V.R Fuel Can for Trolley - Victorian Railways Fuel Can for Trolly Motor Spirit Highly Inflammable Transporting Tin Container "Motor Spirit" is just another name for petrol. "K" and the "KS" Kasey Trolleys were two stroke petrol motors Operation, Care and Maintenance of Track Motors Victorian Railways, 1959 http://www.geoffsrailpix.com/Documents/Motors.pdf gives the following : Inspection motor type B, - straight petrol Inspection motor type V, - pre-mixed petrol Motorised tricycle type M.T., - pre-mixed petrol Gang motor type K.S., - pre-mixed petrol Gang motor type K - pre-mixed petrol Motor cars altered for rail uses (Wiki) Petrol Inspection Car This was a small car numbered '1' and named the Inspection Car. It was built in England in 1923, but was not found in the 1936 stocktake. Gang Motor The eight-horsepower Gang Motor held five people, and was built at Arden Street in late 1923. In 1950 the vehicle was removed from the rolling stock register and given to "Way and Works" as a track motor. Motor Car The Motor Car was put into service in mid 1925, after being fitted with rail wheels in lieu of tyres. In 1927 the car was named "Mr Molomby's Inspection Car", and allocated to Seymour. It was scrapped in 1952. Dodge Cars There were seven Dodge cars in rail service. The cars were numbered 1 to 6, with car 7 listed "No 7 Repair". The cars were built by the Dodge Company of Melbourne and assembled at Newport. Construction was in 1925 and they lasted until 1949.Historic - Victorian Railways - Permanent Way and Works - track equipment - V.R Fuel Can for TrolleyV.R Fuel Can for Trolly - Metal Fuel TinMotor Spirit Highly Flammable V.R 8 ?puffing billy, victorian railways, fuel can, trolley, trolly

The 1950's saw a revolution in small appliances for use in the average household. The hand held self heating(kerosene) iron for which this filling can was provided ,was introduced as a time saving and more convenient iron for pressing clothes and other cloth fabrics. It replaced irons needing an external fire source to heat the ironing plate. These irons continued to be in service, even when electricity was available in cities and larger rural towns. This item was used before and during the electricity supplies available from the Kiewa Hydro Electricity Scheme. These irons remained in use within regional rural areas that had limited or unreliable electrical reticulation and the ability to service them from this filling can was an essential part.n the 1950s and later the Kiewa Valley was still a relatively isolated region which was home to rural properties and small settlements. The availability of electricity and or the financial means to afford new types of electric hand irons ensured that older and sometimes less efficient ironing appliances remained for an extended period covering the 1960s to 1970s. Kerosene products, such as the kerosene self heating (KVHS 0347A) iron and this kerosene filling item, was a cheaper method for farm based domestic and other rural activities requiring a heat source. The use of kerosene as a heat/light source was able to be supplied in bulk and able to be used when floods severed vital roads into this region. The supply of electricity was in summer time subject to interruption from bush fire damaged wooden poles carrying the electrical cables. Self sufficiency by rural populations was the backbone of survival and the ability to store energy sources "on the farm" was a prerequisite of isolated regions, such as the Kiewa Valley, circa 1950s.This specially spout fitted can was provided with the Coleman self heating kerosene iron (see KVHS 0347A). On one side of the half enclosed top of the can there is a small spout(for poring the appropriate liquid into the egg shaped fount container) at the rear end of the hand iron. The can is made from tin. See KVHS 0347B- Instruction sheet; KVHS 0347C- Wrench.On one side of the can in black print on yellow background is "FUEL MEASURING CAN" underneath is "For Coleman Instant-Lite Iron" underneath are four numbered paragraphs detailing the use of this can. Below this is the name and places of manufacture. On the other side of the can is printed "BE SURE" with filling and maintenance instructionskerosene can, ironing, domestic appliances, household appliances

Article was owned by Mart Cruickshank, the mother in law of Peter Simmenauer.One gallon Victa Mower fuel can - green and white with general black printing.domestic items, gardening

3 workers in trench with a machine laying large pipe. ladder at the end of the trench, red fuel can on ground to left of the pipe. The alignment machine is moving along a pre laid track.Kodakorganisation, industry, gas and fuel

Coloured photograph of an aircraft hanger. Equipment and fuel drums can be seen in the foreground.nui dat, photograph, airframe hanger

Centurion model tank.Green in colour set on a board with Red / Orange " Dirt and Dust. Tufts of grass, Fuel cans and amunition puts the tank in its setting- the cannon bares the name -' The Very Diabolical ' Metal plaque placed centre foreground on board in front of tank.R.A.A.C. Centurion MK 5/1' The Very Diabolical' C/S 40 4 Troop C SQN South Vietnam 1971centurion tank, army models, raac

