Rectangular Wooden sportsperson of the year 2004-2013 honour board with Wangaratta High school Logo in top left corner and gold lettering. SPORTS AWARDS 2004 J. Caruso- S. Caruso- T. Chivers- D. Cook- S. Coote- D. McCullough- H.Oliver- C.Porter- J.Shaw- N. Tavare- K. White 2005 D. Allen- N. Boyle- M. Bruce- T. Chivers- O. Hutchinson- K. McDonald- A. Martin- O. McCullough- H. Oliver- D. Scott- K. Surace- N. Tavare 2006 K. Boal- C. Braden- M. Brown-M. Bruce- S. caruso- C. Crimmins- M. Graham- N. Hooper- B. Kerlin- A. Martin- D. McCullough- K. Surace 2007 N. Boyd- D.Boyle- S.Caruso- C.Crimmins- M. Graham- N. Hooper- B. Lorenz- S. Maddern- T. Maddern- B. Mulrooney- E. Newman- T. Patrik- K. Surge- D. Vescio 2008 A. Bennet- L. Cameron- S. Caruso- C. Conley- S. Coote- X. Dewez- H. Espejo- A. Kildea- C. McMahon- P. O'Donoghue- C. Podubinski- C. Porter- D. Vescio SPORTS PERSON OF THE YEAR 2009 A. Kildea 2010 A. Tutt 2011 X. Dewez 2012 X. Dewez 2013 X. Dewez

An original Kerr-Grant Microbalance, modified by E.J.Hartung This balance was invented in the chemistry department by Bertram Dillon Steele, later first Professor of Chemistry at the University of Queensland 1910-1930, in collaboration with Professor Kerr Grant, Physics. The design was widely used by other chemists, including Masson's mentor, Professor Ramsay, working in London on newly discovered rare gases (especially Radon), and Professor Hartung in Melbourne, investigating the chemistry of the decomposition of silver salts in photographic processes. The principle of the microbalance was to measure the change in density of a gas by the shift in the balancing beam due to a change in pressure of the gas in the balance case. The quartz balancing beam was made by Bertram Steele who was particularly skilled in glassblowing. A quartz beam is the beam of the Aston microbalance based on the Steele/Grant instrument, and described by F.W. Aston, the inventor of the mass spectrometer. The bulb at one end of the beam contained a fixed amount of air, so that a change in the pressure of gas in the balance case changed the buoyancy of the beam, yielding a displacement in the beam which could be measured. By this means, differences in weight of about 10 nanogram could be measured, in amounts of up to 0.1 gram. Such differences are significant the increase in weight of a metal sample due to surface oxidation (Steele's interest) in the weight loss due to radioactive decay of Radium (Ramsay's work), and in the estimates of density change due to the isotopic distribution of Neon (Aston). Ernst Johannes Hartung was a chemist and astronomer. Educated at the University of Melbourne (BSc 1913, DSc 1919), he became lecturer in 1919, associate professor in 1924, and succeeded Rivett as chair of chemistry in 1928, remaining in this position until 1953. Hartung?s lecturing style surged with enthusiasm and he employed the use of screen projections to demonstrate chemical phenomena to large undergraduate classes. In 1935 he recorded Brownian movement in colloidal solutions on 35 mm cinefilm, which was later copied onto 16 mm film for the Eastman Kodak Co. World Science Library. This can be viewed in the Chemistry laboratory. He researched the photo decomposition of silver halides, and was awarded the David Syme Prize in 1926. He devoted time to the design and construction of a large, new chemistry building for the School of Chemistry (built 1938?1939). During World War II he was approached by Professor Thomas Laby, chairman of the Optical Munitions Panel, to chair the advisory committee on optical materials, to produce high quality optical glass in Australia. This was successful, with large-scale production achieved within ten months at a reasonable cost. Hartung served three terms as general President of the (Royal) Australian Chemical Institute, was an ex-officio councillor of the Council for Scientific and Industrial Research, and a Trustee of the Museum of Applied Science (now part of Museum Victoria).An original Kerr-Grant Microbalance, modified by E.J. Hartung.

