Showing 348 items
matching apparatus
-
Flagstaff Hill Maritime Museum and Village
Equipment - Traveller pulley block, 1860s
The life saving breeches buoy was attached to a traveller block such as this one. The assembly was sent from shore to ship and back to transport the stranded people and goods safely to shore. Saving lives in Warrnambool – The coastline of South West Victoria is the site of over 600 shipwrecks and many lost lives; even in Warrnambool’s Lady Bay there were around 16 known shipwrecks between 1850 and 1905, with eight lives lost. Victoria’s Government responded to the need for lifesaving equipment and, in 1858, the provision of rocket and mortar apparatus was approved for the lifeboat stations. In 1859 the first Government-built lifeboat arrived at Warrnambool Harbour and a shed was soon built for it on the Tramway Jetty, followed by a rocket house in 1864 to safely store the rocket rescue equipment. In 1878 the buildings were moved to the Breakwater (constructed from 1874-1890), and in 1910 the new Lifeboat Warrnambool arrived with its ‘self-righting’ design. For almost a hundred years the lifesaving and rescue crews, mostly local volunteers, trained regularly to rehearse and maintain their rescue skills. They were summoned when needed by alarms, gunshots, ringing bells and foghorns. In July 1873 a brass bell was erected at Flagstaff Hill specifically to call the rescue crew upon news of a shipwreck. Some crew members became local heroes but all served an important role. Rocket apparatus was used as recently as the 1950s. Rocket Rescue Method - Rocket rescue became the preferred lifesaving method of the rescue crews, being much safer that using a lifeboat in rough seas and poor conditions. The Government of Victoria adopted lifesaving methods based on Her Majesty’s Coast Guard in Great Britain. It authorised the first line-throwing rescue system in 1858. Captain Manby’s mortar powered a projectile connected to rope, invented in 1808. The equipment was updated to John Dennett’s 8-foot shaft and rocket method that had a longer range of about 250 yards. From the 1860s the breeches buoy and traveller block rocket rescue apparatus was in use. It was suspended on a hawser line and manually pulled to and from the distressed vessel carrying passengers and items. In the early 1870s Colonel Boxer’s rocket rescue method became the standard in Victoria. His two-stage rockets, charged by a gunpowder composition, could fire the line up to 500-600 yards, although 1000 yards range was possible. Boxer’s rocket carried the light line, which was faked, or coiled, in a particular way between pegs in a faking box to prevent twists and tangles when fired. The angle of firing the rocket to the vessel in distress was measured by a quadrant-type instrument on the side of the rocket machine. Decades later, in 1920, Schermuly invented the line-throwing pistol that used a small cartridge to fire the rocket. . The British Board of Trade regularly published instructions for both the beach rescue crew and ship’s crew. It involved setting up the rocket launcher on shore at a particular angle, determined by the Head of the crew and measured by the quadrant, inserting a rocket that had a light-weight line threaded through its shaft, and then firing it across the stranded vessel, the line issuing freely from the faking board. A continuous whip line was then sent out to the ship’s crew, who hauled it in then followed the instructions – in four languages - on the attached tally board. The survivors would haul on the line to bring out the heavier, continuous whip line with a tail block connected to it. They then secured the block to the mast or other strong part the ship. The rescue crew on shore then hauled out a stronger hawser line, which the survivors fixed above the whip’s tail block. The hawser was then tightened by the crew pulling on it, or by using the hooked block on the shore end of the whip and attaching it to a sand anchor. The breeches buoy was attached to the traveller block on the hawser, and the shore crew then used the whip line to haul the breeches buoy to and from the vessel, rescuing the stranded crew one at a time. The rescue crew wore scarlet, numbered armbands and worked on a numerical rotation system, swapping members out to rest them.This traveller block is significant for its connection with local history, maritime history and marine technology. Lifesaving has been an important part of the services performed from Warrnambool's very early days, supported by State and Local Government, and based on the methods and experience of Great Britain. Hundreds of shipwrecks along the coast are evidence of the rough weather and rugged coastline. Ordinary citizens, the Harbour employees, and the volunteer boat and rescue crew, saved lives in adverse circumstances. Some were recognised as heroes, others went unrecognised. In Lady Bay, Warrnambool, there were around 16 known shipwrecks between 1850 and 1905. Many lives were saved but tragically, eight lives were lost. Wood and brass pulley block or 'traveller', used in conjunction with the Breeches Buoy. The block has double brass inline sheaves and brass rollers on each cheek of the pulley. Each shell is scored for the strop. The thimble on the strop has a wooden slat attached for quick release of the Breeches Buoy. A portion of rope is connected.flagstaff hill maritime museum and village, flagstaff hill, maritime museum, maritime village, warrnambool, shipwreck, life-saving, lifesaving, rescue crew, rescue, rocket rescue, rocket crew, lifeboat men, beach rescue, line rescue, rescue equipment, rocket firing equipment, rocket rescue equipment, maritime accidents, shipwreck victim, rocket equipment, marine technology, rescue boat, lifeboat, volunteer lifesavers, volunteer crew, life saving rescue crew, lifesaving rescue crew, rocket apparatus, rocket rescue method, shore to ship, rocket apparatus rescue, stranded vessel, line throwing mortar, mortar, rocket rescue apparatus, line thrower, line throwing, lifeboat warrnambool, beach apparatus, breeches buoy, petticoat breeches, petticoat buoy, traveller chair, life jacket, traveller, traveller block, running block, block, pulley, hawser, faking, faking box, faked line, faking board, italian hemp, quadrant, protractor, tally board, light line, whip line, endless whip, beach cart, hand barrow, sand anchor, welsh hand barrow, her majesty’s coast guard, harbour board, government of victoria, harbour master, l.s.r.c., lsrc -
Flagstaff Hill Maritime Museum and Village
Equipment - Rocket Key, John Dennett, c. 1860s
This rocket launcher key was used with the Dennett's Rocket Launcher system to remove the end cap of the Dennett's Rocket to expose the propellant to be fused . Saving lives in Warrnambool – The coastline of South West Victoria is the site of over 600 shipwrecks and many lost lives; even in Warrnambool’s Lady Bay there were around 16 known shipwrecks between 1850 and 1905, with eight lives lost. Victoria’s Government responded to the need for lifesaving equipment and, in 1858, the provision of rocket and mortar apparatus was approved for the lifeboat stations. In 1859 the first Government-built lifeboat arrived at Warrnambool Harbour and a shed was soon built for it on the Tramway Jetty, followed by a rocket house in 1864 to safely store the rocket rescue equipment. In 1878 the buildings were moved to the Breakwater (constructed from 1874-1890), and in 1910 the new Lifeboat Warrnambool arrived with its ‘self-righting’ design. For almost a hundred years the lifesaving and rescue crews, mostly local volunteers, trained regularly to rehearse and maintain their rescue skills. They were summoned when needed by alarms, gunshots, ringing bells and foghorns. In July 1873 a brass bell was erected at Flagstaff Hill specifically to call the rescue crew upon news of a shipwreck. Some crew members became local heroes but all served an important role. Rocket apparatus was used as recently as the 1950s. Rocket Rescue Method - Rocket rescue became the preferred lifesaving method of the rescue crews, being much safer that using a lifeboat in rough seas and poor conditions. The Government of Victoria adopted lifesaving methods based on Her Majesty’s Coast Guard in Great Britain. It authorised the first line-throwing rescue system in 1858. Captain Manby’s mortar powered a projectile connected to rope, invented in 1808. The equipment was updated to John Dennett’s 8-foot shaft and rocket method that had a longer range of about 250 yards. From the 1860s the breeches buoy and traveller block rocket rescue apparatus was in use. It was suspended on a hawser line and manually pulled to and from the distressed vessel carrying passengers and items. In the early 1870s Colonel Boxer’s rocket rescue method became the standard in Victoria. His two-stage rockets, charged by a gunpowder composition, could fire the line up to 500-600 yards, although 1000 yards range was possible. Boxer’s rocket carried the light line, which was faked, or coiled, in a particular way between pegs in a faking box to prevent twists and tangles when fired. The angle of firing the rocket to the vessel in distress was measured by a quadrant-type instrument on the side of the rocket machine. Decades later, in about 1920, Schermuly invented the line-throwing pistol that used a small cartridge to fire the rocket. . The British Board of Trade regularly published instructions for both the beach rescue crew and ship’s crew. It involved setting up the rocket launcher on shore at a particular angle, determined by the Head of the crew and measured by the quadrant, inserting a rocket that had a light-weight line threaded through its shaft, and then firing it across the stranded vessel, the line issuing freely from the faking board. A continuous whip line was then sent out to the ship’s crew, who hauled it in then followed the instructions – in four languages - on the attached tally board. The survivors would haul on the line to bring out the heavier, continuous whip line with a tail block connected to it. They then secured the block to the mast or other strong part the ship. The rescue crew on shore then hauled out a stronger hawser line, which the survivors fixed above the whip’s tail block. The hawser was then tightened by the crew pulling on it, or by using the hooked block on the shore end of the whip and attaching it to a sand anchor. The breeches buoy was attached to the traveller block on the hawser, and the shore crew then used the whip line to haul the breeches buoy to and from the vessel, rescuing the stranded crew one at a time. The rescue crew wore scarlet, numbered armbands and worked on a numerical rotation system, swapping members out to rest them. This rocket launcher key is a necessary part of the equipment for the the rocket launcher, which is significant for its connection with local history, maritime history and marine technology. Lifesaving has been an important part of the services performed from Warrnambool's very early days, supported by State and Local Government, and based on the methods and experience of Great Britain. Hundreds of shipwrecks along the coast are evidence of the rough weather and rugged coastline. Ordinary citizens, the Harbour employees, and the volunteer boat and rescue crew, saved lives in adverse circumstances. Some were recognised as heroes, others went unrecognised. In Lady Bay, Warrnambool, there were around 16 known shipwrecks between 1850 and 1905. Many lives were saved but tragically, eight lives were lost.Key, part of the Rocket Rescue equipment. T shaped metal key, round handle across the top and hexagonal shaped shaft and square end. Used to remove the end cap of the Dennett's Rocket to expose the propellant to be fused . Donation from Ports and Harbour.flagstaff hill maritime museum and village, flagstaff hill, maritime museum, maritime village, warrnambool, great ocean road, lady bay, warrnambool harbour, port of warrnambool, tramway jetty, breakwater, shipwreck, life-saving, lifesaving, rescue crew, rescue, rocket rescue, rocket crew, lifeboat men, beach rescue, line rescue, rescue equipment, rocket firing equipment, rocket rescue equipment, maritime accidents, shipwreck victim, rocket equipment, marine technology, rescue boat, lifeboat, volunteer lifesavers, volunteer crew, life saving rescue crew, lifesaving rescue crew, rocket apparatus, rocket rescue method, shore to ship, rocket apparatus rescue, stranded vessel, line throwing mortar, mortar, rocket rescue apparatus, line thrower, line throwing, lifeboat warrnambool, rocket house, rocket shed, rocket machine, rocket head, rocket launcher, rocket line, beach rescue set, rocket set, john dennett, rocket key, rocket launcher key, life saving -
Melton City Libraries
Photograph, Melton Fire Brigade Memorial Wall, 2013
