Neville Bunning in RAAF Uniform .16 a,b, c - foolscap sized pages relating to various methods for doing different things with RAAF planes neville bunning, raaf, uniform, mainplanes, airframes, joints, fuselage, lockheed hudson, lockheed vega, light components, strength and weights, slinging aircraft, slings, slinging points, kittyhawk, vultee vengence

Lucas Electrical manufactured light and electrical components for many vehicle manufacturers in England and many manufacturers used them as accessories or added extras.Lucas granted Richards Body Builders of Adelaide, Australia, permission to use the phrase 'King of the Road' as their trade nick name.Kidney shaped metal & glass, four lens number-plate & tail light combinationKing of the Road maker's marktail light, stop light, light tail, king of the road light, number plate light

Andrew John BALSILLIE MBE, JP. (Born Bendigo) Jack as he was known enlisted in the Australian Army near the end of WWII No 31224 age 16 years. He then served in Malaya 1959 - 1961then Vietnam with the rank of Captain with 1st Aust Task Force HQ Light Aid Detachment (LAD) 7.5.1969 - 7.11.1969, HQ Aust Force Vietnam Army component 8.11.1969 - 7.5.1970. He retired with the rank of Major in 1985 after 40 years plus. He was awarded an MBE in 1969 for his services to the Australian War Memorial. Elected to Committee Bendigo RSL 1988 - 1993 with Snr Vice President 1989 - 1993, re-elected 1999 - 2000. Re-elected again in 2002 as Snr Vice President. He was elected to Bendigo City Council 1990 - 1993 serving as Mayor in 1993. .1) Bush hat, floppy, khaki canvas, belonged to Major J BALSILLIE. .2) - .4) Gauze wound dressing in brown cotton pack, 2 rolls per pack. .5) Neck cloth, green cotton..1) Inside hat: Maj J Balsillie. .2) - .4) Labelled: First Field Dressings.headwear, medical dressings

This uniform belonged to Sapper Hughes 3795948 of the Royal Australian Engineers Corps. By the date on the uniform, it is assumed that he served C 1968.This uniform has significance as an example of a uniform worn by soldier ranks for daily work and dress parades.Khaki coloured long trousers with attached suspenders. They have a button up front (5 brown plastic buttons). There are two pockets on either side of the trousers and one button up pocket on the back right with a flap that is fastened with a single brown plastic button. There are three extra brown plastic buttons on the back exterior of the waistband and six belt loops on the whole length of the waist band. The interior pocket fabric is more light weight and a slightly more green in colour. The interior of the right back pocket includes a white patch of fabric with printed inscriptions and further inscriptions written in black ink just above. The suspenders are composed mostly of blue, grey, beige, black and cream striped thick fabric. There are also silver coloured metallic components (which include inscriptions) and leather sections, most of which have a reddish/brown coating on the exterior and a white coating on the interior. One leather component has inscriptions in black ink on the interior as opposed to a white coating. The suspenders are attached to the trousers by six brown plastic buttons on the interior of the waistband. Back pocket interior inscriptions on the green fabric: HUGHES / 3795948 Back pockket interior inscriptions on the white fabric: E.W. P/LTD. / SOUTH AUSTRALIA / 1968 / (a symbol of a broad arrow) / Class 8405-66-025-6405 / Batch 67 / Mill / Size and Waist 28C / Matching Jacket 35 /36C / DRY CLEAN ONLY / CREASES SET BY SIROSET / REPRESS ON ORIGINAL CREASES / MENDING PATCH ATTACHED / NAME HUGHES. J.W. / ARMY No. 3795948 8PL Bcoj Identical metallic clip inscriptions on two of the suspenders: POLICE / (embossed image of a police baton)royal australian engineers, warrnambool rsl, warrnambool, engineer, hughes, sapper hughes, 3795948, hughes 3795948, uniform, army uniform, trousers, army