This trade mark (V inside a clover) was German. It was used by the lamp makers Veritas Efsca Works in Birmingham, and for a time by Valor Co. Ltd. which took over Veritas. Valor Co. Ltd. was established in Birmingham in 1890 and produced oil containers for the Anglo-American Oil Com. In 1901 the firm advertised themselves as Stampers And Pieces. Later it was named 'The Valor Co. and was associated with the Aston Brass Co., and advertised as makers of oil lamps and stoves. Valor became a maker of oil heaters cookers and many other products that were fueled by oil. Later it sold gas heaters and ovens. In 1936 Valor Co. Ltd. was made a Public Company and operated under the name The Velor Company Ltd. The company changed names over the years and it was still operating under Velor Fires in January 2002.Oil or kerosene lamps were the means of lighting for homes, farms and industry in the late 19th and early-to-mid 20th centuries. Lamps like these were important as Lighthouse Keepers and Assistant Keepers' equipment. They were in common use in until the lighting was powered by gas and electricity. The reflector at the back of the lamp makes it of greater significance as most lamps don't have this feature. The logo is also interesting as it originated in Germany and was used with permission by a British company and the company that brought it out for a short time. Similar lamps are still available today, usually with gas for fuel. Kerosene lamp; blue painted metal fuel can and metal rear reflector support. and a round corrugated reflector at the rear. The mid-section wick is made of brass. The glass cover or chimney is bulbous in shape. Inscriptions include a trademark "V" inside a clover. It is British-made in Birmingham by either Veritas Efsca Works or Veritas Valor.Trademark; "[clover symbol] surrounding a "V" Stamp: "BRITISH MADE" Marked on adjusting device: "English Made 1 in w" Marked on support of deflector shield - "British Made" and symbolwarrnambool, shipwreck coast, flagstaff hill, flagstaff hill maritime museum, flagstaff hill maritime village, oil lamp, table lamp, kerosene lamp, valor co. ltd, v inside a clover, veritas, british made, lamp reflector, lighting, lamp, the valor company ltd

The 1950's saw a revolution in small appliances for use in the average household. This hand held wrench was provided exclusively for the Coleman self heating kerosene (KVHS 0347A) iron and used for the regular changing the kerosene used in it. The iron was used before and during the electricity supplies available from the Kiewa Hydro Electricity Scheme. These irons remained in use within regional rural areas that had limited or unreliable electrical reticulation. Kerosene supplies were cheaper than electricity but also more inconvenient than electric. Electrical appliances become cheaper to buy and maintain in the later part of the 1900's and the now older kerosene iron was faded out.This wrench was required to open the fuel container which stored kerosene in the Coleman hand iron(see KVHS 0347A). This item was part of the maintenance requirement of this particular hand iron. In the 1950s and later the Kiewa Valley was still a relatively isolated region which was home to rural properties and small settlements. The availability of electricity and or the financial means to afford new types of electric hand irons ensured that older and sometimes less efficient ironing remained for an extended period covering the 1960s to 1970s. Kerosene products, such as this kerosene iron was a cheaper method for farm based domestic and other rural activities requiring a heat source. The use of kerosene as a heat/light source was able to be supplied in bulk and able to be used when floods severed vital roads into this region. The supply of electricity was in summer time subject to interruption from bush fire damaged wooden poles carrying the electrical cables. Self sufficiency by rural populations was the backbone of survival(use of this wrench was a part of rural life). The ability to store energy sources "on the farm" was a prerequisite of isolated regions, such as the Kiewa Valley, circa 1950s.This item is a flat cast iron wrench, which has been specifically made for KVHS 0347A (kerosene iron). The wrench has four specific forms cut into the steel which fit firmly around their targeted nut and other fixtures. Also see See KVHS 0347B- Instruction sheet; and KVHS 0347D Fuel can.ironing, iron maintenance tool, domestic appliances, household

Sad-irons or "solid" irons were made by blacksmiths and used to smooth out material by pressing the hot iron over it. A piece of sheet -iron was placed over the kitchen fire and the irons placed on it could be heated whilst remaining clean of ash.. The women used 2 irons - one heating while the other was used. Thick cloth or gloves protected their hands from the hot irons. The handle was removed from the cool iron and re- attached to remove the hot iron from the fire. The cool iron was replaced on the fire or stove to heat again. These irons were cleaned with steel wool to prevent them marking the material. If the iron was too hot the material would scorch. Most homes set aside one day for ironing and some large households had an ironing room with a special stove designed to heat irons. However, most women had to work with a heavy, hot iron close to the fireplace even in summer. Late in the 19thC designers experimented with heat retaining fillings for these irons. William Coleman began selling Kerosene lanterns in 1900 in Kingfisher, Oklahoma, USA. He moved to Wichita, Kansas in 1902 and the company became world wide. The company also produced a range of cooking stoves and domestic irons. This spirit- fuelled flat iron was very popular in 1920s - 30s These sad irons remind us of the difficult circumstances experienced in their daily routines by the pioneers and early settlers of Moorabbin Shire The family of Miss M Curtis were early settlers in Moorabbin ShireA) spirit- fuelled, sad iron with chrome plated sole c1920, and metal trivet The iron is blue enamel with a white speckled body, with a hemispherical tank for the Coleman 'Lighting Petrol' that provided the heat for smoothing the material B) Coleman Fuel measuring can and funnellMetal Trivet/stand " COLEMAN" ; Petrol can " COLEMAN" / MEASURING CAN / for INSTANT LIGHTING IRON/ with printed instructionssad iron, kitchen equipment, coleman william, kansas, oklahoma, pioneers, early settlers, market gardeners, sewing, craftwork, clothing, moorabbin, brighton, bentleigh, fireplaces, stoves, petrol fuelled irons, spirit flat irons, coleman lamp stove co. ltd.

