researches to reconstruct the methods and technologies used in the late 1800s and early 1900s. This particular item appears to have been removed from it's original site where it would have been used to assist with mining. It is possible that this photograph has been taken for recording purposes or as part of a machinery exhibition. Prior documentation records that this piece of equipment had connections to the Rocky Mountains Mining Company. Today, the Rocky Mountains Gold Mining company is famous in Beechworth for having been instrumental in the creation of the Rocky Mountain tunnel. Construction for this tunnel began in 1859 when a group of 12 men blasted a 400ft long tailrace though the rock beneath the town of Beechworth. Today, the 800ft tunnel, completed in 1871, is a popular tourist attraction but during the decades of gold mining, the purpose of this tunnel was to divert water away from the main sluicing operations so miners could better access gold and precious materials. The tunnel was used for this purpose for many years, later becoming useful for the Zwar Brother's tannery and currently as an outfall drain for Lake Sambell. This area continued to be mined until the early 1900s. The period when this item was in use is unclear but it is estimated to have been in the 1870s based on the design and appearance of the image. The gold works at the Rocky Mountain Tunnel closed in the early 1920s but the impact of mining remains in Beechworth today and therefore the study of photographs like this one which contain mining equipment can further understanding of mining in this region.This photograph has historic and research potential for study on the gold mining of the Beechworth region and types of equipment used to locate gold after the initial gold rush of 1853-1854 which resulted in the discovery of the surface gold and required miners to dig deeper to access precious metals. The clarity of the photo, and its good preserved condition, means it can continue to be used for research. This photo is part of a collection of six photos all within the Burke Museum Collection which depict mining equipment.Square black and white photograph on card.7793.1beechworth, mining, goldmining, goldmining equipment, beechworth burke museum

This three-dimensional Distant Signal is part of a Flagstaff Signal set of ball, cone and drum shapes. It has been woven and then fabricated with strong metal swivel fittings and loops for suspending from a high point on a flagstaff at a signal station or on a ship’s masthead. The cane signal was constructed to withstand all weather and to be visible from a long distance. The gaps between the woven cane allow air to pass through, minimising possible swaying. Similar sets were made from rope or fabric. Warrnambool's Flagstaff was erected in 1854. Its primary use was to display visual signals that could convey messages between land and sea. It was also used to notify the local population of the approach of ships. One of the popular signalling codes in use in the early-to-mid 1800s was the Marryat’s Code but there were others in use as well; there was no one standard code. In 1857 the International Marine Conference adopted an International Code of Signals as a standard communications system for all vessels that could be understood in many different languages. The Normanby Advertiser reported on June 5th 1857 a query from the Post Master General as to whether the request of the Chief Harbour Master would be carried out, in that Warrnambool would receive a new flagstaff and a set of Marryatt’s signal flags. The Table of Codes was published, showing how to use combinations of these flags to send messages. The Code was revised in 1887 to cover situations where distance, light, wind and weather conditions affected the visibility of the flags and prevented clear communication. The first report of the International Code of Signals Committee of 1897 warned signalmen not to rely on ordinary semaphore flags and introduced a Distant Signal Code using either particular semaphore flags or the three-dimensional shapes of a ball, cone and drum that aligned with the semaphore flag shapes of a circle, pennant and square. International Code of Signals In 1931, after World War I’s experiences in using signal codes, the International Code of Signals conference in Washington revised and published the rules for the conduct of signalling. One of the changes was that “the use of the Distant Signals and of fixed semaphore was abandoned”. It is of interest to know that modern marine law in many countries insists that a set of Day Shapes must be carried onboard vessels of a certain size. These highly visible geometric shapes are used at sea in daylight to communicate messages between vessels. They are used in a similar way to the Distant Signals, in that different combinations of shapes represent different messages. The set of shapes includes a ball, cylinder, cone and diamond. The shapes are hung between the top of the vessel’s foremast and the front of the vessel. They are only coloured black and are about 1.5 metres high. The vertical line of shapes can mean messages such as Boat not under command, Fishing, and Under sail and power.Distant Signals were an important means of marine communication from the late 1880s to the early 1930s, including during World War I. They were an advancement to the International Shipping Codes and safety. The cane signals’ shapes appear to be the same from whatever direction they are viewed, removing confusion about the message they convey. The same shapes continue to be used today for the sets of Day Shapes used as marine navigational signals that are mandatory on certain-sized vessels.Distant Signal Ball, part of a Flagstaff signal set. A round woven cane ball, painted black, with a metal rod passing through the centre. The rod has a loop at each end, then a concave, octagonal metal plate that rests on the outside surface of the ball, serving as a washer. The rod has swivels at each end.flagstaff hill, flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, distant signal, signal, maritime signal, ball signal, signal shape, flagstaff signal, signal station, masthead signal, communications, marine technology, signals, marine signals, flaghoists, international marine conference, international code of signals, signal codes, marine safety, signal flags, day shape, daymark, day symbol, navigation, warrnambool flagstaff, 1854, 1857 1931, 1887, 1897

This three-dimensional Distant Signal is part of a Flagstaff Signal set of ball, cone and drum shapes. It has been woven and then fabricated with strong metal swivel fittings and loops for suspending from a high point on a flagstaff at a signal station or on a ship’s masthead. The cane signal was constructed to withstand all weather and to be visible from a long distance. The gaps between the woven cane allow air to pass through, minimising possible swaying. Similar sets were made from rope or fabric. Warrnambool's Flagstaff was erected in 1854. Its primary use was to display visual signals that could convey messages between land and sea. It was also used to notify the local population of the approach of ships. One of the popular signalling codes in use in the early-to-mid 1800s was the Marryat’s Code but there were others in use as well; there was no one standard code. In 1857 the International Marine Conference adopted an International Code of Signals as a standard communications system for all vessels that could be understood in many different languages. The Normanby Advertiser reported on June 5th 1857 a query from the Post Master General as to whether the request of the Chief Harbour Master would be carried out, in that Warrnambool would receive a new flagstaff and a set of Marryatt’s signal flags. The Table of Codes was published, showing how to use combinations of these flags to send messages. The Code was revised in 1887 to cover situations where distance, light, wind and weather conditions affected the visibility of the flags and prevented clear communication. The first report of the International Code of Signals Committee of 1897 warned signalmen not to rely on ordinary semaphore flags and introduced a Distant Signal Code using either particular semaphore flags or the three-dimensional shapes of a ball, cone and drum that aligned with the semaphore flag shapes of a circle, pennant and square. International Code of Signals In 1931, after World War I’s experiences in using signal codes, the International Code of Signals conference in Washington revised and published the rules for the conduct of signalling. One of the changes was that “the use of the Distant Signals and of fixed semaphore was abandoned”. It is of interest to know that modern marine law in many countries insists that a set of Day Shapes must be carried onboard vessels of a certain size. These highly visible geometric shapes are used at sea in daylight to communicate messages between vessels. They are used in a similar way to the Distant Signals, in that different combinations of shapes represent different messages. The set of shapes includes a ball, cylinder, cone and diamond. The shapes are hung between the top of the vessel’s foremast and the front of the vessel. They are only coloured black and are about 1.5 metres high. The vertical line of shapes can mean messages such as Boat not under command, Fishing, and Under sail and power.Distant Signals were an important means of marine communication from the late 1880s to the early 1930s, including during World War I. They were an advancement to the International Shipping Codes and safety. The cane signals’ shapes appear to be the same from whatever direction they are viewed, removing confusion about the message they convey. The same shapes continue to be used today for the sets of Day Shapes used as marine navigational signals that are mandatory on certain-sized vessels.Distant Signal Cone, part of a Flagstaff signal set. A woven cane cone, painted black, with a metal rod passing through the centre and two crossed metal bars at the base. The central rod has a loop at the top and passes through the bars at the base, finishing in a metal loop. The rod has swivels at each end.flagstaff hill, warrnambool, flagstaff hill maritime museum and village, shipwreck coast, marine navigation, marine communications, communication signal, lifesaving, ship at sea, day shape, masthead signal, day signal, day mark signals, marine technology, safety equipment, navigation equipment, marine day shape, day marker, cane day shape, signal cone, day signal cone, cone signal, cone day shape, distant signal, flagstaff signal, signal station, communications, signals, marine signals, flaghoists, international marine conference, international code of signals, signal codes, marine safety, signal flags, daymark, day symbol, navigation, warrnambool flagstaff, 1854, 1857 1931, 1887, 1897

