The Ballarat School of Mines is a predecessor institution of Federation University Ausgtralia.Five copies of the Ballarat School of Mines Students' Magazine bound in a blue hard cover and quart bound in calf. 1902 - Retirement of Herbert L. Krause 1905 - Mt Lyall Ore Deposits Images: Ballarat School of Mines Sports Association Committee and Officers, 1905 Standing left to right: W. Pearce, T. Williams, S. Hepburn, Seward, W. Figgis, J.R. Reid, P. Elliott Sitting left to right: P.A. Pratt, N. Buley, John Sutherland, H.R Murphy, J. Inglis, R. Nevett 1906 Excursion to Broken Hill, The Artistic Printing Process, Hints on Portraiture, Arizona, Cornish Mining Images Ballarat School of Mines and AusImm at the Central Mine, Broken Hill; At Iron Knob, Brown Boveri Turbo Generator at Block 10, Junction Mine plant or Potter Process, Broken Hill Propriety Mill, Carlyon's Hotel, Sam Jamieson, Electrical Labortory, Ballarat School of Mines Rowing Eight, Sports Committee,ballarat school of mines, magazines, sports committee, thomas williams, mount lyell, w. pearce, t. williams, s. hepburn, seward, w. figgis, j.r. reid, p. elliott, p.a. pratt, n. buley, john sutherland, h.r murphy, j. inglis, r. nevett, herbert l. krause, broken hill, artistic printing process, hints on portraiture, arizona, cornish mining, ausimm at the central mine, broken hill, iron knob, brown boveri turbo generator at block 10, junction mine plant or potter process, broken hill propriety mill, carlyon's hotel, sam jamieson, electrical labortory, ballarat school of mines rowing eight, sports committee,, rowing on lake wendouree, boat shed, h. valentine, l. seward, c. macgennis, d. don, m. gaunt, h. owne, l. nott, s. leathes, j.a. reid, h.r. murphy, alfred mica smith, r. hosking, zeehan, moonta, wallaroo, smelting silver, south africa, south australia excursion, sunnyside woollen mills, tasmanian excursion, swedish iron, mt jukes excurson, western australian gold ore, wynne-grant furnace, bhp sintering slimes, leggo furnace, mine ventilation, mount morgan mine, mount pani ltd, new zealand coal, adelaide school of mines, students' association, at iron knob, ausimm, excursions, visits, south australian excursion

Document on foolscap paper some notes on Dudley House Bendigo Victoria, Australia courtesy of Mr Geoffrey, C. Ingleton father was the former Town Clerk of Bendigo, appointed 1 January 1924. The layout of the building at ground floor level involved the removal of walls along the left side from the entrance creating one large room. Alterations required replacement of doors, 1920's style , with decorative glass panels and door knobs of the period. This report contains excellent descriptions of furniture installed at the house, including a grandfather clock, framed etchings, easy chairs with loose floral covers, and a number of 'occasional chairs' of Rose-wood or Cedar in Edwardian design. The furniture was purchased from Morley Johnson of Bendigo and Sydney. There were also china cabinets, a gramophone in a large upright rose-wood cabriole-shaped cabinet. The name Dudley house may have been earned by reputation, or had a connection to a former tenant - perhaps a State Official or a caretaker.bendigo, history, dudley house

This tester was used between 1950 and 1980's. As part of the Occupation, Health and Safety requirements, equipment used to monitor the performance of electricity producing generators, regularly, hand held testers were used to check the insulation and the "earth" pin were up the the required operational levels. As the generators and their ancillary monitoring equipment was spread over a large area and cumbersome to service small hand held devices were required. These had to always be safe for the user to operate. A selected range of high quality meters were recalibrated every two years in the Meter and Calibration Laboratory at Yarraville(near Melbourne) This meter is very significant to The Kiewa Hydro Electricity Scheme because it was an integral part of maintaining the electricity producing water driven generators of the power stations. The reason why this meter was so essential is that provided the safety check on equipment used to monitor each Hydro Generator that they were complying within the grid network parameters. Grid parameters are set so that if there is an electrical fault on the system, that fault can be attended to with a very small change in the output stability of each generator. It is essential that the voltage of the network remain within the set limits. Generators are at Dartmouth, Mackay, Clover, West Kiewa, Yarrawonga, Cain Curran and three Power Stations in the Thornton area.This hand driven current generator produces 500 volts by winding the handle(on funnel curved side) to keep the voltage constant(one minute per test). The whole body is made from caste aluminium. One of the functions of this meter is to test the isolation resistance of any equipment being tested. This is to see if that equipment is safe to handle(no electrical shocks). The second function is to test the earth pin of any portable electrical equipment. The turn key on one side can direct which function is required(marked insulation or continuity). On the top side(enclosed in a glass fronted marked scale) is a continuity scale(top) and an insulation scale(bottom). This is covered , when not in use by "flip up" lid with manufacturer's details and name of the instrument. Opposite the winder are two screw tight knobs. One marked earth(left side) and one marked line(right side). On the top and next to the glass windowed scales in a post manufacture SEC Vic equipment equipment ID number. For carrying purposes there is chromed steel (fold together) handle.The bottom of the unit has two metal "feet" 150mm long by 114mm wideManufacturer's details on top side "MEG" underneath "INSULATION AND CONTINUITY TESTER" below this "constant 500 VOLT pressure" below this "REGISTERED MEG MEGGER TRADE MARK" below this "REG DESIGN NO. 690326" below this "UNITED KINGDOM PATENT Nos. 193746, 197178, 198182, 202062, 202398, 204649, 350715" below this "SUPPLIED BY THE GENERAL ELECTRIC Co. Ltd OF ENGLAND" below this "MAGNET HOUSE, KINGSWAY LONDON W.C.2" 'sec vic kiewa hydro scheme, alternate energy supplies, alpine feasibility studies temperature, rainfall

