The School of Mines Annual Report, 9 February, 1881, Additional Examination Statute 1880, Balance Sheet, Certificates Granted by Council, Donations and Fees - carriage of, Extracts from Visitors' Book, Fees, Form of Bequest, Honorary Correspondents, Life Governors, Mining and Mineral Contributions Invited - Paper of Particulars, Museum - open to visitors, Office Bearers, Obituary, Report of the Lecturer in Mathematics, Report of the Lecturer in Mining-Land- and Engineering-Surveying, Report of the Lecturer in Mechanical Engineering, Report of the Lecturer in Telegraphy, Report of the Curator of the Museum (with Plans), Report of the Superintendent of Laboratories, Subjects and Lecturers, Subjects and Examiners, Statement of Receipts and Expenditure for the year 1880, Subscriptions and Donations from 1 January to 31 December 1880, The Lal-Lal Iron Ore Deposits - (with Section and Plan)Pale green booklet of 70 pages, Annual Report 1880. Image of Guage Test Tower, Image of The School of Mines, Plan of Ground and Buildings - Albert Street, The School of Mines Ballaarat - The Museum - Plan of Groundfloor, Image of the Lal-Lal Iron Ore Deposits, Moorabool Riverthe school of mines, annual report, additional examination statute 1880, balance sheet, certificates granted by council, donations and fees - carriage of, extracts from visitors' book, fees, form of bequest, honorary correspondents, life governors, mining and mineral contributions invited-paper of particulars, museum open to visitors, office bearers, obituary, report of the lecturer in mathematics, report of the lecturer in mining-land and engineering-surveying, report of the lecturer in mechanical engineering, report of the lecturer in telegraphy, report of the curator of the museum (with plans), report of the superintendent of laboratories, subjects and lecturers, subjects and examiners, statement of receipts and expenditure for the year 1880, subscriptions and donations from 1 january to 31 december 1880, the lal-lal iron ore deposits-(with section and plan), obituary - sir redmond barry - arthur leahy - jacob upfold - john day, mr james oddie, dr. r. f. hudson, john victor, chas. wm. thomas, w. h. shaw, walter d. campbell, ferdinand m. krause, joseph flude, geo. perry, w. hy. barnard, examination statute, his excellency sir wm. f. drummond jervois, charles h. pearson, t. brodribb, professor pepper, james mitchell, robert adam, wm. lant carperter, h. b. de la poer wall, w. h. brokenshire, arthur parker, henry parkinson, c. davies, simon richards, c. v. gorton, c. r. blackett, david jones, wilberforce dyke, ferdinand krause, ballarat school of mines museum, ballarat school of mines museum plan, lal lal ore deposits, moorabool river, william land carpenter, william jervois, william henry tbarnard

The School of Mines Ballaarat. Annual Report 1883. Statement of Receipts and expenditure, general balance sheet, and list of subscriptions donations 1883. Annual Report, Balance Sheet, Certificates granted by the Council, Examination Papers - Elementary Science Classes (Appendix), Fees, Honorary Correspondents. Life Governors, Museum - open to visitors, Office Bearers, Paper of Particulars, Report of the Curator of the Museum and Library, Report of the Superintendent of Laboratories, Report of the Lecturer in Mathematics, Report of the Lecturer in Mechanical Engineering, Report of the Lecturer in Telegraphy, Report of the Lecturer in Materia Medica, Report of the Lecturer of Astronomy, Scale of Charges for Assays and Analyses, Examinations Held, Statement of Receipts and Expenditure for the year 1883, Subjects and Lectures, Subjects and Examiners, Subscriptions and Donations, from 1st January to 31st December 1883.Ballaarat School of Mines annual Report. Soft cover pale green booklet of 67 pages. Includes a colour Geological Map of Lal Lal and a sketch Section from Lal Lal to the Moorabool. Inscription on front cover 'Office Copy' On pages 4 and 5 some names have been crossed out and others added.ballarat school of mines, annual report, balance sheet, certificates granted by the council, examination papers, fees, honorary correspondents, life governors, museum, office bearers, paper of particulars, ballarat school of mines museum, library, superintendent of laboratories, mathematics, mechanical engineering, telegraphy, lecturer in materia medica, statement of receipts and expenditure for the year 1882, examiners, subcriptions and donations, alfred mica smith, chemistry, metallurgy, f.m. krause, ferdinand krause, geology, mineralogy, scientific mining, t.h. thompson, practical mining, w.h. shaw, h. reid, mechanical enginnering, phoenix foundry company (limited), phoenix foundry, arthur. a. buley, mining, engineering surveying, walter. d. campbell, j. wall, astronomy, james oddie, natural philosophy, elementary mechanics and hydrostatics, magnetism and electricty, sound, light and heat, j.f. usher, materia medica, pharmacy, physiology, w.h. shawmechanical engineering, h.m. andrew, h.d. de la poer wall, thomas mann, p.c. fitzpatrick, h. rosale, john lewis, w.c. kernot, mccoy, j. cosmo newbery, baron von mueller, samuel w. macgowan, w.p. bechervaise, r.l.j. ellery, astronomer, j.m. bickett, james bickett, n. kent, a. martin, r.s. mitchell, w.h. keast, p. matthews, d. milliken, j.t. richards, jonathan robinson, h. brookes allen, joseph bosisto, c.r. blackett, m.l.a., william. johnson, government of victoria analyst, moorabool, lal lal, skipton, coal, skipton coal discovery, lal lal creek, moorabool falls, lal lal race course, lal lal falls, moorabool river, william h. keast

