Erection of staff quarters at Pretty Valley was completed in April, 1947 and accommodation for construction workers commenced in 1948 but suspended on 11th May for winter and resumed on 9th November. Construction of this camp was completed in 1949. A large dam was proposed at this site but was never constructed. Instead a small diversion dam was built which diverts water either to Rocky Valley Dam or to McKay Creek Power Station.An historical record of the type of accommodation provided for workmen during the construction of the Kiewa Hydro Scheme during the 1940's/50's.A black and white photograph of Pretty Valley Camp, c 1949. Dead trees are in the foreground, on both the left and right side of the photograph and a small snow gum is evident. There are camp huts and a much larger building behind these, possibly a workshop, and power poles are evident bringing electricity to the site.Handwritten in blue ink on back of photograph "Pretty Valley Camp. 5600 ft. above sea level".pretty valley, dam, water, workmen, camp

This book provides in chronological order the development of the Kiewa Hydro-electricity scheme from the first concept (1911) to final construction work (1961). It covers the first attempt to utilise the power of the Victorian Alps water system. It started from a private syndicate and developed to the current State Electricity Commission of Victoria. The incentive for the Hydro scheme was to make money and not as an alternative to the carbon producing coal fired power plants. These coal fired power plants were increasing in numbers to service an ever increasing demand made by population expansion, especially in cities and large rural settlements. This demand spiraled up after World War II when there was a tremendous spike in immigration numbers due to refugees and displaced persons in Europe. The ability to utilise the untapped water provided by the winter snow fields, for a higher yield in electricity, was a powerful incentive to overcome the physical hardships in this remote Alpine region. Future power requirements may initiate the re-installation of the other two power stations(Pretty Valley and Big Hill) covered in original Scheme. This publication not only covers the development of the Kiewa Valley region with respect to population (within a socio-economical framework) but also the subtle but yet strong physical changes of a relatively pristine alpine region. The demands that an ever growing regional population places on the environment is clearly documented in print and black and white photographs. The working and living conditions of those who constructed and gave life to this hydro scheme is well documented in this book. It may be viewed as spartan now but was relevantly good at that moment in time, especially for those workers fleeing a devastated European environment. The successful planning and consideration to minimising any intrusion upon the natural alpine forests and high plains can viewed as an example (compared to the Tasmanian Hydro schemes) of how future hydro schemes (an inevitable requirement) will proceed. Most rural towns (in the early 1900s) were built by unencumbered rural based citizens, with the exception of Mount Beauty and Falls Creek. These two settlements were brought into life by a State (Victorian) Authority for a specific function and program. They were a gated community, that is, only open to construction workers involved with the hydro scheme. All facilities within these communities were provided by the State Electricity Commission of Victoria. The impact on the social, financial and individual independency of the community, by the transition from the S.E.C .environment to one of local government (Shire of Bright), had in some cases a severe impact.This hard covered book has a green cover with pictures on the front and back covers. The front cover has a coloured picture of a snow covered Mount Bogong taken from the opposite mountain range. The valley between both ranges has a whisk of mist over it. At the bottom of this picture are three black and white photographs covering the construction of the Kiewa Hydro - Electricity Scheme. On the back cover is a photograph, (black and white) detailing the Bogong village and Junction dam containing lake Guy. The inside front cover is a black and white photograph which details the construction of the West Kiewa tailrace tunnel during April 1951. The inside back cover is a black and white photograph of the concrete pour at the Clover Dam circa 1952. All photographs and sketches are in black and white. The pages are approximately 160 g/m2 and those which have photographs are on gloss paper.Book spine: "The Kiewa Story Graham Napier Geoff Easdown" alongside this is a white framed circle with white spokes radiating out and underneath in white lettering SECkiewa valley, hydro scheme, victorian alpine region, electricity generators, graham napier, geoff easdown

Collected by Mary Gilbert. This folder belonged to Mary Gilbert and was probably used by her whilst teaching at Orbost High School and as a member of the Orbost Historical Society. Mary Isabelle Gilbert was born in 1905 in Orbost, Australia. She was born to John Gilbert and Annie Cameron Gilbert, and had seven sisters and one brother. Four siblings died at a young age. .She was a teacher historian loved and respected by her family and the wider community. This item is a useful research tool.A manila folder containing b/w newspaper cuttings relating to the progress of Orbost power, mail and water supply. The articles are from various newspapers.. 732.2 is a report by Mr A. Sambell. C.E. on the Orbost Water Supply. 732.3 is from the Weekly Times, July 17 1968 and is titled "Snowy River Mail Follows Our Ancient Track". 732.4 is from the Snowy River Mail, May 16 1962 and is titled " Power To Orbost in Keeping with State's Progress. 732.5 is from the Snowy River Mail, May 16 1962 and is titled " The Vital Power of Electricity".orbost-power-water-supply