Ernest W (Bon) Barrie, 1909 – 1985 Melton Fire Brigade (and predecessor Bush Fire Brigade) Apparatus Officer, 1945 - 1953 Captain, 1951 - 1965 Mt Cotterill Fire Brigades’ Group Elected Group Officer, on the formation of the Group, 1967. As Group Communications Officer he operated the VL3 LY base radio station from home on a 24 hour basis for fire brigades of Melton, Rockbank, Sydenham, Diggers Rest, Toolern Vale, Truganina and Werribee. With his brother Edgar, he built the first Melton Fire Truck. It was housed on the family property until a fire station was constructed in the Melton township. Recipient of the Queens Medal, 1979 Recognised for 44 years of service on the Melton Fire Brigade Memorial Wall Plaque, dedicated May 2013 Mt Cotterell Fire Brigades G H Q and aerial was erected at No 17 - 19 First Avenue in 1974 at the home of Edna and Bon Barrie. Previously the Mt Cotterell Group VL3LY communication headquarters occupied their h ome in Ferris road at its inception in 1967. The First Avenue headquarters and map room, with radio equipment was also housed at the residence. It was operated with an additional cable connection to Fireman Wayne Sullivan (Deputy C/O) who resided at the rear in Kurrajong Cr.Section of the Melton Fire Brigade Memorial wall with brigade members who have passed away while as members. emergency services, local identities -
Flagstaff Hill Maritime Museum and Village
Container - Case, Early 20th century
This small case is lined with a metal insert and shows remnants of a carry strap. It could have been used for storing and carrying fuses or cartridges for the life saving Rocket Launcher machine. The protective metal insert would help keep the contents dry or cool and protect from flame. It is part of the collection of rescue equipment in the Rocket House used by the life saving rescue crew. Saving lives in Warrnambool – The coastline of South West Victoria is the site of over 600 shipwrecks and many lost lives; even in Warrnambool’s Lady Bay there were around 16 known shipwrecks between 1850 and 1905, with eight lives lost. Victoria’s Government responded to the need for lifesaving equipment and, in 1858, the provision of rocket and mortar apparatus was approved for the lifeboat stations. In 1859 the first Government-built lifeboat arrived at Warrnambool Harbour and a shed was soon built for it on the Tramway Jetty, followed by a rocket house in 1864 to safely store the rocket rescue equipment. In 1878 the buildings were moved to the Breakwater (constructed from 1874-1890), and in 1910 the new Lifeboat Warrnambool arrived with its ‘self-righting’ design. For almost a hundred years the lifesaving and rescue crews, mostly local volunteers, trained regularly to rehearse and maintain their rescue skills. They were summoned when needed by alarms, gunshots, ringing bells and foghorns. In July 1873 a brass bell was erected at Flagstaff Hill specifically to call the rescue crew upon news of a shipwreck. Some crew members became local heroes but all served an important role. Rocket apparatus was used as recently as the 1950s. Rocket Rescue Method - Rocket rescue became the preferred lifesaving method of the rescue crews, being much safer that using a lifeboat in rough seas and poor conditions. The Government of Victoria adopted lifesaving methods based on Her Majesty’s Coast Guard in Great Britain. It authorised the first line-throwing rescue system in 1858. Captain Manby’s mortar powered a projectile connected to rope, invented in 1808. The equipment was updated to John Dennett’s 8-foot shaft and rocket method that had a longer range of about 250 yards. From the 1860s the breeches buoy and traveller block rocket rescue apparatus was in use. It was suspended on a hawser line and manually pulled to and from the distressed vessel carrying passengers and items. In the early 1870s Colonel Boxer’s rocket rescue method became the standard in Victoria. His two-stage rockets, charged by a gunpowder composition, could fire the line up to 500-600 yards, although 1000 yards range was possible. Boxer’s rocket carried the light line, which was faked, or coiled, in a particular way between pegs in a faking box to prevent twists and tangles when fired. The angle of firing the rocket to the vessel in distress was measured by a quadrant-type instrument on the side of the rocket machine. Decades later, in 1920, Schermuly invented the line-throwing pistol that used a small cartridge to fire the rocket. . The British Board of Trade regularly published instructions for both the beach rescue crew and ship’s crew. It involved setting up the rocket launcher on shore at a particular angle, determined by the Head of the crew and measured by the quadrant, inserting a rocket that had a light-weight line threaded through its shaft, and then firing it across the stranded vessel, the line issuing freely from the faking board. A continuous whip line was then sent out to the ship’s crew, who hauled it in then followed the instructions – in four languages - on the attached tally board. The survivors would haul on the line to bring out the heavier, continuous whip line with a tail block connected to it. They then secured the block to the mast or other strong part the ship. The rescue crew on shore then hauled out a stronger hawser line, which the survivors fixed above the whip’s tail block. The hawser was then tightened by the crew pulling on it, or by using the hooked block on the shore end of the whip and attaching it to a sand anchor. The breeches buoy was attached to the traveller block on the hawser, and the shore crew then used the whip line to haul the breeches buoy to and from the vessel, rescuing the stranded crew one at a time. The rescue crew wore scarlet, numbered armbands and worked on a numerical rotation system, swapping members out to rest them. This small leather carrying case is significant for its connection with the rocket rescue equipment, local history, maritime history and marine technology. Lifesaving has been an important part of the services performed from Warrnambool's very early days, supported by State and Local Government, and based on the methods and experience of Great Britain. Hundreds of shipwrecks along the coast are evidence of the rough weather and rugged coastline. Ordinary citizens, the Harbour employees, and the volunteer boat and rescue crew, saved lives in adverse circumstances. Some were recognised as heroes, others went unrecognised. In Lady Bay, Warrnambool, there were around 16 known shipwrecks between 1850 and 1905. Many lives were saved but tragically, eight lives were lost.Leather case, brown with contrasting stitching, protective metal insert divided into two compartments. Rectangular shape. Roller buckle on front with remnants of the matching strap. Also remnants of a leather strap on the side, possibly a shoulder strap.flagstaff hill maritime museum and village, flagstaff hill, maritime museum, maritime village, warrnambool, great ocean road, shipwreck, life-saving, lifesaving, rescue crew, rescue, rocket rescue, rocket crew, lifeboat men, beach rescue, line rescue, rescue equipment, rocket firing equipment, rocket rescue equipment, maritime accidents, shipwreck victim, rocket equipment, marine technology, rescue boat, lifeboat, volunteer lifesavers, volunteer crew, life saving rescue crew, lifesaving rescue crew, rocket apparatus, rocket rescue method, shore to ship, rocket apparatus rescue, stranded vessel, line throwing mortar, mortar, rocket rescue apparatus, line thrower, line throwing, line-firing pistol, line throwing gun, schermuly pistol, pistol rocket apparatus, line throwing cartridge, l.s.r.c., lsrc, leather case, cartridge case, fuse case, ammunition case -
Flagstaff Hill Maritime Museum and Village
Uniform - Arm Bands, c. 1860s
Members of the Life Saving Rescue Crew would wear scarlet arm bands such as these as part of their uniform, with each member having a different number. The crew would work as a team to haul in the victims of the shipwreck. The leader of the crew would call out one or several member's numbers to give them a break during the rescue, while other members took their place. All members would then be relieved at some time during the rescue. Saving lives in Warrnambool – The coastline of South West Victoria is the site of over 600 shipwrecks and many lost lives; even in Warrnambool’s Lady Bay there were around 16 known shipwrecks between 1850 and 1905, with eight lives lost. Victoria’s Government responded to the need for lifesaving equipment and, in 1858, the provision of rocket and mortar apparatus was approved for the lifeboat stations. In 1859 the first Government-built lifeboat arrived at Warrnambool Harbour and a shed was soon built for it on the Tramway Jetty, followed by a rocket house in 1864 to safely store the rocket rescue equipment. In 1878 the buildings were moved to the Breakwater (constructed from 1874-1890), and in 1910 the new Lifeboat Warrnambool arrived with its ‘self-righting’ design. For almost a hundred years the lifesaving and rescue crews, mostly local volunteers, trained regularly to rehearse and maintain their rescue skills. They were summoned when needed by alarms, gunshots, ringing bells and foghorns. In July 1873 a brass bell was erected at Flagstaff Hill specifically to call the rescue crew upon news of a shipwreck. Some crew members became local heroes but all served an important role. Rocket apparatus was used as recently as the 1950s. Rocket Rescue Method - Rocket rescue became the preferred lifesaving method of the rescue crews, being much safer that using a lifeboat in rough seas and poor conditions. The Government of Victoria adopted lifesaving methods based on Her Majesty’s Coast Guard in Great Britain. It authorised the first line-throwing rescue system in 1858. Captain Manby’s mortar powered a projectile connected to rope, invented in 1808. The equipment was updated to John Dennett’s 8-foot shaft and rocket method that had a longer range of about 250 yards. From the 1860s the breeches buoy and traveller block rocket rescue apparatus was in use. It was suspended on a hawser line and manually pulled to and from the distressed vessel carrying passengers and items. In the early 1870s Colonel Boxer’s rocket rescue method became the standard in Victoria. His two-stage rockets, charged by a gunpowder composition, could fire the line up to 500-600 yards, although 1000 yards range was possible. Boxer’s rocket carried the light line, which was faked, or coiled, in a particular way between pegs in a faking box to prevent twists and tangles when fired. The angle of firing the rocket to the vessel in distress was measured by a quadrant-type instrument on the side of the rocket machine. Decades later, in about 1920, Schermuly invented the line-throwing pistol that used a small cartridge to fire the rocket. . The British Board of Trade regularly published instructions for both the beach rescue crew and ship’s crew. It involved setting up the rocket launcher on shore at a particular angle, determined by the Head of the crew and measured by the quadrant, inserting a rocket that had a light-weight line threaded through its shaft, and then firing it across the stranded vessel, the line issuing freely from the faking board. A continuous whip line was then sent out to the ship’s crew, who hauled it in then followed the instructions – in four languages - on the attached tally board. The survivors would haul on the line to bring out the heavier, continuous whip line with a tail block connected to it. They then secured the block to the mast or other strong part the ship. The rescue crew on shore then hauled out a stronger hawser line, which the survivors fixed above the whip’s tail block. The hawser was then tightened by the crew pulling on it, or by using the hooked block on the shore end of the whip and attaching it to a sand anchor. The breeches buoy was attached to the traveller block on the hawser, and the shore crew then used the whip line to haul the breeches buoy to and from the vessel, rescuing the stranded crew one at a time. The rescue crew wore scarlet, numbered armbands and worked on a numerical rotation system, swapping members out to rest them. This set of scarlet arm bands is significant for its connection with local history, maritime history and marine technology. Lifesaving has been an important part of the services performed from Warrnambool's very early days, supported by State and Local Government, and based on the methods and experience of Great Britain. Hundreds of shipwrecks along the coast are evidence of the rough weather and rugged coastline. Ordinary citizens, the Harbour employees, and the volunteer boat and rescue crew, saved lives in adverse circumstances. Some were recognised as heroes, others went unrecognised. In Lady Bay, Warrnambool, there were around 16 known shipwrecks between 1850 and 1905. Many lives were saved but tragically, eight lives were lost.Arm bands; three scarlet flannel arm bands with black cotton backing and a metal buckle on one end. White cotton embroidery forms letters and numbers, with each arm band having a different number. Part of the uniform of the Life Saving and Rescue Crew.Embroidered on front "L.S. 1 R.C." "L.S. 8 R.C." "L.S. 13 R.C." flagstaff hill maritime museum and village, flagstaff hill, maritime museum, maritime village, warrnambool, great ocean road, lady bay, warrnambool harbour, port of warrnambool, tramway jetty, breakwater, shipwreck, life-saving, lifesaving, rescue crew, rescue, rocket rescue, rocket crew, lifeboat men, beach rescue, line rescue, rescue equipment, rocket firing equipment, rocket rescue equipment, maritime accidents, shipwreck victim, rocket equipment, marine technology, rescue boat, lifeboat, volunteer lifesavers, volunteer crew, life saving rescue crew, lifesaving rescue crew, rocket apparatus, rocket rescue method, shore to ship, rocket apparatus rescue, stranded vessel, line throwing mortar, mortar, rocket rescue apparatus, line thrower, line throwing, lifeboat warrnambool, arm band, armband, scarlet arm band, l.s.r.c., lsrc, red arm band -
Flagstaff Hill Maritime Museum and Village
Equipment - Tally Board, 1860s