The late 19th to early 20th century stone cottage with weatherboard extensions. From research, it has been determined that the cottage was the Port Fairy (Belfast) Lighthouse Keepers cottage. The dome roof in the background indicates a lighthouse, in which case the cottage would have been the living quarters for a lighthouse keeper and assistant keeper. The narrow poles could have been for signals and antennae. The object on the rock stack looks like a large metal milk can.The photograph shows a typical late 19th to early 20th century cottage, abandoned at dilapidated for many years. Black and white rectangular photograph mounted on card. The image shows a dilapidated stone cottage with an old picket fence. Extending behind the stone cottage are gabled roofs above weatherboard walls. The cottage has corrugated roof sheets of different colours, and four chimneys, three with chimney pots. From research, it has been determined that the cottage was the Port Fairy (Belfast) Lighthouse Keepers cottage. Near the fenceline on the left, a corrugated water tank is positioned below a pipe joined to the roof gutter. Nearby are a timber shed and timber walls or screens. In the background are two tall narrow poles with spheres on top, higher than the cottage, with one pole on each side, the left one attached to the building. A domed roof with a knob on top is on the right behind trees. Several angular shapes appear on the horizon on the left, one almost hidden by the trees. The foreground is rocky and slopes uphill on the right. At the foot of the slope is a stack of closely fitted rocks with an object shaped like a milk can on top and an object to its left that is like an open grid. Handwritten Inscriptions are on the reverse side of the photograph.Pencil on board: " D9 / 200 x 150" Pen on sticker: "52"flagstaff hill maritime museum and village, warrnambool, great ocean road, shipwreck coast, cottage, lighthouse, iron roof, stone building, picket fence, water tank, weatherboard building, 19th century cottage, early 20th century cottage, abandoned cottage, antenna, chimneys, milk can

Alan Doney darkroom collection: 40a dartk room equipment collection 40b four film devreloping cannisters, adapts to adjustable film sizes (35mm, 120mm etc) 40c spool winder in two parts, stored in scotch tape tin 40d developer lens holder and fil/negative constraint for enlarging photos 40e darkroom light shade with electricity chord 40f red darkroom safety light for developing film with the darkroom 40g three developing items - two lens caps, thremometer caps/containers, & photo developing tongs 40h leather pouch for protection of flat ground glass panes 40i steel slide cover & bracket 40j two sets of steel film weights to hold/hang developed photograph films 40k rubber tubes and syphons 40l two plastic measuring beakers & two (yellow & blue) plastic spoons for developing process 40m KODAK film flow solution (Keogh's Camera Store $1.02) & KODAK plus-X pan film tin container 40n three darkroom miscellaneous items (includes Uniprint eqipment knob)

The cabinet has a curved back and would have been custom‐built to fit the dimensions of the lantern room interior. It is likely to date from when the lighthouse was built in 1884 and may have been among the items delivered by the government steamer dispatch early in March which included ‘the lantern and other fittings for the Cape Nelson Lighthouse’. The Public Works Department provided a range of lightstation furnishings including office desks and cabinets, and domestic settings for keepers’ quarters, with nineteenth century items often stamped with a crown motif and the PWD monogram however the curved cupboards installed in Victoria’s lighthouse lantern rooms do not appear to display this small feature. Further research may reveal more about their manufacture and it is tempting to think that they were perhaps even supplied by Chance Bros as part of the entire lantern room installation. The company usually provided the timber battens for the lantern room paneling, and a cabinet may have been included in the assemblage. Another possibility is that the specially designed cabinet was made on site by carpenters along with other fittings. It is not known whether it is attached to the wall or movable; if attached it is considered to be a fixture and included in the Victorian Heritage Register listing for the lightstation (VHR H1773). Its location, when identified in the CMP of April 1995, was on the ‘lower lantern level’, where there was also a ‘timber step ladder’ (Argus, 6 March 1884, p6. nineteenth or early twentieth century), ‘timber framed lighthouse specification’, ‘timber framed chart’ and telephone .Residue on the furnishing indicates that it was formerly painted green, the colour of some of the other fixtures in the room, such as the original cast iron ladder. It is now partially varnished and the corner to the top’s edging on the right side has been cut off. The lighthouse also has a large curved back, two‐door cupboard. Other similar cabinets with curved backs survive at Cape Schanck, varnished wood cabinet with brass door knob, no drawers; Point Hicks, painted green with silver doors, no drawers and Gabo Island, bench top, 2‐door, no drawers, green paint removed to reveal cedar timber). Cape Nelson’s curved cabinet is unique among these examples for having drawers. The cabinet is a unique, original feature of the lantern room and has first level contributory significance for its historic values and provenance.The bench top cupboard has two drawers, each above a door, and each door is framed and beveled around a central panel. The cabinet has a curved back.