The carte de visite, English: 'visiting card', was a format of small photograph which was patented in Paris by photographer André Adolphe Eugène Disdéri in 1854, although first used by Louis Dodero. Each photograph was the size of a visiting card, and such photograph cards, in an early form of social media, were commonly traded among friends and visitors in the 1860s. Albums for the collection and display of cards became a common fixture in Victorian parlors. The popularity of the format and its rapid uptake worldwide were due to their relative cheapness, which made portrait photographs accessible to a broader demographic, and prior to the advent of mechanical reproduction of photographs, led to the publication and collection of portraits of prominent persons. It was the success of the carte de visite that led to photography's institutionalization. https://en.wikipedia.org/wiki/Carte_de_visite Three B&W male portraits undated a. R.O. Henderson, studio photo with pillar, by Johnstone O'Shannessy & Co. b. Henry Jackson, head portrait in Dec. 1866, Photographed by Batchelder, Pall Mall, Sandhurst c. Mr. Jackson oval portrait facing left; photographed by N White, photographer, Mitchell Street, Sandhurst.photos, photographers

A cutting from from a Melbourne Legacy President's report showing a photo of Legatee George Blackwood (President of Melbourne Legacy in 1975). It was collected to be a record of a photo of past presidents. In World War 2 Legatee Blackwood served in the AIF in the Middle East, New Guinea and Borneo in the Corps of the Royal Australian Electrical and Mechanical Engineers and was awarded an OBE for services whilst commanding the 2/1 Army Field Workshop with the 9th Australian Division in the Alamein Campaign. He achieved the rank of Colonel. He joined Legacy in 1964 on the nomination of Legatees John Summerton and AN Fraser. The article was part of an album of past presidents from 1965 to 1989. The folder included biographical details and obituaries, eulogies and death notices of prominent Legatees. The items have been catalogued separately.A record of Legatee George Blackwood a past president of Legacy. The information was collected to record the lives of prominent legatees in a folder.Article with a black and white photo of Legatee George W Blackwood - President 1975past presidents, george blackwood

An article from the Melbourne Legacy Bulletin on the death of Legatee George Blackwood (President of Melbourne Legacy in 1975). The Bulletin published articles on Legatees when they passed away. Legatee Blackwood, born in 1907 and died in 1982. In World War 2 Legatee Blackwood served in the AIF in the Middle East, New Guinea and Borneo in the Corps of the Royal Australian Electrical and Mechanical Engineers and was awarded an OBE for services whilst commanding the 2/1 Army Field Workshop with the 9th Australian Division in the Alamein Campaign. He achieved the rank of Colonel. He joined Legacy in 1964 on the nomination of Legatees John Summerton and AN Fraser. The article was part of an album of past presidents from 1965 to 1989. The folder included biographical details and obituaries, eulogies and death notices of prominent Legatees. The items have been catalogued separately.A record of Legatee George Blackwood a past president of Legacy. The information was collected to record the lives of prominent legatees in a folder.Typed copy of a page from the Legacy Bulletin on the death of Legatee George Blackwood - President 1975Bulletin No 1209. 17.6.1982. Page No 3 and 4past presidents, vale, george blackwood