Bushfire behaviour is influenced by many factors including temperature, relative humidity (RH), forest type, fuel quantity and fuel dryness, topography and even slope. Wind has a dominant effect on the Rate of Spread (ROS), as well as fire size, shape and direction. Temperature and relative humidity have major impacts on fuel dryness and therefore upon the availability of fuel for combustion. The amount of fine fuel available can increase rapidly from nearly zero when fuel moisture content is more than 16% after rain or a heavy morning dew, to many tonnes per hectare as fuel dries out later in the day and the moisture content drops below 9%. This explosive escalation in the amount of available fuel can happen over a few hours on hot and windy days. This device is used for determining air temperature and relative humidity. It contains two thermometers, one of which is covered with a wick saturated with ambient temperature liquid water. These two thermometers are called dry bulb and wet bulb. Once the thermometers to reach equilibrium temperatures the two thermometers are quickly read. The figures are then used to convert the dry bulb temperature TDB and the wet bulb temperature TWB into humidity information. The wet bulb temperature is approximately equal to the adiabatic saturation temperature. Relative humidity meter in wooden box two stainless steel tubes contain wet and dry thermometers A small clock drives a fan motor in the base to circulate airforests commission victoria (fcv), weather, bushfire

Bushfire behaviour is influenced by many factors including temperature, relative humidity (RH), forest type, fuel quantity and fuel dryness, topography and even slope. Wind has a dominant effect on the Rate of Spread (ROS), as well as fire size, shape and direction. Temperature and relative humidity have major impacts on fuel dryness and therefore upon the availability of fuel for combustion. The amount of fine fuel available can increase rapidly from nearly zero when fuel moisture content is more than 16% after rain or a heavy morning dew, to many tonnes per hectare as fuel dries out later in the day and the moisture content drops below 9%. This explosive escalation in the amount of available fuel can happen over a few hours on hot and windy days. A sling psychrometer is a simple device for determining air temperature and relative humidity. It contains two thermometers, one of which is covered with a wick saturated with ambient temperature liquid water. These two thermometers are called dry bulb and wet bulb. When the sling psychrometer is spun rapidly in the air, the evaporation of the water from the wick causes the wet bulb thermometer to read lower than the dry bulb thermometer. After the psychrometer has been spun long enough for the thermometers to reach equilibrium temperatures, the unit is stopped, and the two thermometers are quickly read. A psychrometric scale on the side of the instrument is then used to convert the dry bulb temperature TDB and the wet bulb temperature TWB into humidity information. The wet bulb temperature is approximately equal to the adiabatic saturation temperature. The thermometers fold back into the plastic handle when not in use. Used to measure temperature and relative humiditySling PsychrometerBACHARACH INSTRUMENTS - Pittsburg PAbushfire, forests commission victoria (fcv)

The 1950's saw a revolution in small appliances for use in the average household. This hand held self heating(kerosene) iron was introduced as a time saving and more convenient iron for pressing clothes and other cloth fabrics. It replaced irons needing a separate fire source to heat the ironing plate. These irons continued to be in service, even when electricity was available in cities and larger rural towns (domestic electric steam irons were invented in 1938). This item was used before and during the electricity supplies available from the Kiewa Hydro Electricity Scheme. These irons remained in use within regional rural areas that had limited or unreliable electrical reticulation.In the 1950s and later the Kiewa Valley was still a relatively isolated region which was home to rural properties and small settlements. The availability of electricity and or the financial means to afford new types of electric hand irons ensured that older and sometimes less efficient ironing remained for an extended period covering the 1960s to 1970s. Kerosene products, such as this kerosene iron was a cheaper method for farm based domestic and other rural activities requiring a heat source. The use of kerosene as a heat/light source was able to be supplied in bulk and able to be used when floods severed vital roads into this region. The supply of electricity was in summer time subject to interruption from bush fire damaged wooden poles carrying the electrical cables. Self sufficiency by rural populations was the backbone of survival and the ability to store energy sources "on the farm" was a prerequisite of isolated regions, such as the Kiewa Valley, circa 1950s.This Coleman kerosene iron has a solid steel chrome plated(press) base with a painted (blue) wooden handle. The handle is stud fastened onto an oblong shaped rolled steel handle frame and screwed (two screws) onto the base plate. Both the heating plate and the top securing plate are shaped similar to a river boat. The main housing enclosing the heating element is enamel coated(blue in colour) steel and has a half hole for lighting the kerosene at the rear end. Behind the handle and protruding upwards is a stainless steel fully enclosed container (bowl shaped) for the main supply of kerosene to the burner or generator(enclosed within the main body of the iron. The bowl has an air valve and inlet for pressurised air intake (hand pump) On the bottom rear of the fuel bowl there is a screw regulated fuel pump. The fuel heated base plate provides the heat for this advertised "self heating iron(instant lighting). See KVHS 0347B- Instruction sheet; KVHS 0347C- Wrench; and KVHS 0347D Fuel can.Stamped on the base plate of the handle, front region "COLEMAN LAMP & STOVE CO." below this "WICHITA KAN" below this"TORONTO CAN". In the middle of the handle base and in larger print "COLEMAN Instant-Lite" At the rear location in large print "MODEL 4" in smaller print below "MADE IN U.S.A." below this "PAT#1718473"household appliances, alternative non electrical ironing appliances, domestic appliances, kerosene appliances