The boards each have instructions adhered to each side, printed in four languages (English, French, Dutch and German). At the beginning of a shore-to-ship rescue the instructions are sent to the distressed vessel after the first rocket line was received by them. The stranded people on the vessel follow the instructions to assist the life saving rescue crew in saving their lives. Saving lives in Warrnambool – The coastline of South West Victoria is the site of over 600 shipwrecks and many lost lives; even in Warrnambool’s Lady Bay there were around 16 known shipwrecks between 1850 and 1905, with eight lives lost. Victoria’s Government responded to the need for lifesaving equipment and, in 1858, the provision of rocket and mortar apparatus was approved for the lifeboat stations. In 1859 the first Government-built lifeboat arrived at Warrnambool Harbour and a shed was soon built for it on the Tramway Jetty, followed by a rocket house in 1864 to safely store the rocket rescue equipment. In 1878 the buildings were moved to the Breakwater (constructed from 1874-1890), and in 1910 the new Lifeboat Warrnambool arrived with its ‘self-righting’ design. For almost a hundred years the lifesaving and rescue crews, mostly local volunteers, trained regularly to rehearse and maintain their rescue skills. They were summoned when needed by alarms, gunshots, ringing bells and foghorns. In July 1873 a brass bell was erected at Flagstaff Hill specifically to call the rescue crew upon news of a shipwreck. Some crew members became local heroes but all served an important role. Rocket apparatus was used as recently as the 1950s. Rocket Rescue Method - Rocket rescue became the preferred lifesaving method of the rescue crews, being much safer that using a lifeboat in rough seas and poor conditions. The Government of Victoria adopted lifesaving methods based on Her Majesty’s Coast Guard in Great Britain. It authorised the first line-throwing rescue system in 1858. Captain Manby’s mortar powered a projectile connected to rope, invented in 1808. The equipment was updated to John Dennett’s 8-foot shaft and rocket method that had a longer range of about 250 yards. From the 1860s the breeches buoy and traveller block rocket rescue apparatus was in use. It was suspended on a hawser line and manually pulled to and from the distressed vessel carrying passengers and items. In the early 1870s Colonel Boxer’s rocket rescue method became the standard in Victoria. His two-stage rockets, charged by a gunpowder composition, could fire the line up to 500-600 yards, although 1000 yards range was possible. Boxer’s rocket carried the light line, which was faked, or coiled, in a particular way between pegs in a faking box to prevent twists and tangles when fired. The angle of firing the rocket to the vessel in distress was measured by a quadrant-type instrument on the side of the rocket machine. Decades later, in 1920, Schermuly invented the line-throwing pistol that used a small cartridge to fire the rocket. . The British Board of Trade regularly published instructions for both the beach rescue crew and ship’s crew. It involved setting up the rocket launcher on shore at a particular angle, determined by the Head of the crew and measured by the quadrant, inserting a rocket that had a light-weight line threaded through its shaft, and then firing it across the stranded vessel, the line issuing freely from the faking board. A continuous whip line was then sent out to the ship’s crew, who hauled it in then followed the instructions – in four languages - on the attached tally board. The survivors would haul on the line to bring out the heavier, continuous whip line with a tail block connected to it. They then secured the block to the mast or other strong part the ship. The rescue crew on shore then hauled out a stronger hawser line, which the survivors fixed above the whip’s tail block. The hawser was then tightened by the crew pulling on it, or by using the hooked block on the shore end of the whip and attaching it to a sand anchor. The breeches buoy was attached to the traveller block on the hawser, and the shore crew then used the whip line to haul the breeches buoy to and from the vessel, rescuing the stranded crew one at a time. The rescue crew wore scarlet, numbered armbands and worked on a numerical rotation system, swapping members out to rest themThis pair of tally board is significant for its connection with local history, maritime history and marine technology. Lifesaving has been an important part of the services performed from Warrnambool's very early days, supported by State and Local Government, and based on the methods and experience of Great Britain. Hundreds of shipwrecks along the coast are evidence of the rough weather and rugged coastline. Ordinary citizens, the Harbour employees, and the volunteer boat and rescue crew, saved lives in adverse circumstances. Some were recognised as heroes, others went unrecognised. In Lady Bay, Warrnambool, there were around 16 known shipwrecks between 1850 and 1905. Many lives were saved but tragically, eight lives were lost.Tally boards, two, rectangular wooden boards, both with a hole drilled into one short end. Instructions are glued onto the boards. They were printed in light letters onto dark canvas in four languages (English, French, Dutch and German). Text (English) "MAKE THIS HAWSER FAST ABOUT 2 FEET ABOVE THE TAIL BLOCK. CAST OFF WHIP FROM HAWSER. SEE ALL CLEAR AND THAT THE ROPE IN THE BLOCK RUNS FREE, AND SHOW SIGNAL TO THE SHORE."flagstaff hill maritime museum and village, flagstaff hill, maritime museum, maritime village, warrnambool, great ocean road, lady bay, warrnambool harbour, port of warrnambool, tramway jetty, breakwater, shipwreck, life-saving, lifesaving, rescue crew, rescue, rocket rescue, rocket crew, lifeboat men, beach rescue, line rescue, rescue equipment, rocket firing equipment, rocket rescue equipment, maritime accidents, shipwreck victim, rocket equipment, marine technology, rescue boat, lifeboat, volunteer lifesavers, volunteer crew, life saving rescue crew, lifesaving rescue crew, rocket apparatus, rocket rescue method, shore to ship, rocket apparatus rescue, stranded vessel, line throwing mortar, mortar, rocket rescue apparatus, line thrower, line throwing, lifeboat warrnambool, beach apparatus, rocket machine, rocket head, rocket launcher, rocket line, beach rescue set, rocket set, tally board, rescue instructions -
Flagstaff Hill Maritime Museum and Village
Functional object - Jug, Between 1910 -1936
The beginning of standardised weights and measures began In Victoria when the Melbourne Observatory received sets of standard weights and measures, which had been tested in Britain against the then British Imperial standards. These included the primary standard yard and pound for the Colony of Victoria. Other standards of weights and measure held by shires and the administrative body's within the colony could then be compared to these primary standards. A Weights and Measures Act was passed in Victoria in 1862, establishing local inspectors throughout the colony. By the 1870s each local council and shire in Victoria held a set of standards that were used to test scales, weights and dry measures used by wholesalers, factories and shops. Every ten years the councils’ standards would themselves need to be rechecked against the Victorian Standards. The checking was done by the Victorian Customs Department in the 19th century, but with the transfer of responsibility for customs to the Federal Government in 1901, weights and measures function was retained by the Victorian Government and was shifted to the Melbourne Observatory. In 1904, a new building was erected at the south end of the Great Melbourne Telescope House, where the standard weights and measures and testing equipment was installed. This room had a large whirling apparatus for testing air meters and became known as the Whirling Room. When the Melbourne Observatory closed in 1944, the Weights and Measures Branch was formed to continue and this branch remained at the Observatory site unit until 1995.An example of a brass measuring jug made specifically to maintain government standard liquid measurements that were sold to the public. The probability is that this artefact was made sometime between George V reign (1910-1936) and gives us today a snapshot of how imperial weights and measures were checked by Government departments prior to decimalisation and how a standard for the various types of measurement was developed in Australian based on the Imperial British measurement system. The container has social significance as an item used in Victoria as a legal standard measure to ensure that goods sold in Victoria were correct. Jug brass haystack form with a deep lip and pouring spout, small neck and broad base. It displays a curved pistol handle. Inscription at base of handle top of jug stamped 61 GVR SM. These marks signify that the measure complied with the Victorian Government capacity liquid standard measurement. Item made during the reign of George V (1910-1936 (GVR).Other marks indicate model number (61) & SM possible could be either small measure, the maker, or Standards Melbourne.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village -
Flagstaff Hill Maritime Museum and Village
Equipment - Galvanised Jug, 1930s
The beginning of standardised weights and measures began In Victoria when the Melbourne Observatory received sets of standard weights and measures, which had been tested in Britain against the then British Imperial standards. These included the primary standard yard and pound for the Colony of Victoria. Other standards of weights and measure held by shires and the administrative body's within the colony could then be compared to these primary standards. A Weights and Measures Act was passed in Victoria in 1862, establishing local inspectors throughout the colony. By the 1870s each local council and shire in Victoria held a set of standards that were used to test scales, weights and dry measures used by wholesalers, factories and shops. Every ten years the councils’ standards would themselves need to be rechecked against the Victorian Standards. The checking was done by the Victorian Customs Department in the 19th century, but with the transfer of responsibility for customs to the Federal Government in 1901, weights and measures function was retained by the Victorian Government and was shifted to the Melbourne Observatory. In 1904, a new building was erected at the south end of the Great Melbourne Telescope House, where the standard weights and measures and testing equipment was installed. This room had a large whirling apparatus for testing air meters and became known as the Whirling Room. When the Melbourne Observatory closed in 1944, the Weights and Measures Branch was formed to continue and this branch remained at the Observatory site unit until 1995.An example of a galvanised measuring jug made specifically to maintain government standard liquid measurements that were sold to the public. The probability is that this artifact was made around the first quarter of the 20th century and gives us today a snapshot of how imperial weights and measures were used before decimalisation and how a standard of measurement for merchants was developed in Australian based on the Imperial British measurement system. The container has social significance as an item used in Victoria as a legal standard measure to ensure that goods sold in Victoria were correct given the item is galvanised it was probability used for kerosene or petrol etc not for liquids used for human consumption. Jug conical shaped with rounded top coming to a very slight point wide handle at back. VIB.L.66 1/2 Gall capacity unsure of the markings 66 could mean the model number capacity is 1/2 an imperial gallon VIB.L markings not known possibly a company or Victorian Department that the jug was made for and no longer active.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village -
Flagstaff Hill Maritime Museum and Village
Galvanised Jug
The beginning of standardised weights and measures began In Victoria when the Melbourne Observatory received sets of standard weights and measures, which had been tested in Britain against the then British Imperial standards. These included the primary standard yard and pound for the Colony of Victoria. Other standards of weights and measure held by shires and the administrative body's within the colony could then be compared to these primary standards. A Weights and Measures Act was passed in Victoria in 1862, establishing local inspectors throughout the colony. By the 1870s each local council and shire in Victoria held a set of standards that were used to test scales, weights and dry measures used by wholesalers, factories and shops. Every ten years the councils’ standards would themselves need to be rechecked against the Victorian Standards. The checking was done by the Victorian Customs Department in the 19th century, but with the transfer of responsibility for customs to the Federal Government in 1901, weights and measures function was retained by the Victorian Government and was shifted to the Melbourne Observatory. In 1904, a new building was erected at the south end of the Great Melbourne Telescope House, where the standard weights and measures and testing equipment was installed. This room had a large whirling apparatus for testing air meters and became known as the Whirling Room. When the Melbourne Observatory closed in 1944, the Weights and Measures Branch was formed to continue and this branch remained at the Observatory site unit until 1995. An example of a galvanised measuring jug made specifically to maintain government standard liquid measurements that were sold to the public. The probability is that this artifact was made around the first quarter of the 20th century and gives us today a snapshot of how imperial weights and measures were used before decimalisation and how a standard of measurement for merchants was developed in Australian based on the Imperial British measurement system. The container has social significance as an item used in Victoria as a legal standard measure to ensure that goods sold in Victoria were correct given the item is galvanised it was probability used for kerosene or petrol etc not for liquids used for human consumption. Galvanised Iron jug with rounded top, Inscription on handle at back. 2 gallon GV.35flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village -