1. Jacket - Khaki colour wool serge fabric, battle dress style, belted at the waist with metal buckle. Green colour plastic buttons. Collar, shoulder epaulettes, two front pockets with button down flap. Shoulder sleeve insignia, navy blue colour with gold embroidered lettering "ROYAL AUSTRALIAN ELECTRICAL AND MECHANICAL ENGINEERS". Rank Insignia - lower sleeve - Warrant Officer, Class 1. Manufacturers white cotton fabric label, inside left pocket. 2. Trousers - Khaki colour wool serge fabric. green plastic button, metal zipper fly, Fob pocket, two side pockets, one back pocket with button down flap. Manufacturers white cotton fabric label, back inside waistband.1. & 2. Manufacturers information - black ink print "BERENSEN PTY LTD/VICTORIA 1961/62/ NAME/ SERVICE NO./ DRY CLEAN ONLY/ PRESS IN ORIGINAL/ CREASE LINE/ USE DAMP CLOTH OR/ STEAM IRON/ MEDIUM TO HOT RANGE/ CREASE SET BY SIRO SET. Black ink stamp "DM FIELD/ WO2/ 313679".uniform, army, battle dress

"Herbert Rex WILLIS" Reg No. 342872 Service Details. Refer Cat No. 5231.31. Jacket - Khaki colour, wool serge fabric, Battle dress style, belted at the waist with metal buckle and brown plastic buttons. Collar, shoulder epaulettes, two front pockets with concealed button down flap and sleeve cuffs. Shoulder insignia - with yellow lettering - "ROYAL AUSTRALIAN ELECTRICAL & MECHANICAL ENGINEERS". Rank insignia on sleeves - brown, white and red, - Warrant Officer Second Class. Service Ribbons above left pocket L-R, Vietnam Campaign Medal. Long Service Medal, South Vietnamese Medal with clasp "60-". Light khaki colour cotton twill fabric lining. Manufacturers white cotton twill fabric label - inside on left pocket lining. 2. Lanyard - dark blue colour cotton cord with knots. 1. Manufacturers information on label - black ink print "REGIMENTAL NO./ NAME", Red ink print "M.TX/IZE 5". On pocket lining - purple ink "D^D/ MADE IN AUSTRALIA/ 1954. On collar lining - handwritten, black ink pen "WILLIS" .uniform, army, battle dress, rex willis

This guillotine is a hand operated machine specifically designed to cut through multiple sheets of paper or card. It has a very heavy and sharp single blade knife mounted between vertical guides or runners. The main users of a machine like this is in by the printing and publication binding industry. Book binding companies use a guillotine to evenly trim the pages of a book after it has been bound. The way the guillotine is used is - paper or card is stacked squarely on the flat table and pushed firmly against the back guide - the handle below the table at the front of the machine is wound around, which brings the back guide forward, pushing the paper stack forward and positioning the centre of the stack below the vertical frame - the upper wheel is wound around, which brings the clamp and firmly in position on top of the paper, to hold it very firmly - the large wheel on the side of the machine is turned around to lower the long sharp blade down onto the pages and cut them through. The sharp edge of the blade is protected somewhat from becoming blunt; a block of wood sits in the table under the stack of paper An early model of a guillotine was patented in 1837 by Thirault, who built a model with a fixed blade. Guillotines similar in principal to this one were patented by Guillaume Massiquot in 1844 and 1852. Over the years many improvements have been made and operation has moved from man power to electricity. Oscar Friedheim Ltd. was the importer and wholesaler of a large range of machinery and equipment for the printing and bookbinding industry. He sold most of his equipment under his own name. On this guillotine or paper cutter he refers to the origin of the guillotine’s manufacture only as “German Manufacrure”. A reference book “Commercial Bookbinding: a description of the processes and the various machines used" by Geo. Stephen, 1910, recommends Oscar Friedheim, amongst others, for the supply of “reliable cutting machines for hand or power”. It also recommends Oscar Friedheim’s for a wide range of other printing machinery and processes. OSCAR FRIEDHEIM LIMITED, LONDON Oscar Friedheim Ltd. was established in 1884 and operated from Ludgate in London. The company was an importer and wholesale supplier in the 1880’s, offering machinery and equipment for the printing and packaging industry for the UK and Ireland. The company became incorporated in 1913. An advertisement of 1913 includes a telegraphic code plus two telephone numbers for Oscar Friedheim Ltd and invites readers to call at the Ludgate, London, showrooms to see the machines working. The company later became Friedheim International Ltd. The book titled “Friedheim, A Century of Service 1884-1984 by Roy Brewer, celebrates Oscar Friedheim’s achievements. Friedheim International currently operates from Hemel Hempstead, on the northern outskirts of London UK. It promotes itself as “… the leading supplier of finishing, converting and packaging machinery to the printing, graphic arts, and highly varied packaging industries in the UK and Ireland. The company’s policy is simple – “employ the best people, work with the best equipment manufacturers in the world, and treat our customers as partners!” The company still sells guillotines. The guillotine is significant for its ability to represent aspects of the printing trade in Warrnambool and in a typical port town circa 1850 to 1910. It represents communication methods and processes used in the time before electrically powered equipment became common in industry.Guillotine (or paper cutter), hand operated. Metal framework with vertical guides, stand and metal mechanical parts including wheels and gears. Table with back guide; handle below front of table winds to move the back guide. A wheel at top of machine winds to adjust pressure of the clamp on the work on the table below it. The cutting blade fits between vertical guides; a timber insert in the table below the blade helps minimise the loss of sharpness of the blade. A handle on the side of the machine turns a large spoked wheel, which rotates a large gear, causing the blade to move up and down. Makers details are on a small oval plaque with embossed maker’s details is screwed onto main body. Maker is O Friedheim, London, and the machine is of German manufacture, circa late 1880’s.Maker’s plaque inscribed "O. FRIEDHEIM / London / German Manufacture"flagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, maritime museum, shipwreck coast, flagstaff hill maritime village, great ocean road, printing machinery, printer’s guillotine, paper guillotine, paper cutter machine, oscar friedheim ltd london, friedheim international ltd, bookbinding industry, printing industry