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 ceramic lid is from a Holloway’s Ointment pot. It was retrieved from the wreckage of the LOCH ARD. The vessel was laden with an up-to-date, high-value cargo, including luxury items intended for the Melbourne International Exhibition in 1880. Britain exported her manufactures to the Australasian colonies and the Americas. Holloway’s Ointment was one nineteenth-century pharmaceutical product that was advertised in both these markets. The price of this particular jar and its contents was printed on the label as “2S 9D” (2 shillings and nine pence). This value calculated to the approximate price in 2014, would be £51.31 (UK pounds and decimal pence) or $85 AU ― quite an expensive ointment. The label also shows a picture of a stone tablet with the inscription "IN POTS AT 1/½, 2/9, 4/6,11/-, 22/- & 33/- EACH”, which is most likely the alternative prices that the ointment was available for in differently sized containers. Holloway’s claims for his “great remedy” included the cure of sores, wounds, ulcers and boils, gout, rheumatism, diphtheria, bronchitis, influenza, sore throats, coughs and colds, “all varieties of skin diseases”, scrofula, ringworm, scurvy, “dropsical swellings” and liver disease, piles, fistulas, and internal inflammation. The salve cream was said to penetrate the skin when rubbed on; purifying internal tissues and organs, cleansing all bodily fluids particularly the blood, and eradicating all disease from the body. Purchasers were assured that if Holloway’s Ointment alone did not affect immediate cure, then the combination of it and Holloway’s Pills (sold separately) most certainly would. Thomas Holloway began manufacturing and marketing his miraculous ointment from premises at 244 Strand in the 1840s, moving to the more prestigious address of 533 Oxford in the late 1860s. The London address was an important part of his promotional appeal and was displayed prominently on the packaging of his products. Holloway’s attention to marketing is also observed in the pseudo-Classical emblems that decorated his containers. The sign of a snake curled around a staff is a longstanding and commonly recognised symbol of the physician’s power to heal. Similar reference on this lid is also being made to an ancient goddess of healing and her healthy young offspring. History of the Loch Ard: The Loch Ard got its name from ”Loch Ard” a loch which lies to the west of Aberfoyle, and the east of Loch Lomond. It means "high lake" in Scottish Gaelic. The vessel belonged to the famous Loch Line which sailed many vessels from England to Australia. The Loch Ard was built in Glasgow by Barclay, Curdle and Co. in 1873, the vessel was a three-masted square-rigged iron sailing ship that measured 79.87 meters in length, 11.58 m in width, and 7 m in depth with a gross tonnage of 1693 tons with a mainmast that measured a massive 45.7 m in height. Loch Ard made three trips to Australia and one trip to Calcutta before its fateful voyage. Loch Ard left England on March 2, 1878, under the command of 29-year-old Captain Gibbs, who was newly married. The ship was bound for Melbourne with a crew of 37, plus 17 passengers. The general cargo reflected the affluence of Melbourne at the time. Onboard were straw hats, umbrella, perfumes, clay pipes, pianos, clocks, confectionery, linen and candles, as well as a heavier load of railway irons, cement, lead and copper. There were other items included that were intended for display in the Melbourne International Exhibition of 1880. The voyage to Port Phillip was long but uneventful. Then at 3 am on June 1, 1878, Captain Gibbs was expecting to see land. But the Loch Ard was running into a fog which greatly reduced visibility. Captain Gibbs was becoming anxious as there was no sign of land or the Cape Otway lighthouse. At 4 am the fog lifted and a lookout aloft announced that he could see breakers. The sheer cliffs of Victoria's west coast came into view, and Captain Gibbs realised that the ship was much closer to them than expected. He ordered as much sail to be set as time would permit and then attempted to steer the vessel out to sea. On coming head-on into the wind, the ship lost momentum, the sails fell limp and Loch Ard's bow swung back towards land. Gibbs then ordered the anchors to be released in an attempt to hold its position. The anchors sank some 50 fathoms - but did not hold. By this time the ship was among the breakers and the tall cliffs of Mutton Bird Island rose behind. Just half a mile from the coast, the ship's bow was suddenly pulled around by the anchor. The captain tried to tack out to sea, but the ship struck a reef at the base of Mutton Bird Island, near Port Campbell. Waves subsequently broke over the ship and the top deck became loosened from the hull. The masts and rigging came crashing down knocking passengers and crew overboard. When a lifeboat was finally launched, it crashed into the side of Loch Ard and capsized. Tom Pearce, who had launched the boat, managed to cling to its overturned hull and shelter beneath it. He drifted out to sea and then on the flood tide came into what is now known as Lochard Gorge. He swam to shore, bruised and dazed, and found a cave in which to shelter. Some of the crew stayed below deck to shelter from the falling rigging but drowned when the ship slipped off the reef into deeper water. Eva Carmichael a passenger had raced onto the deck to find out what was happening only to be confronted by towering cliffs looming above the stricken ship. In all the chaos, Captain Gibbs grabbed Eva and said, "If you are saved Eva, let my dear wife know that I died like a sailor". That was the last Eva Carmichael saw of the captain. She was swept off the ship by a huge wave. Eva saw Tom Pearce on a small rocky beach and yelled to attract his attention. He dived in and swam to the exhausted woman and dragged her to shore. He took her to the cave and broke the open case of brandy which had washed up on the beach. He opened a bottle to revive the unconscious woman. A few hours later Tom scaled a cliff in search of help. He followed hoof prints and came by chance upon two men from nearby Glenample Station three and a half miles away. In a complete state of exhaustion, he told the men of the tragedy. Tom then returned to the gorge while the two men rode back to the station to get help. By the time they reached Loch Ard Gorge, it was cold and dark. The two shipwreck survivors were taken to Glenample Station to recover. Eva stayed at the station for six weeks before returning to Ireland by steamship. In Melbourne, Tom Pearce received a hero's welcome. He was presented with the first gold medal of the Royal Humane Society of Victoria and a £1000 cheque from the Victorian Government. Concerts were performed to honour the young man's bravery and to raise money for those who lost family in the disaster. Of the 54 crew members and passengers on board, only two survived: the apprentice, Tom Pearce and the young woman passenger, Eva Carmichael, who lost her family in the tragedy. Ten days after the Lochard tragedy, salvage rights to the wreck were sold at auction for £2,120. Cargo valued at £3,000 was salvaged and placed on the beach, but most washed back into the sea when another storm developed. The wreck of Lochard still lies at the base of Mutton Bird Island. Much of the cargo has now been salvaged and some items were washed up into Lochard Gorge. Cargo and artefacts have also been illegally salvaged over many years before protective legislation was introduced in March 1982. One of the most unlikely pieces of cargo to have survived the shipwreck was a Minton majolica peacock- one of only nine in the world. The peacock was destined for the Melbourne 1880 International Exhibition in. It had been well packed, which gave it adequate protection during the violent storm. Today the Minton peacock can be seen at the Flagstaff Hill Maritime Museum in Warrnambool. From Australia's most dramatic shipwreck it has now become Australia's most valuable shipwreck artifact and is one of very few 'objects' on the Victorian State Heritage Register.The shipwreck of the Loch Ard is of significance for Victoria and is registered on the Victorian Heritage Register ( S 417). Flagstaff Hill has a varied collection of artefacts from Loch Ard and its collection is significant for being one of the largest accumulation of artefacts from this notable Victorian shipwreck of which the subject items are a small part. The collections objects give us a snapshot of how we can interpret the story of this tragic event. The collection is also archaeologically significant as it represents aspects of Victoria's shipping history that allows us to interpret Victoria's social and historical themes of the time. Through is associated with the worst and best-known shipwreck in Victoria's history. The ceramic lid off a Holloway’s Ointment container, retrieved from the wreckage of the LOCH ARD. The artefact is white with the pale blue image of a woman (seated) and a child (standing). The woman is draped in a soft white robe and her throne is beside a pillar that is entwined by a serpent. The child points to an inscribed stone tablet he is holding on the other side of seated woman. The front face of the lid, at the base of the woman on the throne, bears the label “HOLLOWAY’S OINTMENT”. Below this, in smaller letters, is written “TRADE MARK” and “2S.9D.” On the stone tablet pointed to by the child is inscribed “533 OXFORD ST. LONDON”, and beneath this, “IN POTS AT 1/½, 2/9, 4/6,11/-, 22/- & 33/- EACH”.flagstaff hill, warrnambool, flagstaff hill maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, loch line, loch ard, captain gibbs, eva carmichael, tom pearce, glenample station, mutton bird island, loch ard gorge, holloway’s ointment, ceramic lid, pot lid, nineteenth-century medicines, pharmaceutical marketing