The vessels boiling electrical was used by soldiers of 8/13 Victorian Mounted Rifles when it was equipped with Centurion tanks 1966-71. A boiling vessel fitted to British armoured fighting vehicles that permit the crew to heat water and cook food by drawing power from the vehicle electrical supply. It is often referred to by crewmembers (not entirely in jest) as the most important piece of equipment in a British armoured vehicle. The "Vessel Boiling Electric" or "BV" was an innovation at the very end of World War II, when the Centurion tank was introduced with the device fitted inside the turret. Previously, British tank crews had disembarked when they wanted to "brew-up" (make tea), using a petrol cooker improvised from empty fuel cans[4] called a "Tommy cooker". Use of the BV enabled the crew to stay safely inside the tank and reduced the time taken for breaks. The first version, known as VBE No 1, began to be replaced in the early 1950s by the stainless steel No 2 version. A VBE No 3 had improved electrical sockets and was less prone to leakage. The principal use of the BV is to heat ration pouches or tins; the hot water is then used for making drinks or washing. The BV is cuboid and accommodates four tins; typically matching the crew numbers of an armoured fighting vehicle. Ration tins are supplied without adhesive labels so the surrounding water is not contaminated. A vehicle with a defective BV is declared unfit for purpose. It is common practice for a junior member of a vehicle crew to be unofficially appointed "BV Commander", responsible for making hot drinks for the other soldiers. Example of article which improved efficiency and well-being of tank soldiers.Cilinderical metal vessel with close fitting lid, folding handle and electrical socket on side.military, tank, centurion, meals, boiling

Representative samples of fuel such as bark, leaves, twigs etc were minced and the moisture measured The availability of fuel to burn depends largely on its moisture content. When it exceeds 20-25% not much will burn, whereas 12-15% is generally ideal for fuel reduction burning, but if the moisture content drops as low as 7-10% virtually everything will ignite, and fire behaviour becomes extreme. During the afternoon of the Ash Wednesday bushfires on 16 February 1983 fuel moisture contents were recorded at Stawell as low as 2.7%. Fine fuels like leaves and bark can rapidly absorb moisture after a shower of rain, or from the air when the Relative Humidity (RH) is high, and the temperature is low. Conversely, they can also dry out very quickly. So even though the overall fuel quantity in the forest doesn’t change, the fine fuel availability can increase rapidly from zero after rain to many tonnes per hectare as the fuel dries out. This can happen over a few hours on hot and windy days. Heavy fuels like logs on the ground take longer to dry out. Adaption of a timber moisture meter made by the FCV radio lab to measure fuelforests commission victoria (fcv), bushfire, forest measurement

Used to mince fuel samples to measure moisture content Representative samples of fuel such as bark, leaves, twigs etc were minced and the moisture measured The availability of fuel to burn depends largely on its moisture content. When it exceeds 20-25% not much will burn, whereas 12-15% is generally ideal for fuel reduction burning, but if the moisture content drops as low as 7-10% virtually everything will ignite, and fire behaviour becomes extreme. During the afternoon of the Ash Wednesday bushfires on 16 February 1983 fuel moisture contents were recorded at Stawell as low as 2.7%. Fine fuels like leaves and bark can rapidly absorb moisture after a shower of rain, or from the air when the Relative Humidity (RH) is high, and the temperature is low. Conversely, they can also dry out very quickly. So even though the overall fuel quantity in the forest doesn’t change, the fine fuel availability can increase rapidly from zero after rain to many tonnes per hectare as the fuel dries out. This can happen over a few hours on hot and windy days. Heavy fuels like logs on the ground take longer to dry out. Fuel mincer Made at Altona as an alternative design to the commercial Spong Mincer With wooden plug to push fuel into the mincer and glass jar to collect sampleforests commission victoria (fcv), bushfire, forest measurement

Used to mince fuel samples to measure moisture content Representative samples of fuel such as bark, leaves, twigs etc were minced and the moisture measured The availability of fuel to burn depends largely on its moisture content. When it exceeds 20-25% not much will burn, whereas 12-15% is generally ideal for fuel reduction burning, but if the moisture content drops as low as 7-10% virtually everything will ignite, and fire behaviour becomes extreme. During the afternoon of the Ash Wednesday bushfires on 16 February 1983 fuel moisture contents were recorded at Stawell as low as 2.7%. Fine fuels like leaves and bark can rapidly absorb moisture after a shower of rain, or from the air when the Relative Humidity (RH) is high, and the temperature is low. Conversely, they can also dry out very quickly. So even though the overall fuel quantity in the forest doesn’t change, the fine fuel availability can increase rapidly from zero after rain to many tonnes per hectare as the fuel dries out. This can happen over a few hours on hot and windy days. Heavy fuels like logs on the ground take longer to dry out. Battery operated Fuel mincer. Plugs into 12 volt car cigarette lighter socket Adaption using parts from commercial food processor Made at Altona as an alternative design to the commercial Spong Mincer Glass jar to collect sampleforests commission victoria (fcv), bushfire, forest measurement