The Salamandra is a Polish glider designed by Waclaw Czerwinski at the Military Glider Workshops in Krakow in 1936. This glider, designated “W.W.S.1”, was produced in substantial numbers prior to the second world war and used in Poland and some other eastern European countries for training pilots. Only one example survived the war, hidden away in the village of Goleszow in Silesia. In addition, no technical drawings could be found, so when the glider was discovered, the Gliding Institute being keen to re-establish gliding in Poland, used the glider to draw up new plans for construction. Five were built for the Institute in 1947 before production was resumed of the “Salamandra 48” at the SZD Jezow Workshops. Improvement were made by adding airbrakes and structural changes for the “Salamandra 49” and a windscreen and larger tailplane were changes adopted for the “Salamandra 53”. An export version designated “53A” was sold to and built under licence in China. Production of the Salamandra ceased in the early 1960s. Total production may have been in excess of 500. The glider was well regarded as a light weight trainer capable of soaring performance. The Museum’s replica was built by Ray Ash and may be may be classified as a “Salamandra 53”. However, he has added something of his own to the design by replacing the cable runs in the wings with control rods. The glider is substantially complete. The wings and tail / rudder surfaces have been covered with poly-fibre fabric. The fuselage woodwork is sealed with varnish. In addition to the finishing work (including painting) and rigging of the main components, the linkages for Ray’s control rod modification may need further engineering to make them operational. The Ray Ash Salamandra is the first of the type to appear in Australia. The Salamandra did not play any role in the development of gliding in Australia in the early years. However, it is an important exhibit in that it shows in tangible form a nacelle fuselage training glider in configuration and construction detail. As such it revisits the pioneering era of the 1930s and 1940s in Australia when wood, wire and fabric were the rule and the nacelle primary glider was generally the first step up for pilots who had mastered the basics in an open primary.Nacelled solo training glider of traditional wood and fabric construction. Construction incomplete.Noneaustralian gliding, sailplane, glider, salamandra, czerwinshi, poland, ash

Bendigo Saleyards Relocation Study - Planning Report and Environment Effects Statement for the City of Bendigo by A E Huefner & Associates Pty Ltd in association with Meldrum Burrows & Partners. Book has a light brown cover with black plastic binder spine. Green and yellow pages separate some sections. The front cover has a sketch of a stock transport with a pig, sheep and cattle behind gates. Contents include: Introduction, Summary, Recapitulation on the Feasibility Report which includes The Need for Action, the Site and Existing Uses Adjacent to the Site, The Proposal which includes Concept, Project Description, Components, Siting of Facilities, Land Clearing, Earthworks, Darainage, Buildings and Structures, Roads and Pavements, Services, Landscaping, Soil Profile and Construction Programme. Invironmental Effects which include Visual Impact Dust, Odours, Effluent, Effluent Treatment System, Traffic, Artificial Lighting, Noise, Operational Failures and Nature Conservation Effects. Statutory Planning Considerations which includes Zoning Controls and Suggested Procedure for Initiating I.D.O. Amendment. Appendices are: A.- Copy of Tit;e, B - Soil Investigation, C - Acoustic Assessment and D - Suggested Draft Amendment to Shire of Marong I.D.O. Contains a photo of the area - View of the Site, looking South and a number of drawings. Copies of various Council Reports referring to the Saleyards Relocation Project. It has a bright yellow cover and a hard plastic type spine. Mentioned in the reports is the cost to bring the old saleyards up to standard and list of improvements. Reports are as at 16th July, 1984. Mustard coloured book with plastic spine titled Bendigo Saleyards Relocation Study Feasibility Report by Meldrum Burrows & Partners in association with A E Huefner & Associates Pty Ltd and Acil Australia Pty Ltd dated September, 1983. Items mentioned are: Introduction, Summary, Background, Role in Livestock Marketing for the Bendigo Saleyards (Acil Australia Pty. Ltd., Saleyard Relocation: Strategic Considerations, Financial Implications and Conclusion. Appendix 1: Estimation of Livestock Population in Catchment Area. Drawings in Fig 1 Existing Bendigo Saleyards and Surrounding Land Uses, Fig 2 Catchment Area for Bendigo Saleyards 1983, Fig 4.1 Estimated Sheep Populatiuon in Catchment Area 1976 - 77 to 1981 - 82, Fig 4.2 Estimated Cattle Population in Catchment area 1976 -77 to 1981 -82, Fig 3 Possible Saleyard Relocation Areas, Fig 4, Directions from which access to possible Saleyard Locations would be obtained - Estimated percentage of sheep to cattle stock, Fig 5 Possible Saleyard Locations - Northern Area, Fig 6 Possible Locations of Saleyards - Inner West, Fig 7 Possible Locations of Saleyards - Outer West. Considerations were made as to renovate the existing saleyards or to move them elsewhere. Effluent, transport and stock movement, and condition of the yards were a problem.bendigo, council, cattle markets, bendigo saleyards collection - bendigo saleyards relocation study - planning report and environment effects statement, a e huefner & associates pty ltd, meldrum burrows & partners, city of bendigo, state electricity commission, mal styles, bendigo college of advanced education, n j fieldew, pryce goodale & duncan pty ltd, p b swift, shire of marong