60lbs rail that was used throughout the Victorian rail network. In 1887 Gibbs, Bright and Co. had a contract with Victorian Railways for railway and canal construction and supply of Krupp Rails. Gibbs, Bright and Co were merchant bankers and shipping agents and merchants who where also Directors of the GWR ( Great Western Railway ) and the Ship The "Great Britain" in England Gibbs, Bright and Company had principally been involved in shipping and trading, mainly in the West Indies, but following the discovery of gold in Victoria they established an office in Melbourne and soon became one of the leading shipping agents and merchants in the Colony. They expanded into passenger shipping and soon established offices in Brisbane, Sydney, Newcastle, Adelaide and Perth as well as launching passenger services between England, Mauritius and New Zealand. Gibbs, Bright also held a number of financial agencies from British mortgage, finance and investment companies as well as representing several British insurance companies in Australia. In addition they conducted a growing import business as well as an export business that included livestock, dairy produce, wool and flour. Also the company played a substantial part in the development of Australia's mineral resources, starting with lead in 1895, and later venturing into tin, gold, copper, cement and super phosphates. In Australia, after WWI, many of the larger companies were managing their own import and export so Gibbs, Bright and Company tended to focus its Agency business on smaller companies while expanding their interest into other markets such as timber, wire netting, zinc, stevedoring, road transport, marine salvage, gold mining as well as mechanical, structural, electrical and marine engineering. The Company's shipping interests continued to grow as well and still formed a major part of its business. In 1948 the parent company in England took the major step from tradition when they changed the business from a partnership into a private limited company. The name was the same, Antony Gibbs and Sons Limited, and in practice the effect of the change was very little. Some of the firm's branches and departments had already become limited companies and the formation of a parent company simplified the structure. The Australian operation was in time changed to Gibbs Bright & Co Pty Ltd in 1963. In 1848 Alfred Krupp becomes the sole proprietor of the company which from 1850 experiences its first major growth surge. In 1849 his equally talented brother Hermann (1814 - 1879) takes over the hardware factory Metallwarenfabrik in Berndorf near Vienna, which Krupp had established together with Alexander Schöller six years earlier. The factory manufactures cutlery in a rolling process developed by the brothers. Krupp's main products are machinery and machine components made of high-quality cast steel, especially equipment for the railroads, most notably the seamless wheel tire, and from 1859 to an increased extent artillery. To secure raw materials and feedstock for his production, Krupp acquires ore deposits, coal mines and iron works. On Alfred Krupp's death in 1887 the company employs 20,200 people. His great business success is based on the quality of the products, systematic measures to secure sales, the use of new cost-effective steel-making techniques, good organization within the company, and the cultivation of a loyal and highly qualified workforce among other things through an extensive company welfare system. From 1878 August Thyssen starts to get involved in processing the products manufactured by Thyssen & Co., including the fabrication of pipes for gas lines. In 1882 he starts rolling sheet at Styrum, for which two years later he sets up a galvanizing shop. The foundation stone for Maschinenfabrik Thyssen & Co. is laid in 1883 with the purchase of a neighboring mechanical engineering company. In 1891 August Thyssen takes the first step toward creating a vertical company at the Gewerkschaft Deutscher Kaiser coal mine in [Duisburg-]Hamborn, which he expands to an integrated iron and steelmaking plant on the River Rhine. Just before the First World War he starts to expand his group internationally (Netherlands, UK, France, Russia, Mediterranean region, Argentina). info from The company thyssenkrupp - History https://www.thyssenkrupp.com/en/company/history/the-founding-families/alfred-krupp.htmlHistoric - Victorian Railways - Track Rail - made by Krupp in 1888Section of VR Krupp 1888 Rail mounted on a piece of varnished wood. Rail made of ironpuffing billy, krupp, rail, victorian railways