This three-dimensional Distant Signal is part of a Flagstaff Signal set of ball, cone and drum shapes. It has been woven and then fabricated with strong metal swivel fittings and loops for suspending from a high point on a flagstaff at a signal station or on a ship’s masthead. The cane signal was constructed to withstand all weather and to be visible from a long distance. The gaps between the woven cane allow air to pass through, minimising possible swaying. Similar sets were made from rope or fabric. Warrnambool's Flagstaff was erected in 1854. Its primary use was to display visual signals that could convey messages between land and sea. It was also used to notify the local population of the approach of ships. One of the popular signalling codes in use in the early-to-mid 1800s was the Marryat’s Code but there were others in use as well; there was no one standard code. In 1857 the International Marine Conference adopted an International Code of Signals as a standard communications system for all vessels that could be understood in many different languages. The Normanby Advertiser reported on June 5th 1857 a query from the Post Master General as to whether the request of the Chief Harbour Master would be carried out, in that Warrnambool would receive a new flagstaff and a set of Marryatt’s signal flags. The Table of Codes was published, showing how to use combinations of these flags to send messages. The Code was revised in 1887 to cover situations where distance, light, wind and weather conditions affected the visibility of the flags and prevented clear communication. The first report of the International Code of Signals Committee of 1897 warned signalmen not to rely on ordinary semaphore flags and introduced a Distant Signal Code using either particular semaphore flags or the three-dimensional shapes of a ball, cone and drum that aligned with the semaphore flag shapes of a circle, pennant and square. International Code of Signals In 1931, after World War I’s experiences in using signal codes, the International Code of Signals conference in Washington revised and published the rules for the conduct of signalling. One of the changes was that “the use of the Distant Signals and of fixed semaphore was abandoned”. It is of interest to know that modern marine law in many countries insists that a set of Day Shapes must be carried onboard vessels of a certain size. These highly visible geometric shapes are used at sea in daylight to communicate messages between vessels. They are used in a similar way to the Distant Signals, in that different combinations of shapes represent different messages. The set of shapes includes a ball, cylinder, cone and diamond. The shapes are hung between the top of the vessel’s foremast and the front of the vessel. They are only coloured black and are about 1.5 metres high. The vertical line of shapes can mean messages such as Boat not under command, Fishing, and Under sail and power.Distant Signals were an important means of marine communication from the late 1880s to the early 1930s, including during World War I. They were an advancement to the International Shipping Codes and safety. The cane signals’ shapes appear to be the same from whatever direction they are viewed, removing confusion about the message they convey. The same shapes continue to be used today for the sets of Day Shapes used as marine navigational signals that are mandatory on certain-sized vessels.Distant Signal Ball, part of a Flagstaff signal set. A round woven cane ball, painted black, with a metal rod passing through the centre. The rod has a loop at each end, then a concave, octagonal metal plate that rests on the outside surface of the ball, serving as a washer. The rod has swivels at each end.flagstaff hill, warrnambool, flagstaff hill maritime museum and village, shipwreck coast, marine navigation, marine communications, communication signal, lifesaving, ship at sea, day shape, masthead signal, day signal, day mark signals, marine technology, safety equipment, navigation equipment, marine day shape, day marker, cane day shape, signal ball, day signal ball, ball signal, ball day shape, distant signal, flagstaff signal, signal station, communications, signals, marine signals, flaghoists, international marine conference, international code of signals, signal codes, marine safety, signal flags, daymark, day symbol, navigation, warrnambool flagstaff, 1854, 1857 1931, 1887, 1897

This three-dimensional Distant Signal is part of a Flagstaff Signal set of ball, cone and drum shapes. It has been woven and then fabricated with strong metal swivel fittings and loops for suspending from a high point on a flagstaff at a signal station or on a ship’s masthead. The cane signal was constructed to withstand all weather and to be visible from a long distance. The gaps between the woven cane allow air to pass through, minimising possible swaying. Similar sets were made from rope or fabric. Warrnambool's Flagstaff was erected in 1854. Its primary use was to display visual signals that could convey messages between land and sea. It was also used to notify the local population of the approach of ships. One of the popular signalling codes in use in the early-to-mid 1800s was the Marryat’s Code but there were others in use as well; there was no one standard code. In 1857 the International Marine Conference adopted an International Code of Signals as a standard communications system for all vessels that could be understood in many different languages. The Normanby Advertiser reported on June 5th 1857 a query from the Post Master General as to whether the request of the Chief Harbour Master would be carried out, in that Warrnambool would receive a new flagstaff and a set of Marryatt’s signal flags. The Table of Codes was published, showing how to use combinations of these flags to send messages. The Code was revised in 1887 to cover situations where distance, light, wind and weather conditions affected the visibility of the flags and prevented clear communication. The first report of the International Code of Signals Committee of 1897 warned signalmen not to rely on ordinary semaphore flags and introduced a Distant Signal Code using either particular semaphore flags or the three-dimensional shapes of a ball, cone and drum that aligned with the semaphore flag shapes of a circle, pennant and square. International Code of Signals In 1931, after World War I’s experiences in using signal codes, the International Code of Signals conference in Washington revised and published the rules for the conduct of signalling. One of the changes was that “the use of the Distant Signals and of fixed semaphore was abandoned”. It is of interest to know that modern marine law in many countries insists that a set of Day Shapes must be carried onboard vessels of a certain size. These highly visible geometric shapes are used at sea in daylight to communicate messages between vessels. They are used in a similar way to the Distant Signals, in that different combinations of shapes represent different messages. The set of shapes includes a ball, cylinder, cone and diamond. The shapes are hung between the top of the vessel’s foremast and the front of the vessel. They are only coloured black and are about 1.5 metres high. The vertical line of shapes can mean messages such as Boat not under command, Fishing, and Under sail and power.Distant Signals were an important means of marine communication from the late 1880s to the early 1930s, including during World War I. They were an advancement to the International Shipping Codes and safety. The cane signals’ shapes appear to be the same from whatever direction they are viewed, removing confusion about the message they convey. The same shapes continue to be used today for the sets of Day Shapes used as marine navigational signals that are mandatory on certain-sized vessels.Distant Signal Cone, part of a Flagstaff signal set. A woven cane cone, painted black, with a metal rod passing through the centre and two crossed metal bars at the base. The central rod has a loop at the top and passes through the bars at the base, finishing in a metal loop. The rod has swivels at each end.flagstaff hill, warrnambool, flagstaff hill maritime museum and village, shipwreck coast, marine navigation, marine communications, communication signal, lifesaving, ship at sea, day shape, masthead signal, day signal, day mark signals, marine technology, safety equipment, navigation equipment, marine day shape, day marker, cane day shape, signal cone, day signal cone, cone signal, cone day shape, distant signal, flagstaff signal, signal station, communications, signals, marine signals, flaghoists, international marine conference, international code of signals, signal codes, marine safety, signal flags, daymark, day symbol, navigation, warrnambool flagstaff, 1854, 1857 1931, 1887, 1897

This three-dimensional Distant Signal is part of a Flagstaff Signal set of ball, cone and drum shapes. It has been woven and then fabricated with strong metal swivel fittings and loops for suspending from a high point on a flagstaff at a signal station or on a ship’s masthead. The cane signal was constructed to withstand all weather and to be visible from a long distance. The gaps between the woven cane allow air to pass through, minimising possible swaying. Similar sets were made from rope or fabric. Warrnambool's Flagstaff was erected in 1854. Its primary use was to display visual signals that could convey messages between land and sea. It was also used to notify the local population of the approach of ships. One of the popular signalling codes in use in the early-to-mid 1800s was the Marryat’s Code but there were others in use as well; there was no one standard code. In 1857 the International Marine Conference adopted an International Code of Signals as a standard communications system for all vessels that could be understood in many different languages. The Normanby Advertiser reported on June 5th 1857 a query from the Post Master General as to whether the request of the Chief Harbour Master would be carried out, in that Warrnambool would receive a new flagstaff and a set of Marryatt’s signal flags. The Table of Codes was published, showing how to use combinations of these flags to send messages. The Code was revised in 1887 to cover situations where distance, light, wind and weather conditions affected the visibility of the flags and prevented clear communication. The first report of the International Code of Signals Committee of 1897 warned signalmen not to rely on ordinary semaphore flags and introduced a Distant Signal Code using either particular semaphore flags or the three-dimensional shapes of a ball, cone and drum that aligned with the semaphore flag shapes of a circle, pennant and square. International Code of Signals In 1931, after World War I’s experiences in using signal codes, the International Code of Signals conference in Washington revised and published the rules for the conduct of signalling. One of the changes was that “the use of the Distant Signals and of fixed semaphore was abandoned”. It is of interest to know that modern marine law in many countries insists that a set of Day Shapes must be carried onboard vessels of a certain size. These highly visible geometric shapes are used at sea in daylight to communicate messages between vessels. They are used in a similar way to the Distant Signals, in that different combinations of shapes represent different messages. The set of shapes includes a ball, cylinder, cone and diamond. The shapes are hung between the top of the vessel’s foremast and the front of the vessel. They are only coloured black and are about 1.5 metres high. The vertical line of shapes can mean messages such as Boat not under command, Fishing, and Under sail and power.Distant Signals were an important means of marine communication from the late 1880s to the early 1930s, including during World War I. They were an advancement to the International Shipping Codes and safety. The cane signals’ shapes appear to be the same from whatever direction they are viewed, removing confusion about the message they convey. The same shapes continue to be used today for the sets of Day Shapes used as marine navigational signals that are mandatory on certain-sized vessels.Distant Signal Ball, part of a Flagstaff signal set. A round woven cane ball, painted black, with a metal rod passing through the centre. The rod has a loop at each end, then a concave, octagonal metal plate that rests on the outside surface of the ball, serving as a washer. The rod has swivels at each end.distant signal, flagstaff signal, signal station, masthead signal, communications, marine technology, signals, marine signals, flaghoists, international marine conference, international code of signals, signal codes, marine safety, signal flags, day shape, daymark, day symbol, navigation, warrnambool flagstaff, 1854, 1857 1931, 1887, 1897