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 book of Illustrated Directions was produced for use with the Davis New High Arm Vertical Feed (VF) Sewing Machine. The first model of the High Arm was produced in 1881, and the ‘New’ model, Model 2 VF, was introduced from 1883 and continued at least until 1885, when the Model 3 VF was manufactured. Job Davis, an inventor, showed his Davis Sewing Machine to two brothers in Watertown. The brothers, John and Joseph Shaldon, who founded the Davis Sewing Machine Company in February 1868 in Watertown, New York. The firm moved to Ohio in the 1890. Its early sewing machines were known as the Vertical Feed machines. These machines differed from others, in that there were two presser feet that moved and held the cloth as the needle went in and out of it. This type of action was also called ‘walking foot’ by makers of similar machines. Other machines used a feed dog below the machine’s bed to move the fabric. The Davis Company was awarded a Patents for its improvement to sewing machines. London offices were set up at 54, Queen Victoria Street, London in 1982. It was known as the Vertical Feed Sewing Machine Company. An article published in March 1885 states that the London Manager of the Vertical Feed Sewing Machine Company has 300,000 machines world-wide, including 4,000 in England alone. It claimed that the Auxiliary Forces Uniform and Equipment Company in Limerick, Ireland, was running its machines with steam power and could produce first-class work at the rate of 1,500 stitches per minute. The hand stitched binding of the manual is an example of early book binding processes. The is significant for its relationship to the Davis New High Arm Vertical Feed sewing machine, which was invented in 1866 and became popular in the domestic market. It was also used in industrial conditions as a labour-saving machine, one of the many machines that were part of the Industrial Revolution when steam power replaced manual power in many factories. Paper book with stitched binding. Printed text and illustrations contained within the 42-page booklet. The manual includes drawn diagrams and instructions for use of the Davis New High Arm Vertical Feed Sewing Machine, a foot treadle machine made in the 1880s. Front cover: "ILLUSTRATED DIRECTIIONS for the NEW HIGH ARM DAVIS Vertical Feed Sewing Machine and its Accessories and Attachments"flagstaff hill maritime museum and village, great ocean road, shipwreck coast, sewing machine manual, davis sewing machine, new high arm sewing machine, model 2 vf, vertical feed, sewing machine instructions, sewing machine directions, job davis, john sheldon, joseph sheldon, high arm sewing machine, watertown, new york, vertical feed sewing machine company, treadle, steam sewing machine, auxiliary forces uniform and equipment company, limerick, ireland

