At the beginning of the 1890s, the Kew businessman and Town Councillor, Henry Kellett, commissioned J.F.C. Farquhar to photograph scenes of Kew. These scenes included panoramas as well as pastoral scenes. The resulting set of twelve photographs was assembled in an album, Kew Where We Live, from which customers could select images for purchase.The preamble to the album describes that the photographs used the ‘argentic bromide’ process, now more commonly known as the gelatine silver process. This form of dry plate photography allowed for the negatives to be kept for weeks before processing, hence its value in landscape photography. The resulting images were considered to be finely grained and everlasting. Evidence of the success of Henry Kellett’s venture can be seen today, in that some of the photographs are held in national collections.It is believed that the Kew Historical Society’s copy of the Kellett album is unique and that the photographs in the book were the first copies taken from the original plates. It is the first and most important series of images produced about Kew. The individual images have proved essential in identifying buildings and places of heritage value in the district.Dight’s Falls in Studley Park is an artificial weir built on a natural rock bar across the Yarra. The weir was built in the 1840s to provide water to the ‘Ceres’ flour mill, one of the earliest industrial sites in Melbourne. The falls were later to be named after the owner of this mill. In 1888, William Guilfoyle, Director of the Melbourne Botanical Gardens had called for fresh water to be piped from above the weir to the Botanical Gardens, using a pumping station on the Kew side of the Falls, a holding reservoir in Walmer Street and a series of pipes from there to the Gardens. This system was opened in May 1891. Farquhar’s photograph of the man-made weir obscures the industrial activity on both sides of the Falls and focusses solely on the river and the surrounding natural vegetation. The photograph probably predates the disastrous flooding of the Yarra River in July 1891, the greatest to have occurred in the Colony since the foundation of Melbourne.Dight's Fallskew illustrated, kew where we live, photographic books, henry kellett, yarra river

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.

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.

This utility truck was one of two used by the Albury Gas Co, from the Gas Works in Kiewa Street, Albury to service the coal gas supply system in Albury during the war years from 1939-1945. The gas bags were installed as petrol was in short supply. One of the trucks was driven by John (Jack) Stanley Cruickshank, also known as Wodonga's Gas Man. Jack became foreman for the Wodonga Branch of the Albury Gas Co. An 80 millimetre galvanised steel pipeline was installed from the Albury Gas Co. in Kiewa Street, Albury, to 26 Church Street, Wodonga. A 40 horsepower pump pushed the gas to holding tanks. Sections of the gas pipeline to Wodonga can still be observed under some of the bridges from Albury to Wodonga. Jack also supervised the laying of the gas pipes in the streets of Wodonga, being hand dug by a gang of 15- 20 men. He was Wodonga's first Gas Fitter, both fitting gas appliances and overseeing their maintenance. Jack Cruickshank passed away in 1979 and is buried at the Wodonga Cemetery.This image is significant because it represents the installation of gas supply to Wodonga, Victoria.A black and white photo of a large van with a gas-filled bag on top of it and also a portrait of Jack Cruickshank. Photos are mounted together with text in a wooden frame.jack cruickshank, wodonga gas supply co.

Foam injection slip on unit mounted on a sloping frame for training and demonstration purposes This technology was developed at Altona in the 1990sforests commission victoria (fcv), fire pump, bushfire

Newspaper article: A sustainable award, Diamond Valley Leader, 1 November2006, Architect and building Llewellyn Pritchard won resource Efficiency Housing Award, finalist in HIA Greensmart Building of the Year Award. House – Environmental Leader (Published: Nillumbik Now and Then /​ Marguerite Marshall 2008; photographs Alan King with Marguerite Marshall.; p186) In 2006 environmental awareness was mushrooming in the community, which is reflected in the award-winning house at Main Road near Wattletree Road, Eltham. At first sight, the building appears a mix of a classic Eltham mud-brick house and an avant-garde building style. The crown of solar panels stretching along the width of the curved roof, indicates that this is no ordinary house. In fact it signals a new building trend of minimal impact on the environment. Yet it utilises the environment with high technical expertise to achieve comfort and cut running and maintenance costs. In recognition of this, its designer/builder, Conscious Homes, won the 2006 National HIA Greensmart Resource Efficiency Award. For Conscious Homes director, Llewellyn Pritchard, this house reflects a philosophy, strengthened by his connection with Aboriginal culture, through his foster siblings. Pritchard believes the sustainable way indigenous Australians lived and their spiritual connection with land, demonstrates how humanity is part of the ecology. His interest in environmental design stemmed from growing up in bushy Eltham Shire, with its mud-brick tradition. This was followed by studying Architecture at RMIT in the early 1980s, and learning about passive solar design. Pritchard says this house demonstrates that environmental sustainability is not about sacrifice, but about exceptional levels of occupant comfort, savings in running costs and modern fittings and appliances.1 The solar panels on the north roofs are intentionally obvious to make a statement about what the building is doing. But inside the systems are hidden and interactive with conventional services, such as the underground water tank. The house is water and energy self-sufficient and at 12 squares is much smaller than conventional houses, to minimise resources. Yet it accommodates his family of four with three bedrooms, a living/dining and kitchen area and a bathroom/laundry. Importantly the building is designed to last hundreds of years, by being able to be modified as the need arises, such as for commercial use. In this way the structure minimises its environmental impact. The solid double mud-brick walls (which are insulated) include steel beams and supporting frame, allowing the future removal or alteration of any section. The materials are local, recycled and of low toxicity where possible.2 Inside and out, the mud-brick is rendered and sealed with a combination of cement and sand and a mud-based coating in a soft golden hue increases its life. Inside, the golden-brown timber is plantation Mountain Ash and the concrete floors throughout – of local stone aggregate with a clear seal – have a natural looking random stone appearance. The house sustains a stable temperature of around 20 degrees, assisted by the concrete slab floor. The many large double-glazed windows and highlights (windows set high on walls) provide cross-flow ventilation. The north-facing living area maximises heating from the lower winter sun and is cooler in summer, because the sun is higher. Heating comes from a solar hydronic slab system. All appliances and fittings are high efficiency energy or water rated. Appliances in the timber kitchen include a gas stove and a dishwasher, using the building’s own power and water. French doors open from the living area to a deck, concealing the treatment system for all waste water. This is pumped through sub-soil drippers to the indigenous garden beds and no-dig vegetable patch. Below the carport is the 80,000-litre rainwater tank and at the back, the boiler room houses the solar boiler, water tank access, domestic water supply pump, filter gear and hydronic slab heating controls. The solar system is backed up with gas, which is needed to heat water only in winter. Gas used is less than one quarter of that for an average home with ducted heating. Excess power is fed back to the grid and the building uses about one quarter of the mains electricity of an average home. Other local builders have followed Pritchard’s lead in resource efficiency for minimal environmental impact.main road, eltham, businesses, llewellyn pritchard, hia greensmart building of the year award., efficiency housing award, conscious homes australia pty ltd