The Orungal was originally built in Glasgow in 1923 for the Khedival Mail Steamship & Graving Dock Company of Egypt and named the S.S. Fezara. Due to the effects on steamship companies of the Great Depression including the steep costs of building new ships and increases in running costs and port charges, no new passenger ships had been ordered in Australia since before World War One. To meet demand for passenger berths, the Fezara (5826 tons) along with its sister ship the Famaka (5856 tons, renamed Ormiston), were chartered by the Australasian United Steam Navigation Company Ltd (A.U.S.N.Co.) in 1927. Both the A.U.S.N.Co and the Khedival Mail Steamship Co. were part of the P&O Group. The Orungal operated in this role as an interstate passenger and mail steamer between 1927 and 1940, being used mainly on the Melbourne to Queensland and Western Australian runs, with 240 single class berths. Following the outbreak of World War Two six of the nine large passenger liners servicing mainland Australian passenger and mail trades were requisitioned by the Government to ferry equipment, troops and supplies. Some of them were converted to armed merchant cruisers and used for patrol work and escort duties in the Indian and Pacific Oceans. The Orungal had originally been requisitioned by the government along with the Zealandia on 25 June 1940, to transport troops to Darwin, but was returned to commercial service because "of her unsuitability", perhaps too slow for the demands of the work. Despite being rejected for patrol and convoy duties the Orungal still had a vital role as one of only three passenger liners left to service the mainland Australian trade. Following its requisitioning by the Government shortly after war broke out, it had been fitted out with defensive armament. On its final voyage arriving at Port Phillip Heads from Sydney, Captain Gilling was attempting to enter the Heads ahead of a worsening south-westerly storm and, with a minefield known to have been laid in the area, had been warned by the Navy not to deviate from the swept channel. The captain and crew held fears that in the stormy seas a mine may have been carried away. In the worsening weather a blur of lights at Barwon Heads was mistaken for Port Lonsdale, and the Orungal steamed ashore onto Formby Reef, just east of the entrance of the Barwon River - instead of passing safely through the middle of the Rip. At the Marine Board Inquiry Capt. Gilling - who had been master of the Orungal since 1926 - stated that after becoming uneasy about his position and changing course to starboard one point: " At 10.21 pm I ordered the engine room to stand by and gave instructions for the patent log to be hauled in and for the sounding-gear to be got ready. Approximately two minutes later, in a flash of lightning, I saw land off the port beam. I immediately recognised it as Barwon Heads, and ordered the helm to be put hard to starboard, but the vessel struck before she had time to answer the helm" Barwon Heads and Ocean Grove residents were startled to hear the shrill blast of the ship's whistle, followed by the bright flares and explosions of signal rockets. The Queenscliff lifeboat crew, who had responded to the tragic collision between the Goorangai and another passenger liner the Duntroon in Port Phillip Bay less than 24 hours earlier, were later praised for their efforts in safely taking off all the passengers and crew. Most of the passengers were asleep at the time of the wreck, and were woken up by the commotion, the ship shaking "from stem to stern" and stewards ordering them to lifeboat stations in driving rain. It was a dramatic time with the ship siren wailing and distress rockets being fired. It was reported that "When it was found the ship was safe, the passengers all went to the music room. There they sang and danced for several hours. The ship's orchestra played merrily, and amateur performers among the passengers clowned, danced and sang to keep the laughter going. In the early hours of the morning passengers went to their cabins, most of them to sleep soundly while the keel grated on the rocks". At dawn the Queenscliff lifeboat arrived at the scene having been launched at 2.30am, and cautiously approached the ship which was being "battered by mountainous seas". By 5am oil from a burst oil line was helping to calm seas around the Orungal sufficiently enough for the lifeboat to approach, and all the passengers and crew were taken off in several trips by the lifeboat. A Court of Inquiry later found that the wreck was caused by an abnormal set of current to the north-west and cleared the officers and crew of neglect of duty. The sight of a huge liner almost on the beach saw an unprecedented amount of traffic as people drove an estimated 10,000 cars, using some 60,000 gallons of fuel in a time of strict petrol rationing, to see the spectacle. Salvage operations began in an attempt to refloat the vessel, scheduled for the high tide on 15 December 1940. However, during these operations, at 2.30 am on 13 December 1940, a major fire broke out, believed to have been caused by spontaneous combustion in the boiler room. The ship was soon ablaze, with smoke pouring from its hatches and ventilators, and at mid-morning the magazine exploded fiercely. Of the 60 men working aboard the vessel two were severely burned and had to be taken to Geelong Hospital. The gathered spectators witnessed the eerie sight of the ship's hull glowing red when night fell. The well-known building demolition contractor Whelan the Wrecker bought the salvage rights, and methodically proceeded to dismantle the ship and its fittings. The drama was not yet over for the wreckers when - without warning - the burnt-out hulk was 'attacked' by RAAF for strafing practice. Salvage rights were transferred to another private owner in 1963. By 1945 the combined effects of the exposed location, fire and salvage had seen what was left of the wreck disappear beneath the waves. The site today is marked by two of the four Scotch type boilers sitting upright and exposed at low tide, just north-east of the small boats channel at the entrance to Barwon Heads. Large sections of steel hull plating and framing, and impressively large pieces of ships structure and machinery including masts, booms, deck winches, propeller shaft, flywheel, and a thrust block lie scattered about and make the site an interesting shallow dive. It is interesting to compare the site of the Orungal with the intact remains of similar large passenger ships scuttled in deep water in the Ships' Graveyard, such as the Milora and Malaita. The site is subject to waves and surge, and is best dived on flat calm days The teacup originated from the SS Orungal and was likely used heavily in the ship's life as a passenger, mail and cargo carrier around Australia. The teacup is significant for its connections to SS Orungal and of this ships connected story of being sunk in extraordinary circumstances in the local region. A.U.S.N. Co. Ltd. Teacup salvaged from SS Orungal ss orungal, fezara, world war two, barwon heads, ocean grove

