Electroconvulsive therapy (ECT) was invented in Italy in the late 1930s. ECT is a medical treatment most commonly used in patients with severe major depression or bipolar disorder that has not responded to other treatments. Psychiatrists had already discovered that inducing seizures could relieve symptoms of mental illness. Before ECT, this was done with the use of chemicals, usually one called Metrazol. More can be read here: http://theconversation.com/electroconvulsive-therapy-a-history-of-controversy-but-also-of-help-70938 This machine was used both at Aradale Mental Hospital and J Ward. The object is significant because it is a well preserved instrument that illustrates the medical apparatus used at both Ararat Mental Hospital and J Ward for the treatment of mental illness.A metal instrument. The front contains three knobs, two switches, and power button. Two fully intact electrical cords - One leads to the paddles used on the patient: One used to attach to the electric source [power point]. Paddles are made of hard plastic and stainless steel metal. The back has a compartment where the paddles can be stored. The top has a carry handle.Manufacturer: Siemens Power supply: 220V 85AC, 50Hzmentalhealth, psychiatrichealth, depression, #bipolardisorder

Metal lamp, battery powered, with 60 mm lens on front, folding carry handle and spring clip on back for mounting on equipment. There are two 10 mm holes in the bottomD D broad arrow, maker's name, Lamps Electrical No 1lamp, souvenir, equipment

This catalogue and reference book was used by Dr Angus during his medical practice at the inland Victorian country town of Nhill. It was donated to Flagstaff Hill Maritime Village by the family of Doctor William Roy Angus, Surgeon and Oculist. It is part of the “W.R. Angus Collection” that includes historical medical equipment, surgical instruments and material once belonging to Dr Edward Ryan and Dr Thomas Francis Ryan, (both of Nhill, Victoria) as well as Dr Angus’ own belongings. The Collection’s history spans the medical practices of the two Doctors Ryan, from 1885-1926 plus that of Dr Angus, up until 1969. ABOUT THE “W.R.ANGUS COLLECTION” Doctor William Roy Angus M.B., B.S., Adel., 1923, F.R.C.S. Edin.,1928 (also known as Dr Roy Angus) was born in Murrumbeena, Victoria in 1901 and lived until 1970. He qualified as a doctor in 1923 at University of Adelaide, was Resident Medical Officer at the Royal Adelaide Hospital in 1924 and for a period was house surgeon to Sir (then Mr.) Henry Simpson Newland. Dr Angus was briefly an Assistant to Dr Riddell of Kapunda, then commenced private practice at Curramulka, Yorke Peninsula, SA, where he was physician, surgeon and chemist. In 1926, he was appointed as new Medical Assistant to Dr Thomas Francis Ryan (T.F. Ryan, or Tom), in Nhill, Victoria, where his experiences included radiology and pharmacy. In 1927 he was Acting House Surgeon in Dr Tom Ryan’s absence. Dr Angus had become engaged to Gladys Forsyth and they decided he would take time to further his studies overseas in the UK in 1927. He studied at London University College Hospital and at Edinburgh Royal Infirmary and in 1928, was awarded FRCS (Fellow from the Royal College of Surgeons), Edinburgh. He worked his passage back to Australia as a Ship’s Surgeon on the on the Australian Commonwealth Line’s SS Largs Bay. Dr Angus married Gladys in 1929, in Ballarat. (They went on to have one son (Graham 1932, born in SA) and two daughters (Helen (died 12/07/1996) and Berenice (Berry), both born at Mira, Nhill ) Dr Angus was a ‘flying doctor’ for the A.I.M. (Australian Inland Ministry) Aerial Medical Service in 1928 . The organisation began in South Australia through the Presbyterian Church in that year, with its first station being in the remote town of Oodnadatta, where Dr Angus was stationed. He was locum tenens there on North-South Railway at 21 Mile Camp. He took up this ‘flying doctor’ position in response to a call from Dr John Flynn; the organisation was later known as the Flying Doctor Service, then the Royal Flying Doctor Service. A lot of his work during this time involved dental surgery also. Between 1928-1932 he was surgeon at the Curramulka Hospital, Yorke Peninsula, South Australia. In 1933 Dr Angus returned to Nhill where he’d previously worked as Medical Assistant and purchased a share of the Nelson Street practice and Mira hospital from Dr Les Middleton one of the Middleton Brothers, the current owners of what was once Dr Tom Ryan’s practice. Dr L Middleton was House Surgeon to the Nhill Hospital 1926-1933, when he resigned. [Dr Tom Ryan’s practice had originally belonged to his older brother Dr Edward Ryan, who came to Nhill in 1885. Dr Edward saw patients at his rooms, firstly in Victoria Street and in 1886 in Nelson Street, until 1901. The Nelson Street practice also had a 2 bed ward, called Mira Private Hospital ). Dr Edward Ryan was House Surgeon at the Nhill Hospital 1884-1902 . He also had occasions where he successfully performed veterinary surgery for the local farmers too. Dr Tom Ryan then purchased the practice from his brother in 1901. Both Dr Edward and Dr Tom Ryan work as surgeons included eye surgery. Dr Tom Ryan performed many of his operations in the Mira private hospital on his premises. He too was House Surgeon at the Nhill Hospital 1902-1926. Dr Tom Ryan had one of the only two pieces of radiology