The HMAT A18 Wiltshire (1912-1922) weighed 10,390 tons with an average cruise speed of 13.5 knots or 25.00 kmph. Described as a refrigerated steamship it was b uilt 1912 by John Brown, Clydebank for the Federal S N Co Ltd, London and was propelled by a twin screw, quadruple expansion engine 2 x 4 cylinders each 6500 hp. Owned by the Commonwealth & Dominion Line Ltd, London, it was leased by the Commonwealth until 2 October 1917. It embarked from Egypt on 2 February 1918. On 18 October 1914 at Melbourne embarked the 4th Light Horse Regiment (Victoria) A, B & C squadron & their Machine Gun Section, the 2nd Field Ambulance (Victoria) First Division. The disembarked the 4th Light Horse Regiment in Egypt on 10 December 1914. On 01 November 1914 The Wiltshire assembled with the first convoy at King George's Sound, Albany Western Australia in transporting the first detachment of the Australian and New Zealand Imperial Expeditionary Forces. It completed nine transport voyages from Australia commencing 18 October 1914 until final voyage from Sydney 9th November 1918. During that time The Wiltshire carried the 4th Field Artillery Brigade (Victoria) 2nd Division Artillery and their 1st Reinforcements, 1st Division Ammunition Column 1st Division Artillery 4th Reinforcements, thirty-four Infantry Battalion Reinforcements, the 10th, 11th & 12th Field Artillery Battery (Victoria) 4th Field Artillery Brigades, the 4th Brigade Ammunition Column 4th Field Artillery Brigade, the 1st Siege Artillery Brigade 15th Reinforcements, the 4th Light Horse Regiment (Victoria) A, B & C squadron & their Machine Gun Section, six Light Horse Brigade Reinforcements, the 1st Veterinary Section (New South Wales) 11th Reinforcements, the 1st Mobile Veterinary Section (New South Wales) 1st Division 11th Reinforcements, the 2nd Mobile Veterinary Section (Victoria, New South Wales) 2nd Division 11th Reinforcements, the 1st Cyclist Battalion (New South Wales and Queensland) 3rd Reinforcements, the 2nd Field Ambulance (Victoria) First Division & Medical Officers. After the conclusion of World War One is was wrecked Rosalie Bay, Great Barrier Island New Zealand 31 May 1922 on passage London for Dunedin. Onboard was a crew of 103 plus 1 stowaway, and 10,000 ton of general cargo. No lives lost and is now a well frequented 'Dive' wrecksite. (http://www.flotilla-australia.com/hmat.htm#A18)Photographic postcard of the troopship Wiltshire out at sea.world war one, world war, wiltshire, troop ship, mmm

Climax geared locomotive No. 1694 in active service on special occasions - stored at Emerald Station A Miraculous Survivor Climax locomotive No.1694 is a miraculous survivor of a rare breed of steam locomotive. For about 100 years from the mid-1850s sawn timber was carted from Victorian sawmills to the nearest railway station by timber tramway. These tramways were generally very rough, steeply graded, sharply curved, and of narrow gauge. Many had wooden rails, and horses provided haulage. The better ones used steam locomotives. In all about fifty steam locomotives are known to have worked on Victorian timber tramways. These locomotives were usually somewhat peculiar - made to cope with arduous, rough conditions, rather than speed. Climax locomotive No.1694 is the only one of these locomotives to survive intact. It was built in 1928 by the Climax Manufacturing Company, Corry, Pennsylvania, USA, for the Forests Commission of Victoria. The distinctive feature of the Climax locomotive is that the cylinders do not directly connect to the driving wheels. Instead they drive a cross shaft near the centre of the locomotive. From there the drive is transmitted to the small driving wheels through rotating shafts, universal joints, and bevel gears. The driving wheels are mounted in two four-wheel bogies so that they can easily follow sharp curves in the track. None of these features are found in normal steam locomotives. The result is a locomotive that is extremely powerful for its size, and that will cope with sharp curves and steep grades with ease. But this is at the cost of speed, Climax locomotive No.1694 is just about flat-out at 13 km/h (8 mph). Climax Locomotive Built in 1928 for the Forests Commission of Victoria and painted all-over black with the name CLIMAX painted on the sides of the cab in white block letters, this locomotive was issued to the Tyers Valley tramway which branched off the Moe to Walhalla line at Collins Siding. This locomotive was withdrawn from service in 1949 following the closure of the tramway and in 1950 it travelled from Tyers Junction to Collins Siding to Erica where it remained stored until 1965. Loaned to the Puffing Billy Preservation Society for its Steam Museum, it was taken to Menzies Creek in 1965 where it remained until 1982 when the Emerald Tourist Railway Board bought it and transferred it to Belgrave for restoration. It was returned to service for special use on the Belgrave to Gembrook line in 1988 painted in its original all-over black livery, except that the word “Climax” on the sides of the cab was now painted in the style of the Climax Manufacturing Co., a style that this locomotive had never carried.Historical - Industrial railway - Forests Commission of Victoria, Timber Logging Climax Locomotive Climax geared Steam locomotive made of steel and wrought iron Climax 1694climax locomotive works, climax, geared steam locomotive, puffing billy, climax locomotive no. 1694, steam locomotive

This plaque recognises the Wycheproof servicemen from State School No1757 who served in the 1914-1919 War. The actual large Honour Roll hangs in the old historic Wycheproof State School building.This Honour Roll contributes to and is part of the nation's collection of War Records; it is unique,believed to be the only one of its kind.PHOTO of large Wycheproof School Honour Roll WW1, on wall at the former Wycheproof S.S. No.1757 building - now the Mount Wycheproof Museum. The plaque of solid wood has cylindrical wooden pillars each side of the 55 gold inscribed names - 12 FALLEN servicemen and marked with a +. Raised wooden carved grapes and leaves adorn the top edge. In the centre, on the scroll are dedication words in Honour of the Brave Men From Wycheproof State School. A small wooden cupboard is attached underneath for War Service Records. This photo is in a display Book registered number 02089 at the Court House. Anderson, E. , Anderson, N. , Boyce W. , Bruce R. , Brotherson, H. , + Brotherson, L. , Barker, D. , Beardon, G., Currie N. , Currie, G. , Cutts, R. , Cutts, A. , Chisholm, A. , Cooper, C. , Duckmanton, S. , Dooley, N. , Dooley, J. , Donnelly, T. , Gibb, J.R. +Gregson A. , Hurcules, W. , Hurcules, C. , Hurcules, N. , + Hayes, L. , Hayes, G. , +Hotham, J. , Hindson, E. , Heap, A. , Holloway, V. , Headley, J. , + Kearney, P. , Matheson, H., Matheson, J. , Miles, H. , McDonald, G., McDonald, W., +W., McElphinney, D. , McElphinney, D. , Pratt, A. , + Orrock, P. , + Orrock, A. , + Robinson, S. , Redgen, J. , + Ryan, J.F. , + Slocombe, R. , Stewart, C. , Stewart, R. , Stavely, W. ,+ Sayers, W. , Secombe, W. , Taylor, R. , Tucker, C. , Thomas, R. , Wilson, S. , Ward, P. + Supreme Sacrifice Anderson, E. , Anderson, N. , Boyce W. , Bruce R. , Brotherson, H. , + Brotherson, L. , Barker, D. , Beardon, G., Currie N. , Currie, G. , Cutts, R. , Cutts, A. , Chisholm, A. , Cooper, C. , Duckmanton, S. , Dooley, N. , Dooley, J. , Donnelly, T. , Gibb, J.R. +Gregson A. , Hurcules, W. , Hurcules, C. , Hurcules, N. , + Hayes, L. , Hayes, G. , +Hotham, J. , Hindson, E. , Heap, A. , Holloway, V. , Headley, J. , + Kearney, P. , Matheson, H., Matheson, J. , Miles, H. , McDonald, G., McDonald, W., +W., McElphinney, D. , McElphinney, D. , Pratt, A. , + Orrock, P. , + Orrock, A. , + Robinson, S. , Redgen, J. , + Ryan, J.F. , + Slocombe, R. , Stewart, C. , Stewart, R. , Stavely, W. ,+ Sayers, W. , Secombe, W. , Taylor, R. , Tucker, C. , Thomas, R. , Wilson, S. , Ward, P. + Supreme Sacrifice wycheproof - school, honour roll, world- war-one, wycheproof- servicemen