Staff Members of the Ballarat School of MinesA black and white photograph showing 18 men. Standing L-R: S.B. Vial (Chemistry); W. Doepel (Clerk); Alfred E.C. Kerr (Mechanical Engineering); Arthur Garrard (Battery Manager); Henry Hall (Drawing); W. Kerr Grant (Mathematics); C.E. Campbell (Photography); J.M. Sutherland (Electricity); H.R. Murphy (Assayer); Charles A. Dean (Cyanide Works). Sitting: Daniel Walker (Chemistry); Thomas S. Hart (Mineralogy & Curator); Fred. J. Martell (Registrar); Alfred Mica Smith, Senior Professor (Chemistry, Metallurgy, etc); J.S. Dawburn (Engineering & Surveying); Dr J.F. Usher (Materia Medica). Seating (Front): P.A. Osborne (Assistant Assayer); Godfrey Hart (Museum). .2) is a framed copy of the photograph in a carved timber from from Peake's BallaratFramer's plate 'Peake's Ballarat' Framed mount 'The Ballarat School of Mines, Staff 1900'ballarat school of mines, alfred mica smith, daniel walker, thomas hart, s.b. vial, w doepel, alfred kerr, arthur garrard, henry hall, w kerr grant, ce campbell, john sutherland, hr murphy, charles dean, fred martel, j.s. dawburn, j.f. usher, p.a. osborne, godfrey hart, c.e. campbell, w. kerr grant, kerr grant

This double-sheaved wooden ship’s block or pulley is a mechanical device used for lifting and moving heavy objects. It has two grooved wheels joined together, each with an axle between the cheeks or sides of the grooved wheel. Blocks and tackle are included in a ship’s rigging. These pulleys and ropes are used for the mechanical advantage they provide for lifting, moving and re-arranging the setting of the sails, which are very heavy work. Blocks are also used to load and unload the ship’s cargo. The FALLS of HALLADALE- The sailing ship Falls of Halladale was an iron-hulled, four-masted barque, used as a bulk carrier of general cargo. She left New York in August 1908 bound for Melbourne and Sydney. In her hold was general cargo consisting of roofing tiles, barbed wire, stoves, oil, and benzene as well as many other manufactured items. After three months at sea and close to her destination, a navigational error caused the Falls of Halladale to be wrecked on a reef off the Peterborough headland on the 15th of November, 1908. The captain and 29 crew members survived, but her cargo was largely lost, despite two salvage attempts in 1908-09 and 1910. The Court of Marine Inquiry in Melbourne ruled that the foundering of the ship was entirely due to Captain David Wood Thomson's navigational error, not too technical failure of the Clyde-built ship. The Falls of Halladale was built in1886 by Russell & Co., at Greenock shipyards on the River Clyde, Scotland for Wright, Breakenridge & Co of Glasgow. The ship had a sturdy construction built to carry maximum cargo and was able to maintain full sail in heavy gales, one of the last of the 'windjammers' that sailed the Trade Route. She and her sister ship, the Falls of Garry, were the first ships in the world to include fore and aft lifting bridges. The new, raised catwalk-type decking allowed the crew to move above the deck in stormy conditions.This artefact is important as it is an example of the materials and design of late-19th century ship’s rigging equipment. The object is also significant for its association with the historic sailing ship Falls of Halladale, wrecked in local waters in the early 20th century. The clipper ship Falls of Halladale shipwreck is of historical significance and is listed on the Victorian Heritage Register, No. S255. She was one of the last ships to sail the Trade Routes. She was one of the first vessels to have fore and aft lifting bridges. The vessel is an example of the remains of an international cargo ship and also represents aspects of Victoria’s shipping industry.Ship's block; a double-sheave wooden block with thick concretion on it. The rope block was recovered from the wreck of the sailing ship, Falls of Halladale.Noneflagstaff hill, maritime museum, maritime village, warrnambool, great ocean road, shipwreck coast, falls of halladale, shipwreck, peterborough, 1908 shipwreck, peterborough shipwreck, russell & co., greenock, wright breakenridge & co. glasgow, clipper ship, machine, mechanical advantage, block, wooden block, pulley, tackle, sheave, ship rigging, double-sheave, twin sheave, captain david wood thomson, iron ship, four-masted ship, sailing ship, windjammer, clyde, wright, breakenridge & co of glasgow, fore and aft lifting bridges