Used to measure fuel moisture content Representative samples of fuel such as bark, leaves, twigs etc were minced and the moisture measured The availability of fuel to burn depends largely on its moisture content. When it exceeds 20-25% not much will burn, whereas 12-15% is generally ideal for fuel reduction burning, but if the moisture content drops as low as 7-10% virtually everything will ignite, and fire behaviour becomes extreme. During the afternoon of the Ash Wednesday bushfires on 16 February 1983 fuel moisture contents were recorded at Stawell as low as 2.7%. Fine fuels like leaves and bark can rapidly absorb moisture after a shower of rain, or from the air when the Relative Humidity (RH) is high, and the temperature is low. Conversely, they can also dry out very quickly. So even though the overall fuel quantity in the forest doesn’t change, the fine fuel availability can increase rapidly from zero after rain to many tonnes per hectare as the fuel dries out. This can happen over a few hours on hot and windy days. Heavy fuels like logs on the ground take longer to dry out. Adaption of a commercial timber moisture meter measure fuelTF 933 Cforests commission victoria (fcv), bushfire, forest measurement

Used to measure moisture content by electric current resistance Representative samples of fuel such as bark, leaves, twigs etc were minced and the moisture measured The availability of fuel to burn depends largely on its moisture content. When it exceeds 20-25% not much will burn, whereas 12-15% is generally ideal for fuel reduction burning, but if the moisture content drops as low as 7-10% virtually everything will ignite, and fire behaviour becomes extreme. During the afternoon of the Ash Wednesday bushfires on 16 February 1983 fuel moisture contents were recorded at Stawell as low as 2.7%. Fine fuels like leaves and bark can rapidly absorb moisture after a shower of rain, or from the air when the Relative Humidity (RH) is high, and the temperature is low. Conversely, they can also dry out very quickly. So even though the overall fuel quantity in the forest doesn’t change, the fine fuel availability can increase rapidly from zero after rain to many tonnes per hectare as the fuel dries out. This can happen over a few hours on hot and windy days. Heavy fuels like logs on the ground take longer to dry out. Commercial timber moisture meter used to measure fuelDCR9-Tforests commission victoria (fcv), bushfire, forest measurement

Used to prepare fuel samples to measure their moisture content. Representative samples of fine fuel such as bark, leaves, twigs etc were minced first through a course mincing plate, then a fine plate and the moisture content measured with a Speedy moisture meter or other device. The availability of fuel to burn depends largely on its moisture content. When it exceeds 20-25% not much will burn, whereas 12-15% is generally ideal for fuel reduction burning, but if the moisture content drops as low as 7-10% virtually everything will ignite, and fire behaviour becomes extreme. During the afternoon of the Ash Wednesday bushfires on 16 February 1983 fuel moisture contents were recorded at Stawell as low as 2.7%. Fine fuels like leaves and bark can rapidly absorb moisture after a shower of rain, or from the air when the Relative Humidity (RH) is high, and the temperature is low. Conversely, they can also dry out very quickly. So even though the overall fuel quantity in the forest doesn’t change, the fine fuel availability can increase rapidly from zero after rain to many tonnes per hectare as the fuel dries out. This can happen over a few hours on hot and windy days. Heavy fuels like logs on the ground take longer to dry out. Spong No 10 food mincerforests commission victoria (fcv), bushfire, forest measurement

The kerosene lamp was one of the most common oil lamps used and was manufactured until the 1980s. This lamp appears to be a modern reproduction of an earlier optional wall-mounted kerosene lamp. The lamp has been produced as an example of a 19th and early 20th-century marine kerosene navigation lamp. Marine lamp; portside metal kerosene lamp with two flat sides, and a curved front. The front has a red ridged glass lens insert and the name "port" is inscribed on a fixed brass plaque. A round chimney is on top of the lid and it has a catch. The fuel tank and wick can be removed through the base. The metal appears to be electroplated.Inscribed on the plaque; "PORT"warrnambool, shipwreck coast, flagstaff hill, flagstaff hill maritime museum, flagstaff hill maritime village, lamp, ship lamp, port lamp, marine lamp, navigation lamp, port, lantern, kerosene lamp, marine technology, ship light, portable lamp