After years of precursory surveying, debate and proposals the most ambitious civil engineering project of the day, the Overland Telegraph Line, began construction in September 1870. Superintendent of Telegraphs, Sir Charles Todd led the construction through “terra incognita,” guided by the precursory surveys of John McDowall Stuart and technologies such as his prismatic surveying compass. The unknown and hostile landscape claimed the lives of several men and scores of transport animals in the dogged pursuit of telegraphic connection to the rest of the world. Completed in August 1872, the Line connected Australia to the world via telegraph wires running 3,200 kilometres from Port Augusta in South Australia, to Darwin, then connecting via submarine cable to Java and beyond. The “earth [had been] girdled with a magic chain” according to the then Governor of New South Wales, Sir Hercules Robinson. How does it work? For use in surveying, the sight vane and prism are turned up on their hinge and the instrument is held horizontally either in the palm of one's hand or on a tripod. Two small discs of red and green glass attached to the prism can be flipped down over the sight line to reduce glare. The objective is to bring the subject into the sightline created by the prism, aligning with the thread of the sight-vane until the subject is bisected evenly. Once aligned, the division on the card may be read through the prism. This reading provides the magnetic azimuth, used for calculating the bearings of distant landmarks. Circular instrument mounted in a brass case with glass window and brass lid. The compass card face four black compass points printed on mint green paper; on the underside the magnetic needle would be affixed, all held in place by a brass knob at the centre. The arched labels of "Sawtell" and "Adelaide" and the Prince of Wales feathers appear to have been affixed with adhesive which has since yellowed in the areas of application on the compass card. The compass face is printed with numbers, every 10 degrees from 10 - 360, printed in reverse indicating this compass would have once held a mirror at the sighting bracket. On one side of the brass case is a brass hinged sighting-prism, possibly of ebonite. The sighting-prism is mounted in a hinged brass bracket on one edge of the brass case. It has two flip-type filter glasses (red and green) and folds down into a retracted travelling position. A hinged brass bracket on the opposite edge would have held the sighting bracket - carrying the sighting vane and mirror - which is now missing or removed. Under the hinge is a lever, possibly related to the movement of the bracket. Underneath the brass case is an indented circle with screw threads, possibly for attachment to a tripod, and indistinguishable marks scratched into the surface.Etched on to the centre of the lid, "Sawtell ADELAIDE / No 792." Affixed to the paper compass face, possibly from separate pieces of paper, "SAWTELL / ADELAIDE" with the Prince of Wales Feathers above "SAWTELL". Underneath on remains of white tape in red: "159."surveying, compass, charles todd, overland telegraph line, telegraph

Phenyle has been used for decades as a cleaner and disinfectant. It is well know for its use for cleaning outdoor toilets and easily identified by its strong odour. The brown glass bottle is immediately recognised as containing a poison. We've all seen them in a hundred different mystery movie scenes. The medicine cabinet opens and there, sitting on a shelf, is the incriminating object -- the ominous dark bottle with the skull and crossbones on the label. In off-screen reality, however, poison bottles have quite a different identity -- they are distinctive, varied, colorful -- and definitely collectible. Obviously, the one thing that sets the poison bottle apart from all other bottles is the need for prominent and immediate identification as a receptacle for toxic material, and this was achieved in a number of ways, including shape, color, embossing and labeling. Poisons were commonly found in the home for the purpose of controlling rodents and other pests, and were sold by grocers and druggists. For consumer protection, as far back as 1829, New York State made mandatory the marking of the bottles with the word "poison" in large letters. Then, in the middle of the 19th century, the American Pharmaceutical Association recommended legislation regarding identification of all poison bottles. In 1872 the American Medical Association also made recommendations -- namely that poison bottles be made of colored glass, and also have a rough surface on one side -- making them identifiable even in the dark -- and the word "poison" visible on the other (the skull and crossbones wasn't quite as ubiquitous as those movies led us to believe). However, passing these laws was not easy, and the manufacturers were essentially left to do as they wished. For collectors, the high point of poison bottle manufacturing was the period ranging roughly from the 1870s to the 1930s. At that time some, of the bottles were distinguished by particularly bright colors, such as cobalt blue (the most common) and emerald green. Others, particularly rare and collectible, had unusual -- and appropriate -- shapes, including skulls, leg bones and coffins. In order to better identify these lethal vessels by feel (not forgetting that there were many people in this period who could not read) when groping for them in the dark, they had such elaborate tactile patterns as quilted diamonds, lattices, hobnails and prominent vertical or horizontal ribbing, as well as spiky knobs and ridges. In addition, many had sharp points on top for the same precautionary purpose. Further efforts to distinguish poison bottles from others included uncommon multisided and triangular shapes, and unusual, hard-to-open tops, the predecessors of the modern child-proof openings. https://www.southcoasttoday.com/story/lifestyle/2001/08/19/poison-bottles-steeped-in-history/50352280007/The recognition and awareness of bottles containing poisonpous substances is extremely important for safety reasons.Bottle, brown glass, diamond shaped. "Bright Star" phenyle. Paper label attached, but peeling off and badly damaged. Corked with contents. Text moulded into glass, some with a border of stars. Poisonous contents, not to be taken. Registered Number 2140. Volume is 20 fluid ounces. Printed label "Bright Star". Text is moulded in the glass in raised lettering: "PHENYLE" outlined and decorated with star border. "POISONOUS", "NOT TO BE TAKEN" "V / DM / A" within oval, "REGD NO. 2140" (D and O are smaller and underlined) . Base is marked "F190".flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, bright star, phenyl, cleaning and disinfecting chemical, poison, bottles