Flagstaff Hill Maritime Museum and Village
Functional object - Galvanised Jug
The beginning of standardised weights and measures began In Victoria when the Melbourne Observatory received sets of standard weights and measures, which had been tested in Britain against the then British Imperial standards. These included the primary standard yard and pound for the Colony of Victoria. Other standards of weights and measure held by shires and the administrative body's within the colony could then be compared to these primary standards. A Weights and Measures Act was passed in Victoria in 1862, establishing local inspectors throughout the colony. By the 1870s each local council and shire in Victoria held a set of standards that were used to test scales, weights and dry measures used by wholesalers, factories and shops. Every ten years the councils’ standards would themselves need to be rechecked against the Victorian Standards. The checking was done by the Victorian Customs Department in the 19th century, but with the transfer of responsibility for customs to the Federal Government in 1901, weights and measures function was retained by the Victorian Government and was shifted to the Melbourne Observatory. In 1904, a new building was erected at the south end of the Great Melbourne Telescope House, where the standard weights and measures and testing equipment was installed. This room had a large whirling apparatus for testing air meters and became known as the Whirling Room. When the Melbourne Observatory closed in 1944, the Weights and Measures Branch was formed to continue and this branch remained at the Observatory site unit until 1995.An example of a galvanised measuring jug made specifically to maintain government standard liquid measurements that were sold to the public. The probability is that this artifact was made around the first quarter of the 20th century and gives us today a snapshot of how imperial weights and measures were used before decimalisation and how a standard of measurement for merchants was developed in Australian based on the Imperial British measurement system. The container has social significance as an item used in Victoria as a legal standard measure to ensure that goods sold in Victoria were correct given the item is galvanised it was probability used for kerosene or petrol etc not for liquids used for human consumption. Jug galvanised conical shaped with rounded top, handle at back. 3 gallon GV.27flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village -
Flagstaff Hill Maritime Museum and Village
Equipment - Jug
The beginning of standardised weights and measures began In Victoria when the Melbourne Observatory received sets of standard weights and measures, which had been tested in Britain against the then British Imperial standards. These included the primary standard yard and pound for the Colony of Victoria. Other standards of weights and measure held by shires and the administrative body's within the colony could then be compared to these primary standards. A Weights and Measures Act was passed in Victoria in 1862, establishing local inspectors throughout the colony. By the 1870s each local council and shire in Victoria held a set of standards that were used to test scales, weights and dry measures used by wholesalers, factories and shops. Every ten years the councils’ standards would themselves need to be rechecked against the Victorian Standards. The checking was done by the Victorian Customs Department in the 19th century, but with the transfer of responsibility for customs to the Federal Government in 1901, weights and measures function was retained by the Victorian Government and was shifted to the Melbourne Observatory. In 1904, a new building was erected at the south end of the Great Melbourne Telescope House, where the standard weights and measures and testing equipment was installed. This room had a large whirling apparatus for testing air meters and became known as the Whirling Room. When the Melbourne Observatory closed in 1944, the Weights and Measures Branch was formed to continue and this branch remained at the Observatory site unit until 1995.An example of a galvanised measuring jug made specifically to maintain government standard liquid measurements that were sold to the public. The probability is that this artifact was made around the first quarter of the 20th century and gives us today a snapshot of how imperial weights and measures were used before decimalisation and how a standard of measurement for merchants was developed in Australian based on the Imperial British measurement system. The container has social significance as an item used in Victoria as a legal standard measure to ensure that goods sold in Victoria were correct. Jug conical shaped with rounded top coming to a very slight point wide handle at back. VIB.L.66 1/2 Gall capacityflagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village -
Federation University Historical Collection
Equipment - Projector, Victor Bioscope, c1910
A Bioscope show was a fairground attraction consisting of a travelling cinema. The heyday of the Bioscope was from the late 1890s until World War I. Bioscope shows were fronted by the largest fairground organs, and these formed the entire public face of the show . A stage was usually in front of the organ, and dancing girls would entertain the crowds between film shows. Films shown in the Bioscope were primitive, and the earliest of these were made by the showmen themselves. Later, films were commercially produced. Bioscope shows were integrated, in Britain at least, into the Variety shows in the huge Music Halls which were built at the end of the nineteenth century. After the Music Hall Strike of 1907 in London, bioscope operators set up a trade union to represent them. There were about seventy operators in London at this point. (http://en.wikipedia.org/wiki/Bioscope_show) The Projector was a rather unreliable piece of apparatus, powered by a variety of light sources, including Calcium Oxide (Lime-Light). A Calcium Carbide Burner, or the rather more superior Carbon Arc. All these methods were highly unpredictable & quite frankly...dangerous! Often resulting in explosions, burning down the entire Show! (which is probably why NO original Shows still exist. Alfred Ball's Bioscope, pictured below, built in 1905 was struck by lightning, shortly after the picture was taken! (http://www.circus-entertainer.co.uk/heritage.htm) In 1909 the first bioscopes pictures were shown at the Ballaarat Mechanics' Institute.Brass and green painted metal film projectorbioscope, vector, entertainment, projector, film, theatre, movie -
University of Melbourne, School of Chemistry
Gold Assay Balance
Born in Ireland, John Drummond Kirkland trained as a chemical analyst through apprenticeship in a medical laboratory in Dublin, before migrating to Australia in 1852 and moving to Melbourne in 1855. While still an undergraduate medical student at the University of Melbourne, he was appointed lecturer in chemistry following the sudden death of John Macadam in 1865. Due to the enthusiastic support of his fellow students this temporary role became a permanent appointment the following year. Kirkland continued his studies, graduating in medicine in 1873 and surgery in 1880. His son, John Booth Kirkland, was appointed as his assistant in 1878, later leading to accusations of nepotism. In 1882 John Drummond Kirkland became the University?s first professor of chemistry and metallurgy, continuing until his death in 1885. Today?s researchers use a high performance computing facility named ?Kirkland? after the first Professor of Chemistry at the University of Melbourne. Chemistry was still controlled by the medical school during Kirkland?s career, but became part of the science degree from 1886, along with the appointment of David Orme Masson as professor. Kirkland struggled for University funding to buy new apparatus. To compensate, he bought much from his own personal funds, including analytical chemistry equipment. Chemistry was first taught at Melbourne in the medical school, located in the area now occupied by Physics and the Ian Potter Museum of Art.Gold Assay Balance, almost certainly Kirkland's own. -
Parks Victoria - Gabo Island Lightstation
Tanks, kerosene vaporiser
The heavy twin tanks formerly contained vaporised kerosene which was used as a fuel to light the lantern. Kerosene became available in the 1860s as the oil industry in the United States developed, and vaporised kerosene soon became the most common system of illumination. The kerosene vapour lamp was perfected by Chance Bros. for burning the light in their renowned lenses. The system involved vaporising kerosene under pressure and mixing it with air and then burning the vapour to heat an incandescent mantle. The lamp had to be watched throughout the night in case a mantle broke, and the tanks needed to be maintained by hand-pumping each hour or so. Kerosene tanks like these were developed in the early twentieth century, and kerosene as a fuel was phased out by electricity, with the last kerosene system in Australia eventually replaced in 1985. The wick lamp in Gabo Island’s light was altered to a vaporised incandescent kerosene mantle burner in 1909. They would have been in use until 1935, when the light was electrified and the original first-order lens was replaced by a fourth-order lens. The Gabo Island tanks, which are presumed to be those used in the lighthouse between 1909 and 1935, are not attached to the optical apparatus and are no longer in the lighthouse. They are also missing the pressure gauges that were formerly attached to the top of each cylinder. Cape Schanck has a pair of unattached tanks, which are not historically associated with the lighthouse. Point Hicks has an iron stand that formerly supported its lighthouse oil tanks. Despite their lack of intactness, the Gabo Island tanks have first level contributory significance for their provenance to the lightstation and historic association with the lantern’s original Chance Brothers first order lens, which was removed in 1935Two large green cylinders standing in a metal frame. There is also a pumping mechanism attached to the stand with a wooden handle. -
Federation University Historical Collection
Book, Mechanics' Magazine vol. 3, 1825 (exact)
Hardcovered book, half leather bound with marbled paper. Formerly book number 4040 from the Ballaarat East Public Library. Contents include: new pit-saw, self-moving carriage (car), Lord Worcestor's steam engine, extinction of fires, Cameron's Soda Water Apparatus, Newton's Lectures on Astronomy, coining at the Royal Mint, mechanical geometry, lifting ships by steam, voltaic-mechanic agent, steam navigation, portable hand-mill, Brown's pneumatic engine, Bell's invention for saving lives from shipwreck, triple pump, cycloidal chuck, potato-washer, sand clock, Galvanic electricity, perpetual motion, Hadley's Quadrent, Wollaston's Night-Bolt, rope bridges, boring machinery, locomotive steam-engines, new London Bridge, naval architecture, steam and water wheel, Spencer's Patent Forge, boat with wings, ivory profile portraits, Jenning's Gas burner, Ramage's Telescope, washing machine, tallow lamp, iron masts, self regulating pendulum, prismatic compass, simple blowpipe. Includes image of Henry Brougham, and many drawings of inventions.non-fictioncar, newton, fire, shipwreck, bell, naval architecture, locomotive, ballaarat east public library, ballarat east public library, ballarat east library, henry brougham, potassium, meridian lines, pit saw, self moving carriage, lord worcestor, steam engine, cameron s, soda water, astronomy, royal mint, mechanical geometry, lifting ships by steam, voltaic mechanic agent, steam navigation, hand mill, brown s pneumatic engine, triple pump, cycloidal chuck, potato washer, sand clock, galvanic electricity, perpetual motion, hadley s quadrent, wollaston s night bolt, rope bridges, boring machinery, steam engines, new london bridge, steam and water wheel, spencer s patent forge, boat with wings, ivory profile portraits, jenning s gas burner, ramage s telescope, washing machine, tallow lamp, iron masts, self regulating pendulum, prismatic compass, simple blowpipe, bookplate -
Moorabbin Air Museum
Accessory (Item) - Beaufighter Pilots Escape kit
-
Moorabbin Air Museum
Accessory (Item) - Leather Satchel Marked With Associated Airlines - Melbourne
-
Phillip Island and District Historical Society Inc.