Bushfire behaviour is influenced by many things including temperature, relative humidity, forest type, fuel quantity and fuel dryness, topography and even slope. Wind has a dominant effect on the Rate of Spread (ROS), and also bushfire size, shape and direction. Fuel arrangement is as important as fuel quantity (tonnes/ha). Fibrous and ribbon bark, together with elevated and near-surface scrub fuels act as ladders which lead flames into the tree canopy. But the availability of fuel to burn depends largely on its moisture content. When it exceeds 20-25% not much will burn, whereas 12-15% is generally ideal for fuel reduction burning, but if the moisture content drops as low as 7-10% virtually everything will ignite, and fire behaviour becomes extreme. During the afternoon of the Ash Wednesday bushfires on 16 February 1983 fuel moisture contents were recorded at Stawell as low as 2.7%. Fine fuels like leaves and bark can rapidly absorb moisture after a shower of rain, or from the air when the Relative Humidity (RH) is high, and the temperature is low. Conversely, they can also dry out very quickly. So even though the overall fuel quantity in the forest doesn’t change, the fine fuel availability can increase rapidly from zero after rain to many tonnes per hectare as the fuel dries out. This can happen over a few hours on hot and windy days. Heavy fuels like logs on the ground take longer to dry out. Since the 1930s foresters, firefighters and researchers have been working to develop quick and reliable techniques for measuring fuel moisture content. One of the most accurate methods is slowly drying a sample of fuel in a conventional oven for 24-48 hours to remove all the moisture and measuring the weight difference, but this takes time and is not practical in the field when rapid measurements are needed. But oven drying is often used as a benchmark to compare other methods. Microwave ovens are faster but can cause uneven drying and even char the fuel. They are also not very practical for use in the field. Some mathematical models rely on weather records such as rainfall, wind speed, evaporation, cloud cover, shading, relative humidity, slope, aspect and season of the year to predict soil and fuel moisture. The Keetch-Byram Drought Index of soil dryness is the most common. But complex fuels with leaves, twigs, grass etc make the predictive models often inadequate for fine fuels. The most common technique in Victorian forests until recently was the trusty Speedy Moisture Meter. Originally developed in England during the 1920s for measuring moisture in wheat and other grains it was adapted for Australian forest fuels in the 1950s (I think). Fuel was first ground using a Spong mincer, often attached to the bullbar of a vehicle, and a small sample placed into the Speedy together with a measure of calcium carbide and then sealed. A chemical reaction created gas pressure which was read on the external dial. There were important techniques with cleaning, mincing and using the chemicals with the Speedy to give reliable readings, but it was quick, inexpensive, robust, portable and practical in the field. It was used routinely before igniting a fuel reduction burn or measuring fuel moisture differentials on slash burns. But in about 1996, Karen Chatto and Kevin Tolhurst from the Department’s Creswick Research Station developed the Wiltronics Fuel Moisture meter which measured electrical resistance. Wiltronics is an Australian owned company operating from Ballarat. The final result was a kit that was portable, accurate and could reliably measure fuel moisture contents between 3% and 200%. Although expensive, it is now widely used by fire agencies around the world which has virtually relegated the Speedy to the back cupboard.Prototype Fuel moisture meterT-H Fine Fuel Meterforests commission victoria (fcv), bushfire, forest measurement

This particular specimen is found in Wolgan Valley, New South Wales. It could be linked to the abandoned oil shale mining sites in Wolgan Valley such as Newnes. Newnes was an industrial complex operational in the early 20th century is now partly surrounded by Wollemi National Park. It produced motor spirit, kerosene, and gas oil. Newnes's Torbanite oil shale rock contained around 350 litres of oil shale per tonne. The Torbanite was mined by the Commonwealth Oil Corporation Ltd. Oil shale is a sedimentary rock and also a form of fossil fuel. It is often formed millions of years ago and usually contain fossilised remains of plants and/or animals. Oil shale is rich in kerogen that releases hydrocarbon when heated. These hydrocarbon can be used as an alternative petroleum or natural gas. The oil-shale rock was converted into oil by "destructive distillation"; the rock being heated until it broke down to form an oily vapour and an ash residue. Oil bearing shale is one of Australia's national assets. There are many oil companies established in Australia. It reflects Australia's rich natural resources as well as connection to the Australia's engineering and oil industry. The booming oil shale extraction businesses can be traced as far back as 1920s. This specimen is part of a larger collection of geological and mineral specimens collected from around Australia (and some parts of the world) and donated to the Burke Museum between 1868-1880. A large percentage of these specimens were collected in Victoria as part of the Geological Survey of Victoria that begun in 1852 (in response to the Gold Rush) to study and map the geology of Victoria. Collecting geological specimens was an important part of mapping and understanding the scientific makeup of the earth. Many of these specimens were sent to research and collecting organisations across Australia, including the Burke Museum, to educate and encourage further study.Piece of dark gray oil bearing shale with shades of light brown and fossilised leavesExisting label: OIL BEARING SHALE with / FOSSILISED LEAVES / Locality: Wongan Valley, NSW / Donor: Miss M. Cambell geological specimen, geology, geology collection, burke museum, beechworth, oil shale, shale, fossil fuels, alfred selwyn, wolgen valley, 1868 geological survey of victoria, rocks, sedimentary rocks, newnes, torbanite, commonwealth oil corporation ltd