This auger was used in the making of components for the ship model Sovereign of the Seas. It is part of a collection of objects used by Jim Williams, maker of fine ship models from about 1930-1955. Most of the components for the models, as well as many of the tools, were handmade by Jim Williams. Jim’s family has donated the ship model “Sovereign of the Seas” and many tools, accessories and documents used in the making of this and other ship models have been donated to Flagstaff Hill Maritime Village. Ship model of HMS Sovereign of the Seas, scale model of 17th Century English war ship, was handmade and carved from plans, enclosed in airtight glass case. All components of that model, including even the smallest pulleys, were hand crafted using tools designed and made by Jim. Outstanding details include functional rigging and moving cannons. Please see our record 3732 of the mode Sovereign of the Seas for further details of the ship and the maker. This auger is connected with the hobby and skill of ship model making that has been crafted as a leisure activity for many generations. The hobby is often chosen by serving and retired mariners who appreciate the connection with maritime history. This auger was used by local Warrnambool man, Jim Williams, who was employed at Cramond and Dickson clothing store, and then at Fletcher Jones menswear for 27 years. It was used in making components for the model of the historic ship, the Sovereign of the Seas. The Sovereign of the Seas was a historic 17th century English war ship with important maritime heritage. Small auger, metal shank with threaded tip, and light coloured, oval shaped wooden handle. This auger is part of a collection of tools and accessories once used by Jim Williams, maker of a series of ship models 1930-1955 including “HMS Sovereign of the Seas”. flagstaff hill, warrnambool, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, jim williams, james bernard williams, ship model hobby, ship model tools, ship model making equipment, ship model making accessories, auger, hand tool, sovereign of the sea, ship model, hobby, ship model tool, tool

Optometrists are trained to examine eyes and prescribe visual aids such as spectacles. The optometer pictured in the media section of this document dates from the 1800s. The optometer was used with various lenses to determine the refraction of the eye. Refraction means the extent to which light is bent by an individual's eye. The result can determine how short-sighted or long-sighted they are, and the strength of spectacles required. In the second half of the 1800s, ophthalmologists also devised instruments to measure the separate components of vision. Dr Jules Badal developed the pictured instrument in 1876. It was based on an optometer invented by William Porterfield in 1759. The brass stands look as though they were made for an optometer to be table mounted, with heavy brass stands and designed to hold a cylindrical object securely as would be required by an optometer. Stands appear to have been very well made and very early probably early to mid 19th Century by a well known scientific instrument maker given there are no inscriptions or marks to indicate the time period made or maker it is difficult to assume significance to these items at this point in time as well as the items are incomplete.The brass stands believed to be for mounting an early Optometer an (ophthalmic instrument) Noneflagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, stands for scientific instrument