Each year World War One and World War Two veteran, and Ballarat Teachers' College Principal addressed the College community for ANZAC Day. The following are excerpts of his 1947 address. "...But we should do more than remember, and instead of pausing once a year for this purpose is should be our aim to remember daily - every day should be an Anzac Day so that we shall be inspired to take stock of ourselves if we are tryig to be worthy of almidst 100,000 dead who died to keep this country free to progress nobly towards a worthy goal, What are we dong about it? As a body of teachers er should be particulalrly concerned, as in our hands largely the growth of the children lies. In the schools we can do much in our work of every day to develop right standards and a better outlook amongst the children it is our privilege to teach. We can successfully teach the three "R's" but if this is all we do then we have failed. Is should be our aim, living in the spirit of those who gace so much, to dedicate ourselfes to the work of teaching young people how to live; to train them gently in ethical standards of conduct; to take responsibility; to live through the operation with otherts; to be prepared to give service without thought of personal gain; to realise to the full all that is best in them for the good of all. What we should do and how it is to be done is difficult to descibe, but if we ourselves have taught something of the Anzac Sprit we shall not fail. In particular, we shold take care of the orphan and th child of the disabled soldier. We should explore all avenues to see what that these children get every opportunity for higher education. As far as it lies in our power we should see that these children do not suffer - thus the legacy of war is ours. In a few months you will be going out to your schools. You will have young children around you. Let you arims be high. Try to live worthily and let your little community be the better and the finer for your coming. If you achiec somethig of thise then 100,000 shall nit have died in vain." Blue soft covered, stapled booklet named 'Extra Muros', the magazine of the Ballarat Teachers College, ANZAC Day. The contents include: The Year's Sport, J. Arthur Rank; Music; Dingo Blood; Anzac Day 1947; History of Sport; J. Arthur Rank Named images include: staff and students; Sports Committee; Social Committee; Student Council; Magazine Committee' Daylesford Camp; Anglesea Camp; Grampians Camp; Exies, College staff and students;A number of authorgraps are written into the back page. ballarat teachers' college, ellwood, lord, robinson, tozer, connelly, pattenden, collins, blake, faulds, sunderland, miller, bryan, yeo, frank lord, lindsay w. harley, lindsay w. harley, anzac day

Safety lamp made for underground miners to replace naked flame lightingUsed in underground mining in Ovens or Buckland mining districtsmetal and glass oil powered lamp(partly obscured on glass) BRITISH MFP. ( on brass) 3BB BOSS ( on screw off base) 56 and 10mining, lamp, oil, safety, kerosene, underground