Yields information about the drawings that were used by the depot or workshop staff as reference drawings. Has a strong association with the depot workshop staff. Yields information about equipment on Ballarat tramcars and Signalling.Folder containing 46 blueprints or Dyeline prints of SEC tram equipment drawings. Front of folder made from a cloth back sheet of paper extended to secure to a thick cardboard runner. Rear of folder made from an old tram advertising panel or cardboard sheet, cut to size and secured to a thick cardboard runner with a cloth backing on both sides. Sheets secured with three brass screwed clips. Front cover damaged in bottom right hand corner. Rear cover breaking apart on outside around cloth binding. Heavy dirt marks from “grease” on bottom half of rear cover. Contains 46 drawings which have been individually catalogued and numbered on the rear of each drawing within the folder. Some of the drawings have been folded. Reg Item Micro Film No. Old BTPS No. SEC Drawing No Title 4807 42/4 1 VB4/8103C Westinghouse T1F Controller Main Cylinder Segments. 4867 47/2 2 BA-T8-8128 Westinghouse 225N Motor Case Bolt 4830 22/3 B 3 BA-T7-7666 Half Ball Brake Hanger Link, Driving Wheel, Brill Maximum Traction Truck 22E 4868 44/3A 4 BA-T8-8113 Split Suspension Bearing for Type W225 Motor (Westinghouse) 4869 52/2 5 BA-T8-8158 Contact Tips for G.E. Compressor Controller 4818 52/3 6 BA-T8-8159 GE B-23 Contact Finger Tips for G.E. Type ‘B’ Main Cylinder 4870 6/1 7A BA-T3-6734 Brass Nut for Switch Mechanism 4829 6/2 7B BA-T3-6735 Tongue Clip Link for Switch Mechanism 4871 6/3 7C BA-T3-6736 Fulcrum for Switch Mechanism 4872 6/4 7D BA-T3-6737 Plunger for Switch Mechanism 4832 7/6 8 BA-T3-6754 Pivot for Switch Mechanism No numbers 9 or 10 4873 17/5 11 BA-T7-7639 Detail of Motor Pinion for Brill Cars 4831.2 21/4 B 12 BA-T7-7661A Half Ball Hanger Links – single bogie trucks 4874 21/6 13A BA-T7-7663 Axle Box Inner Spring Driving Wheels Maximum Traction Truck 22E 4875 22/1 13B BA-T7-7664 Axle Box Outer Spring Driving Wheels Maximum Traction Truck 22E 4876 22/2 14 BA-T7-7665 Body Spring Brill Maximum Traction Truck 22E 4830.2 22/3B 15 BA-T7-7666A Half Ball Brake Hanger Link Driving Wheel Brill Maximum Traction Truck 22E 4877 22/4 16 BA-T7-7667 Body Spring, Brush Maximum Traction Truck 22E 4820.2 22/6 A 17 BA-T7-7669 Wear cups for Half Ball Brake Hanger Links, Single & Double Bogie Trucks 4878 50/5 18 BA-T8-8149 Connections of Line Breaker and Ratchet Switch for use with Drum Controller 4879 74/6 19 BA-T13-8757/9 Signal boxes, Back of Panel Wiring and External Connections 4880 45/1 20 BA-T8-8116 Trolley Harp 4806 15/3 21 BA-T7-7625 Equalizing Lever, Fulcrum, Brill 21 E truck 4881 15/5 22 BA-T7-7626A Brake Beam Fulcrum Brill 21E truck 4808 16/1 23 BA-T7-7628 Pinion Remover, GE 201G and GE 202 motors 4882 16/3 24 BA-T7-7630 Spring Posts, Brill 21E Truck 4883 21/3 25 BA-T7-7660 Brake Shoe Holder, Driving Wheel, Maximum Traction Truck Brill 22E 4884 21/5 26 BA-T7-7662 Brake Rod Guide, Single Bogie Trucks 4885 22/5 27 BA-T7-7668 Brake Shoe Holder, Pony Wheel, Maximum Traction Truck Brill 22E 4809 42/2 B 28 BA-T8-8101 Trolley Wheel and Axle 4815 42/1 B 29 BA-T8-8102A Motor Suspension Bearing, GE 202 Motor 4796.2 42/5 30 BA-T8-8104 Connection Diagram WH 225N Motor 4886 42/6 B 31 BA-T8-8105B Motor Suspension Bearing, GE 201 Motor 4797.2 48/6 32 BA-T8-8137 WH T1F Controllers 4816 49/2 33 BA-T8-8138 Connection Diagram GE 202 Motor 4887 49/3 34 BA-T8-8139 Connection Diagram K-36-J Controller 4888 50/3 35 BA-T8-8146 GE K-36-JR Controllers, with line breaker (Connection diagram) 4889 50/6 36 BA-T8-8150 Commutator for Westinghouse 225N Motor 4846 51/1 37 BA-T8-8151A Armature Bearing Lining, Commutator End, Type GE 201G Motor 4813 51/2 38 BA-T8-8152 Armature Winding Diagram Westinghouse 225 Motor 4840.2 51/40 39 BA-T8-8154A Armature Bearing Lining, Pinion End, Type GE201G Motor 4890 51/6 40 BA-T8-8156 Armature Bearing Lining, Pinion End, Type GE202A Motor 4891 52/1 41 BA-T8-8157A Armature Bearing Lining, Commutator End, Type GE202A Motor 4892 64/5 42A BA-T9-8392A Step Hangers, Single and Double Bogie Trucks, Hinged Type 4785.2 64/6B 42B BA-T9-8392/1A Step Hangers, Single and Maximum Traction Trucks, Fixed Type 4812.2 43/1 43 BA-T8-8106B GE K36J Controller, Main Cylinder Segments 4893 50/2 44 BA-T8-8145A GE B23E Controller, Main Cylinder Segments 4816 65/2 45 BA-T9-8394B Door Lock for Motorman’ Cabin Maximum Traction Trucks. 4810 73/3 46 BA-T13-8757 Ballarat Electric Tramways Signalling System, Arrangements & Details of Box.On front cover of folder, "1 - 46"trams, tramways, drawings, ballarat, sec, depot, workshops

28 sheets contained within a folded buff coloured cover secured with folded metal clips and washers, titled "Air Brakes for Tramways". Published by the Westinghouse Brake & Saxby Signal Co. Ltd. of 82 York Road, Kings Cross London in 1933/34. Contains various data sheets for various Westinghouse brake system components. Cover sheet with index. Air brakes for Tramways - June 1934 - fold out sheet and single sheet - DP12. Interconnection of air and magnetic track brakes - June 1934 - fold out sheet and a single sheet - DP12a Motor Driven Air compressor - type DH - March 1933 - four sheets - DP1 Air Compressor type E13 - June 1934 - two sheets - DP18 Electric compressor Governor's - ES16, ES16C and NS16 - April 1934 - six sheets - DP7 Drivers Brake Valve No. 9 - July 1934 - one sheet - DS7 Improved self lapping Driver's Brake Valve - October 1933 - two sheets - DP27a Westinghouse Air brake cylinders - April 1934 - two sheets -DP35 Quick Release Valve - June 1934 - 1 sheet - DS18 Double Check Valve - July 1934 - 1 sheet DS8 Double Check Valve No. 19 - June 1934 - 1 sheet DS8a Conductors Emergency Valves - June 1934 - 2 sheets - DP37 Pneumatic Sanding apparatus - July 1934 - 1 sheet DS11 Safety Valve Type N - June 1934 - 1 sheet DS17. Contents scanned to COTMA Web site 5/2/2011."Colin Rutledge" stamped on top of page 1 and date stamp of "The Westinghouse Brake Co. Ltd. Melbourne 17 Dec 1934" on front cover.trams, tramways, westinghouse, tramcar brakes, compressors, governors, equipment

It took 15 years to invent the can. It took 100 more to invent a standard way to open it. In the 19th century, decades after the invention of canning, there were virtually no can openers. Canned food, such as sardines, came with its own "key" to peel back the tin lid. Birth of the can One of the oddest things about the can opener is that the can predates it by almost 150 years. Though common today, cans were once military-grade technology. In 1795, Napoleon, to whom the phrase "an army marches on its stomach" is attributed, offered 12,000 francs to anyone who could find a way to preserve food. Without any knowledge of bacteria or their role in food spoilage, scientists didn't even know where to begin. It took 15 years before a chef named Nicholas Appert claimed the prize after successfully jarring food. Soon after that, his countryman Philippe de Girard came up with a variant on Appert's method—metal tins—and sold the idea to the British. Spoiled food, and the sickness it caused, was a widespread problem. The public would have benefited from canned food, but for decades cans were almost exclusively for the army and the navy. The canning process, with its hours of boiling and steaming, its scrupulous cleanliness, its heated metal, and its need for a great deal of disposable material, made canned food far too expensive for anyone but the military. No can openers were needed or even possible. The metal of early cans was too thick to make openers practical. Soldiers and sailors had plenty of sharp objects on hand and made ample use of them when they wanted to eat. During the 19th century, the process of canning was refined and mechanised, and the metal wall of the average can slimmed down enough that a civilian could get it open—if that civilian had the right tool. No one had that tool yet, so early cans had to open themselves. In other words, they came with built-in openers. The result was a confusing but pleasing free-for-all, in terms of product engineering. Each type of food came with its own kind of can, and each kind of can came with its own kind of opener. Tinned fish and meat were often sold in rectangular cans. These cans were fitted with a "key" that would roll down the top of the can. Coffee, beans, and other types of meat were packaged in cylinders with metal strips that could be peeled back with their own kinds of built-in keys. Cans of milk, which didn't need to be completely opened, came with puncture devices. As tinned food became more common, its containers became more regular. A nice cylindrical can became the norm, and, as these cans filled kitchens, more engineers put their minds to finding a convenient way to open all of them. The first standalone can opener worked on a simple principle: point, stab, and pull. From the mid-19th century to the end of World War I, the typical can opener looked roughly like a wrench, if the lower 'jaw' of the wrench were replaced with a blade. People used the blade to puncture the top of the can near its edge, push the upper jaw against the side of the can, and drag the blade through the metal along the rim. Because meat was the first and most popular canned substance, these can openers were often shaped to look like cows and given the nickname 'bully beef can openers'. The bully beef can opener, popular in the mid-19th century, resulted in many lost fingers. Later, a corkscrew was added that was seated in the handle, and could be pulled out for use. Bully beef can openers were so common, effective, and sturdy that they are still frequently available on collectors' sites. Some are advertised as “still working,” and every last one of them is, without a doubt, soaked in the blood of our ancestors. Dragging a sharp blade along the edge of a can is certain to cause injury sooner or later. So once people got a reliable can shape and a reliable way to get the can open, the search was on for a reliable way to get a can open without the possibility of losing a finger. The answer came in 1925, from the Star Can Opener Company of San Francisco. This is probably the first can opener that resembles the one people have in their kitchens today. Instead of using a blade to pry open a metal can, buyers could clamp the edge of the can between two wheels and twist the handle of one of the wheels to move the blade around the lip. The Star can openers weren't perfect. Compared to the bully beef model, they were flimsy and breakable, but they probably prevented a few injuries. Six short years after the Star model came to market, the first electric can opener was invented. It was patented in 1931 by the Bunker Clancey Company of Kansas City, who had already been sued by the Star Can Opener Company for trying sell a double-wheeled can opener like the Star model (the case was dismissed). The electric can opener must have seemed like the wave of the future and a sure-fire seller, but it proved to be too far ahead of its time. In 1931 not that many households had electricity, and those that did weren't interested in buying can openers. The Bunker Clancey Company was subsequently bought by the Rival Company, which still makes small appliances like can openers today. It took another 25 years for electrically powered can openers to become practical. In the 1950s, Walter Hess Bodle and his daughter, Elizabeth Bodle, developed an electric can opener in the family garage. Walter came up with the opener's blades and motor, and Elizabeth sculpted the outside. Their can opener was a free-standing unit that could sit on the kitchen counter. The Udico brand of the Union Die Casting Company put it on the market in time for Christmas in 1956 and had great success with it. Over the next few years it came out in different styles and colours, and, like the bully beef can opener, has become a collector's item. Also like the bully beef model, Udico can openers often still work. They don't make 'em like they used to. Although there have been some design changes and refinements over the last sixty years, there have yet to be any more leaps forward in can opener technology. If you're resentfully opening a can, you are almost certainly doing it using the Star design, manually forcing the can between two wheels, or the Bodle design, clamping the can into a free-standing electrical opener. Whether or not you enjoy your holiday meals, at least you can be happy that you are not getting poisoned by your own food or cutting open your hand with the blade you use to get at it. That's something, right?The can opener, Bottle opener and the corkscrew are still very important and essential items in most kitchens.Metal can opener, chromed, with bottle opener, and a corkscrew seated in the handle.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, canning, can opener, corkscrew, bottle opener, kitchen equipment