It is no secret that copper is currently experiencing a huge upsurge in popularity. This is mainly thanks to its beautiful colour featuring heavily in the ranges of countless homeware retailers. There is, however, far more to this lustrous metal than just its appearance. For example, it has a greater level of thermal conductivity than any other metal (except silver); roughly 60% higher than aluminium and 3000% higher than stainless steel. This means copper is capable of heating up very quickly when compared to other metals. Perhaps a less commonly known property of copper is it being inherently antimicrobial. A wide range of harmful microbes are unable to survive for more than a couple of hours when in contact with a surface made of copper or one of its alloys (brass and bronze). This has led to it often being used for frequently touched surfaces such as door knobs, push plates and taps. A seemingly perfect material for cooking, it is therefore no surprise that it has been used in kitchens for millennia. But exactly when did we learn to utilise copper and its valuable assets? Origins It is hard to pin down an exact date when copper cookware was first introduced. Pieces discovered in regions of the middle east were dated as far back as 9000BC, suggesting cooking with copper began during the Neolithic period (≈10000-2000BC). As civilisations became increasingly capable in metallurgical techniques, metals such as copper became more widely used. It would have been around this time that copper replaced stone as the material used for making tools and cooking vessels. The use of copper is also well documented in Ancient Egypt. Not only was it used to produce water and oil containers, but it was also used to in medical practices. The antimicrobial nature of copper was exploited long before the concept of microorganisms was fully understood. The Smith Papyrus, a medical text written between 2600 and 2200BC records the use of copper in sterilising wounds and drinking water. Tin Lining Although copper is essential to many processes within the human body, it can become toxic if consumed in excess. It was this knowledge that gave rise to lining cookware with tin, a technique used for hundreds of years to prevent copper leaching in to food. These tin linings would eventually wear out and during the 18th and 19th century, it was common for people to send pans away to be re-tinned. This practice is becoming increasingly rare, as are the craftsmen who perform it. Despite this, there are still manufactures producing tin-lined copper cookware who also offer a re-lining service. Perhaps the best known of these is Mauviel, a French manufacturer who have been making this type of cookware since 1830. Tin has now largely been replaced by stainless steel as an interior cooking surface. Not only is it more cost effective, but the high grade of stainless steel used in premium cookware (typically 18/10) is highly resistant to corrosion and more durable than tin.Copper saucepans are still used in many kitchens.Small copper saucepan with long handle and three ridges around the circumference. Extensive corrosion.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, copper, saucepans, kitchen equipment

This chest is the typical mid-18th century model. Thought to have belonged to captain James Volum.A medicine chest was a necessity for all sea journeys. Sometimes surgeons were onboard ships if there were passengers but on merchant ships, the captain had to be able able to look after his crew. A medium size mahogany cabinet with four protruding feet, small free hinged handles on left and right sides which are positioned approximately 5/8ths up from the bottom of the item, these handles can hinge 100 degrees upwards. The front and back 6/8ths of the cabinet can hinge open, as can the top of. Both front and back doors can be locked closed with their own respective hook latch which is on both sides of the cabinet. The top lid can be locked by interacting with a metallic keyhole which is present on the front of the cabinet close to the top. Revealed by opening the top lit is storage location with two rows of three storage spaces and one row of four. Revealed by opening the front door, is a single shelf with six divided locations for an equal number of glass containers, though only five remain in complete form. Below this self are three rows of drawers of differing dimensions, each with a small white knob. There are two drawers of equal width in the first row. Each drawer has four equally divided sliding pieces on its top face. When removed, these lids reveal a respective small space. Present on small paper labels on each of these lids are identifiers of the material which was stored. There are three equally sized drawers in the second row, which are less wide than the previous row. Only two of the drawers in this row have lids, of which each only have a single lid which covers a single compartment, each of these have a single label on them. The middle drawer contains a small glass mortar and pestle which are restrained by small wooden fixtures within the drawer. There are two drawers of equal width and greater height than any of the previous drawers in the third row. The first drawer has a single compartment containing multiple vials of varying dimensions, some of which feature a paper label with a respective inscription. Some of these vials are broken. In the second drawer has no lid which covers its four equally sized glasses. These are restricted by a wooded piece with four circular cut-outs. Revealed by opening the back door are two equally sized and spaced shelves which both have four divided locations which are filled by eight respective glass containers. These glass containers are of similar design to those in the front compartment but are larger. Some of these glass jars have paper labels like those found on previous glass containers.Label on top lid:volum collection, medecine chest, portable furniture, geelong, peterhead, scotland, captain, seafaring, whaling, london, bishopsgate, old gravel lane, london docks, tobacco dock, james burrows