Information from Norman F. Dalton: Ballarat had a reticulated DC supply in the early part of last century and in 1905 had sufficient generating capacity to enable the trams to be changed from horse drawn to DC electricity. The use of electricity increased with the main power station located on Wendouree Parade, near Webster Street, under the ownership of The Electric Supply Company of Victoria. AC generating plant was installed in 1925 and conversion to AC proceeded. In 1934 the company was taken over by the State Electricity Commission Victoria (SECV) and more AC generation was installed and the changeover of customers was accelerated. This is around the time that the Synchronome Frequency Checking Mast Clock was installed at the Wendouree Parade Power Station. The SECV Annual Report of 1921 states: ::Section 11 of the act directed the COmmission to enquire into the question of securing the adoption of such standards of plant and equipment of a system, frequency and pressure for the generation and distribution of electricity as will admit of the efficient interconnection of undertakings throughout the State. In 1934 when the SECV took over the Ballarat operations the question of linking with the State grid had been a planned operation for some years but due to financial considerations had hindered it and in fact would continue to do so for a further 10 years. So while the need for close frequency control for interconnection was hardly an issue, the need to keep electric clocks correct was important, particularly as this item was a frequent sales point to cover the inconvenience and sometimes expense of converting from DC to AC. The clock is a very accurate pendulum clock with provision for varying effective length during operation for precise time regulation. There are two normal time dials and one is controlled by the pendulum and the other is operated by the system frequency. When the clock was in use it was installed by the MEter and Tests Laboratory and the time was checked daily by radio time signals. The two dials were repeated in the operators control panel in the Power Station. A maximum deviation between the two dials was set in the operating instructions (eg 5 seconds) and the operator would correct this when necessary by remote manual alteration of the turbine governor set point. The clock was used to drive and regulate a system of "slave" clocks which were used to display the time in various locations around the power station. A slave clock is a simple clock which is driven by a small electric motor, its accuracy is regulated by the master clock every 30 seconds to ensure that it and all the other slave clocks in the station are on exactly the right time; slave clocks were placed in various locations, from common rooms to workshops. A master clock could potentially run thousands of slave clocks at one plant. The clock also contains a rectifier. A rectifier is a device that is used to convert AC power to more stable DC current.Two clocks in a timber case. Both are electric, one is powered by the main pendulum mechanism, the other is a self contained electric clock. The main mechanism is of the gravity arm and roller type, which sends an impulse to the slave clocks every 30 seconds. The This Synchronome Frequency Checking Master Clock was used at the Ballarat Power Station. Below the main section of the case is a smaller cabinet containing a rectifier to provide consistent DC power for the clock. The rectifier was made by the Victorian company Hilco, which was located in Burwood. There is a high chance this is not the original rectifier from this clock as there appears to be brackets to hold a larger device in the space the rectifier occupies.Front below main clock face on front of case: "Patented Sychronome Brisbane" Lower left-hand clock face: "Frequency time" Lower right-hand clock face: "Standard Seconds" Synchronous electric clock mechanism on door (Frequency time clock): >200/250 V. 50~ >"Synchronomains" Made in England >Direction indicator for clock starting switch >"To start move lever in direction of arrow and release" >"Patent applied for" Mechanism for "standard seconds" clock: >"English Made" >"Patented" >Serial number "321" >0 above right-hand pillar on front-plate Mechanism for "standard seconds" clock: >"English Made" >"Patented" >Serial number "321" >0 above right-hand pillar on front-plate Mechanism for main clock face: >"English Made" >"Patented" >Serial number "8751" >0 above right-hand pillar on front-plate Inside case, back panel, top enamel plate: >Seconds Battery + Pos. > Battery Common or - Neg. >1/2 min dials Inside case, back panel, bottom enamel plate: external seconds dial Inside case, right hand side, electrical knobs: two switches, both "A.C. mains" Pendulum rod, below suspension spring: Serial number (?) 0000005 Rectifier in bottom cabinet: >"Hilco Rectifier" >"A.C. Volts 230/240" >"Model 1060/S" >"A.C. Amperes" >"Serial No. 1060/S >"Phases 1" >"D.C. Volts 6" >"C.P.S. 50" >"D.C. Amperes 1" >"Made in Australia by Hilco Transformers McIntyre St., Burwood, Victoria." Bakelite electrical plug: makers mark Lower cabinet, RH side panel, pressed tin plate: "AC" (upside down) Brass speed adjustment, outer right RH side: "S" and "F" Ivory and wood pendulum beat ruler: >Ruler, with 0 in centre and numbers 1-5 in ascending order from centre on left and right. > "Synchronome Patent." Steel plate, back panel, inside case, right hand side: >N R A" (descending) >"2191" serial number/part number Face of main clock: "Synchronome Electric" synchronome frequency checking master clock, electricity, state electricity commission, wendouree parade power station, secv, clock, time, pendulum, electric supply company of victoria, norman f. dalton, ballarat power station, rectifier, slave clock

collected by Ballarat School of Mines Principal G.H.BeanlandMagazines bound in ASEA folder, blue spine and black cloth boardselectrical engineering, generators, graham beanland, power stations, voltage control, electrohydraulic governor for water turbines, high voltage dc transmission, oil-minimum contraction circuit-breakers, lightening arresters, air-blast circuit breakers, testing circuit breakers, closing mechanisms for high voltage circuit-breakers, outdoor isolators, series capacitors, capacitor voltage transformers, guide to current transformers, routine testing of power tranformers, generator

