Large Platform Lamp used by Railways to signal train at stoppings, Cubed in shape with angled sides. Plain glass front, Red-coloured lens on both sides, which can be opened to reveal plain glass.. Covered chimney on top . Bracket on the back to hang the lamp up. railway, platform lamp, lantern, signal, kerosene

Metal (silver-plated?) cylindrical base with a column rising up to a cylindrical storage area for kerosene. On top of this are three wires protruding out from the burner area. These wires would be used to hold the glass lens (not with the lamp)lamp, lantern, light, kerosene

Metal cylindrical base to store kerosene. Metal "arch" connected to the base and holding the top metal vent in place. The top vent and bottom vents have wire metal holding the glass lens in place. There is also a wire handle Lanora Australia, on baselamp, lantern, light, kerosene

Prior to the launch of the motor powered Queenscliffe, three row boats were in service as lifeboats. This lantern was part of the equipment of the third lifeboat up to 1926.A brass lamp which was part of the safety equipment on board the Third Queenscliff LifeboatBrass Lantern with interchangeable port and starboard glass filters run of kerosene.Brandt Bros Melbourne Manufacturers 422 Elizabeth Streetlight, navigational safety

The seven weights (0008.4 and 0136.3) are circular in shape with a hole in the centre and a groove cut across the radius. They were specifically designed to fit into a weight tube, which allowed movement of the weights that were used for driving the clockwork mechanism for turning the lighthouse lens. They are most likely original to the Chance Brothers system installed in 1913, which was originally equipped with a set of ten, each weighing around thirty kilograms.The weights were moved vertically in similar fashion to the way weights move on a grandfather clock. As the weight fell, the optic clock was driven and the lens was turned. To keep the clock turning, the weight needed to be wound back up to the top of its travel. Lighthouse keepers had to constantly wind the clock to keep the light active, and at least two keepers needed to observe a strict roster of hours. When electric motors were invented, weights became obsolete and the motors were able to turn the optic for as long as there was power to drive them. Wilsons Promontory’s Chance Bros. kerosene operated light, which was turned by a clockwork mechanism, was replaced by small electric motor in 1975, reducing the number of keepers and eliminating the need for weights. Cape Schanck has a set of fourteen weights remaining in situ in the lighthouse weight tube as well as another four detached weights, two of which may be associated with the 1859 mechanism. A small number of detached cast iron weights and two associated rods remain at the Point Hicks Lightstation and one weight is displayed in the lantern room at Cape Otway.The Wilson Promontory weights have first level contributory significance for the insights they provide into the technology and operations of a late nineteenth/early twentieth century lighthouse which has since been superseded. They are well provenanced and are significant for their historical value as part of the lightstation’s Chance Brothers optical system installed in 1913.Four circular disc shaped lead weights, all with a narrow section cut out to the middle of shape. (as in slice of cake)

Used in the early 20th CenturyAn early 20th Century glass and rusted tin "hurricane" lamp with three wire curved horizontal bands protecting the clear chimney glass. This is a portable lantern with an oil tank at the bottom that forms the base of the lamp. The tank is filled through a metal tube with a screw top lid and it also houses a wick and knob that increases or decreases the length of the wick.lantens, kerosene lamps, lighting equipment, lamps

Used in the early 20th CenturyAn early 20th Century glass and rusted tin "hurricane" lamp with curved wire protecting the clear chimney glass. This is a portable lantern with an oil tank at the bottom that forms the base of the lamp. The tank is filled through a metal tube with a screw top lid and it also houses a wick and knob that increases or decreases the length of the wick.lamps, kerosene lamps, lighting equipment, lanterns

A small number of heavy cast iron weights and two rods remain at the Point Hicks Lightstation. These weights comprise one rod with a forked top and four circular weights attached to the bottom of the shaft. The weights and rods were part of the original clockwork mechanism that was fitted beneath the lens to keep the kerosene‐fuelled light turning. They were attached to a cable or chains and moved vertically in similar fashion to the way weights move on grandfather clocks. As the weight fell, the optic clock was driven and the lens was turned. To keep the clock turning, the weight needed to be wound back up to the top of its travel. The cables and weights in this lighthouse were visible as they moved through the length of the tower up to the lantern room. It was usual for systems to move inside a tube extending up to the top, but in this case the tower’s cast iron spiral staircase, which is supported on cantilever cast iron brackets set into the concrete wall, spiralled around the space in which they moved. Lighthouse keepers had the arduous job of having to constantly wind the clock to keep the light active, and at least two keepers needed to observe a strict roster of hours. When electric motors were invented, all of this became redundant and the motors were able to turn the optic for as long as there was power to drive them. In December 1964, the original 1890 Chance Bros kerosene‐fuelled light and clockwork mechanism were replaced by small electric motor, and the number of keepers reduced to two. The six circular weights and rods originate from the obsolete system and may have been part of a larger set. Wilsons Promontory retains seven of its original set of ten weights, all of which are detached from the tower’s weight tube. Cape Schanck has a set of fourteen weights remaining in situ as well as another four detached weights, which have inscriptions. One weight is displayed in the lantern room at Cape Otway. The image shows four of the clockwork weights attached to a rod with a forked top. They were part of the original clockwork mechanism that was fitted beneath the lens to keep the kerosene‐fuelled light turning. The Aldis lamp in its case sits on the floor next to the weights. Source: Parks Victoria.The Point Hicks weights have first level contributory significance for the insights they provide into the superseded technology and operations of a late nineteenth century lighthouse. They are well provenanced and are significant for their historic value as part of the lightstation’s Chance Brothers optical system installed in 1890. Four circular metal weights are stored on a metal rod with a forked section at the top. The weights have a cut out section which allows the weights to be removed easily.