Both the Light switch and Door knob were used in Box Cottage during the late 19thC and early 20thC by the Box and Rietman families. William and Elizabeth Box purchased the two ten acre Lots of land with the Cottage in 1868 where they raised their family of 12 children and developed a flower garden producing seedlings. August and Frieda Rietman rented the Cottage 1917 with 1 acre of land and purchased it in 1935 where they raised 2 children while August established Rietman's Landscaping Pty Ltd making pressed concrete garden furniture. Porcelain is a ceramic material made by heating materials, generally including kaolin, in a kiln to temperatures between 1,200 and 1,400 °C The toughness, strength and translucence of porcelain, relative to other types of pottery, arises mainly from vitrification and the formation of the mineral mullite within the body at these high temperatures. Porcelain and other ceramic materials have many applications in engineering, especially ceramic engineering. Porcelain is an excellent insulator for use at high voltage, especially in outdoor applications, see Insulator (electricity)#Material. Examples include: terminals for high voltage cables, bushings of power transformers, insulation of high frequency antennas and many other components. Both the Light switch and Door knob were used in Box Cottage during the late 19thC and early 20thC by the Box and Rietman families. William and Elizabeth Box purchased the land with Cottage in 1868 and raised their familya) An electric light switch that would be attached to a wall. An Ivory Porcelain Base Single Light Switch with antique Brass top b) A porcelain door knob Both items used in Box Cottage early 20th Ca) On base BRITISH MADE / ENGLAND / 4 / 6959 lights, porcelain, electricity, early settlers, moorabbin, cheltenham, bentleigh, box william, box elizabeth, rietman august, rietman frieda, market gardeners, flower gardens, seedling nurseries, world war 1 1914-18, war memorials, sculpture, pottery, pressed concrete, door handles, door knobs

Lens was once the spare lens of the Cape Nelson Lighthouse.|Lens on display in MDC, with interactive component provided by the piece of broken lens - for handling. Investigations underway to use a low-watt light in the lens, which is in working order. Photos in Supplementary File.Glass lens with steel supports, painted black with bronze hinges and latches. From Cape Nelson Lighthouse - spare lens. Base for display purposes - section of contemporary concrete pipe.Front: (no inscriptions)lighthouse, cape nelson lighthouse