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 handpiece that would be fitted with a dental tool. On the foot is painted lettering naming it "The Brentfield" and there is a fine line of light coloured paint creating a border around the name. The paint under the lettering is peeling off. The drill has a Y-shaped, three footed cast iron base, one foot being longer than the other two. A vertical 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 adjustable telescoping pipes, joins into the top of this frame. 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, down and around. There is a pulley each side of the joint of the arm and a short way along the arm is fitted a short metal pipe. A little further along the arm a frayed-ended cord hangs down from a hole. At the end of the arm is another pulley and a joint from which hangs a long, thin metal pipe with two pulleys and a fitting on the end. A treadle, or foot pedal, is joined to the long foot of the base, and joined at the toe to the crank that turns the driving-wheel. 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 fits 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 foot pedal has a cross-hatch pattern on the heel and the ball of the foot has tread lines across it. The end of the toe and the instep areas have cut-out pattern in them. "The ____/ Brentfield / __ DE IN L___" (Made in London) painted on the long foot of the base. Marked on the drill connection is “Richter De Trey, Germany”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, the brentfield, richter de trey, german dental fitting, london dental drill

July 1945. Eighteen young British, Australian and New Zealand special forces from a top-secret underwater warfare unit prepare to undertake three audacious missions against the Japanese. Using XE-craft midget submarines, the raiders will creep deep behind Japanese lines to sink two huge warships off Singapore and sever two vitally important undersea communications cables. Success will hasten ultimate victory over Japan; but if any of the men are captured they can expect a gruesome execution. Can the Sea Devils overcome Japanese defences, mechanical failures, oxygen poisoning and submarine disasters to fulfill their missions? Mark Felton tells the true story of a band of young men living on raw courage, nerves and Adrenalin as they attempt to pull off what could be the last great raid of World War Two.ww2, special operations, submarine operations

When the fabric is removed from the loom it is often stiff, rough and uneven. There are a number of finishing processes, both mechanical and chemical that give wool fabrics their special look and feel. The fabric is often scoured again to remove oils and dirt picked up during manufacture. It is then pressed. For a soft and fluffy surface, the fabric is brushed. For a smooth surface, it is shorn. For centuries, machines similar to this teasle gig were used to finish fabrics. It uses the prickly flower head off the teasle plant (Dispsacus Fullonum) to do the delicate work to raise the surface, or nap, the woollen cloth. At least 1,500 teasle heads are needed for one gig. The teasel is a thistle like plant whose dried heads are used on the teasel gig. They are fixed to frames around the drum, or gig. The gig turns in the opposite direction to the flow of the cloth until the nap is raised. Also spelled as Teazel Gig.Large metal machine with wooden rollers and teasel covered drum.textile finishing, raising, raising machinery, teasel gig, fabric, wool processing, plants, thistle, drum

John Lundy-Clarke grew up in the Kalorama/Mt Dandenong area and later in life (1972-74) began to write a comprehensive history of the district working from an original settlement map in an effort to cover all areas. Alan Price was the son of Edward John Price and Myra (nee Wilson) Price. He had a brother Edward Joseph 2nd (Teddie). Alan and Teddie were the grandsons of early settlers Edward Joseph and Annie (nee Ross) Price. Alan Price worked at his brother's depot in Ringwood, in charge of mechanical equipment. He rode to and from work on his motorbike. Alan was killed in a motorbike accident on his way home from work in 1971. Alan married Patricia Guerin in 1960. They had five daughters and one son. The family had a house on part of Lot 5 facing Mt Dandenong Road.Black and white close up of man in suit and tie. Reverse of photograph has handwritten description by John Lundy-Clarke. Alan Price 1969. Son of Edward John Price and Myra nee Wilson. alan price, patricia guerin, edward joseph (teddie) price, edward john price, myra price, myra wilson, edward joseph price, annie price, annie ross, kalorama, accident