A small number of heavy cast iron weights and two rods remain at the Point Hicks. The weights and rods were part of the original clockwork mechanism that was fitted beneath the lens to keep the kerosene-fuelled light turning. They were attached to a cable or chains and moved vertically in similar fashion to the way weights move on grandfather clocks. As the weight fell, the optic clock was driven and the lens was turned. To keep the clock turning, the weight needed to be wound back up to the top of its travel. The cables and weights in this lighthouse were visible as they moved through the length of the tower up to the lantern room. It was usual for systems to move inside a tube extending up to the top, but in this case the tower’s cast iron spiral staircase, which is supported on cantilever cast iron brackets set into the concrete wall, spiralled around the space in which they moved. Lighthouse keepers had the arduous job of having to constantly wind the clock to keep the light active, and at least two keepers needed to observe a strict roster of hours. When electric motors were invented, all of this became redundant and the motors were able to turn the optic for as long as there was power to drive them. In December 1964, the original 1890 Chance Bros kerosene-fuelled light and clockwork mechanism were replaced by small electric motor, and the number of keepers reduced to two. The six circular weights and rods originate from the obsolete system and may have been part of a larger set. Wilsons Promontory retains seven of its original set of ten weights, all of which are detached from the tower’s weight tube. Cape Schanck has a set of fourteen weights remaining in situ as well as another four detached weights, which have inscriptions . One weight is displayed in the lantern room at Cape Otway. The Point Hicks weights have first level contributory significance for the insights they provide into the superseded technology and operations of a late nineteenth century lighthouse. They are well provenanced and are significant for their historic value as part of the lightstation’s Chance Brothers optical system installed in 1890.PHLS0005.1 Round cast iron weight with flat base used for lens clock-work mechanism attached to a bent metal rod. PHLS0005.2 Removable round cast iron weight with flat base used for lens clock-work mechanism stored above the other weight.

The two hand-held, portable kerosene lamps each have green enamel caps over the glass. They were used from around the 1930s until 1993, and one is now located on the groundfloor level of the lighthouse and the other is in the assistant lightkeeper’s quarters. The brand name of the Point Hicks lamp, while not stated is probably Coleman, Tilley or Austramax, which were all similarly made, portable pressurised kerosene lamps. Coleman brand pressure lamps and lanterns were first made in about 1905 by American, William Coleman, and their English competitor was the firm, Tilley. The Australian company Austramax began manufacturing kerosene pressure lamps in Brunswick in 1946, making the bases and the workings by hand, turning out 1000s of lamps each week. Portable lamps were used worldwide where bright light was needed and they became essential as an emergency back-up source of light for the lightstation as well as the lantern room. Through the multiplication of light by the lighthouse lenses, they could provide a tower with a 26 nautical mile range. Lamps similar to the two Point Hicks examples can be found at Gabo Island, one of which is a green enamelled Austramax lamp; Cape Nelson (Austramax), and similar lamps are held at Cape Schanck and Cape Otway. The two Point Hicks lamps have first level contributory significance for their historic value and provenance, and as representative examples of lamps that were widely used in Australian lightstations between the 1930s and 1960s.PHLS0008.1 & PHLS0008.2 Pressurised kerosene lamp, cover over glass is made of green enamelled metal.

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 is a typical example of a flat wick domestic paraffin lamp used in households prior to the introduction of electricity.A flat-wick lamp is a simple type of paraffin lamp, which burns paraffin drawn up through a wick by capillary action. A flat-wick lamp has a fuel tank (fount), with the lamp burner attached. Attached to the fuel tank, four prongs hold the glass chimney, which acts to prevent the flame from being blown out and enhances a thermally induced draft. The glass chimney needs a "throat", or slight constriction, to create the proper draft for complete combustion of the fuel; the draft carries more air (oxygen) past the flame, helping to produce a smokeless light, which is brighter than an open flame would produce. The wick holder has holes around the outer edges. When the lantern is lit and a chimney is attached, the thermally induced draft draws air through these holes and passes over the top of the wick. This has a cooling effect and keeps the wick from over heating. The lamp burner has a flat wick, made of cotton. The lower part of the wick dips into the fount and absorbs the paraffin; the top part of the wick extends out of the wick tube of the lamp burner, which includes a wick-adjustment mechanism. Adjusting how much of the wick extends above the wick tube controls the flame. The wick tube surrounds the wick and ensures that the correct amount of air reaches the lamp burner. Adjustment is usually done by means of a small knob operating a cric, which is a toothed metal sprocket bearing against the wick. If the wick is too high, and extends beyond the burner cone at the top of the wick tube, the lamp will produce smoke and soot (unburned carbon). When the lamp is lit, the paraffin that the wick has absorbed burns and produces a clear, bright, yellow flame. As the paraffin burns, capillary action in the wick draws more kerosene up from the fuel tank. All paraffin flat-wick lamps use the dead-flame burner design, where the flame is fed cold air from below, and hot air exits above. (Source: Wikipedia accessed 24 Nov 2023) This lantern has a circular heavy green glass base for holding the paraffin. The base has a 12mm green glass handle. There is a small clear glass chimney with a fluted upper edge and some bubbles in the glass. The metal burner and wick holder has four metal prongs to hold the glass chimney in place. The round metal wick winder is functioning. There is a small amount of residual paraffin in the base. The flat wick is made of cotton.There are no markings to indicate the manufacturer.paraffin lamp, flat wick lamp, domestic lantern