It took 15 years to invent the can. It took 100 more to invent a standard way to open it. In the 19th century, decades after the invention of canning, there were virtually no can openers. Canned food, such as sardines, came with its own "key" to peel back the tin lid. Birth of the can One of the oddest things about the can opener is that the can predates it by almost 150 years. Though common today, cans were once military-grade technology. In 1795, Napoleon, to whom the phrase "an army marches on its stomach" is attributed, offered 12,000 francs to anyone who could find a way to preserve food. Without any knowledge of bacteria or their role in food spoilage, scientists didn't even know where to begin. It took 15 years before a chef named Nicholas Appert claimed the prize after successfully jarring food. Soon after that, his countryman Philippe de Girard came up with a variant on Appert's method—metal tins—and sold the idea to the British. Spoiled food, and the sickness it caused, was a widespread problem. The public would have benefited from canned food, but for decades cans were almost exclusively for the army and the navy. The canning process, with its hours of boiling and steaming, its scrupulous cleanliness, its heated metal, and its need for a great deal of disposable material, made canned food far too expensive for anyone but the military. No can openers were needed or even possible. The metal of early cans was too thick to make openers practical. Soldiers and sailors had plenty of sharp objects on hand and made ample use of them when they wanted to eat. During the 19th century, the process of canning was refined and mechanised, and the metal wall of the average can slimmed down enough that a civilian could get it open—if that civilian had the right tool. No one had that tool yet, so early cans had to open themselves. In other words, they came with built-in openers. The result was a confusing but pleasing free-for-all, in terms of product engineering. Each type of food came with its own kind of can, and each kind of can came with its own kind of opener. Tinned fish and meat were often sold in rectangular cans. These cans were fitted with a "key" that would roll down the top of the can. Coffee, beans, and other types of meat were packaged in cylinders with metal strips that could be peeled back with their own kinds of built-in keys. Cans of milk, which didn't need to be completely opened, came with puncture devices. As tinned food became more common, its containers became more regular. A nice cylindrical can became the norm, and, as these cans filled kitchens, more engineers put their minds to finding a convenient way to open all of them. The first standalone can opener worked on a simple principle: point, stab, and pull. From the mid-19th century to the end of World War I, the typical can opener looked roughly like a wrench, if the lower 'jaw' of the wrench were replaced with a blade. People used the blade to puncture the top of the can near its edge, push the upper jaw against the side of the can, and drag the blade through the metal along the rim. Because meat was the first and most popular canned substance, these can openers were often shaped to look like cows and given the nickname 'bully beef can openers'. The bully beef can opener, popular in the mid-19th century, resulted in many lost fingers. Bully beef can openers were so common, effective, and sturdy that they are still frequently available on collectors' sites. Some are advertised as “still working,” and every last one of them is, without a doubt, soaked in the blood of our ancestors. Dragging a sharp blade along the edge of a can is certain to cause injury sooner or later. So once people got a reliable can shape and a reliable way to get the can open, the search was on for a reliable way to get a can open without the possibility of losing a finger. The answer came in 1925, from the Star Can Opener Company of San Francisco. This is probably the first can opener that resembles the one people have in their kitchens today. Instead of using a blade to pry open a metal can, buyers could clamp the edge of the can between two wheels and twist the handle of one of the wheels to move the blade around the lip. The Star can openers weren't perfect. Compared to the bully beef model, they were flimsy and breakable, but they probably prevented a few injuries. Six short years after the Star model came to market, the first electric can opener was invented. It was patented in 1931 by the Bunker Clancey Company of Kansas City, who had already been sued by the Star Can Opener Company for trying sell a double-wheeled can opener like the Star model (the case was dismissed). The electric can opener must have seemed like the wave of the future and a sure-fire seller, but it proved to be too far ahead of its time. In 1931 not that many households had electricity, and those that did weren't interested in buying can openers. The Bunker Clancey Company was subsequently bought by the Rival Company, which still makes small appliances like can openers today. It took another 25 years for electrically powered can openers to become practical. In the 1950s, Walter Hess Bodle and his daughter, Elizabeth Bodle, developed an electric can opener in the family garage. Walter came up with the opener's blades and motor, and Elizabeth sculpted the outside. Their can opener was a free-standing unit that could sit on the kitchen counter. The Udico brand of the Union Die Casting Company put it on the market in time for Christmas in 1956 and had great success with it. Over the next few years it came out in different styles and colours, and, like the bully beef can opener, has become a collector's item. Also like the bully beef model, Udico can openers often still work. They don't make 'em like they used to. Although there have been some design changes and refinements over the last sixty years, there have yet to be any more leaps forward in can opener technology. If you're resentfully opening a can, you are almost certainly doing it using the Star design, manually forcing the can between two wheels, or the Bodle design, clamping the can into a free-standing electrical opener. Whether or not you enjoy your holiday meals, at least you can be happy that you are not getting poisoned by your own food or cutting open your hand with the blade you use to get at it. That's something, right?The can opener is still a very important and essential item in most kitchens.Can opener, right handed, metal, upper blade section serrated, inscription 'Peerless Pat.Feb 11-90'.Peerless Pat.Feb 11-90flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, cannning, can opener, kitchen equipment