An aneroid barometer is an instrument used for measuring air pressure as a method that does not involve liquid. Invented in 1844 by French scientist Lucien Vidi, the aneroid barometer uses a small, flexible metal box called an aneroid cell (capsule), which is made from an alloy of beryllium and copper. The evacuated capsule (or usually several capsules, stacked to add up their movements) is prevented from collapsing by a strong spring. Small changes in external air pressure cause the cell to expand or contract. This expansion and contraction drives mechanical levers such that the tiny movements of the capsule are amplified and displayed on the face of the aneroid barometer. Many models include a manually set needle which is used to mark the current measurement so a change can be seen. This type of barometer is common in homes and in recreational boats. It is also used in meteorology, mostly in barographs and as a pressure instrument in radiosondes.5 inch Aneroid barometer on wooden basebarometer, aneroid

This prospectus contains the history of Leahy's electrical . The objectives of this company were to allow expansion of the present business ( est,1946) , to take advantage of the excellent corner site and to modernise the building and carry all heavy duty electrical and mechanical lines for commercial users and farmers.Attached was a hire car services which operated as Leahy's Hire cars. The service of the the previous business commenced in 1946 at 82 Fairy Street and grew to employ up to 25 tradesmen. However the assets of the business were lost May1, 1950 when building stock and plant was destroyed by fire.In October 1950 Mr leahy purchased the freehold on the corner of Liebig and Koroit Streets Warrnambool The directors of the new company were John James Leahy, John Beynon Dwyer, William John Taggart Walter, William James Croft, Martin White and James Albert Affleck. They aimed to raise 50000 pounds with 100000 shares at ten shillings each. This document shows the beginnings of one of Warrnambool's most successful 20th century companies. It lists the people associated with it from its inception many of whom were and are well known in the district. It therefore has strong social and historical significance.Cream soft card cover with dark blue text. It is stapled together and contains 6 pages on cream paper with black text.back cover is plain.Prospectus of Leahy's Electrical Industries Ltd Warrnambool Vic, 19th April 1951.warrnambool, j j leahy, jim leahy, leahy's electrical industries, prospectus leahy's electrical industries 1951

A butter churn is a device used to convert cream into butter. This is done through a mechanical process, frequently via a pole inserted through the lid of the churn, or via a crank used to turn a rotating device inside the churn. The use of butter is mentioned in biblical works and the earliest butter churn vessels belonging to Beersheba culture in Israel were found in Bir Abu Matar going back to Chalcolithic period between 6500–5500 BC. The butter churn in Europe may have existed as early as the 6th century AD, In the European tradition, the butter churn was primarily a device used by women, and the churning of butter was an essential responsibility along with other household chores. In earlier traditions of butter making, nomadic cultures placed milk in skin bags and produced butter either by shaking the bag manually, or possibly by attaching the bag to a pack animal, and producing butter simply through the movement of the animal. An item used to make butter in a domestic situation by turning a handle until the cream inside has turned to butter.Butter churn, wooden, lid pieces screwed or nailed together. Brass bearing on side with iron turning handle.Handle marked 28204 no other marks to indicate manufacturer or date of productionflagstaff hill, warrnambool, shipwrecked coast, flagstaff hill maritime museum, flagstaff hill maritime village, great ocean road, churn, butter churn, wooden churn, butter making, food, dairy, kitchen utensil

Sport and available playing areas were important and every effort was made to provide this for the students when they moved into the new building in 1921. The terraces leading down from the gaol wall were terraced and clearing areas of rubble to provide playing areas for football and cricket was done by the students. In November 1922, a tennis court was opened in the Battery Paddock. It was designed by Syd Chambers and constructed by Les Waller, former students of the Ballarat School of Mines. A new tennis court was built and opened in 1934, in the same area. This photograph is of the 1938 Tennis Team - Ballarat Junior Technical School. The boys standing are L to R: D. Eltringham and J. Burt. Seated on the left is W. Rowe and W. Edwards on the right. They are with Mr J. Hosie - staff member 1938-41. Donald Eltringham was Dux of the school in 1938. He obtained a Diploma in Electrical Engineering and Mechanical Engineering from the School of Mines Ballarat - 1944/47A formal group of four boys in tennis outfits with racquets and one adult male.Photographer's stamp embossed on front with rubber stamp on back "Richards & Cc - photographers - Ballarat. In pencil - "Jun Tech" and "1938"tennis court, battery paddock, syd chambers, les waller, ballarat school of mines, 1938 tennis team, ballarat junior technical school, eltringham, burt, rowe, edwards, j. hosie, electrical engineering, mechanical engineering