Newspaper clippings relating to the Ballarat School of Mines and its students. This also includes the Ballarat Junior Technical School and the Ballarat Girls' Technical School. Selected items * Courier 27 May 1961 - Apprenticeship - Training Today for Tomorrow * Courier 22 February 1922 - Hopes for University Education in 1963 * More Women Graduates Needed * 30 July 1963 - Linking Technical and Liberal Education Streams * Courier 2 November - SMB's New Role in New Syllabus * 23 November 1963 0 New School Diploma courses explained * Courier 31 March 1964 - Artists and art critics: What young people thought of art show. * The Age, 25 March 1965 - Martin Report Urges Extension of High Education * Courier 11 June 1965 - Nuclear Power Won't be Missedr.w. richards, dick richards, john gilbert, ceramics, e.w. doney, antarctica, city of ballarat craftsmen certificates, scrap book, ken wach, bjts fees register, allen bourquin, p. collier, j. crisp, john dulfer, fenner, charles, gillin, murray, gray, thomas, j. graham hopwood, hunting, f, wesley lancaster, landells, r., lochhead, j.s., lochhead, james, mctaggert, mavis, mcvitty, henry moritz, moritz, henry, kathleen rice, albert w. steane, stevens, don, kenneth wach, ian g. whitcher, noel whitcher, a.m (bill) wilkinson, harold yates, international students, asian students, richard tan, jack tay, andrew vu, zulkilfie h. abdullah, sebastopol technical school foundations, charles fenner, e. elsbury, c. o'toole, w. lancaster, v. nicholson, douglas vendy, richards medal, william hudson, a.j. bethune, ballarat school of mines workshops, m.y. jamagagni, peter agrums, thai, j. boonsoong, h. trudinger, kevin whiter, brewery chimney, murray gillan, don stevens, bella guerin, hester darby retirement, rubie lonie, cadets, f.g. procter retirement, albert coates, d.e. richardson, lydiard st closure, geoff brown, neville bunning, walter reimann, robert norton, jill norton, b. bryan, kaspars bitans, martin report, edith lawn, mavis mctaggart retirement, richard chong, zulkiflie h. abdullah, alumni, ian whitcher, l.f.j. hillman, h. elliott, hester darby, duke of edinburgh, philips electrical industries pty ltd, lois morris, ballarat school of mines banner, embroidery, craftsman certificate, technical training week, apprenticeships, 3rd university, generator, j.j. skuja, sebastopol technical school, pine plantation, art students, centenary medal, bathtub race, tippett hall, bath tub run, metallurgy, lydiard street closure, honor blazer, soil studies, rolls royce car engine, jon rowe', allan bourquin, ruby loney, lindsay hillman, yates geological centre, geoffrey mainwawaring, ballarat school of mines renovations, ross gray, casper bitans, apprenticeship training, boat race, apprenticeship week, f.g. proctor, mount clear site, john jungwirth, ballarat school of mines open night, wayne johnson, j. hanford stevens, peter richards, r.c. chan, mavis mctaggert, gladstone procter

The lathe-making business incorporated in 1902 as Drummond Bros Ltd originated in the fertile mind of Mr Arthur Drummond, said to have been living at that time at Pinks Hill, on the southern edge of Broad Street Common, west of Guildford. Mr Drummond, whose accomplishments included several pictures hung in the Royal Academy, was unable to find a lathe suitable for use in model engineering. In 1896 he designed for himself a ‘small centre lathe … which had a compound slide rest with feed-screws and adjustable slides’. He also designed and built ‘lathes of 4.5 inch and 5 inch centre height, which had beds of a special form whereby the use of a gap piece was eliminated but the advantages of a gap-bed lathe were retained’. Assisted by his brother, Mr Frank Drummond, who had served an apprenticeship to an engineering firm at Tunbridge Wells, the first lathes were made in a workshop adjoining Arthur Drummond’s house. The demand that speedily built up led to the decision to form a company and manufacture the lathes for sale commercially. Land was acquired nearby, at Rydes Hill, and the first factory built. The enterprise was a success, and the company quickly established ‘a high reputation in this country and abroad for multi-tool and copying lathes, and gear-cutting machines’. Other lathes were added to the range, including the first of the ’round bed’ machines for which the firm became widely known. A Drummond 3.5 inch lathe was among the equipment of Captain Scott’s 1912 expedition to the South Pole, and large numbers of 3.5 inch and 4 inch designs were exported to Australia, Canada and India. By the outbreak of war in 1914, 5 inch, 6 inch and 7 inch screw cutting lathes, arranged for power drive, were on sale. Large orders were received from the government for 3.5 inch lathes, for use in destroyers and submarines, and 5 inch lathes for the mechanised section of the Army Service Corps. The latter were used in mobile workshops. The factory worked night and day to supply the forces’ needs, until production was disrupted by a fire which destroyed a large part of the works in May 1915. As soon as rebuilding was complete work restarted. At the end of the war the entire production was being taken by the Government departments, a special feature being a precision screw lathe, bought by the Ministry of Munitions in 1918. Between the wars Drummond Bros Ltd introduced new machines for the motor vehicle, and later the aircraft industry, and the works were extended on many occasions to fulfill the increasing orders. The Maxicut multi-tool lathe (1925), designed for high-production turning operations, was one of the first machines of this type to be built in England. It was followed (1928) by an hydraulic version for turning gear blanks, and similar work. Further developments provided machines which, during the Second World War, turned all the crankshafts and propeller shafts for Bristol engines. Others, ordered by the Ministry of Supply were employed in turning shells, and many other specific needs of vehicle and aircraft manufacture were catered for by new types of Drummond lathes. Production of the small centre lathes ceased during the war when the company needed to concentrate on building multi-tool lathes and gear shapers. After the war a completely new Maxicut range was introduced, replacing the older versions, and fully automatic. The types were continually developed, and new versions manufactured until the end of the company’s life in 1980. The disappearance from the scene of Mr Arthur Drummond in 1946, and the end of the company’s autonomous existence in 1953 when the company was acquired by William Asquith Ltd, which was in turn bought by Staveley in 1966, meant that the factory at Rydes Hill became one – albeit very effective – part of a large national engineering company. Achievements at the Guildford works during its last years included the development of automated Maxicut gear-shapers in what was ‘probably the most fully automated gear shop in the country’, while a machine from Guildford was sent to the Osaka Fair in 1962. In 1963 an agreement was signed with Hindustan Machine Tools for the manufacture of Maxicut gear-shapers in state owned factories in Bangalore and Chandigarh. During 1963 the two largest multi-tool lathes ever made in the UK were installed in Ambrose Shardlow’s works in Sheffield for handling cranks up to 14 foot long. In 1976 Drummond lathes were included in Staveley’s £14,000,000 installation in Moscow of an automated production line for Zil motor cars. Up to the end invention continued at Guildford: a new Drummond Multi-turn memory-controlled machine was shown at the International Machine Tool Exhibition in 1977. This could not save the works from the pressures of the late 1970s, and Staveley Industries closed its Guildford site in 1980.An early example of a lathe that was designed primarily for the hobbyist model maker. It is in good condition and sought today by collectors as many of it's attributes were innovative at the time and lead to further development and incorporation of some of its features into more industrial models of production machinery. Lathe, round bed, treadle powered lathe, Drummond Type A, Serial number and maker's inscription. 1920-1923, Made by Drummond Brothers in Guildford, Surrey, England. Lathe is complete with Chuck, Tool post and Tail Stock in situ (30 extra parts)"MADE BY DRUMMOND BROTHERS LIMITED - PATENT TEES - RYDE'S HILL n GUILDFORD SURREY", "Serial Number 01470," "L44" or "L45 " flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, lathe 1920-1923, round bed lathe, treadle lathe, drummond type a, guildford surrey, drummond brothers guildford surrey england, tread'e