The tuck making tool is part of a set of tools and Instructions for a Wertheim New High Arm Sewing Machine as well as the "B' Medium, Cylinder Arm and Titania Machines. This sewing machine accessory was donated with our collection's Wertheim sewing machine accessory box. The box contains twelve accessories, the instruction book and the receipt for the purchase of a Wertheim sewing machine. The receipt was written on July 23rd 1891 by the Wertheim distributor in Melbourne, Hugo Wertheim. His business was the Wertheim Sewing Machine and Hapsburg Piano Depot, trading at 173 Williams Street, Melbourne. The purchaser was Mrs Burrowes from Burrumbeet, Victoria, a district northwest of Ballarat. She paid £6-6 (six pounds and six shillings) in cash. The receipt was signed by H. Wertheim and the other signatory looks like John A. Cherry. Hugo Wertheim (1854-1919) was an agent for his father’s cousin Joseph Wertheim, a well-established sewing machine manufacturer in Germany. He was born in Lispenhausen, Germany, and migrated to Melbourne in October 1875, where he opened a merchandising business at 39 Flinders Lane East. He returned to Germany in 1885 to marry Joseph Wertheim's daughter Sophie Emilie. The couple came back to Melbourne, and Hugo quickly established a substantial business selling sewing machines, bicycles, pianos and other mechanical devices, under brands such as Wertheim, Electra, Planet, Griffin and Hapsburg. He exhibited at agricultural shows and in 1901 at the Pan American Exposition, Buffalo, United States of America. One of his staff was O. C. Beale, who later set up his own piano business in New South Wales. Hugo continued to own 25 per cent of one of Beale's companies, which became Wertheim's Queensland business. In 1908 Hugo Wertheim opened a piano factory in Richmond, Melbourne, aiming to produce 2000 pianos and player pianos a year, predominantly using Australian materials. In laying the foundation stone, Prime Minister Alfred Deakin observed that “few men with such opportunities for a life of ease would have embarked on such an enterprise” Hugo died of chronic hepatitis in 1919 at his home in South Yarra. His eldest son, Herbert Joseph (1886-1972), continued the business. The piano factory closed in 1935, becoming a Heinz food processing plant and in 1955, GTV Channel 9 studios and offices. The Wertheim Sewing Machine Company – Joseph Wertheim (1804–1899) founded the company in 1868 in Frankfurt, Germany. At this time Joseph was the Frankfurt city delegate for the Democratic Party. At its height, the Wertheim factory employed approximately 650 workers. The company used a trademark of a dwarf holding a hammer which is known to have been used until at least 1925, however in 1909 a Star of David was also registered. In 1870 a Wertheim subsidiary was formed in Barcelona, Spain. The business imported and sold complete machines, including the English Jones machine. Locals began calling the sewing machines “las rapidas”, and the business became known as “las casa de las rapidas”. In 1915 production began of a totally manufactured Spanish Wertheim machine. Wertheim in Germany continued manufacturing machines until 1932 when the Wertheim family fled to Spain. Despite converting to Christianity from Judaism, they feared the political unrest in Germany during that time. Wertheim Spain became Rapida SA and was then the sole manufacturer of the Wertheim machines. The factory was managed by Karl Wertheim under the alias Carlos Vallin. The sewing machine accessory is part of a donation that connected to domestic life in 1891 during the Victorian era. It is significant for connecting the Melbourne distributor of Wertheim sewing machines, Hugo Wertheim, to Victoria’s northwest district where the purchaser lived. It is also significant for connecting the Melbourne distributor to the importing of goods from the well-known German manufacturer of early domestic sewing machines, Joseph Wertheim. Tuck marker or creaser for a Wertheim sewing machine. Made by Joseph Wertheim , Germany, and distributed by Hugo Wertheim, William Street Melbourne. Circa 1891flagstaff hill, flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, sewing machine tool, sewing machine accessory, tucker, tuck maker, creaser, wertheim, joseph wertheim, germany, hugo wertheim, victorian era, sewing machine, wertheim sewing machine and hapsburg piano depot, wertheim sewing machines, domestic machines, dressmaking, home industry, fashion

This is a set of 16 photograph of the Royal Australian Survey Corps’ Johnson Ground Elevation Meter (JGEM) Survey Vehicle taken at the Army Survey Regiment, Fortuna, Bendigo. The JGEM vehicle was extensively used by RA Svy within Australia from the late 1960s. A limited number of Ground Elevation Meter (GEM) station wagon type vehicles were manufactured by General Motors Corporation (GMC) in the USA for the United States Geological Survey, Canada’s mapping agencies, RA Svy and National Mapping (Natmap). The GEM was a four-wheel drive, four-wheel steer vehicle. Four-wheel steering was necessary to avoid systematic errors caused by non-tracking of front and rear wheels on conventionally steered vehicles. The manufacturer substituted the rear axle with a front axle and connected them to form the four-wheel steering mechanism. The two Australian GEM vehicles, referred to as Johnson GEMs (JGEMs) were converted into right-hand drive. After delivery in 1964, acceptance Natmap and RA Svy testing and operator training was undertaken at the Army's School of Military Survey located at Balcombe, Victoria. A small fifth wheel was mounted on a cantilever arm suspension midway between the front and rear wheels on the right side of the vehicle. It was lowered to and raised from its operating position by use of a constant pressure air cylinder. A telescopic bar, suspended between the front and rear axles, provided the reference datum for the angle measurement. The wheel provided the velocity or distance signal through a pulse generator system. A sensitive pendulum mounted on this bar provided the angle measurement for each minute distance traversed. The JGEM contained electromechanical instruments used to determine relative elevations, by trigonometric principles, along a traversed path. These relative elevations were obtained through apparatus which measures the instantaneous angle of inclination of the road and the instantaneous velocity of the meter along such a path. Road routes over which the JGEM operated were planned so that each started and ended as near as practicable to an existing point of known elevation (formally referred to as a level traverse bench mark). The difference in height from the bench mark and the road surface alongside the JGEM’s fifth wheel was measured with a level and staff. Along each route, mapping control photo reference points where new elevation values were required were identified on aerial photographs. Under favourable conditions it was possible to survey as much as 160km in an ordinary working day. The first of RA Svy’s JGEM operations was undertaken in 1:250,000 scale map areas of Queensland. CPL John Hook was the JGEM’s main operator in the early 1970s undertaking operations covering 1:250,000 scale map blocks over northern Victoria and central NSW, each requiring 36 points (9 runs of photography and 4 points across. SPR Lyn Thompson and SPR Bob McDonagh teamed with CPL Hook on some of these JGEM operations. When RA Svy was integrated into the Royal Australian Engineers in 1996, the JGEM vehicle with the Survey Corps collection was donated to its museum. It is believed to be the last of the original manufactured fleet in existence. The JGEM has undergone extensive refurbishment to achieve roadworthiness and is currently housed at The Australian Army Museum of Military Engineering, Hoslworthy Barracks, NSW. It can be viewed by making an appointment with the museum’s curator.This is a set of 16 photograph of the Royal Australian Survey Corps’ Johnson Ground Elevation Meter (JGEM) Survey Vehicle taken at the Army Survey Regiment, Fortuna, Bendigo. The photographs were on 35mm slide film and were scanned at 96 dpi. They are part of the Army Survey Regiment’s Collection. .1) - Photo, colour, c1960s, Johnson Ground Elevation Meter (JGEM) Survey Vehicle .2) - Photo, colour, c1960s, JGEM instrumentation, on-board computer. .3) - Photo, colour, c1960s, JGEM instrumentation. .4) - Photo, colour, c1960s, JGEM instrumentation, on-board computer. .5) - Photo, colour, c1960s, JGEM tyre pressure controller .6) - Photo, colour, c1960s, JGEM rear doors, SGT Geoff Briggs. .7) - Photo, colour, c1960s, JGEM 5th wheel distance/angle measurement device in lowered position, SGT Geoff Briggs. .8) - Photo, colour, c1960s, JGEM 5th wheel distance/angle measurement device in lowered position. .9) & .10) - Photo, colour, c1960s, JGEM tyre pressure system, SGT Geoff Briggs. .11) - Photo, colour, c1960s, JGEM tyre pressure system. SGT Geoff Briggs. .12) - Photo, colour, c1960s, JGEM levelling scope, levelling staff, unidentified technicians. .13) & .14) - Photo, colour, c1960s, JGEM levelling scope, unidentified technician. .15) & .16) - Photo, colour, c1960s, probably survey operation adjusted height plotted on block base sheet. .1P to .16P - Some of the equipment is annotated on the frame of the 35mm slides.royal australian survey corps, rasvy, army survey regiment, army svy regt, fortuna, asr, surveying

Yields information about the preparations undertaken by the Ballarat Fire Brigade to form a welcoming arch for a visiting Governor General..Digital image from the Wal Jack Ballarat Album of Ballarat No. 20 passing under the two LaFrance fire brigade ladders forming an arch outside the Ballarat City Fire station on 8/3/1955 to greet the Governor General Sir William Slim, Sturt and Raglan Streets. Wal's album notes say "No. 20 passing under 2-100' extension ladders as an arch to welcome Sir William Slim, Governor General. Sturt and Raglan St 8-3-1955." See image i2 for rear of photograph. See image i3 for hi res scan of print. See image i4 for hi res scan of negative\ Neville Britton of the BTM advised 2/5/2020: Seven LaFrance 100' ladders built by the American LaFrance Company, of Elmira, New York arrived in Australia in 1942 as part of the WW2 lend lease program. One each to Perth, Brisbane and Adelaide. Four initially to the MFB but within a short period of time went to the CFA. One each to Geelong City FS, Ballarat City FS and Bendigo FS. The fourth was a stand in and was located at the Ballarat FS when not required. Thus the two ladders in the photo at the Ballarat City FS. I was a volunteer at Ballarat City FB from 1967 and commenced my career employment there in 1970. The two LaFrance ladders were still in Ballarat at that time. In the mid 70's the 'spare' was allocated to the Dandenong FS. They were retired in the 1980's. The four Victorian ladders still survive. Ex Geelong City is at the Fire Services Museum Victoria. They have a second one that was acquired by a private collector. It was neglected and returned to the FSMV in poor condition. Ex Ballarat City was driven to Sydney and remains at the Museum of Fire at Penrith. The fourth one was acquired by a private collector and stored in a shed in North Geelong and never moved. He recently died and it may have been sold. They had a V12 petrol engine with all ignition parts duplicated. So two Distributors, two ignition coils and two spark plugs per cylinder. Splash feed engine lubrication.On rear in ink. Top right hand corner "T175" within the Wal Jack stamp. "SEC Ballarat No. 20 passing under the two LaFrance yank extension ladders ( to greet the Governor General Sir William Slim) Sturt and Raglan Streets. and the date "8 Mar 1955"trams, tramways, sturt st, governors, fire station, ceremonies, tram 20