Junction (Lake Guy) Dam is a 'slab and buttress' type wall. A timber frame is built and then filled with concrete. The first batch of concrete was placed in September, 1940. By June, 1941 the buttresses were finished to a height safe from floods and in October of that year a flood of 2,800 cusecs occurred but with only slight damage to the installations. Industrial trouble caused some delays but there was also slow progress on the part of the contractor and the work was taken over by the S.E.C., terminating the contract. The dam was completed in March, 1944. A walkway was made through the dam wall. Lake Guy was named after Mr. L.T. Guy who was the Resident engineer, in charge of construction work and associated activities on the Kiewa Area from 1939 to November 1946Photos of the construction of the Junction Dam detail the harsh conditions faced by construction workers, building dams and villages to accommodate workers in the 1940s to the 1950s. Australia at this period in time, experienced a surge of population (influx of World War II refugees), which was the catalyst for developing and undergoing an enormous hydroelectricity program for the Alpine regions, both in Victoria and New South Wales. This program was initiated to supply electricity to the major southern Australian cities of Adelaide, Melbourne and Sydney. It was thought that these developments would reduce, if not eliminate, the requirement for coal driven power stations. However time has demonstrated that these power stations have not matched the demand required by the industries and the populations of the major urban and cities.Black and white photograph of Junction Dam constructionjunction dam, bogong, secv

Junction (Lake Guy) Dam is a 'slab and buttress' type wall. A timber frame is built and then filled with concrete. The first batch of concrete was placed in September, 1940. By June, 1941 the buttresses were finished to a height safe from floods and in October of that year a flood of 2,800 cusecs occurred but with only slight damage to the installations. Industrial trouble caused some delays but there was also slow progress on the part of the contractor and the work was taken over by the S.E.C., terminating the contract. The dam was completed in March, 1944. A walkway was made through the dam wall. Lake Guy was named after Mr. L.T. Guy who was the Resident engineer, in charge of construction work and associated activities on the Kiewa Area from 1939 to November 1946.Diversion dams are installed to raise the water level of a body of water to be redirected. The redirected water is used for hydro electric power generation. A diversion tunnel is usually bored through solid rock next to the dam site to bypass the dam construction site. The dam is built while the river flows through the diversion tunnel.Photos of the construction of the Junction Dam detail the harsh conditions faced by construction workers, building dams and villages to accommodate workers in the 1940s to the 1950s. Australia at this period in time, experienced a surge of population (influx of World War II refugees), which was the catalyst for developing and undergoing an enormous hydroelectricity program for the Alpine regions, both in Victoria and New South Wales. This program was initiated to supply electricity to the major southern Australian cities of Adelaide, Melbourne and Sydney. It was thought that these developments would reduce, if not eliminate, the requirement for coal driven power stations. However time has demonstrated that these power stations have not matched the demand required by the industries and the populations of the major urban and cities.Black and white photograph of Junction Dam diversion tunnel at Bogong VillageHandwritten on back - Junction Dam Diversional Tunnelbogong, secv, junction dam, lake guy