The design of this and other similar treadle powered dental engine (or dentist drill) was in common use by dentists from the 1870’s into the 1920's. When electricity became accessible to most communities the electrically powered dental engines began to take over from the treadle power. Over the ages teeth were extracted using picks and scissors and other gouging instruments. Bow drills, hand drills and even a "bur thimble" drill were later used to prepare cavities for filling. Some drills were made bendable by attaching flexible shanks between the metal bur and the handle, giving access to the teeth at the back of the mouth. Other mechanical devices were introduced along the way, such as clockwork drills, but they were hard to handle and inefficient. Over the centuries “dentistry has been performed by priests, monks and other healers. This was followed by barbers; the barber’s chair may well have been the precursor to the dental chair. “(SA Medical Heritage Society Inc.) In 1871 James Morrison patented the first commercially manufactured 'foot treadle dental engine', the first practica dental engine although others had been introduced as early as 1790 (by John Greenwood). Handmade steel burs or drills were introduced for dental handpieces, taking advantage of the significant increase in the speed of the drill. In 1891 the first machine-made steel burs were in use. The treadle drill reduced the time to prepare a cavity from hours to less than ten minutes. In 1876 the Samuel S. White Catalogue of Dentist Instruments listed a 12 ½ inch wheel diameter dental engine, with 14 bright steel parts, for sale at US $55 In today’s market, this is the equivalent to US $1200 approx. The specifications of that dental engine are very similar to the this one in our Flagstaff Hill Maritime Village’s collection. It is interesting to note that workings of a similar treadle dentist drill were used and modified to power a treadle spinning wheel of one of the volunteer spinners at Flagstaff Hill Maritime Village. The foot treadle dental engine was a milestone in dental history. “Historic importance of treadle powered machines; they made use of human power in an optimal way” (Lowtech Magazine “Short history of early pedal powered machines”) The invention of a machine to speed up the process of excavation of a tooth lead to the invention of new burs and drills for the handpieces, improving speed and the surgical process of dentistry. They were the fore-runner of today’s electrically powered dental engines. This treadle-powered dentist drill, or dentist engine, is made of iron and steel and provides power for a mechanical dental hand-piece that would be fitted with a dental tool. The drill has a three footed cast iron base, one foot being longer than the other two. A vertical C shaped frame is joined into the centre of the base, holding an axle that has a driving-wheel (or flywheel) and connecting to a crank. A slender, shoulder height post, made from telescoping pipes, joins into the top of this frame and is height adjusted by a hand tightened screw with a round knob. On the post just above the frame is a short metal, horizontal bar (to hold the hand-piece when it is not in use). A narrow tubular arm is attached to the top of the stand at a right angle and can move up and down. At the end of the arm is a firmly fixed, flexible rubber hose protected for a short distance by a sheath of thin metal. At the end of the hose there is a fitting where the drill’s hand-piece would be attached; a small, silver coloured alligator clip is also at the end. A treadle, or foot pedal, is hinged to the heel to the long foot of the base, and joined at the toe to the crank that turns the driving-wheel. There is a spring under the toe of the treadle. The metal driving-wheel has a wide rim. Touching the inside of the rim are four tubular rings that bulge towards the outside of the driving-wheel, away from the pole, and all meet at the hub of the axle. The axle is bulbous between the inside of the driving-wheel and the frame then passes through the frame and is attached on the other side. The driving-wheel has a groove around which a belt would sit. The belt would also fit around a pulley on the arm, at the top of the post. The pulley is joined to a rod inside the arm and this spins the drill's hand-piece and dental tool holder. The two shorter feet of the base are made from a long metal bar that has been curved outwards, and its centre is bolted to the base of the pole. Under the ends of the curved legs of the base are wedge shaped feet. The driving-wheel is decorated in light coloured paint on both sides, each side having three sets of floral decals evenly spaced around them, and each about a sixth of the wheel's circumference. Similar decoration is along the sides of the frame. The foot pedal has decorative cutout patterns in the centre of the foot and at the toe. On the long foot of the stand is some lettering with a fine, light coloured border around it. The lettering is hard to read, being a dark colour and flaking off. There are also remnants of fine, light coloured flourishes. The foot pedal has lettering of the maker’s trade mark cast into the metal at the ball of the foot. Lettering on the base is peeling and difficult to read. The foot pedal has a trade mark cast into it that looks like a combination of ‘C’ , ‘S’ , ‘A’, ‘R’. flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, dentist, teeth, dental drill, dental engine, treadle drill, foot powered drill, treadle engine, orthodontics, dental surgery, james morrison