In the 1650s, the newest exciting development had arrived on Britain’s shores, this time it was tea from China. As it was brought back from overseas, tea was incredibly scarce and as such its price was very high; in 1664, the cost of tea was already 40s per pound, although this is not as high as what it would become when taxed in the 18th century. This resulted in only the social elite enjoying a cup of tea, and most commonly tea was enjoyed in coffee houses, and teapots were therefore not yet a household item. As the East India Company imported larger quantities of tea, it became more widely available and a larger section of the British population were able to enjoy it meaning that, by 1669, tea was available nearly everywhere. Likely due to the fact that tea was first enjoyed in coffee houses, the first known teapot resembles a coffee pot, with a tapering cylindrical shape and standing much taller than what we now know as a teapot at 13.5 inches tall. Into the 1680s, these teapots were given a conical cover for the spout that was fixed to the pot via a chain. As Queen Anne took the throne in 1702, teapots had become much more widely used and had formed two common groups. The first style of teapot was the pear shaped style which began to appear in 1705. The pear shaped pot usually had a domed lid and sometimes featured a finial. This form was generally supplied with a heater and stand as well as having a baluster shaped handle on one side. This iteration would disappear by 1725 but does make a reappearance in the 1740s, only this time as an inverted pear shape. The second group was the more spherical, or globular, shape which appeared in 1710. The globular teapot had a flush, hinged lid as well as a narrow moulded rim foot and a straight sided, tapering spout. Both generalised groups of teapots have polygonal examples – that is, teapots that are made up of straight sided segments – but six or seven sided teapots are incredibly rare. There is one known example of a seven sided globular teapot, made by Isaac Ribouleau in 1724. This is so unique because polygonal teapots are much more technically difficult and time consuming to make. Other than the occasional band of engraving round the shoulder of the teapot, they remain quite plain until c.1740 when scrollwork and chased shells begin to be applied for decoration. ‘Chasing’ is the process of decorating the front of a piece of metal by indenting the back, without cutting or engraving. From 1755 until 1770, silver teapots became incredibly uncommon and it is likely that this either reflects a change in drinking habits or changing trends producing a favour for porcelain. This dip in popularity could also be in response to the outrageous taxes placed on tea, up to 119%! In 1765, the Leeds creamware globular teapot seemed to kickstart a resurgence and this, combined with the Commutation Act of 1784 – which reduced tax on tea from 119% to 12.5% – saw teapots return in all their forms. It’s around this time, in 1780, that a form of teapot with a detachable, openwork stand appeared; however, the plain, oval teapot remained the most popular in the 1780s and 90s. In the later years of George III’s tenure on the throne, during the last decade of the 18th century, there was a revival of chasing and embossing teapots with flower and foliage designs. At the turn of the century, the spherical, partly fluted teapot with classical decoration was superseded by a more oblong shaped pot that sat on four spherical feet. This was then changed again when teapots became more melon shaped. It was at this time that the capacity of a teapot greatly increased and the previously wooden or ivory handles were replaced by silver handles with ivory washers for insulation. As Britain entered into the Victorian era, the design quality often suffered as there was a tendency to over-decorate the silver. In the early 19th century, the last major addition to the shape of the teapot, a raised collar was added between the cover and body. Whilst this seems to just be for decoration, there is some speculation that it could also be to prevent overspills. https://www.marklittler.com/silver-teapots-history/ This item shows that silver and silver plated teapots were used for tea making.Plain sliver teapot. Heavy oxidation. Dented.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, teapot, silver, siver plate, tea

John Glass Cramond 1829 and James Dickson 1831-1910 were founders of a large drapery store. Both were Scots and both came separately to Australia in 1852. Cramond initially came for gold but soon opened a store in St Kilda with a post Office attached and he was the first post master there. Dickson was a farmer’s son but became a draper and while he was unsuccessful on the Bendigo diggings and then returned to Melbourne where he met Cramond and soon after they opened a store on Lonsdale Street. They opened their business in Warrnambool in 1855 as a general store with groceries, drapery and ironmongery. Both partners were involved with the community and James Dickson was an original director of the Warrnambool Woollen Mill 1909 and the Warrnambool Cheese and butter factory. He also served on the committee of management of Warrnambool Base Hospital. This case was a wedding gift from James Dickson Jnr to his wife Mary Glass Cramond on the occasion of their wedding. This item has significance on a number of levels. It belonged to a member of one of Warrnambool’s earliest pioneering families and it marks the occasion when the two families of Cramond and Dickson were linked through the marriage of James Dickson jnr and Mary Glass Cramond. The firm played a significant part in the development of the city and traded for nearly 150 years. It therefore has social significance to Warrnambool. The item is well provenance with the case initialed and items within the case monogrammed. The case and its items are aesthetically quite beautiful as well as being typical of travelling or dressing cases of the more well to do, of the time. Mappin & Webb were manufacturers of some standing with the Mappin name appearing in manufacturing as early as 1775.The company has held a royal warrant as silversmiths since 1897 to the present day and as crown jeweler since 2012. Throughout this time, they have manufactured quality items for the luxury market. It provides an insight into the way ladies travelled and the items which they considered essential. This consists of a black leather with leather handle attached with brass fittings. Middle opening with side pocket on one side with metal catches. Inside has removable sections for holding the numerous containers and items belonging to the case. Interior of the case is dark blue satin. The items contained within the case are as follows: 321.1 Luggage case 321.2 Glass bottle rectangular, silver monogrammed lid, empty. 321.3 Tall round glass bottle, silver monogrammed lid, empty. 321.4 Small glass bottle with pink powder, silver monogrammed lid. 321.5 Small multi sided bottle with stopper and brass hinged lid. 321.6 Tall round bottle with silver monogrammed lid. 321.7 Tall thin multi sided bottle with brass lid. 321.8 Cream coloured monogrammed jar cotton wool inside. 321.9 Clothes brush rectangular cream back. 321.10.1Glove stretcher bone coloured .10.2 Case black leather. 321.11.1 hair comb cream with silver edge .11.2 Case black leather 321.12 Hair brush cream handle 321.13Spatula cream monogrammed 321.14 Mirror, silver round with handle. 321.15 Writing compendium .1 Case black leather .2 Pen with nib .3 Lead pencil .4 Navy satin covered blotting book 321.16 Inkwell glass bottle in small black leather case. 321.17 Match striker in leather case. 321.18 Mirror in black leather case rectangular 321.19 Small case for visiting cards. 321.20Sewing kit rectangular, contains threads and needles pkts x 3 321.21Container, small, hinged tortoise shell patterned. 321.22.1 Manicure set .2 Scissors small .3 Scissors large .4Corkscrew with Mother of pearl handle .5 Pocket knife with Mother of pearl handle .6Tweezers with Mother of pearl handle .7 File with Mother of pearl handle .8 Fine hook Mother of pearl handle .9 Bodkin .10 Bodkin 321.23 Hairbrush oval silver backed 321.24 Mirror silver handled hand mirror. 321.25 Hairbrush wooden handled with Mother of pearl inlay. 321.26 Cylinder, silver with removable lid and small phial of iodine labelled Felton’s pocket iodine. 321.27 Phial small glass with gold decorations. 321.28 Inhaler with insert 321.29 Thimble, metal. 321.30 Silver backed hair brush 321.31 silver backed clothes brushEngraved on side pocket: M.G.D. Mappin and Webb Sheffield and London. Some of the items are monogrammed as per the list above. A number of the glass bottles have lids hallmarked Mappin & Webb London and Sheffield makers stamped inside lid with hall marks history of warrnambool, cramond and dickson, mary glass cramond, dressing bag, woman's toiletry bag 1880

Edna Barrie at the cairn, photo received from Graeme Minns in 1988. The cairn marks the site of Jimmy Melrose's plane crash in Melton South. The accident which happened on July 5th 1936. In 1934 Melrose made headlines with a series of spectacular flights. In July of that year, he set around Australia record and in that year established a new solo Australia England record when he flew to England to compete in the MacRoberston race with a De Havilland Puss Moth VH- YQO. The only Australian and the only solo pilot to complete the course within the time limit. He was seventh in finishing order and third in the handicap section making news again during the race with a dramatic landing in Darwin with empty fuel tanks. Late in 1935 Melrose imported the Phoenix for his “Adelaide to Anywhere” Charter Service. The previous year the Heston Aircraft Company had taken over the interests of the well known Comper Aircraft Company, and the first production of the new firm was the Phoenix, a single-engined all wooden five seater machine of sesquiplane configuration. The forward half of the fuselage was a streamlined rectangular section and the rear portion was a monocogue shell; the whole was of plywood fabric covered. The wing was built up of spruce box spars and lattice ribs, ply covered from the leading edge to the front spar and the fabric covered over the remainder. The tail surfaces were of similar construction. The most notable feature of the design was the lower stub wing which ran right across the fuselage embodying two box spars, plywood covered it housed the main undercarriage wheels when retracted and provided a substantial anchorage for the Nu form wing struts. The Dowty undercarriage retracted inwards, operated manually by hydraulic packs, Dual control fitted, with side by side seating for the pilots and three passenger seats behind. Power was a 200 h.p. De Havilland Gipsy VI 6 cylinder inverted in-line air-cooled engine. Six Phoenix were built; five of them registered in Great Britain and one of those was later sold abroad the remaining four were impressed into the R.A.F. in 1940. Specifications were: 40 feet 4 inches length 30 ft 2 ins height, 9ft 7ins, wing area 270 sq ft, Tare weight 2,600lbs loaded weight 3,300lbs; cruising speed 360 m.p.h. landing 50mph ceiling 14,000 ft range 700 miles. Melrose’s machine the first production aircraft was built early in 1936 and test flown of the 24th March. Painted green it carries the words “South Australian Centenary 1936” in silver of the fuselage and the name “Billing on the engine cowling in honor of Melrose’s uncle Noel Pemberton Billing, pioneer designer and founder of the Supermarine Aviation Company. The delivery flight was planned as a goodwill mission to publicise the forthcoming South Australian Centenary celebrations. Melrose left Dympne on the 9th April 1936, and flying via Marseilles, Naples, Athens, Baghdad, Basra, Karachi, Jodphur, Calcutta, Akyab, Penang, Singapore, Lombok, Darwin, Newcastle Waters and Alice Springs reached Adelaide on the 25th of April. Continuing the goodwill flight to other States, he visited Melbourne, Sydney, Newcastle, Grafton, Brisbane, Coff’s Harbour, Sydney again, Launceston, Hobart and Mount Gambier before returning to Adelaide on the 13th May. During June Jimmy made some charter flights and early in July was engaged by Mr. A.J. Campbell a director of several mining companies from Melbourne to Darwin to commence at Essendon on the4th July. However on that day low cloud and steady rain caused the postponement. There was little improvement and Melrose was advised to delay the departure again. However he wished to reach Oodnadatta that night, and when he observed the break in the clouds decided to leave. He planned to climb above the cloud and fly to Adelaide at 3,000 feet. The aircraft was airborne about 8.10 a.m. and was last seen from Essendon climbing above the clouds. At 8.45 people at Melton (30 miles West of Melbourne) heard an approaching aircraft. The engine noise increased abnormally and eye witnesses saw the machine fall out of control from the cloud base about 800 feet and then disintegrate, fragments were scattered for 1½ miles and both occupants were killed. Hand written carbon copy by Edna Barrie.Typed by Wendy Barrie March 2014 Last Flight of Jimmy Melrose by John Burke Parade Magazine July 1972 Page 2 –4 This article gives the take off time of 7.50 am from Essendon Airport Eyewitness account at the time Maisie Arthur’s description. Newspaper article. Edna Barrie at the site of the 'Cairn'local identities, local significant events