Photograph Album, Kodak, Phillip Island Cemetery, c 1990
The Album was compiled by Nancy McHaffie late 1990's, with the assistance of Edith Jeffery's, with her book "Garden of Memories" and extensive knowledge of Phillip Island. The Cemetery lies back from the road and is surrounded by Manna Gums, rare Peppermint Gums, Blackwoods and other native trees. In all 25 acres of land were set aside as Crown Land in the land settlement of 1868. There are 6.2 acres of wetlands near the cemetery entrance.466-29: John Blake Cleeland lived in the house his father built, "Woolamai House" in Newhaven. His property ran cattle, horses and angora goats. He had a great love of the sea although he never went to sea. He logged all shipping movements around the Eastern passage of Westernport. He was Captain-in-charge of the Rocket Apparatus Station at Newhaven, which was a rescue service for shipping. 466-30: Eleanor Blake (nee Lucas) came out from Ireland in 1860 together with her husband Edward Hudson Blake and children. For most of her life in Australia, she resided at Hastings. Her youngest daughter Isabella married John Cleeland, both of whom are buried in the cemetery. Eleanor moved from Hastings to "Woolamai House" in later years. 466-31: Margaret Jane Cleeland (nee Kennon) married John Blake Cleeland on May 21st 1903 at South Yarra. She was the daughter of Stanley Stowell Kennon, a farmer and her mother was Isabella (nee Turner). Margaret died in 1909 at the age of 30 years. At the time of her death she was survived by three children: Eileen Henrietta, Ivy Florence & Reita Vermont.phillip island cemetery, nancy mchaffie, edith jeffery, cleeland -
Kiewa Valley Historical Society
Electric Megger (Insulation Tester) and its case
Megger as the device was called, is in fact its brand name. It is a device that supplies a DC (direct current as per car batteries) voltage to enable testing of electrical apparatus. This particular device produces 250volts DC when the handle is turned vigorously. If an electrical device, such as a kettle or toaster, blew a fuse or tripped a circuit breaker, when switched on, then it must be checked electrically before any more use. Following the repair of the faulty item a megger would be used to check if either of the AC 240volt plugs leads were touching the metal case (earth). The output leads of the megger would be connected with one to the earth (metal case) and the other to each of the power connections in turn. A good megger reading of 50,000 ohms (resistance) would enable the device to be returned to service. A reading of zero ohms resistance would mean that it would again blow a fuse, and was therefore unsafe to use. In the electrical industry e.g. the former State Electricity Commission, a megger would be used to test lots of similar item in sequence. Because of the vigorous job of winding the handle, two persons were often used to save time. One would crank madly whilst the other shifted the leads. This particular megger is of a small voltage, but other meggers are bigger and have a few ranges of DC voltages able to be selected. The optimal megger for large Generating machines was motor driven megger. This was applied to the device being tested for a duration of approximately 30 minutes with reading of the resistance taken at regular intervals.All equipment belonging to the State Electricity Commission of Victoria was labelled with a metal plaque attached to it. The SECV constructed the Kiewa Hydro Electric Scheme in the Upper Kiewa Valley and on the Bogong High Plains. The scheme began in 1938 and finished in 1961 when this megger was used and also possibly later as the SECV remained to maintain and operate the Scheme. This megger is of significance in relation to the advancement of technology.A rectangular box in dark brown bakerlite casing. It has an agent's plaque fixed to the left of the face and on the right is the marker's recessed stamp. In the middle in a transparent window so the level of ohms can be read. The front also has two recessed fixing knobs in black. On one side is a crank handle with a knob that lifts up and is turned vigorously to create the voltage. The back has four recessed screws and four small leather pads. There is a hole on each side to insert wires. There are two copper insulated wires. The SECV Plaque states: State/Electricity Commission/of/Victoria/ Electrical Engineer's Section/ No.1747 The Agent's Plaque states: H. Rowe & Co. Pty Ltd/Melbourne & Sydney/Sole Agents/in Australia for/Evershed & Vignoles Ltd Maker's states: 500 volts/Megger/Regd Trade Mark/Made in England/Patent No/400728electrical meters, electrical equipment, fuses, safety, state electricity commission of victoria, mt beauty, bogong village -
Federation University Historical Collection
Document - Document - Syllabus, Education Department: Technical Schools Syllabus, 1921
A syllabus for each subject taught in Technical Schools that was provided by the Education Department of Victoria. .1: Syllabus for Heat Engines - side 1, Grade 1; side 2, Grade 2 .2: Syllabus for Refrigeration - Grade 1 and Grade 2 on side 1. .3: Syllabus for Farm Irrigation and Irrigation Engineering - side one, Farm Irrigation; side 2, Irrigation Engineering. .4: Mechanics and Mechanics applied to Mining - 4 pages covering Mechanics (Applied) Grade 1, Grade 2, Mechanics (Applied) Structures, Grade 3, Mechanics (Applied) Machines, Grade 3; Mechanics Applied to Mining and Theoretical Mechanics .5: Syllabus for Mechanics and Heat - First Grade Mechanics students will be required to know the general principles and formulae of the science, apparatus used method of using and to verify formulae experimentally. Second Grade course includes all subjects for Grade 1 plus Newton's proof of the parallelogram of forces, rotation round fixed axis, laws of rotary motion of a body, resistance, harmonic motion, friction,impulsive forces, barometer corrections and Heat and thermodynamics. Third Grade students, an intimate knowledge of the courses for first and second grades plus remaining portions of thermodynamics. A special course for Evening Students in Mechanics and Heat outlined. .6: Syllabus for Electricity - covers the requirements for First Grade, Second Grade and Grade 3. Areas covered are Magnets and Magnetism, Electroscopes and Electrification, Electronic Fields, Voltaic Electricity, Measurement of Current, Electromagnetism, Amperemeters, Resistance, Electrical Technology,A5 size pages, typed. Some are doubled sided.education department victoria, technical schools, syllabus, 1921, heat engines, refrigeration, farm irrigation, irrigation engineering, mechanic, mechanics applied to mining, mechanics and heat, electricity -
Bay Steamers Maritime Museum
model steam engine
This model was found in the collection of Bay Steamers Maritime Museum. It is not knowt who created it but it is supposed that it was constructed to educate the many masters of the Wattle in the operation of a steam engine - a not so common mode of power these days. A Bay Steamers Maritime Museum examined the model in March 2012 and discovered that is was in poor repair. Using his existing knowledge, and with reference to some historic texts, he made some repairs and returned the model to working order. Here is his anaylsis of the situation as an excerpt from the Bay Steamers Maritime Museum newsletter Steamlines May 2012 "I was confronted with a model of a steam engine used years ago as a training aid for hopeful steam engineers. Already having a knowledge of steam operations, I considered a museum write-up for that model a ‘piece of cake’. However, on turning the model’s crankshaft, the valve timing seemed ‘out of kilter’ with the movement of the piston. Problem was that the two eccentrics on the crankshaft were not properly secured to it. Eventually I fastened the two eccentrics to the crankshaft where I felt that they should be and then realized that one of them had a chain-driven valve-timing device attached. This would be adjusted while an engine was running to achieve best performance and fuel economy whilst in operation by accurately controlling the period of time during which steam under pressure from the boiler would be admitted to the cylinder and give greater time for the steam to expand in the cylinder, move the piston and turn the crankshaft and thus, drive the attached apparatus. When the valves were correctly set up it was then possible to get the model to function properly.The model comprises a green section, which is the actual the model mounted on a brown painted board. There are two parts of the model, painted white representing the steam passages, and black representing the cast- iron portions of the cylinder-block casting, and of the main valve sliding between the cylinder a second sliding valve. Of the black portions, one slides back and forth being connected to a rod which is connected to an eccentric clamped to the crankshaft and is the nearer to the flywheel of two eccentrics. This eccentric is attached to the crankshaft at an angle of 90 degrees to the crank-pin attached to the flywheel. To operate the model simply turn the flywheel by means of the handle attached to its crank-pin. A second eccentric is also attached to the crankshaft, further away from the first eccentric, and it is adjusted to operate 90 degrees from the first eccentric (that is, 180 degrees from the crank-pin) A piston (painted silver) is located in a plastic cylinder and has a piston rod which passes through one end of the cylinder, (in actual practice a steam-proof gland seals the cylinder against loss of steam) terminating in a cross-head slide between four rails guiding it. From this cross-head, a connecting rod joins the piston-rod to the flywheel via the crank-pin attached to the flywheel which is part of the crankshaft. (In actual practice, a flywheel may not be used, particularly in a multi-cylinder engine.) The white portions of the model painted nearest to the cylinder represent the two steam ports cast into the main cylinder block, whilst one section painted in between those two represents the exhaust outlet (which may be connected to a condenser to conserve water, or to the open air). The main slide valve has three white-painted portions painted thereon. It has two white-painted marks representing the steam passages to the steam ports into the cylinder, and a third section in between the other two, being that part of the valve through which exhaust steam passes in line with the ports in the cylinder block. By rotating the flywheel, the operations of an engine will be observed as steam is admitted to the main valve via the gap between the two jaws of two moveable portions of a second sliding valve which is operated by the second eccentric attached to the crank-shaft. This eccentric is used to finely tune the valve timing of this model to obtain best running results of an engine. There are various methods used for reversing a steam engine. model compound steam engine, steam engine, model, crankshaft, valve, flywheel, wattle, engineer, eccentrics -
Melton City Libraries
Document, Design of Dinner, c.1970
Melton Fire Brigade history In a letter to George Minns of 24th March 1942 from the Forests Commission the brigade was registered Class ‘F’ with the certificate of Registration N. 425. In December 1935 a public meeting was held with the purpose of forming a bush fire brigade. Constable Roy Corbett was elected Captain a position he held until 1941 and 1945 –1949. 1942 EW Barrie. 1st Lieut 2nd Lieut TL Barrie 1943 EW Barrie 2nd Lieut 1944 : : MELTON RURAL FIRE BRIGADE Established under CFA act 1944 1945- 1953 EW Barrie Apparatus Officer 1951- 1965 EW Barrie Captain 1967- 1979 EW Barrie elected Group Communication Officer of the Mt Cotterill Fire Brigades. RADIO In 1954 the Fire Brigade introduced 2 HF (high frequency) radios, one was installed in the Fire truck and the other in the Captains utility. 1956- 16th March Licence granted to the County Fire Authority Melton to establish a MOBILE transmitting and receiving station. Area of operation, Melton and District on the frequency (kc/s) 3836 for the exchange of messages relating to the fighting and prevention of fires during actual fires or periods of fire hazard with the CFA Bacchus Marsh base station VL3OX. 1958- 22nd May Commonwealth of Australia, Postmaster-General’s Department Special Licence No H 702 under the Wireless Telegraphy Act 1905-1950 is hereby transferred to Mr. E.W. Barrie, Captain, Melton Rural Fire Brigade to establish a MOBILE transmitting and receiving station. Call sign VL3 OX 6 and VL 3OX 7Group officer Bon Barrie's invitation to a Fire Brigade formal dinner emergency services -
Flagstaff Hill Maritime Museum and Village