A foghorn is a device that uses sound to warn of navigational hazards like rocky coastlines, or boats of the presence of other vessels, in foggy conditions. The term is most often used with marine transport. When visual navigation aids such as lighthouses are obscured, foghorns provide an audible warning of rocky outcrops, shoals, headlands, or other dangers to shipping. An early form of fog signal was to use a bell, gong, explosive signal or firing a cannon to alert shipping. From the early 20th century an improved device called the diaphone was used in place of these other devices, The diaphone horn was based directly on the organ stop of the same name invented by Robert Hope-Jones, creator of the Wurlitzer organ. Hope-Jones' design was based on a piston that was closed only at its bottom end and had slots, perpendicular to its axis, cut through its sides, the slotted piston moved within a similarly slotted cylinder. Outside of the cylinder was a reservoir of high-pressure air. Initially, this air would be admitted behind the piston, pushing it forward. When the slots of the piston aligned with those of the cylinder, air passed into the piston, making a sound and pushing the piston back to its starting position, whence the cycle would be repeated. This method of producing a low audible sound was further developed as a fog signal by John Northey of Toronto and these diaphones were powered by compressed air produced by an electric motor or other mechanical means that admitted extremely powerful low-frequency notes. The example in the Flagstaff collection is an early cased and portable diaphone used on pleasure or sailing craft. By manually turning the crank handle air is produced and fed into valves that direct air across vibrating metal reeds to produce the required sound. in foggy weather, fog horns are used to pinpoint a vessels position and to indicate how the vessel is sailing in foggy conditions. One blast, when sailing on starboard tack and two blasts, when sailing on a port tack and three dots, when with wind is behind the vessel. Since the automation of lighthouses became common in the 1960s and 1970s, most older foghorn marine installations have been removed to avoid the need to run the complex machinery associated with them, and have been replaced with an electrically powered diaphragm or compressed air horns. The example in the collection is significant as it was used in the early 19th century for sailing vessels was important but these portable crank fog horns have also been superseded by modern electric varieties. Therefore the item has a historical connection with sailing and maritime pursuits from our past.English Rotary Norwegian Pattern nautical foghorn within a boxed pine varnished case with exposed corner dovetailing, original leather carrying strap, brass side crank, and original copper trumped horn. Card accessory with Directions for Use in both English and French.Noneflagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, foghorn, maritime technology, maritime communication, marine warning signal, portable foghorn, bellows foghorn, crank handle, robert hope-jones, john northey

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

Brown soft covered book. Contents include: Winning Brown Coal at Yallourn Dredge Operation for Overburden Removal Boiler Plant at the Yallourn Power Station Electrical Equipment at the Yallourn Power Station Steam Plant at the Yallourn Power Station Yallourn-Melbourne High Tension Line Yarraville Terminal Station Transmission distribution High Transmission Towers for River Crossing Sugarloaf-Rubicon Hydroelectric Development Briquette factory Subsidiary Activities at Yallourn Future Developments thompson's engineering & pipe co. ltd, briquettes, electricity, power generation, yallourn, yallourn briguetting works, transmission lines, high tension switchgear, insulators, australian porcelain company, substation, brown coal, high tension line, sugarloaf-rubicon, plans, suspension tower, transposition tower, yarraville terminal station, condenser, newport power station, gippsland, hydroelectric