http://en.wikipedia.org/wiki/File:Tilley-storm-lantern-X246-May- Tilley storm lantern, this model has been in production since 1964 The Tilley Lamp derives from John Tilley’s invention of the hydro-pneumatic blowpipe in 1813 in England. http://en.wikipedia.org/wiki/Kerosene_lamp#Pressure_lamp Pressure lamps are far more sophisticated than wick lamps and produce a much brighter light, although they can be quite complicated and fiddly to use. This type of lamp is commonly known in the UK as a "Tilley lamp", after a manufacturer of the same name, and in North America as a "Coleman lantern" for similar reasons. A kerosene blowtorch displaying the various aspects of the kerosene burnerA pressure lamp has a fuel tank at the bottom with a small pump to pressurise the kerosene. There is a narrow gap up to the top of the lamp, called a flue, and at the top of the lamp there is a burner (gas outlet). Directly underneath the burner is the mantle, a fabric bag coated with chemicals that incandesce when heated by the gas flame. The burner lamp is known for its brightness. It is so bright because of the amount of pressure that is placed onto the wick. This pressure allows a steady flow of the gasoline and a constant light Tilley Storm Pressure Lantern, model no x246 has a stainless steel base which is filled with kerosene, with a pump used to pressurize the kerosene vapor. Under the base is a sticker.On top is a black hood with vents which sits on the glass heat resistant shade. The glass shade has an etched label. It has a white and pink mantle on the central rod with a long shaped stainless steel handle, this folds down when not in use.Base - Sticker Tilley Lamp Model X246 Etched on glass shade Tilley, Durosil, ITI, Heat Resistant. Made in Englandlantern tilley pump pressure mantle kerosene methylated spirits stainless steel lamp kerosene lamp round glass cylinder

This magic lantern or slide projector was used to project glass slides on to a screen The magic lantern was the chief visual entertainment for the public before the introduction of the moving picture and consequent cinema entertainment. This one probably dates from about 1915 but its provenance is not known.This magic lantern is an important and interesting object as it shows us the way people in the early 20th century were entertained. The few people who owned this type of projector would give public showings of slides of people and scenes and sometimes raise money for a charitable cause in this way. This is a glass slide projector or magic lantern with a rectangular metal lantern body partly open at the back. The back has a top section that is attached with a metal hinge and lifts up and outwards. The lantern base also has a side opening with a metal knob for opening and a metal panel with a blue glass inset. Inside the lantern body is the lamp and an electric cord (the illuminant system may have originally been fuelled by paraffin or another oil burner). On top of the lantern body is a smaller rectangular metal box in two sections. This can be removed. The illuminant system is brass and slides out. It has two mechanisms for adjusting the focus and a covering over the lens opening which can be pulled up. There is also a wooden slide holder which can be pulled in and out of the projector. ‘W.B. British Made’ social history, history of warrnambool, glass slide projector

The tank provides heavy and direct firepower against enemy targets. Its main armament is a 105mm gun which can fire high explosive, armour-piercing, anti-personnel and smoke ammunition. The main gun can engage a pin point target at distances up to 2500m and area targets up to 8000m As with other members of the Leopard family, the gun tank is powered by a V-10 four stroke, supercharged diesel engine developing 610kW. It has a maximum speed of about 62km/h and can "snorkel" through water. These tanks were never used outside Australia and have never been used in combat.Crew 4: Crew Commander, Gunner, Operator, Driver Engine MTU supercharged V-10, (37.4 litres) Fuel Capacity 985 litres Hull Armour 70mm Turret Armour Classified Main Armament L7A3 105mm rifled gun Length 9.54m (with gun in combat position) Width 3.37m Height 2.62m (4.8m with radio aerials) leopard tank

This jacket is part of a Royal Australian Army Ordnance Corps uniform. The Royal Australian Army Ordnance Corps (RAAOC) is responsible for various logistics and organisational operations, such as maintenance of parachutes, fuel distribution, personnel administration, exlosive disposal and laundy operations. The jacket was manufactured in 1968 and was worn by an unknown RAAOC serviceman. The patches on his sleeves denote that he had earned qualifications as a parachuter and a marksman and that he was a Warrant Officer 1. Due to the period of manufacture it can be presumed that the serviceman whom this uniform belonged to served Vietnam War.As an historic military uniform dating to 1968, it is presumed that this item would have been used in service during the Vietnam War. The wearer of the uniform is unknown, however the patches and flashes attached signify that the serviceman worked for the Royal Australian Army Ordnance Corps, earned qualifications as a parachuter and marksman and ranked highly as a Warrant Officer 1. The item is representative of a type of uniform worn by high ranking RAAOC servicemen during the 1960’s. It is also in very good condition for its age.A khaki coloured waist length jacket which is composed of a heavy fabric. The jacket fastens with five buttons down the front and a buckle. The buttons are composed of brown plastic and the buckle is a dark grey metal. The buckle is attached to a waistband on the right-hand side which loops around to a strip of fabric on the left-hand side which passes through the buckle. There are two breast pockets, one on each side of the chest. The right breast pocket is fastened with a brown plastic button and the left breast pocket is missing its button. Each pocket has a flap of fabric which covers the button area. The jacket has a collar and an epaulette on each shoulder which are each fastened with one brown plastic button. There is a ribbon of fabric on the interior of the collar with no inscriptions. There are identical crescent shaped red patches on each shoulder, each showing the words in navy blue stitching "Royal Australian Army Ordinance Corps". The upper right sleeve has a khaki coloured parachuting qualification patch, which depicts an air balloon in white stitching, with wings on either side in light blue stitching. The lower section of each sleeve has a Warrant Officer First Class khaki coloured patch. This depicts a shield in red, black, white, blue and gold stitching in the centre which sits beneath a gold and blue striped line and a gold star. There is a gold kangaroo to the left of these motifs and a gold emu to the right. Beneath these motifs there is a ribbon in white, blue and gold stitching with the word "Australia". In addition there are curvilinear green decorative elements with yellow flowers on their ends. The left-hand sleeve also has a brown marksmen qualification patch. This depicts two crossed rifles in white and brown stitching. There is a white label with printed inscriptions on the interior of the left breast pocket. There is also a band of fabric on the interior back waist band which has three button holes.Printed in black inscriptions on the white label: E.W. PTY/LTD. SOUTH AUSTRALIA 1968 (a broad arrow) Class 8405-66-025-641 Batch A.W... Mill (the ‘A.W...’ is in stamped purple ink and there are some other purple inscriptions that are difficult to decipher) SIZE OF CHEST 39/49PR MATCHING TROUSERS 37 PR DRY CLEAN ONLY CREASE UPPER HALF OF LAPELS ONLY NAME..... ARMY No..... (the number 40 is also wrtten in faded black ink in the top right corner of the label)military, jacket, army, raaoc, royal australian army ordnance corps, parachuting, marksman, warrant officer, uniform