equipment in Victoria during his practicing years – The Royal Melbourne Hospital had the other one. Over the years Dr Tom Ryan gradually set up what was effectively a training school for country general-practitioner-surgeons. Each patient was carefully examined, including using the X-ray machine, and any surgery was discussed and planned with Dr Ryan’s assistants several days in advance. Dr Angus gained experience in using the X-ray machine there during his time as assistant to Dr Ryan. Dr Tom Ryan moved from Nhill in 1926. He became a Fellow of the Royal Australasian College of Surgeons in 1927, soon after its formation, a rare accolade for a doctor outside any of the major cities. He remained a bachelor and died suddenly on 7th Dec 1955, aged 91, at his home in Ararat. Scholarships and prizes are still awarded to medical students in the honour of Dr T.F. Ryan and his father, Dr Michael Ryan, and brother, John Patrick Ryan. ] When Dr Angus bought into the Nelson Street premises in Nhill he was also appointed as the Nhill Hospital’s Honorary House Surgeon 1933-1938. His practitioner’s plate from his Nhill surgery states “HOURS Daily, except Tuesdays, Fridays and Saturday afternoons, 9-10am, 2-4pm, 7-8pm. Sundays by appointment”. This plate is now mounted on the doorway to the Port Medical Office at Flagstaff Hill Maritime Village, Warrnambool. Dr Edward Ryan and Dr Tom Ryan had an extensive collection of historical medical equipment and materials spanning 1884-1926 and when Dr Angus took up practice in their old premises he obtained this collection, a large part of which is now on display at the Port Medical Office at Flagstaff Hill Maritime Village in Warrnambool. During his time in Nhill Dr Angus was involved in the merging of the Mira Hospital and Nhill Public Hospital into one public hospital and the property titles passed on to Nhill Hospital in 1939. In 1939 Dr Angus and his family moved to Warrnambool where he purchased “Birchwood,” the 1852 home and medical practice of Dr John Hunter Henderson, at 214 Koroit Street. (This property was sold in1965 to the State Government and is now the site of the Warrnambool Police Station. ). The Angus family was able to afford gardeners, cooks and maids; their home was a popular place for visiting dignitaries to stay whilst visiting Warrnambool. Dr Angus had his own silk worm farm at home in a Mulberry tree. His young daughter used his centrifuge for spinning the silk. Dr Angus was appointed on a part-time basis as Port Medical Officer (Health Officer) in Warrnambool and held this position until the 1940’s when the government no longer required the service of a Port Medical Officer in Warrnambool; he was thus Warrnambool’s last serving Port Medical Officer. (The duties of a Port Medical Officer were outlined by the Colonial Secretary on 21st June, 1839 under the terms of the Quarantine Act. Masters of immigrant ships arriving in port reported incidents of diseases, illness and death and the Port Medical Officer made a decision on whether the ship required Quarantine and for how long, in this way preventing contagious illness from spreading from new immigrants to the residents already in the colony.) Dr Angus was a member of the Australian Medical Association, for 35 years and surgeon at the Warrnambool Base Hospital 1939-1942, He served as a Surgeon Captain during WWII1942-45, in Ballarat, Victoria, and in Bonegilla, N.S.W., completing his service just before the end of the war due to suffering from a heart attack. During his convalescence he carved an intricate and ‘most artistic’ chess set from the material that dentures were made from. He then studied ophthalmology at the Royal Melbourne Eye and Ear Hospital and created cosmetically superior artificial eyes by pioneering using the intrascleral cartilage. Angus received accolades from the Ophthalmological Society of Australasia for this work. He returned to Warrnambool to commence practice as an ophthalmologist, pioneering in artificial eye improvements. He was Honorary Consultant Ophthalmologist to Warrnambool Base Hospital for 31 years. He made monthly visits to Portland as a visiting surgeon, to perform eye surgery. He represented the Victorian South-West subdivision of the Australian Medical Association as its secretary between 1949 and 1956 and as chairman from 1956 to 1958. In 1968 Dr Angus was elected member of Spain’s Barraquer Institute of Barcelona after his research work in Intrasclearal cartilage grafting, becoming one of the few Australian ophthalmologists to receive this honour, and in the following year presented his final paper on Living Intrasclearal Cartilage Implants at the Inaugural Meeting of the Australian College of Ophthalmologists in Melbourne In his personal life Dr Angus was a Presbyterian and treated Sunday as a Sabbath, a day of rest. He would visit 3 or 4 country patients on a Sunday, taking his children along ‘for the ride’ and to visit with him. Sunday evenings he would play the pianola and sing Scottish songs to his family. One of Dr Angus’ patients was Margaret MacKenzie, author of a book on local shipwrecks that she’d seen as an eye witness from the late 1880’s in Peterborough, Victoria. In the early 1950’s Dr Angus, painted a picture of a shipwreck for the cover jacket of Margaret’s book, Shipwrecks and More Shipwrecks. She was blind in later life and her daughter wrote the actual book