Ship Log, 1900-1920
Thomas Walker & Son was internationally renowned in the manufacturing of ships logs. Founding father Thomas Walker (1805–1871), an engineer in Birmingham, patented a mechanical log in 1878 which was a recording instrument that attached to a rail at the stern of a vessel connected by a long cord with a rotor which was towed behind the ship. The instrument dial recorded the distance travelled. Thomas Walker first went into business to manufacture stoves at 58 Oxford Street Birmingham. Walker’s self-feeding stove was widely lauded at the Paris Exhibition of 1855, winning a prize medal and kick starting the first of many notable innovations for the Walker family's manufacturing business. However, it wasn’t until working on an earlier ships log model invented by his Uncle that Thomas Walker became interested in the further development of this device, used to ascertain a ship’s speed. Walker continued to improve on the common log for the company of Massey & Sons and these improvements were deemed revolutionary. This log became a firm favourite of the West India Association (British-based organisation promoting ties and trade with the British Caribbean) and the most common log in use for two generations. It took till 1861 for Thomas Walker and his son, Thomas Ferdinand Walker (1831-1921) to patent the first Walker log of many. Together, with the introduction of the A1 Harpoon Log two years later, they established the Walker Log Business as a force to be reckoned with. By the time of his passing in 1871, Thomas Walker Snr had not only founded a family business with considerable staying power but also instilled a tradition of public service. Having sat as a representative on the Birmingham Town Council for 15 years and played an active role in public works, he was soon given the nickname of ‘Blue Brick Walker’. Much like his father, Thomas Ferdinand Walker changed the face of the maritime industry. His patent of 1897, the ‘Cherub’ log, was a notable departure from the past providing a far more accurate reading and replacing the majority of logs of the age. They were the first to produce an electric log and the Walker factory was one of the first to introduce the 48 hour work week for employees. This ship log was invented and made by a significant marine instrument maker and innovator of machinery. It demonstrates the huge leap taken to improve navigational accuracy at sea with an instrument that was in use for decades. Ship Log, three analogue dials calibrated in increments of Miles, the Rocket Log is a nautical instrument for measuring a vessel’s speed and distance traveled. The floating log was drawn behind the ship over a fixed time period in order to measure the distance traveled. The counter could measure enough miles to cover the maximum distance traveled by a ship in one day. The log has two distinct parts; a brass register, made by Walker, showing the distance recorded and the rotator made by Reynolds, that spins in the water driving the counter. both parts are connected by a linked chain. The register has a cylindrical brass body approx 4.5 cm diameter containing registering mechanism with hardened steel bearings. Distance is indicated by the three pointers on enamel plate as follows: graduated every 10 miles from 0-100; every mile from 1-10; every 1/4 mile from 1/4 -1. A brass sling and eye secured to the body enables it to be attached to the taffrail. The original rotator would have had a cylindrical tapered wooden body, approx 4.5 cm in diameter with three metal alloy fins or could be all made from brass. A towing eye is fitted to the tapered end. The two pieces of apparatus are connected by a length of linked chain, length 22.9 cm."Walkers Rocket Ship-Log Birmingham (Patented)" printed on face-plate. "Made by Thomas Walker".flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, ship log, rocket log, mechanical ship log, measuring instrument, marine instrument, nautical instrument, speed recording instrument, ship log register, walker ship log, walkers rocket ship-log, thomas walker, thomas walker & son, thomas ferdinand walker, walker log business, reynolds ship log rotor, taffrail log, taff rail log, west india association -
Bendigo Military Museum
Photograph - PHOTOGRAPHS WW1, c. 1915 - 1919
Items relating to the collection re Alexander Norman Cummin No 18, 38th Batt AIF, his brother Harold Nesbit Cummin No 1239 Camel Corp. Refer 2535P (Alexander) 2530.3P (Harold) for their service details. .6) Graves photo. On the left, Sydney Graham Issell. He had 4 years pre war service in Senior cadets and Citizens Forces reaching the rank of Sgt. Enlisted on 8.2.1916 No 912 with the rank of Cpl, C Coy 38th Batt age 21 years 11 months. Embark for England 20.6.1916, promoted L/Sgt, embark for France 22.11.1916, hospital 13.5.1917 (NYD) rejoin unit 19.5.1917, WIA 29.5.1917 GSW chest then restated GSW Back, severe, rejoin unit 12.3.1918, KIA 1.8.1918. On the right, Harold James Fraser. He had 5 years pre war service in the Cadets and Citizens Forces. Enlisted on 27.10.1916 No 2802 6th reinforcements 38th Batt age 22 years. Embark for England 16.12.1916, moves through 10th, 14th Training Batt’s then 66th Batt on 28.4.1917, promoted Sgt and alloted No 2802A, embark for France 25.8.1917 as reinforcement 38th Batt, awarded the Military medal (MM)) 12.10.1917 East of Eypres, KIA 1.8.1918. Both were buried at Vaire Wood near Corbie. .1) 2 Australian soldiers in fatigues with what looks like a cooking apparatus, with letters below DROW EC (stylised). .2) 1/2 length portrait of an Australian soldier. .3) Casual portrait of a soldier sitting in fatigues, probably Sandy. Boots look muddy, scrub in background. .4) Portrait of 2 soldiers (allied) fully armed & wearing helmets. .5) Portrait of a soldier (allied) fully armed & dangerous. .6) Black & white photo of 2 graves with white crosses. Soldiers left cross: No 912 SGT SG ISSELL 38 BN AIF, Soldier right cross: No 2802 SGT HJ FRASER 38 BN AIF. .7) Black & white photo showing 2 Australian soldiers casually dressed in the ruins of an old factory. .8) Black & white mini photo showing building ruins & what appears to be derelict boilers. .9) Black & white mini photo showing what appears to be a WWI German soldier kamerading (surrendering). This is probably posing in captured enemy clothing. 10.) Black & white mini photo showing camels at rest. .11) Black & white mini photo showing a blown up British pattern tank MK1 on sandy terrain. A track has detached & curled up over the front of the tank. .1) verso: “Me & Sandy Port De Nieppe May 1917” .2) verso: “Taken in Liverpool, England while on <> leave Jan 1918. To Mother Father & all at home with love from Sandy”photography-photographs, military history - army, 38th -
Flagstaff Hill Maritime Museum and Village
Compass, 1947-1950
Kelvin Company History: The origins of the company lie in the highly successful, if strictly informal, the relationship between William Thomson (1824-1907), Professor of Natural Philosophy at Glasgow University from 1846-1899 and James White, a Glasgow optical maker. James White (1824-1884) founded the firm of James White, who was an optical instrument maker in Glasgow in 1850. He was involved in supplying and mending apparatus for Thomson's university laboratory and working with him on experimental constructions. White was actually declared bankrupt in August 1861 and released several months later. In 1870, White was largely responsible for equipping William Thomson's laboratory in the new University premises at Gilmore hill. From 1876, he was producing accurate compasses for metal ships to Thomson's design during this period and this became an important part of his business in the last years of his life. He was also involved in the production of sophisticated sounding machinery that Thomson had designed to address problems encountered laying cables at sea, helping to make possible the first transatlantic cable connection. At the same time, he continued to make a whole range of more conventional instruments such as telescopes, microscopes and surveying equipment. White's association with Thomson continued until he died. After his death, his business continued under the same name, being administered by Matthew Edwards (until 1891 when he left to set up his own company). Thomson, who became Sir William Thomson and then Baron Kelvin of Largs in 1892, continued to maintain his interest in the business after James White's death in 1884, raising most of the capital needed to construct and equip new workshops in Cambridge Street, Glasgow. At these premises, the company continued to make the compass Thomson had designed during the 1870s and to supply it in some quantity, especially to the Admiralty. At the same time, the firm became increasingly involved in the design, production and sale of electrical apparatus. In 1899, Lord Kelvin resigned from his University chair and became, in 1900, a director in the newly formed limited liability company Kelvin & James White Ltd which had acquired the business of James White. At the same time Kelvin's nephew, James Thomson Bottomley (1845-1926), joined the firm. In 1904, a London branch office was opened which by 1915 had become known as Kelvin, White & Hutton Ltd . Kelvin & James White Ltd underwent a further change of name in 1913, becoming Kelvin Bottomley & Baird Ltd . Hughes Company History: Henry Hughes & Sons was founded in 1838 in London as a maker of chronographic and scientific instruments. The firm was incorporated as Henry Hughes & Sons Ltd in 1903. In 1923, the company produced its first recording echo sounder and in 1935, a controlling interest in the company was acquired by S Smith & Son Ltd resulting in the development and production of marine and aircraft instruments. Following the London office's destruction in the Blitz of 1941, a collaboration was entered into with Kelvin, Bottomley & Baird Ltd resulting in the establishing Marine Instruments Ltd. Following the formal amalgamation of Kelvin, Bottomley & Baird Ltd and Henry Hughes & Sons Ltd in 1947 to form Kelvin & Hughes Ltd., Marine Instruments Ltd then acted as regional agents in the UK for Kelvin & Hughes Ltd who were essentially now a part of Smith's Industries Ltd founded in 1944 and the successors of S Smith & Son Ltd. Kelvin & Hughes Ltd went on to develop various marine radar and echo sounders supplying the Ministry of Transport, and later the Ministry of Defence. The firm was liquidated in 1966 but the name was continued as Kelvin Hughes, a division of the Smiths Group. In 2002, Kelvin Hughes continues to produce and develop marine instruments for commercial and military use. This model compass is a good example of the commercial type of instruments made by Kelvin & Hughes after the world war 2, it was made in numbers for use on various types of shipping after the second world war and is not particularly rare or significant for it's type. Also it was made no earlier than 1947 as the firms of Kelvin, Bottomley & Baird Ltd and Henry Hughes & Sons Ltd who took over from Smith & Sons were not amalgamated until 1947. Given that Smith and Sons is engraved on the compass with Kelvin & Hughes it can be assumed that this compass was made during the company's transitional period to Kelvin & Hughes.Compass, marine or ship's card compass, gimble mounted, with inscriptions. Type is Lord Kelvin 10 inch compass card. Made in Great Britain by Kelvin Hughes Division of S. Smith & Sons (England) Ltd. "LORD KELVIN 10.", "COMPASS GRID", "MANUFACTURED IN GREAT BRITAIN BY", "KELVIN HUGHES DIVISION", "S. Smith & Sons (England) Ltd".flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, marine compass, gimble compass, ship's compass, lord kelvin compass, smith and sons england ltd, henry hughes & son ltd london england, kelvin bottomley & baird ltd glasgow scotland, kelvin & hughes ltd, navigation instrument, scientific instrument, william thomson, james white, baron kelvin of largs -
Ballarat Tramway Museum
Manual, Doug Prosser, "General Electric Data for Car Equipment Maintenance", 1998