These trousers are part of a Royal Australian Army Ordnance Corps uniform. The Royal Australian Army Ordnance Corps (RAAOC) is responsible for various logistics and organisational operations, such as maintenance of parachutes, fuel distribution, personnel administration, exlosive disposal and laundy operations. The trousers were manufactured in 1969 and were worn by an unknown RAAOC serviceman. The patches on the sleeves of the corresponding jacket denote that he had earned qualifications as a parachuter and a marksman and that he was a Warrant Officer 1. Due to the period of manufacture it can be presumed that the serviceman whom this uniform belonged to served in the Vietnam War.As historic military uniform trousers dating to 1968, it is presumed that this item would have been used in service during the Vietnam War. The wearer of the uniform is unknown, however the patches and flashes attached signify that the serviceman worked for the Royal Australian Army Ordnance Corps, earned qualifications as a parachuter and marksman and ranked highly as a Warrant Officer 1. The item is representative of a type of uniform worn by high ranking RAAOC servicemen during the 1960’s. It is also in very good condition for its age.khaki coloured trousers which are composed of a heavy fabric. The trousers button up at the front with 6 plastic buttons. There is an additional strip of fabric attached to the right-hand fly which can be fastened with an extra button on the interior of the left-hand fly. There are an additional 6 buttons along the interior waistband. There are also three buttons on the exterior waistband down the front and a buckle. The buttons are composed of brown plastic. There are two open hip pockets, one on either side, and another button-up pocket on the right-hand side of the back. There is a white label with inscriptions attached to the interior of the back pocket with an extra piece of fabric attached for mending patches.Printed in black inscriptions on the white label: CONWAY BROS. PTY. LTD ADELAIDE 1969 (a broad arrow) Class 8405-66-025-6183 A W M 7 (these characters are stamped in faded black ink) SIZE & WAIST 33R MATCHING JACKET 37-38R in a box are the words: DRY CLEAN ONLY. Re-press on original seams. Creases set by Si-ro-set. Mending patch attached. (end of box containing words) NAME.....DOCKSEY (‘Docksey is in hand-written black ink) ARMY No.....216308 (numbers also hand-written in black ink) (the number 40 is also wrtten in faded black ink in the top right corner of the label)military, army, raaoc, marksman, royal australian army ordnance corps, parachuting, warrant officer, uniform, trousers

Mower fuel container also marked as "Victa Motor Mower Fuel".Metal container for mower fuel.The slogan "Best for 2-stroke", instructions for mixing ideal fuel combination, quick fault finding and advice to shake can before use. petrol cans, mower fuel

The Uebergang family came from Silesia to Australia in 1848 and were early settlers in the Allansford area. The sons and other descendants also purchased farms in the area. The Percy Uebergang family lived at Tooram Park, Allansford from 1912 until 1992. Percy and Myrtle Uebergang's children were twins, Ray and Joyce born in 1926 who lived at Tooram Park until their deaths, Ray in 1986 and Joyce in 1992 after which the property was sold. Neither Ray nor Joyce married and following the death of her brother Joyce set up the Ray and Joyce Uebergang Foundation which supports the local community. The collection of items from their property was put into store for a number of years before being given into the care of the Cheese World Museum. The family often re-used, recycled and repaired items and examples can be seen in the museum. This petrol pump is part of the collection of items given into the care of the Cheese World Museum. As with many rural families the Uebergangs had bulk fuel supplies on-farm. The bowser was used to refuel farm machinery. Mobil's Super Plume petrol was one of the many brands of petrol available from the late 1920s. No electricity was required to work this bowser as it was gravity fed. The amount of petrol was selected by the position of the front lever. Petrol was then pumped into the bowl by the handle on the side of the bowser and gravity=fed to the vehicle. This petrol bowser is an example of a 1920s petrol bowser.allansford, uebergang, vacuum oil company, super plume petrol bowser, petrol bowsers, farm machinery