Junction (Lake Guy) Dam is a 'slab and buttress' type wall. A timber frame is built and then filled with concrete. The first batch of concrete was placed in September, 1940. By June, 1941 the buttresses were finished to a height safe from floods and in October of that year a flood of 2,800 cusecs occurred but with only slight damage to the installations. Industrial trouble caused some delays but there was also slow progress on the part of the contractor and the work was taken over by the S.E.C., terminating the contract. The dam was completed in March, 1944. A walkway was made through the dam wall. Lake Guy was named after Mr. L.T. Guy who was the Resident engineer, in charge of construction work and associated activities on the Kiewa Area from 1939 to November 1946Photos of the construction of the Junction Dam detail the harsh conditions faced by construction workers, building dams and villages to accommodate workers in the 1940s to the 1950s. Australia at this period in time, experienced a surge of population (influx of World War II refugees), which was the catalyst for developing and undergoing an enormous hydroelectricity program for the Alpine regions, both in Victoria and New South Wales. This program was initiated to supply electricity to the major southern Australian cities of Adelaide, Melbourne and Sydney. It was thought that these developments would reduce, if not eliminate, the requirement for coal driven power stations. However time has demonstrated that these power stations have not matched the demand required by the industries and the populations of the major urban and cities.Black and white photograph of Junction Dam spilling at Bogong VillageHandwritten in pencil - Junction Dam spillingbogong, junction dam, lake guy, secv

This item clearly shows the conditions covering both working conditions and housing in the construction of the Junction Dam in the 1940s. Working conditions were extreme and health and safety legislation was at its infancy. The residential buildings were intended to last only for the period of construction, however greater demand for longevity as a tourist haven prevailedThis photo of the construction of the Junction Dam, with The Bogong village as backdrop, details the harsh conditions faced by construction workers, building dams and villages to accommodate workers in the 1940s to the 1950s. Australia at this period in time, experienced a surge of population (influx of World War II refugees), which was the catalyst for developing and undergoing an enormous hydroelectricity program for the Alpine regions, both in Victoria and New South Wales. This program was initiated to supply electricity to the major southern Australian cities of Adelaide, Melbourne and Sydney. It was thought that these developments would reduce, if not eliminate, the requirement for coal driven power stations. However time has demonstrated that these power stations have not matched the demand required by the industries and the populations of the major urban and cities.Black and white photo of original photo with a flashlight reflection in the bottom centre. The photo is on Kodak XtraLife II paper. The paper is semi gloss.This photo is of the construction of the Junction Dam Wall with the Bogong Townshiip in the background.Back of photo is printed " Kodak XtraLite II paperdam construction, bogong village, alpine development, junction dam

Chris Pittard is a painter who has been working with clay for over 15 years. Pittard studied Fine Arts at RMIT and VCA and has exhibited paintings for a number of years. Pittard divides his time between teaching, drawing and painting and working in the ceramics studio where he creates distinctive pieces. Chris Pittard's ceramic pieces translate the narrative to the vessel. His vessels speak to us about our place and even his personal stories become more universal expressions.In early 2005 there was a flood which raged through the creeks cutting through the Shire of Nillumbik (Eltham). Not usually affected by catastrophe, these surging waters destroyed bridges and threatened roads. When the water subsided along the banks of the creek, trees had fallen, flotsam and jetsam piled up and even weeks later the long grass flattened by the flood continued to map the raging waters flow. The combination of slightly threatening and destructive forces and eerie beauty interested me. This at a time when world events of a far more horrific and tragic nature where presented to us by strangely beautiful coloured photos in our daily papers. These connections may not be obvious but it was certainly something I was thinking about while making this ceramic piece.flood, chris pittard, eltham, nillumbik

Menus used on P&O liners SS Himalaya and SS Arcadia 1955-56. After the Great war of 1914-18, Australia experienced what up until then had been its biggest surge in immigration from Europe. Australia was seen as the great land of opportunity and became one of the top places to migrate to, particularly from Britain. The increase in migration to Australia led Britain’s leading shipping line to the Far East, the Peninsular and Oriental Steam Navigation Company (P&O;), to invest in a fleet of new ships of around 20,000 tonnes each to handle the business coming their way.29 Cruise Ship Menus from P&O cruises 1955-56Peninsula & Oriental Steam Navigation Companycruise liners, migrants, menus, p&o

Painted steel

Van De Mark tells the somber story of Lyndon Johnson's valiant but tragic effort to prevent the surging undertow of a far-off war from overwhelming the programs that embodied his cherished vision for America.vietnamese conflict, 1961-1975 - united states, united states - politics and government - 1961-1975, president lyndon johnson