DEFINITION microfarad Posted by: Margaret Rouse WhatIs.com Contributor(s): Kenda, Jack Clements The microfarad (symbolized µF) is a unit of capacitance, equivalent to 0.000001 (10 to the -6th power) farad. The microfarad is a moderate unit of capacitance. In utility alternating-current (AC) and audio-frequency (AF) circuits, capacitors with values on the order of 1 µF or more are common. At radio frequencies (RF), a smaller unit, the picofarad (pF), is often used. This unit is equal to .000000000001 (10^-12) µF. In RF scenarios, capacitances range from about 1 pF to 1,000 pF in tuned circuits, and from about 0.001 µF to 0.1 µF for blocking and bypassing. At audio frequencies (AF), capacitances range from about 0.1 µF to 100 µF. In power-supply filters, capacitances can be as high as 10,000 µF. Capacitor, 1/3 M.F.D. (microfarad) within wooden insulating box. Two terminal posts set in an insulating box. Maker's name and place 1/3 M.F.D No. 34402scientific instrument, capacitor, electrical engineering, laboratory

Item looks to have been adapted for bench top use Sindanyo high temperature insulation boards are manufactured from cement based products, reinforced with selected fibres. They have been specifically designed to provide excellent service under demanding thermal and electrical applications. Sindanyo is a non-asbestos, non-combustible product that is easily machined. This insulation board is a popular option when a high quality, strong and rigid material is required.400/500 Volt, 5 amp, 50 Hz 3-phase balanced load. Circular scale with lead and lag markings and graduations. The 22cm diameter meter rear-mounted to black sindanyo board, supported by wood brackets on wood base. Five terminal posts on panel below meter. Wire connections at rear. No maker's name Patent Number: 162471/20 Serial Number 263475scientific instruments, power factor maker, lead and lag markings, terminal posts, power factor meter, wire connections, sindanyo board, non-combustible, insulation, electrical applications

Metamec was a manufacturer of domestic clocks in the second half of the 20th century, and was based in Dereham, Norfolk, England. The name "Metamec" is derived from "metal-work and mechanics". The company started as an offshoot of the furniture manufacturers Jentique in about 1941, which made boxes for instruments and bombs during World War II.The first Metamec model was a mains-powered mantle clock numbered "701" (approx. 1947). All clocks produced by Metamec were produced to a high standard, The company declined in the late 1980s and went into receivership in December 1984 and sold to FKI of Halifax, West Yorkshire, who continued to use the name until 1993. Now another company is producing clocks under the Metamec name in Derbyshire England Gladys Reed who used this clock was a member of the Ormond Choral Society c 1950. who performed plays and musicals the City of Moorabbin Metamec was a manufacturer of domestic electric clocks in the second half of the 20th century, and was based in Dereham, Norfolk, England Gladys Reed was a member of the Ormond Choral Society c 1950. who performed plays and musicals the City of Moorabbin.Dressing table brass, electric clock with floral pattern.METAMEC / Made in Englandclocks, metamec ltd., norfolk england, reed gladys, clark judy, brighton, moorabbin, furniture, pioneers, clocks, market gardeners, early settlers, mechanics institute cheltenham, ormond choral society, postworld war 11 settlers, housing estates moorabbin 1950, bentleigh,

Both the Light switch and Door knob were used in Box Cottage during the late 19thC and early 20thC by the Box and Rietman families. William and Elizabeth Box purchased the two ten acre Lots of land with the Cottage in 1868 where they raised their family of 12 children and developed a flower garden producing seedlings. August and Frieda Rietman rented the Cottage 1917 with 1 acre of land and purchased it in 1935 where they raised 2 children while August established Rietman's Landscaping Pty Ltd making pressed concrete garden furniture. Porcelain is a ceramic material made by heating materials, generally including kaolin, in a kiln to temperatures between 1,200 and 1,400 °C The toughness, strength and translucence of porcelain, relative to other types of pottery, arises mainly from vitrification and the formation of the mineral mullite within the body at these high temperatures. Porcelain and other ceramic materials have many applications in engineering, especially ceramic engineering. Porcelain is an excellent insulator for use at high voltage, especially in outdoor applications, see Insulator (electricity)#Material. Examples include: terminals for high voltage cables, bushings of power transformers, insulation of high frequency antennas and many other components. Both the Light switch and Door knob were used in Box Cottage during the late 19thC and early 20thC by the Box and Rietman families. William and Elizabeth Box purchased the land with Cottage in 1868 and raised their familya) An electric light switch that would be attached to a wall. An Ivory Porcelain Base Single Light Switch with antique Brass top b) A porcelain door knob Both items used in Box Cottage early 20th Ca) On base BRITISH MADE / ENGLAND / 4 / 6959 lights, porcelain, electricity, early settlers, moorabbin, cheltenham, bentleigh, box william, box elizabeth, rietman august, rietman frieda, market gardeners, flower gardens, seedling nurseries, world war 1 1914-18, war memorials, sculpture, pottery, pressed concrete, door handles, door knobs