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

The Olivetti company was founded in Italy in 1908.This particular typewriter is a Olivetti Lettera 22, oblique front stroke and portable manufactured after 1950. The 1950s and 1960s was a time when British manufactured goods were still purchased by many Australian consumers. The later 1960s onwards, there was a shift, mainly in the cities, to European made goods. The invasion of Japanese manufactured goods was relatively slower, especially in rural areas. The demand for long lasted and dependable merchandise was in the rural area still the most important criteria. The ease of setting up this typewriter and its compact mobility was its major benefit to trades people and travelling professionals, e.g. rural doctors, other medical professionals, accountants, lawyers and educators. This item facilitated the growing numbers of professional nomads requiring a relatively light office stationery package e.g. travelling novelist, writer, businessman and academics. This typewriter needed no electrical or battery power to operate it. Outback Australia, where at this point in time, was still relatively isolated from a good available electrical power reticulation and battery power, and therefore could not be totally measured as a highly efficient office environment.Although this typewriter was purchased from a business in Penrith, Sydney, N.S.W., it is significant that it travelled easily to the Kiewa Valley, demonstrating the mobility of certain sections of the community. This typewriter was designed by an Italian industrial designer, Marcello Nizzoli, in line with the art deco style of the 1930s and the colour and flexibility of the vibrant 1950s. The underlying theme of manufacturing in the 1950s was to produce equipment that was more efficient than what was inherited from the earlier period of 20th century. Improvements were made to this Olivetti typewriter by Giuseppe Beccio by reducing the number of parts made from 3,000 to 2,000. This reduction of parts and therefore cost of production was the major principle of the Japanese manufacturing juggernauts of the post World War II era. Efficiency and low costs material was becoming prime factors in the success of rural industries from the 1960s. Competition from overseas producers was starting to affect rural industries and the removal of the large range of tariff protection, especially rural products, required not only a shift of farm management but a more efficient cost savings modus operandi. This Olivetti Lettera 22, oblique front stroke portable (weighs 4kg) mechanical typewriter has a coral coloured plastic casing. The keys are made of black hardened plastic with white lettering, numbers and symbols (imperial fractions, and pound). It has a QWERTY keyboard as opposed to the Italian QZERTY. It has a lever to move the ribbon between black, neutral (for mimeograph stencils)and red colours (a red key is provided for highlighting specific words,letters or symbols) . This machine is fitted with only a black ribbon. It has a black rubber paper rollers and chromed metal parts on the carriage way. It has four rubber feet underneath the main body. On the left side of the roller there is a lever to adjust the roller from fixed (when mobile) through 1,2 and 3 line space gradients. This model has a key for zero but not one for the number one (uppercase letter l is used) see KVHS 0459 for the carrying bag.On the cover over the ribbon wheels letter strikers has a plate marked "Lettera 22" and the back plate behind the paper roller and in front of the paper supports has a silver metal label marked "olivetti made in great britain".commercial, mobile office equipment, mechanical typewriter

Charcoal grey soft covered booklet with views of the Michigan College of Mines. * General View * Hubbell Hall * Mechanical Engineering Building * Mining and Metallurgy Buildings, with Stamp Mill in the Distance * Chemistry Building * College Club and Gymnasium Building * Architects Sketch of Library and Museum Building * Metallurgy Building * Mining Engineering Building * Assaying Course G1 * General Chemistry Course F1 * Inspecting Drill Operations * Mineralogy - COurses W1 and W2 * Railroad Surveying - Course Q1 * Field Geology * Reporting on Power PLants at Tamarack No. 5 Hoist * Sketching Ore Pockets * Pattern Shop * Physics Course * Underground in Champion Mine * QUalitative Chemistry * Field Surveying * Ore Dressing * HYdraulics Course * Machine Shop * Palaeontology and Historical Geology * Just Up from Lake Angeline Mine, Ishpeming Mineralogical Museum * Gymnasium, College Club Building * Lounging Room of College Club Buildingmichigan college of mines, school of mines, michigan, houghton, michigan, f.w. mcnair, united states of america, schools of mines, michigan school of mines