A black plastic folder containing a set of 38 General Electric Data Sheets for MMTB and tramway trust equipment, dated July 8 1924. Contained in folder with flexible clips. Pages have been punched with four holes. Copy of document made for BTM Feb 1998 by Doug Prosser. For scan of list - see btm780sheet.pdf General Electric Data for Car Equipment Maintenance Contents For scan see btm780d1 (5 pages) Title sheet Data contents summary sheet showing manual prepared for Melbourne & Metropolitan Tramways Board Including Footscray Tramway Trust Hawthorne Tramways Trust Melbourne, Brunswick and Coburg Tramway Trust Prahran and Malvern Tramways Trust. 2 sheets dated July 8, 1924 giving equipment schedules for the various operators, and diagrams. - hard to read the background sheet information. Does not reference the tramcars. For scan see btm780d2 (54 sheets - items 1 to 27) 1. Methods of Removing the Armature from Box Frame Railway Motors Dated 9/1924, 7 pages 2. Instructions for order Magnet Frames for Railways and Mine Haulage Motors 2 pages, not dated 3 Winter Covers for Ventilated Railway Motors - 2 pages 4 Better Commutation for Railway Motors - 1 page 5 Commutator Grooving Machines - 1 page 6 Railway Motor Armature Coils - 2 pages 7 Carbon Brushes for Railway motors - including brush pressure adjustment - 2 pages 8 Renewable Carbon-Way Brush holders for Railway Motors - 2 pages 9 Commutator Grooving Machines (2nd version) - 2 pages 10 The Repair of Railway Motor Commutators - 3 pages 11 Dimensions of Electrical Apparatus used with 600-volv Type PC railway control equipment, (Sheet 15380, dated 2/1/1924) - 1 sheet including · US-13-E Trolley Base, · MS-118-A main switch, · MA-13-F Fuse Box, · MD3 - lightning Arrester, · BJ-386-B Distributing Box, · Type BG Railway Resistors. 12 Connections of Type KM-63-BR Railway Controllers and Equipment - Drawing 15257, 1 page, dated 1/3/1921 with dimension details on rear of type K-63-BR railway controller equipment including: · SG Resister, · BK-13-A Insulator, · MR11 - Circuit breaker, · MD3 - Lightning Arrester box, · K63-BR Controller, · US15C Trolley Base. 13 Method of Supporting Railway Resistors using Porcelain Bolt insulators for 600 and 1500 Volt Work. Drawing dated 1/11/1923, No. 15249B - 1 page 14 Dimensions of Electrical Apparatus used with 600-volv Type M railway control equipment, (Sheet 15381, dated 2/1/1924) - 1 sheet including · US-13-E Trolley Base, · MS-118-A main switch, · MA-13-F Fuse Box, · MD3 - lightning Arrester, · BJ-386-B Distributing Box, · Type BG Railway Resistors. 15 Dimensions of Electrical Apparatus used with 600Volt, Type PC Railway Control Equipment. Drawing No. 15382, dated 2/1/1924. Includes: · C129-A Master Controller, · DA82C Coupler sockets, · MS-14-G switch, · MS-46-H switch. 16 Dimensions of Electrical Apparatus used with 600-volv Type M railway control equipment, (Sheet 15383, dated 2/1/1924) - 1 sheet including · C-169-A Controller · DA-69-B Coupler Socket and DC-66-C Coupler Plug · MS-14-G Switch · MS-46-H-Switch 17 Method of Making Tap Connections for Car Cables -= SD 15468, 1/11/1924, 1 page 18 The Repair of 600 Volt Railway Motor Armatures, 64408, 9/2/1924, 4 pages 19 Proper Method of Mounting and Dismounting Railway Motor Pinions. - 2 pages 20 Pinion Pullers for Railway Motors - 2 pages, dated 8/1/1924. 21 The Care of Railway Motor Bearings - 4 pages 22 Oil Scraper Rings for Air Compressors - 64590 - May 1924 - 1 page 23 Finger Bases for type K 63 controller 1 page 24 Adjustment of Drum Controller fingers - 29/1/1924, 64600A - 1 page 25 Star Wheels for Type K Controllers - 64603 - 1 page 26 Soldering Aluminium Controller Cylinder Castings - 2 pages 27 Porcelain Bolt Insulators for Railway Service - and drawing on rear showing mounting arrangement of resistor Grids - 2 pages. For scan see btm780d3 (13 pages) 28 Connections of Armature and Field Winding for GE-201-F and GE 263A railway motors. DS37869 29 Connections of Armature and Field Winding for GE-201-I railway motors. K1629303 30 Connections of Armature and Field Winding for GE-202 motor, DS 10472 31 Connections of Armature and Field Winding for GE-203 A and GE 226 railway motors. DS23869. 32 Connections of Armature and Field Winding for GE-241 motors - K1629077 33 Connections of Armature and Field Winding for CP25A Air compressor 34 Connections of Armature and Field Winding for CP27A Air compressor 35 Connections of Armature and Field Winding for GE-258 and GE 264 railway motors. K1629343. 36A- Dimensions of Type K-63-BR Railway Controller Equipment 36 US-13-E Trolley Base for Railway Service - 3/1/1923, 64823 - 2 pages 37 Copy of M&MTB (Eastern System) Certificate of Competency as Motorman. 38 Photocopies of a series of four photos of 22E trucks under an SEC tramcar. For scan see btm780d4 (40 pages) 39 Sprague G-E Multiple Unit Control, Type PC, Instruction Book 84772 - Oct. 1922 - 40 Pages. Images of sheets added 2-11-15 trams, tramways, general electric, motors, controllers, trolley pole bases -
Flagstaff Hill Maritime Museum and Village
Parallel Rule, 1947-1950
Navigators use parallel rule with maps and charts for plotting a specific course on a chart. One long edge is used with the compass rose on the chart, aligning the centre of the rose with the desired direction around the edge of the rose. The compass bars are then ‘walked’ in and out across the map to the desired location so that lines can be plotted to represent the direction to be travelled. Kelvin Company History: The origins of the company lie in the highly successful and strictly informal relationship between William Thomson (1824-1907), Professor of Natural Philosophy at Glasgow University from 1846-1899 and James White, a Glasgow optical maker. James White (1824-1884) founded the firm of James White, an optical instrument maker in Glasgow in 1850 and was involved in supplying and mending apparatus for Thomson university laboratory and working with him on experimental constructions. White was declared bankrupt in August 1861 and released several months later. In 1870, White was largely responsible for equipping William Thomson laboratory in the new University premises at Gilmore hill. From 1876, he was producing accurate compasses for metal ships to Thomson design during this period and this became an important part of his business in the last years of his life. He was also involved in the production of sophisticated sounding machinery that Thomson had designed to address problems encountered laying cables at sea, helping to make possible the first transatlantic cable connection. At the same time, he continued to make a whole range of more conventional instruments such as telescopes, microscopes and surveying equipment. White's association with Thomson continued until he died. After his death, his business continued under the same name, being administered by Matthew Edwards until 1891 when he left to set up his own company. Thomson who became Sir William Thomson and then Baron Kelvin of Largs in 1892, continued to maintain his interest in the business after James White's death in 1884, raising most of the capital needed to construct and equip new workshops in Cambridge Street, Glasgow. At these premises, the company continued to make the compass Thomson had designed during the 1870s and to supply it in some quantity, especially to the Admiralty. At the same time, the firm became increasingly involved in the design, production and sale of electrical apparatus. In 1899, Lord Kelvin resigned from his University chair and became, in 1900, a director in the newly formed limited liability company Kelvin & James White Ltd which had acquired the business of James White. At the same time Kelvin's nephew, James Thomson Bottomley (1845-1926), joined the firm. In 1904, a London branch office was opened which by 1915 had become known as Kelvin, White & Hutton Ltd. Kelvin & James White Ltd underwent a further change of name in 1913, becoming Kelvin Bottomley & Baird Ltd. Hughes Company History: Henry Hughes & Sons were founded in 1838 in London as a maker of chronographic and scientific instruments. The firm was incorporated as “Henry Hughes & Sons Ltd” in 1903. In 1923, the company produced its first recording echo sounder and in 1935 a controlling interest in the company was acquired by S Smith & Son Ltd resulting in the development and production of marine and aircraft instruments. Following the London office's destruction in the Blitz of 1941, a collaboration was entered into with Kelvin, Bottomley & Baird Ltd resulting in the establishing “Marine Instruments Ltd”. Following the formal amalgamation of Kelvin, Bottomley & Baird Ltd and Henry Hughes & Sons Ltd in 1947 to form Kelvin & Hughes Ltd. Marine Instruments Ltd then acted as regional agents in the UK for Kelvin & Hughes Ltd who were essentially now a part of Smith's Industries Ltd founded in 1944 and the successors of S Smith & Son Ltd. Kelvin & Hughes Ltd went on to develop various marine radar and echo sounders supplying the Ministry of Transport, and later the Ministry of Defence. The firm was liquidated in 1966 but the name was continued as Kelvin Hughes, a division of the Smiths Group. In 2002, Kelvin Hughes continues to produce and develop marine instruments for commercial and military. This model parallel map ruler is a good example of the commercial diversity of navigational instruments made by Kelvin & Hughes after World War II. It was made in numbers for use by shipping after the second world war and is not particularly rare or significant for it's type. Also it was made no earlier than 1947 as the firms of Kelvin, Bottomley & Baird Ltd and Henry Hughes & Sons Ltd who took over from Smith & Sons were not amalgamated until 1947. It can therefor be assumed that this ruler was made during the company's transitional period to Kelvin & Hughes from Smith Industries Ltd.Brass parallel rule in wooden box with blue felt lining.Rule inscribed on front "Kelvin & Hughes Ltd" " Made in Great Britain"flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, parallel rule, kelvin & hughes ltd, map ruler, plot direction, navigation, maps, echo sounder, kelvin & james white, lord kelvin, baron kelvin of largs, scientific instrument -
Flagstaff Hill Maritime Museum and Village
Equipment - Line faking box, Government of Victoria, 1860s
The rocket line faking box with lid has a frame inside with a specifically designed perimeter of faking pegs. The rocket shot line has been faked, or skilful wound, around these pegs to prevent it from tangling. The line is stored in the box, ready for attaching to the line throwing rocket. Some line faking boxes have a false base that is removed before firing the line-throwing pistol, leaving the line to feed out from the box when the rocket is fired. After the line is attached to the rocket the box tilted slightly and faced towards the wreck to allow it to be freely dispatched. The equipment often includes more that one faking box to make allowance for possible errors, broken lines or the need for a heavier line. Saving lives in Warrnambool – The coastline of South West Victoria is the site of over 600 shipwrecks and many lost lives; even in Warrnambool’s Lady Bay there were around 16 known shipwrecks between 1850 and 1905, with eight lives lost. In 1859 the first Government-built lifeboat arrived at Warrnambool Harbour and a shed was soon built to house it. In 1858 the provision of rocket and mortar apparatus was approved for lifeboat stations in Victoria, and in 1864 a rocket house was built to safely store the rocket rescue equipment. In 1878 the buildings were moved to the Breakwater area, and in 1910 the new Lifeboat Warrnambool arrived with its ‘self-righting’ design. For almost a hundred years the lifeboat and rocket crews, mostly local volunteers, trained regularly to maintain their rescue skills. They were summoned when needed by alarms, gunshots, ringing bells and foghorns. Some became local heroes but all served an important role. By the end of the 1950s the lifeboat and rescue equipment had become obsolete. Rocket Rescue Method - The Government of Victoria adopted lifesaving methods based on Her Majesty’s Coast Guard in Great Britain. It authorised the first line-throwing rescue system in 1858. Captain Manby’s mortar powered a projectile connected to rope, invented in 1808. The equipment was updated to John Dennett’s 8-foot shaft and rocket method that had a longer range of about 250 yards. From the 1860s the breeches buoy and traveller block rocket rescue apparatus was in use. It was suspended on a hawser line and manually pulled to and from the distressed vessel carrying passengers and items. In the early 1870s Colonel Boxer’s rocket rescue method became the standard in Victoria. His two-stage rockets, charged by a gunpowder composition, could fire the line up to 500-600 yards, although 1000 yards range was possible. Boxer’s rocket carried the light line, which was faked, or coiled, in a particular way between pegs in a faking box to prevent twists and tangles when fired. The angle of firing the rocket to the vessel in distress was measured by a quadrant-type instrument on the side of the rocket machine. Decades later, in about 1920, Schermuly invented the line-throwing pistol that used a small cartridge to fire the rocket. The British Board of Trade