Before the introduction of electricity, lighthouses had a clockwork mechanism that caused the lens to rotate with a light source inside that was either powered by Kerosene or Colza oil. The mechanism consisted of a large weight attached by a cable through the centre of the lighthouse to the top where the cable wrapped around a barrel, drum or wheels that controlled the speed of the lights rotation by a clockwork mechanism. The keeper would crank the clockwork mechanism, which would lift the weight ready for the next cycle similar to an old grandfather clock mechanism. Once the weight lifted to its apex at the bottom of the first landing, the keeper would let it fall, which would pull on the cable, which would, in turn, operate a series of gears activating the rotation of the Fresnel optical lens, which would then rotate to create the lighthouse’s unique light speed of rotation characteristic. Creating a specific characteristic required a way to regulate the speed of the rotation, and was important as sailors could identify a particular light by its speed and time between flashes. The weight had to fall at a certain rate to create the proper rotation speed of the lens and a regulator within the mechanism accomplished this. History: From 1851, Chance Brothers became a major lighthouse engineering company, producing optical components, machinery, and other equipment for lighthouses around the world. James Timmins Chance pioneered placing lighthouse lamps inside a cage surrounded by Fresnel lenses to increase the available light output these cages, are known as optics and they revolutionised lighthouse design. Another important innovation from Chance Brothers was the introduction of rotating optics, allowing adjacent lighthouses to be distinguished from each other by the number of times per revolution the light flashes. The noted English physicist and engineer, John Hopkins invented this system while employed at Chance Brothers. Chance Brothers and Company was a glass works and originally based in Spon Lane, Smethwick, West Midlands England. The company became a leading glass manufacturer and a pioneer of British glass making technology. The Chance family originated in Bromsgrove as farmers and craftsmen before setting up a business in Smethwick near Birmingham in 1824. They took advantage of the skilled workers, canals and many other industrial advances taking place in the West Midlands at the time. Robert Lucas Chance (1782–1865), known as 'Lucas', bought the British Crown Glass Company's works in Spon Lane in 1824. The company specialised in making crown window glass, the company ran into difficulty and its survival was guaranteed in 1832 by investment from Chance's brother, William (1788 – 1856). William owned an iron factoring business in Great Charles Street, Birmingham. After a previous partnership that Lucas had dissolved in 1836, Lucas and William Chance became partners in the business which was renamed, Chance Brothers and Company. Chance Brothers invented many innovative processes and became known as the greatest glass manufacturer in Britain. In 1848 under the supervision of Georges Bontemps, a French glass maker from Choosy-le-Roi, a new plant was set up to manufacture crown and flint glass for lighthouse optics, telescopes and cameras. Bontemps agreed to share his processes that up to then had been secret with the Chance Brothers and stayed in England to collaborate with them for six years. In 1900 a baronetcy was created for James Timmins Chance (1814–1902), a grandson of William Chance, who had started the family business in 1771 with his brother Robert. Roberts grandson, James became head of Chance Brothers until his retirement in 1889 when the company became a public company and its name changed to Chance Brothers & Co. Ltd. Additional information: Lighthouses are equipped with unique light characteristic or flashing pattern that sailors can use to identify specific lighthouses during the night. Lighthouses can achieve distinctive light characteristics in a few different ways. A lighthouse can flash, which is when brief periods of light interrupt longer moments of darkness. The light can occult, which is when brief periods of darkness interrupt longer moments of light. The light can be fixed, which is when the light never goes dark. A lighthouse can use a combination of flashing, oscillating, or being fixed in a variety of combinations and intervals to create individual light characteristics. It is a common misconception that a lighthouse's light source changes the intensity to create a light characteristic. The light source remains constant and the rotating Fresnel lens creates the various changes in appearance. Some Fresnel lenses have "bulls-eye" panels create beams of light that, when rotated between the light and the observer, make the light appear to flash. Conversely, some lenses have metal panels that, when rotated between the light and the observer, make the light appear to go dark. This Dioptric clockwork apparatus used to turn a lighthouse optical lens is very significant as it is integral to a lighthouses operation, we can also look at the social aspect of lighthouses as being traditionally rich with symbolism and conceptual meanings. Lighthouses illustrate social concepts such as danger, risk, adversity, challenge and vigilance but they also offers guidance, salvation and safety. The glowing lamp reminds sailors that security and home are well within reach, they also symbolize the way forward and help in navigating our way through rough waters not just on the oceans of the world but in our personal lives be it financial, personal, business or spiritual in nature. Nothing else speaks of safety and security in the face of adversity and challenge quite the way a lighthouse does. Revolving dioptric clockwork apparatus used to turn a Fresnel optical lighthouse lens. A cylindrical cast metal pillar and cabinet painted green with 3 glass doors enclosing the top section. Inside the pillar/cabinet is a large clockwork mechanism used to turn and regulate a lighthouse light by means of weights and a chain attached to same. One door has the name "Adams Mare" in metallic dots similar to "Braille" to the inside edge of door frame.shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, flagstaff hill, maritime-museum, shipwreck-coast, warrnambool, flagstaff-hill-maritime-village, revolving dioptric mechanism, dioptric mechanism for lighthouse, lighthouse clockwork timing mechanism, acetylene lighthouse light mechanism, 19th century lighthouse mechanism, kerosene light, fresnel lenses, colza oil, chance brothers

An optical table is a piece of equipment used for optics experiments and engineering. The Optical Bench is a less sophisticated piece of equipment used for simple experiments. Components such as light sources and lenses can be bolted down and easily shifted along the length of the rail.A solid wood board. A steel ruler scale on top, 0-30mm, mounted along one edge. Fixed along the opposite edge is a 10mm diam. steel bar, 41cm long.W.G. Pye & Co. Eng. Cambridge.physics, scientific instrument, optics, engineering, light sources, lenses, optical table

Probably used at the Ballarat School of Mines as a teaching aid to demonstrate surface wave propagation in liquids.A hollow cast iron base contains electrical components which provide upward illumination of variable frequency. Cover is shaped lile a soup plate, with a 6.5cm diameter lens in the centre. An overhead lens transmits light to an adjustable mirror for viewing from the side. Complet with 240 volt AC lead and plug.scientific instrument