Information from Norman F. Dalton: Ballarat had a reticulated DC supply in the early part of last century and in 1905 had sufficient generating capacity to enable the trams to be changed from horse drawn to DC electricity. The use of electricity increased with the main power station located on Wendouree Parade, near Webster Street, under the ownership of The Electric Supply Company of Victoria. AC generating plant was installed in 1925 and conversion to AC proceeded. In 1934 the company was taken over by the State Electricity Commission Victoria (SECV) and more AC generation was installed and the changeover of customers was accelerated. This is around the time that the Synchronome Frequency Checking Mast Clock was installed at the Wendouree Parade Power Station. The SECV Annual Report of 1921 states: ::Section 11 of the act directed the COmmission to enquire into the question of securing the adoption of such standards of plant and equipment of a system, frequency and pressure for the generation and distribution of electricity as will admit of the efficient interconnection of undertakings throughout the State. In 1934 when the SECV took over the Ballarat operations the question of linking with the State grid had been a planned operation for some years but due to financial considerations had hindered it and in fact would continue to do so for a further 10 years. So while the need for close frequency control for interconnection was hardly an issue, the need to keep electric clocks correct was important, particularly as this item was a frequent sales point to cover the inconvenience and sometimes expense of converting from DC to AC. The clock is a very accurate pendulum clock with provision for varying effective length during operation for precise time regulation. There are two normal time dials and one is controlled by the pendulum and the other is operated by the system frequency. When the clock was in use it was installed by the MEter and Tests Laboratory and the time was checked daily by radio time signals. The two dials were repeated in the operators control panel in the Power Station. A maximum deviation between the two dials was set in the operating instructions (eg 5 seconds) and the operator would correct this when necessary by remote manual alteration of the turbine governor set point. The clock was used to drive and regulate a system of "slave" clocks which were used to display the time in various locations around the power station. A slave clock is a simple clock which is driven by a small electric motor, its accuracy is regulated by the master clock every 30 seconds to ensure that it and all the other slave clocks in the station are on exactly the right time; slave clocks were placed in various locations, from common rooms to workshops. A master clock could potentially run thousands of slave clocks at one plant. The clock also contains a rectifier. A rectifier is a device that is used to convert AC power to more stable DC current.Two clocks in a timber case. Both are electric, one is powered by the main pendulum mechanism, the other is a self contained electric clock. The main mechanism is of the gravity arm and roller type, which sends an impulse to the slave clocks every 30 seconds. The This Synchronome Frequency Checking Master Clock was used at the Ballarat Power Station. Below the main section of the case is a smaller cabinet containing a rectifier to provide consistent DC power for the clock. The rectifier was made by the Victorian company Hilco, which was located in Burwood. There is a high chance this is not the original rectifier from this clock as there appears to be brackets to hold a larger device in the space the rectifier occupies.Front below main clock face on front of case: "Patented Sychronome Brisbane" Lower left-hand clock face: "Frequency time" Lower right-hand clock face: "Standard Seconds" Synchronous electric clock mechanism on door (Frequency time clock): >200/250 V. 50~ >"Synchronomains" Made in England >Direction indicator for clock starting switch >"To start move lever in direction of arrow and release" >"Patent applied for" Mechanism for "standard seconds" clock: >"English Made" >"Patented" >Serial number "321" >0 above right-hand pillar on front-plate Mechanism for "standard seconds" clock: >"English Made" >"Patented" >Serial number "321" >0 above right-hand pillar on front-plate Mechanism for main clock face: >"English Made" >"Patented" >Serial number "8751" >0 above right-hand pillar on front-plate Inside case, back panel, top enamel plate: >Seconds Battery + Pos. > Battery Common or - Neg. >1/2 min dials Inside case, back panel, bottom enamel plate: external seconds dial Inside case, right hand side, electrical knobs: two switches, both "A.C. mains" Pendulum rod, below suspension spring: Serial number (?) 0000005 Rectifier in bottom cabinet: >"Hilco Rectifier" >"A.C. Volts 230/240" >"Model 1060/S" >"A.C. Amperes" >"Serial No. 1060/S >"Phases 1" >"D.C. Volts 6" >"C.P.S. 50" >"D.C. Amperes 1" >"Made in Australia by Hilco Transformers McIntyre St., Burwood, Victoria." Bakelite electrical plug: makers mark Lower cabinet, RH side panel, pressed tin plate: "AC" (upside down) Brass speed adjustment, outer right RH side: "S" and "F" Ivory and wood pendulum beat ruler: >Ruler, with 0 in centre and numbers 1-5 in ascending order from centre on left and right. > "Synchronome Patent." Steel plate, back panel, inside case, right hand side: >N R A" (descending) >"2191" serial number/part number Face of main clock: "Synchronome Electric" synchronome frequency checking master clock, electricity, state electricity commission, wendouree parade power station, secv, clock, time, pendulum, electric supply company of victoria, norman f. dalton, ballarat power station, rectifier, slave clock