published instructions for both the beach rescue crew and ship’s crew. It involved setting up the rocket launcher on shore at a particular angle measured by the quadrant, inserting a rocket that had a light-weight line threaded through its shaft, and then firing it across the stranded vessel, the line issuing freely from the faking board. A tally board was then sent out to the ship with instructions in four languages. The ship’s crew would haul on the line to bring out the heavier, continuous whip line, then secure the attached whip block to the mast or other sturdy part the ship. The rescue crew on shore then hauled out a stronger hawser line, which the ship’s crew fixed above the whip block. The hawser was then tightened using the block on the shore end of the whip. The breeches buoy and endless whip are then attached to the traveller block on the hawser, allowing the shore crew to haul the breeches buoy to and from the vessel, rescuing the stranded crew one at a time. This rocket line faking box is significant for its connection with local history, maritime history and marine technology. Lifesaving has been an important part of the services performed from Warrnambool's very early days, supported by State and Local Government, and based on the methods and experience of Great Britain. Hundreds of shipwrecks along the coast are evidence of the rough weather and rugged coastline. Ordinary citizens, the Harbour employees, and the volunteer boat and rescue crew, saved lives in adverse circumstances. Some were recognised as heroes, others went unrecognised. In Lady Bay, Warrnambool, there were around 16 known shipwrecks between 1850 and 1905. Many lives were saved but tragically, eight lives were lost.Rocket line faking box with loose fitting lid, painted blue on the outside. Rectangular box has two rope handles within wooden rope holders fixed onto each long side and one at each end. The box has a hook and ring at the base each end for releasing the top from the inserted faking frame. The line faking frame is inside the box. It has seventeen wooden pegs along each long side of the frame and three pegs along each short side. A continuous length of rocket line has been faked around the pegs in a specific pattern.flagstaff hill maritime museum & village, flagstaff hill, maritime museum, maritime village, warrnambool, great ocean road, shipwreck, life-saving, lifesaving, rescue crew, rescue, rocket rescue, maritime accidents, rocket crew, beach rescue, line rescue, rescue equipment, rocket firing equipment, rocket rescue equipment, rocket apparatus, beach apparatus, petticoat breeches, breeches buoy, rocket house, rocket shed, lifeboat men, rocket equipment, rocket machine, rocket head, rocket launcher, rocket line, marine technology, line-firing pistol, line throwing gun, beach rescue set, traveller, hawser, faking, faking box, faked line, lady bay, warrnambool harbour, port of warrnambool, volunteer lifesavers, volunteer crew, breakwater, lifeboat warrnambool, rocket rescue method, rocket rescue apparatus, shore to ship, italian hemp, line-throwing pistol, line throwing cartridge, rocket apparatus rescue, stranded vessel, tally board, light line, whip line, endless whip, petticoat buoy, traveller chair, traveller block, her majesty’s coast guard, harbour board, line thrower, line throwing, beach cart, hand barrow, sand anchor, hawser cutter, life jacket, faking board, welsh hand barrow, rocket set, rocket line faking box, faking frame -
Flagstaff Hill Maritime Museum and Village
Equipment - Line faking box, Government of Victoria, 1860s
The rocket line faking box has a frame inside with a specifically designed perimeter of faking pegs. The rocket shot line has been faked, or skilful wound, around these pegs to prevent it from tangling. The line is stored in the box, ready for attaching to the line throwing rocket. Some line faking boxes have a false base that is removed before firing the line-throwing pistol, leaving the line to feed out from the box when the rocket is fired. After the line is attached to the rocket the box tilted slightly and faced towards the wreck to allow it to be freely dispatched. The equipment often includes more that one faking box to make allowance for possible errors, broken lines or the need for a heavier line. Saving lives in Warrnambool – The coastline of South West Victoria is the site of over 600 shipwrecks and many lost lives; even in Warrnambool’s Lady Bay there were around 16 known shipwrecks between 1850 and 1905, with eight lives lost. In 1859 the first Government-built lifeboat arrived at Warrnambool Harbour and a shed was soon built to house it. In 1858 the provision of rocket and mortar apparatus was approved for lifeboat stations in Victoria, and in 1864 a rocket house was built to safely store the rocket rescue equipment. In 1878 the buildings were moved to the Breakwater area, and in 1910 the new Lifeboat Warrnambool arrived with its ‘self-righting’ design. For almost a hundred years the lifeboat and rocket crews, mostly local volunteers, trained regularly to maintain their rescue skills. They were summoned when needed by alarms, gunshots, ringing bells and foghorns. Some became local heroes but all served an important role. By the end of the 1950s the lifeboat and rescue equipment had become obsolete. Rocket Rescue Method - The Government of Victoria adopted lifesaving methods based on Her Majesty’s Coast Guard in Great Britain. It authorised the first line-throwing rescue system in 1858. Captain Manby’s mortar powered a projectile connected to rope, invented in 1808. The equipment was updated to John Dennett’s 8-foot shaft and rocket method that had a longer range of about 250 yards. From the 1860s the breeches buoy and traveller block rocket rescue apparatus was in use. It was suspended on a hawser line and manually pulled to and from the distressed vessel carrying passengers and items. In the early 1870s Colonel Boxer’s rocket rescue method became the standard in Victoria. His two-stage rockets, charged by a gunpowder composition, could fire the line up to 500-600 yards, although 1000 yards range was possible. Boxer’s rocket carried the light line, which was faked, or coiled, in a particular way between pegs in a faking box to prevent twists and tangles when fired. The angle of firing the rocket to the vessel in distress was measured by a quadrant-type instrument on the side of the rocket machine. Decades later, in about 1920, Schermuly invented the line-throwing pistol that used a small cartridge to fire the rocket. The British Board of Trade published instructions for both the beach rescue crew and ship’s crew. It involved setting up the rocket launcher on shore at a particular angle measured by the quadrant, inserting a rocket that had a light-weight line threaded through its shaft, and then firing it across the stranded vessel, the line issuing freely from the faking board. A tally board was then sent out to the ship with instructions in four languages. The ship’s crew would haul on the line to bring out the heavier, continuous whip line, then secure the attached whip block to the mast or other sturdy part the ship. The rescue crew on shore then hauled out a stronger hawser line, which the ship’s crew fixed above the whip block. The hawser was then tightened using the block on the shore end of the whip. The breeches buoy and endless whip are then attached to the traveller block on the hawser, allowing the shore crew to haul the breeches buoy to and from the vessel, rescuing the stranded crew one at a time. This rocket line faking box is significant for its connection with local history, maritime history and marine technology. Lifesaving has been an important part of the services performed from Warrnambool's very early days, supported by State and Local Government, and based on the methods and experience of Great Britain. Hundreds of shipwrecks along the coast are evidence of the rough weather and rugged coastline. Ordinary citizens, the Harbour employees, and the volunteer boat and rescue crew, saved lives in adverse circumstances. Some were recognised as heroes, others went unrecognised. In Lady Bay, Warrnambool, there were around 16 known shipwrecks between 1850 and 1905. Many lives were saved but tragically, eight lives were lost.Rocket line faking box with loose fitting lid, painted black on the outside. Rectangular box has two rope handles within wooden rope holders fixed onto each long side and one at each end. The box has a hook and ring at the base each end for releasing the top from the inserted faking frame. The line faking frame is inside the box. It has seventeen wooden pegs along each long side of the frame and three pegs along each short side. A continuous length of rocket line has been faked around the pegs in a specific pattern.flagstaff hill maritime museum & village, flagstaff hill, maritime museum, maritime village, warrnambool, great ocean road, shipwreck, life-saving, lifesaving, rescue crew, rescue, rocket rescue, maritime accidents, rocket crew, beach rescue, line rescue, rescue equipment, rocket firing equipment, rocket rescue equipment, rocket apparatus, beach apparatus, petticoat breeches, breeches buoy, rocket house, rocket shed, lifeboat men, rocket equipment, rocket machine, rocket head, rocket launcher, rocket line, marine technology, line-firing pistol, line throwing gun, beach rescue set, traveller, hawser, faking, faking box, faked line, lady bay, warrnambool harbour, port of warrnambool, volunteer lifesavers, volunteer crew, breakwater, lifeboat warrnambool, rocket rescue method, rocket rescue apparatus, shore to ship, italian hemp, line-throwing pistol, line throwing cartridge, rocket apparatus rescue, stranded vessel, tally board, light line, whip line, endless whip, petticoat buoy, traveller chair, traveller block, her majesty’s coast guard, harbour board, line thrower, line throwing, beach cart, hand barrow, sand anchor, hawser cutter, life jacket, faking board, welsh hand barrow, rocket set, rocket line faking box, faking frame -
Parks Victoria - Point Hicks Lightstation
Stand, pump & tank
Was the stand for a Chance Brothers air & oil containers fitted with pump handle & pressure gauges.This type of installation was once common and relied on the lightkeeper having to pressurise the cylinders manually at regular intervals throughout the hours of darkness. The oil was fed under pressure to the burner mantle. It is all that remains of an air and kerosene oil tank installation, with each rounded side formerly supporting a heavy iron tank. The containers would have been fitted with a pump handle and pressure gauges. An intact assemblage is displayed in the AMSA offices, Canberra with a text that explains ‘This type of installation was once common and relied on the lightkeeper having to pressurise the cylinders manually at regular intervals throughout the hours of darkness’.The system involved vaporising kerosene under pressure and mixing it with air and then burning the vapour to heat an incandescent mantle. The use of kerosene as a fuel to light the lantern became the most common system of illumination from the 1860s after the oil industry in the United States began to develop. The kerosene vapour burner was created in 1901 by British inventor Arthur Kitson (1859-1937) and perfected by Chance Bros for burning a more intense light in their renowned lenses. The lamp had to be watched throughout the night in case a mantle broke, and the tanks needed to be maintained by hand-pumping each hour or so. The Point Hicks lantern was initially lit by a six-wick Trinity house kerosene burner. This was replaced by the more efficient and brighter 55mm vaporised kerosene mantle burner in 1905, and the tank stand is probably original to this apparatus. Electricity eventually replaced kerosene at Point Hicks in 1964 making the tank installation obsolete, and the last kerosene system in an Australian lighthouse was replaced in 1985. Gabo Island Lightstation has a pair of tanks that are not attached to the optical system and are no longer in the lighthouse. They are also missing the pressure gauges that were formerly attached to the top of each cylinder. An intact tank assemblage is displayed at the Cape Schanck Lighthouse Museum it is detached and not original to the lighthouse. Although corroded, the remnant Point Hicks tank stand has first level contributory importance to the lightstation. It is significant for its provenance and historical value as part of the Chance Bros vaporised kerosene burner introduced in 1905 to intensify the light and improve the efficiency of the system. The rusted iron stand rests on four short legs and is shaped like a pair of spectacles.