Handwritten copy of a report in the Bendigo Advertiser 12/7/1910 Page 2. New Chum Mines. Progress of Bailing Operations. The bailing operations at the New Chum mines have not yet had the desired effect of lowering the water. On the contrary the water continues to rise in the Victoria Quartz which is the mine most directly affected. It is expected that the necessary preparations at the Lazarus will be completed today when it is hoped that bailing will be commenced at that mine. The success of the bailing scheme will largely depend on the efforts of the Lazarus to cope with the water and the progress made during the next few days will be awaited with interest. It is generally believed that the great volume of water is coming north from the southern group of mines. The companies south of the New Chum Consolidated are not bailing, and the pumping service at the New Chum Railway which is installed down to the 550 ft. level has not been operated since that company abandoned work a few months ago. A perusal of the statistics of the New Chum Drainage Association shows that the pumps at the New Chum Railway were lifting on anaverage close on 1,000,000 galls of water per month in the winter. That great volume of water is now pouring from storage dams at 550 feet to the deep levels, and in the natural order of things will have to be lifted by the tanking system in vogue at the mines N.' Document from Albert Richardson Collection of mining history.document, gold, drainage problems, new chum drainage association, victoria quartz influx of water, bendigo advertiser 12/7/1910 page 2, victoria quartz, lazarus, new chum consolidated, new chum railway, new chum drainage association

Series of 12 black and white photographs of the trackwork on the MMTB system. .1 - demolished track at a junction .2 - section of rail showing the flangeway missing .3 - junction plates between different weight railway . .4 - wood blocked track showing broken joint and failure .5 - ditto .6 - V crossing ,7 - ditto at a wooden sleepered crossing with puppy dog spikes. .8 - crossing possibly between tram and rail .9 - H crossing rail showing broken joints and wear .10 - ditto .11 - section of rail pumping - waterlogged .12 - damaged joint, pumping, broken joint plate.trams, tramways, trackwork, rails, points, crossover, track materials, track repairs

Wodonga Waterworks Trust was established in 1897 to control and improve water supply to Wodonga. This included focus on the water quality which had often been a problem. After lobbying the Victorian Department of Water Supply for several years, the first official meeting of the newly constituted Wodonga Waterworks Trust was held on Wednesday 20th October 1897. The Board initially consisted of all Wodonga Shire Councillors, together with Mr Samuel Mason Jr., as the nominee of the Government. Councillor McFarlane was appointed as the first Chairman. This Record Book contains documentation of expenditure of the Wodonga Waterworks Trust from 1908 through to the early 1950s. This includes the official record of payments of £2,897/ 18 /- and £130 to contractor A. A. Hargrave for Erection of the Water Tower. Other payments related to the Water Tower include entries for pumps, gears, pipe laying, pipes, the pump station and related fittings. Construction of the Water Tower was completed in early 1924 and after thorough testing throughout that year, the completed new water system for Wodonga was officially opened on 4th December 1924.This item is significant because it contains financial records related to the construction of one of the oldest and most significant buildings in Wodonga.This large ledger contains both hand written and typed notes documenting financial reports of the Wodonga Water Trust over 40 years. The cover is dark green with brown binding. In the centre of the cover is an red rectangle with text and a border printed in gold.On front cover within gold border BALANCE RECORD WODONGA WATERWORKS TRUSTwodonga waterworks trust, wodonga water tower, a. a. hargrave