The early settlers of Victoria depended on horse drawn vehicles to farm, make roads and railways, deliver produce and transport people. Horse harnesses were an important requisite for all drivers and could be found wherever there were working horses. Horse Harnesses have played an essential role in different cultures throughout history. Simple, utilitarian horse harnesses made of leather straps and iron rings were being used in early China before AD 500 as well as ancient Greece and Rome, allowing horses to pull chariots and ploughs. The Greeks and Romans were the first to use a "horse collar" which distributed the weight of the harness evenly across the horse's chest rather than relying on a "throat harness" that could damage a horse's throat or choke them. During the medieval period, European horse harnesses became more elaborate and decorative. Variations of different horse harnesses were also found in Native American and Middle Eastern cultures. Horse Harnesses usually have four basic components which include - 1. Communication - the bridle, bit and reins allows the driver to communicate instructions and commands to the horse, guiding its movement and direction. 2. Draft - the collar, hame straps, hames, traces and chains enables the horse to draw and pull the load efficiently by distributing the weight and transferring the pulling force to the vehicle. 3. Stopping - the breeching band, pole straps and breast strap helps to control or stabilise the horse and vehicle when moving downhill or stopping. 4. Support - the back pad, backband, belly band and back saddle keep the harness in the correct position and proper alignment. This show harness was used by Mr. Andy Bourke when showing his Clydesdales at shows or demonstrations. Although a more modern example with decorative embellishments, it still has many essential components traditionally found in an everyday working horse harness. The original purpose of the "housen" for example, was to run rain or drizzle off the horse's neck when they had to work in wet conditions - it was laid flat for this purpose on the top of the collar. Nowadays it is purely for show and is often used to advertise a business or stud. Horse brasses and fly terrets were fastened to various parts of a horse's harness. In the early days they probably began as amulets to ward off evil and to bring good luck and continued to be used as a festive decoration. The heyday of horse brasses was between the years 1851 and 1900. Horse brasses are fastened to various parts of the harness with many of their designs being symbolic. The ornamentation on this harness (although not authentic horse brasses) are based on the horse brasses that were popular in the 19th century. This horse harness is a significant example of the equipment that was needed wherever heavy horses were being used - particularly in the early years of Victoria's settlement by white settlers. Harnesses such as this example were used with stage coaches, drays, farming equipment, delivery carts and personal transportation.A leather and metal horse harness used when showing a Clydesdale (or other breed of heavy horse). It is made up of a number of components. 1. Decorative leather cart saddle with two large cloth pads underneath (which have a scalloped leather and stud border), a raised leather pommel and a silver and red coloured metal back strap holder across the top. It has two symmetrical sets of ornamentation (silver hearts and circles) in the front and a wide strap or girth (with a maker's stamp reading "R. Mitchell Saddler") and buckle which attaches the saddle to the horse. 2. Pair of steel hames which are gently curved (to fit on a horse collar) and are topped with steel knobs. They have several steel rings and lugs (to hold straps and chains) and a "Made in England Warranted Steel" stamp. 3. Breeching harness which consists of a number of leather straps, chains and metal rings including a wide padded leather strap with a scalloped edge that sits on the back of the horse and a thick leather strap that goes around the hind quarters of a horse which is joined to the back strap with four shorter vertical straps and buckles. These straps feature silver and red patent leather trim and silver heart shaped ornamentation. The strap also features the maker's stamp of "R. Mitchell". 4. Decorative leather bridle with blinkers featuring the same silver and red patent leather trim on the cheek piece, brow band and throatlatch. It has a stainless steel "Liverpool Driving Bit" with a curb chain, a variety of decorative silver ornaments (rosettes, diamonds plus a heart and two circles) on each end of the forehead band, dropper and strap as well as a silver metal bell (sometimes known as a "fly terret" or "swinger") that sits on the headpiece of the bridle. 5. Leather "violin shaped" dropper (or hanger) with two silver rosette shaped ornaments and a stainless steel clip on the top 6. Stainless steel "Liverpool Driving Bit" with a straight mouthpiece which is ribbed on one side. It has three rein spots (spaces) and a curb chain. 7. Leather arch shaped "Housen" covered in black and red patent leather and decorated with silver studs (some spelling out F H) and bordered with a red fringe. It has a leather strap at the back and two leather loops on the front. 8. Leather padded backband (Australian style "Stallion Draught Roller") decorated with two groups of nine metal "horse brasses" or harness ornaments displaying horseshoe, starburst and horse head designs on blue, red and white striped webbing. The backband has three notched straps at each end, a buckle near the centre and the initial B stamped in two places underneath. 9. Bellyband made of leather and red, white and blue striped webbing. It has a set of three buckles at each end (which correspond with the notched straps of the backband). 10. Wide, thick leather strap which has a buckle and notches at each end. It also has the maker's stamp of "R. Mitchell Saddler". 11.One pair of long leather traces - each with a buckle and notched loop at one end, decorated with a small silver diamond shaped harness ornament. 12. Length of stainless steel heavy duty chain with two swivel connectors.Saddle - "R.MITCHELL / SADDLER" Hames - "MADE IN ENGLAND / WARRANTED / STEEL" "MADE IN ENGLAND / WARRANTED / unclear" Breeching Straps - "R. MITCHELL / MAKER / R. MITCHELL MAKER" Housen - "F H" Backband "B / B' Wide leather strap - "R. MITCHELL / SADDLER"flagstaff hill maritime museum and village, warrnambool, great ocean road, shipwreck coast, harness, horse harness, show harness, clydesdale horses, andy bourke, horse drawn cart, housen, bridle, hames, breeching straps, dropper, bit, liverpool bit, backband, harness ornamentation, bellyband, back saddle, fly terret