Black & White Photograph by the TMSV Sales of a former grip car being transport on a jinker, pulled by three horses. Photo - Victoria Ave at the corner of Beaconsfield Pde - with the Bleak House Hotel in the background. Advised by Mal Rowe. From an email from Robert Green, 19-08-2021 - advised "The Herald of 10 May 1935, p.4 has the following little paragraph : Cable Tram Tableau Entitled “Transport Cavalcade”: Horse-laughs - real ones – were heard today when a team of horses, drawing a lorry upon which was a dis-used cable tram dummy sporting “Collins Street” upon the front and “South Melb Beach” at the rear, passed along Swanston Street. Neddy’s superiority complex at seeing out these early manifestations of our mechanical age was heightened when the front wheel of a nearby motor-truck fell off." Image has been reproduced from a movie - Commuting by Cable?Has the TMSV Sales stamp on rear.trams, tramways, cable trams, grip tram, beaconsfield parade, albert park

A hammer is a tool with a heavy head and a handle, often made of shock-absorbent wood or fiberglass that is used to strike an object. The most common uses for hammers are to drive nails, fit parts, forge metal, and break apart objects. Hammers vary in shape, size, and structure, depending on their uses. Hammers are basic tools in many trades. A hammer is composed of a head most often made of steel and a handle also called a helve or haft. Most hammers are hand tools. A traditional hand-held hammer consists of a separate head and a handle, fastened together by means of a special wedge made for the purpose, or by glue, or both. This two-piece design is often used, to combine a dense metallic striking head with a non-metallic mechanical-shock-absorbing handle -to reduce user fatigue from repeated strikes. If wood is used for the handle, it is often hickory or ash, which are tough and long-lasting materials that can dissipate shock waves from the hammer head. A well used hammer with wooden handle and steel headpioneers, early settlers, market gardeners, moorabbin, brighton, cheltenham, tools, craftsman, carpenters, blacksmiths, builders, woodwork,

This linesman belt was used under the 1947 Electricity Regulations and before tighter Occupation and Health regulations (late 1990's early 2000's) were introduced that mechanical lifting platforms(wherever possible) replaced the belt up the pole method.The safety concern was that it required that tools needed by the linesman had to be placed in a large canvas bag and attached to the belt (extra weight) then the linesman had to climb the ladder. Ladders had to be at the correct angle and not able to "slip" from their initial footings. A full harness and a secondary fall belt is now mandatory for pole linesmen. The safety of fellow workers could be compromised if they were required to assist or recover the first linesman if needed. In 2006 an additional 269 registered lineworkers were employed. Please note that the terminology of linesman has become unisex. The linesman's belt enabled the linesman to place his feet against the pole adjust the belt (if needed) and lean back securely allowing both hands to be free to work with. This linesman belt is very significant to the Kiewa Valley due to the numerous poles and high voltage overhead power structures that needed maintenance for the extensive "mushroom" installation of electrical power polls(wood and metal). On high poles (steel) climbing pegs were welded on, however in the Alpine areas snow in winter caused an OH&S problem which were hard to overcome. The safety of a linesman when maintenance of electricity line on poles can be highlighted by the New Zealand linesman who survived an 11,000 volt shock when carrying out maintenance. For the record 11,000 volts is four times more powerful than execution by "the electric chair". The maintenance of the linesman's belt was his responsibility (keeping it clean and in "good" condition). Labour laws change this initial responsibility, from the linesman, to the employer. Climbing pegs were installed on higher poles that extended beyond the reach of ladders.This thick leather linesman belt is made from two lengths of heavy lengths of leather straps sewn together to make up 80% of the belt. The remaining 20% is "the belt tonge" which has eleven holes for three (solid steel tang) buckle connections.kiewa hydro electricity scheme, victorian state electricity commission, relays, generators, electrical pole maintenance

The school bell has been used in various forms for several centuries. In Australia and the UK it was often a hand bell, located on the teacher's desk in a small school. In larger schools it was positioned in a central area, and one bell was used to signal to all classrooms. In North America it was more usual to find a large bell on a stand located in a central area of the school where it could be heard by everyone throughout the premises. More recently, the school bell has become wall located, and electrically activated, using a mechanical timing apparatus. Now the same bell is computer programmed and activated, although there are many older bells still in operation. The school bell was rung at the beginning at the school day, often to summon students to the morning assembly in larger schools. It was then rung throughout the day to signal the start and end of specific lesson periods, the beginning and end of school morning and afternoon breaks, the lunch period, and the end of the school day, no doubt eagerly awaited by many students! The school bell was used as a timing device in schools to signal the start and end of specific activities.Bell brass with heavy metal square shaped base and wooden handle-hand held, Kel(?)her Melbourne on the topInscribed on the metal at the top of the bell are the letters "Kel(?)her Melbourne" flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, bell, school, lessons