This pump is an Ajax Type L2 Series A model, made and sold by McPherson’s Pty Ltd of Melbourne circa 1930’s to 1940’s, is a mechanical, hand operated, constant flow pressure pump. It would have been used to pump fluids from one area to another, for example from a dam to a tank or used as a bilge pump on a small vessel, mounted on the vessel’s bulkhead, floor or deck. This type of hand pump is sometimes called a ‘Reciprocating Suction Pump’. It has a mechanical pumping action of the lever moves the piston inside the pump up and down. The water is lifted from below the pump through the inlet pipe and into the pump’s cylinder. This action causes the lower valve to close and the piston’s valve opens and the pressure within the pump forces the water out of the pump through the exit pipe. The limitation of this type of pump is that it can only raise the water a maximum of about 7 metres from beneath the ground and yields 24-26 Litres per minute. This type of pump could be used for many purposes such as pumping water or fuel. McPherson’s 1940’s advertisement proclaims “For all jobs on the land – irrigation, spraying, tank, plumbing, fire-fighting – there’s a suitable “Ajax” pump. Send us the details of you pumping problem. Our Expert’s advice will help you choose the right pump – the one that will give you most years of PROFITABLE PUMPING.” (The Australasian (Melbourne) Sat. 26th October 1940.) McPherson’s Pty Ltd, the manufacturer, advertised a similar pump to this one in The Australasian (Melbourne) in 1936, calling it the Ajax Double Acting Hand Pump. In 1942 another advertisement advised that a representative for a fire-fighting equipment supplier was visiting the western district of Victoria. The company could now supply double-action two-spray Ajax pumps at lower prices than similar pumps the district had recently purchased from Adelaide. McPHERSON’S FOUNDER and COMPANY TIMELINE 1860 – Thomas McPherson, a Scottish immigrant (c. 1853 ), founded McPherson’s in Melbourne, supplying pig iron (lead ingots imported as ballast in ships) to local manufacturers. 1882 – Thomas McPherson established a warehouse in Collins St Melbourne and included tools, steam fittings and machinery in his wares. The business expanded to include steam saw mills and became known as Thomas McPherson and Sons (William Murray and Edward). 1888 – Thomas passed away and his sons inherited the business. In 1896 William Murray became the sole proprietor after his brother Edward’s death. 1900 – The firm expanded, establishing Acme Bolt Company to manufacture nuts and bolts. 1912 – McPhersons Pty Ltd established a machinery warehouse and showroom in 554-556 Collins St Melbourne. McPherson’s went on to establish branches in Sydney (1911), Adelaide (1921) and Perth (1930) 1917 - McPherson’s supplied ‘dog spikes’ for the transcontinental railway, running from Eastern to Western Australia. 1918 – A tool works set up in Kensington, Melbourne, manufacturing Macson lathes and made machine tools that previously had to be imported. 1924 – The Bolt Works was transferred to a new building in Melbourne. McPhersons began making pumps. 1929 – McPherson retired. His son (Sir) William Edward McPherson (known as ‘WE’), was born in Hawthorne, Melbourne, in 1898. After his education he began work in his father’s Melbourne hardware and machinery business He took over as governing director when his father retired. 1929-1932 – McPherson’s supplied thousands of tons of rivets from its Richmond (Melbourne) Bolt Works for the construction of the Sydney Harbour Bridge. 1936 – McPherson’s Pty Ltd is advertising Ajax Pumps in newspapers 1934 – McPhersons purchased the property adjoining the warehouse in Collins Street, and during 1935-1936 built a new office and showrooms on the site of 546-445 Collins St. 1939 - McPherson’s acquired the Tool Equipment Co. Pty. Ltd and Associated Machine Tools Australia Pty Ltd was formed to separate McPherson’s machine-tool manufacturing and merchandising interests. 1939 – Ajax Pump Works, a foundry and pump manufacturing plant, was established in Tottenham, Melbourne, and the Ajax Bolt and Rivet Co Pty Ltd began manufacturing in New Zealand. 1944 - McPherson’s became a public company, McPherson’s Ltd. 1948 - The Ajax Pump Foundry opened at Kyneton, Victoria and in the post war years it grew to became a large manufacturer. 1980’s – Ajax Pumps brochure lists the address as 6 Buckhurst St, South Melbourne, Vic 3205 with the Telephone number 03 669 3588 1988 - Ajax Pumps acquired the Forrers Company, which was established in 1921. Manufacturing in Ipswich, Queensland, specialising in submersible sewage pumps. 1991 – KSB Ajax was formed, bringing together the companies KSB and Ajax Pumps 1993 – Manufacturing was moved to state-of-the-art premises in Tottenham, Victoria 2001 - The Forrers facility was moved to Tottenham. 2007 - Company name KSB Ajax Pumps was changed to KSB Australia Pty Ltd. 2009 - KSB Australia opened a branch in Townsville, Queensland. 2011 - KSB Australia moved to its dedicated Water and Waste Water Competence Centre in Bundamba, Queensland. DISPLAY OF THIS AJAX PUMP This pump was installed at Flagstaff Hill Maritime Village as part of a working display in the village by the Friends of Flagstaff Hill, in acknowledgement of the dedicated involvement of one of its long serving members, Bob Crossman. The display was officially opened 31st March 2018 and incorporates a restored Furphy Tank and Water Pipe Stand. The pump is used to draw water from the lake, through the water stand pipe and into the reconditioned Furphy Tank. This Ajax pump made by McPherson’s Pty Ltd is significant for its association with McPherson’s, a prominent manufacturer of hardware in Victoria. McPherson’s is famous for supplying ‘dog-spikes’ for the transcontinental railway (eastern to western Australia, 1917) and rivets for the Sydney Harbour Bridge (1929-1932). The Ajax pump is also of significance because of its association with McPherson’s Governing Director (Sir) William McPherson, former premier and treasurer in Victoria 1928-1929. The former McPherson’s Pty Ltd building in Collins Street Melbourne is now on the Victorian Heritage Register VHR H0942 This pump is representative of mechanical pumps popular in the early to mid-1900’s and still used today. Hand operated pressure pump, double acting. Cast metal case, painted red, with steel hose attachments and long metal lever. Pump is bolted to wooden plank. Model of pump is AJAX, Type L2, Series A pump. Embossed on lower section of pump "L2 - 10", "L2 - -1", "AJAX" “(?) –2-1” Embossed on lower handle “3-7” “L – 4” Embossed on attached plate “FOR SPARE PARTS / TYPE L2 / SERIES A / PUMP ASSEMBLED BY T R” Manufactured by McPherson’s Pty Ltd of Melbourne circa 1930’s - 1940’s.flagstaff hill, warrnambool, flagstaff hill maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, ajax pump works tottenham melbourne, ajax pump factory kyneton, william edward mcpherson, thomas mcpherson of melbourne, mcpherson’s pty ltd melbourne, acme bolt company, tool equipment co. pty. ltd, associated machine tools australia pty ltd, ajax bolt and rivet co. pty ltd new zealand, forrers company ipswich queensland, ksb ajax pumps, ksb australia pty ltd, macson lathes, tool manufacturer early to mid- 20th century, ajax double acting hand pump, ajax type l2 series a pump, qisjax pumps, water pump 1940’s, fuel pump 1940’s, hand operated constant flow pressure pump, reciprocating suction pump, agricultural hand pump, plumber’s hand pump, portable hand pump