Manufactured in the 1960s, this mobile emergency telephone exchange was fitted into a caravan. Part of the Shepparton Division State Disaster Plan, the caravan could be towed to areas affected by disasters to enable communications to recommence. The caravan remained in service until approximately 1974.Mobile infrastructure plays an important role in Australian communications, owing to the often remote and hostile environments in which Australians live and work. Exchanges such as this facilitated phone calls in the aftermath of an emergency, particularly for hospitals, police and other emergency services. Today, Mobile Exchange on Wheels (MEOWs), Cell on Wheels (CoW) and Satellite Cell on Wheels (SatCOW) - which provide temporary landline and broadband services, mobile phone coverage and service in areas without communications infrastructure respectively - are a critical part of emergency response procedures for natural disasters such as fire and flood. Though technology has progressed, the need for rapid service in remote areas remains a present concern of the communications service providers in Australia. This mobile service infrastructure is historically significant as an early example of a service which has evolved over decades, yet is still needed today. The exchange, as a representative example of a vehicle which would provide early-response in a disaster, is socially significant as a facilitator of critical communications needs in devastated communities: access to emergency services and contact with family and friends. The exchange itself, intact from its period of use, provides an insight into technology of the 1970s.Mobile emergency exchange housed in a caravan trailer on 2 wheel base, duralin body, steel tow bar, Caravan divided into 3 sections; the exchange room; the relay room and the main frame room. The exchange room contains 3 switchboards, a folding table, cupboards, benches and switch rack (.1). table (.2), steel bar for attaching the table (.3), back boards of switchboards (.4-.6), switches (.7-.16), box of switches (.17). There is a wall phone magneto, 300 type handset on wall and 2 skylights with wire screens. .11? hat pegs and shelf; there are 2 fluorescent tubes for lighting, all in exchange section. The floor is covered with 2 tone grey tiles and there are wire mesh on outside of windows and a geometric curtain inside behind switch rack. There is a flywire screen door as well as exterior door. The relay room has a sectioned door so half can open at a time. Room contains a cupboard with folding bench top beneath a curtained window. The opposite wall has a bank of batteries and transmission condensers; there is a shelf above window, one fluorescent tube and fuse boxes. Tiles on floor also. The main frame room contains many metres of coiled black covered cable, a black covered magneto wall telephone with 300 type handset; grey plastic jumper cords, a rack of termination points and wire with wasp nests attached. There is a small iron step under door, a fluorescent tube on wall and 3 hat hooks. Roll of Paper Handtowels (.18), cord and handle (.19), red exchange cords and plugs (.20-.22), plastic aluminium runners (.23,.24), headset (.25,.26), logbook (.27), battery readings (.28), box containing papers circuit drawings etc (.29-.93), paper lists off wall (.94,.95). Books, record books etc (.96-.103). Manila folder (.104) containing circuit drawings (105-.124). Wooden drawer (.125), metal drawer containing subscribers master cards, record of faults cards, particular switchboards connected, Junction line cards (.126). Box of valves (.127), box of clamps (.128). Box of 2000 type rack fuses, red 1 1/2 AMPS, black 3 AMP, blue 1/2 AMP (.129). Box of sleeves for covering wire joints (.130), plastic beakers (.131,.132), soap (.133), box of white plastic squares (.134), time switch "Venner BF/43 time switch" Made in England (.135), box of bolts, knobs etc (.136), box of switchboard number indicators (.137), fuse (.138), fuse wire (.139), football card (.140). Box of cartridge fuse 6 AMP (.141). Envelope of drawing pins, rubber bands (.142), black plastic, paper tape centres (.143-.152), metal plug (.153), 2 signs "Beware of vehicles" (.154-.155). Paper listing Naringal East automatic conversion (.156). Green Commonwealth of Australia note pad (.157). Wiring plug for tail lights (.158). Black fuse plugs (.159,.160). Box of bolts (.161). 2 sections of blue plastic coated wires (.162,.163). Gloves used for working on batteries (.164-.167). Wasp nests (.168,.169). White fuse (.170). Photographs of van in use (.171,.172)..1 on front: "ANOTHER / MOBILETRAIL / PRODUCT" "MAX SPEED / 25MPH" "TRAILER BRAKES / --- / " On sides: "EMERGENCY TELEPHONE EXCHANGE" "NO 1" "PMG" "TCQ / GROSS 250 / TARE 182 / LOAD 162" "6" "COUNTRY BRANCH / NORTH REGION / [SHEPPARTON DIVISION]" "LAW'S SIGNS" "Telecom Australia" On back: "DANGER / LONG LOAD" "MQA 3787" .133: "FIR OIL" "AUSTRALIA"mobile telephone exchanges, mobile telecommunications trailers, trailers, transport, natural disaster, black saturday, bushfires, floods, emergency communications

Cliff Beauglehole was an orchardist at Portland, Victoria, who throughout hislife took an intense interest in the plants of Victoria. Over his lifetime he collected 90,000 plant specimens as part of a comprehensive study of Victoria's plants and wrote thirteen books under the heading The Distribution and Conservation of Vascular Plants in Victoria, each written to cover the 13 study areas of the Victorian and Conservation Council.A mounted botanical specimen.beauglehole herbarium, herbarium specimen, botany, herbarium, plant science, plant specimen, field naturalists' club ballarat, federation university herbarium, carex inversa, knob sedge, cyperaceae

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

Victoria once had well over one hundred fire lookouts and firetowers. Fire lookouts, or observation posts, were often just a clearing on a hill or a vantage point, whereas firetowers were definite structures. There are at least three categories of firetowers… (1) tree perches, (2) four-legged towers made of either wood or steel, as well as (3) hilltop cabins and observatories. Many were established by the Forests Commission Victoria (FCV) in the 1920s, but the network was expanded rapidly in response to recommendations of the Stretton Royal Commission after the 1939 Black Friday bushfires. The wooden towers were often built by bush craftsmen like legendary FCV overseer Clem Heather from Orbost. But advances in aerial reconnaissance and radio technology led to the gradual reduction in the number of fixed towers. FFMV now operates 72 firetowers. The CFA, Melbourne Water, Hancock Victorian Plantations (HVP) also operate some, the Army has one at Puckapunyal overlooking the live-firing range. Only two remaining fire towers of this design remain in Victoria (Mt Little Dick and Big Tower in the Mullungdung State Forest). Mt Nowa Nowa and Stringers Knob burnt down in the 2019/20 bushfiresLarge model of an Reef Hills fire tower. Presumably used for instructional purposes. Traditional FCV four legged design with three landings and closed cabin.bushfire, forests commission victoria (fcv)