for her. Dr Angus and his wife Gladys were very involved in Warrnambool’s society with a strong interest in civic affairs. Their interests included organisations such as Red Cross, Rostrum, Warrnambool and District Historical Society (founding members), Wine and Food Society, Steering Committee for Tertiary Education in Warrnambool, Local National Trust, Good Neighbour Council, Housing Commission Advisory Board, United Services Institute, Legion of Ex-Servicemen, Olympic Pool Committee, Food for Britain Organisation, Warrnambool Hospital, Anti-Cancer Council, Boys’ Club, Charitable Council, National Fitness Council and Air Raid Precautions Group. He was also a member of the Steam Preservation Society and derived much pleasure from a steam traction engine on his farm. He had an interest in people and the community He and his wife Gladys were both involved in the creation of Flagstaff Hill, including the layout of the gardens. After his death (28th March 1970) his family requested his practitioner’s plate, medical instruments and some personal belongings be displayed in the Port Medical Office surgery at Flagstaff Hill Maritime Village, and be called the “W. R. Angus Collection”. The W.R. Angus Collection is significant for still being located at the site it is connected with, Doctor Angus being the last Port Medical Officer in Warrnambool. The collection of medical instruments and other equipment is culturally significant, being an historical example of medicine from late 19th to mid-20th century. Dr Angus assisted Dr Tom Ryan, a pioneer in the use of X-rays and in ocular surgery. Radio and Electrical Encyclopaedia and 1935 Catalogue, Homecrafts Pty Ltd, 211 Swanston Street Melbourne. Soft cover. Includes advertisements. (W.R. Angus Collection) flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, radion equipment catalogue, radio equipment reference book, flying doctor, romote medicine, nhill, dr w r angus, nhill base hospital, medical history, mira hospital, medical education, electronic communication, remote medical practice, 1935 radio catalogue, homecrafts pty ltd, homeware, hardware, radio parts, .

This transformer lamp system, which has a dial to transform 240 volts to a minimum of 32 volts was used by electrical technicians to inspect internal parts of the large generators (even in small confined spaces). The reason for the reduction of the 240 volts to the 32 volts was for the safety of the inspector. The SEC Victoria Hydro Scheme's electrical generators are powered by the hydro force of "stored" water at a higher altitude. The establishment of both the NSW and Victorian Hydro schemes was achieved from the mid 1900's to the 1960's. At this the point in time the need for additional power sources to quench both an industrial and domestic demand for electricity was purely an economic and not and environmental (carbon reduction) factor. This hydro scheme was instigated by "the Government of the day" as a bold move and was the major force of the World War II refugee and "technical" workforce inclusion of skilled and unskilled migration into the Australian environment. Although this mass "invasion" of workers with families was thought of in some circles as intrusive, the expansion of population post war years and its integration into the Australian rural sector, produced the multi- lingual multi-cultural diversity of later years.This transformer lamp is very significant to the Kiewa Valley as it was introduced as a very small part of the explosion of human resources into the valley. This influx of population transformed the region from that of a basically quiet rural region to one which evolved into both industrial and larger residential community. This evolution in the valley created a change, not only in the "physical" landscape but also the socio-economic expansion which permitted other "tourist" based industries into the valley. This is also a specific electronic item which was manufactured in Melbourne and not sourced from Europe or Asia. This demonstrates the fast evolution of Australian technology to a high standard compatible to that of the rest of the world.This heavy hand held electrical transformer (transforms 240 volts to 32 Volts) an has one leather handle on the top with three small (gauze filtered) air holes. It also has two 2 pin directional cable distribution (clipsal) in/out points 10amps / 240 volts. There is one glassed in volts/ac meter and one variable switch (180 to 150 voltage in settings of 10 volt increments.There are two vents (one on each of the smaller sides). There is also one three pin electrical lead coming out from the top.On one side is a manufacturer's plaque with "ELECTRONIC A & R EQUIPMENT MELBOURNE" and underneath "TYPE 1719, PRI V. 180 250" underneath "V.A. 1250" underneath "CYC 50" underneath "SEC V. 115" underneath "SEC A. 10 . 8". The label on topside "CAUTION SET SWITCH TO 250 v BEFORE CONNECTING TO MAINS THEN, WITH EQUIPMENT OPERATING, SET METER TO RED LINE.kiewa hydro electricity scheme, victorian state electricity commission, transformers

This protection relay apparatus (a large electrical fuse), which permits the easy monitoring and disconnection of faulty electrical apparatus connected to the large SEC Victoria Hydro Scheme's electrical power producing generators. These generators are powered by the hydro force of "stored" water at a higher altitude. The establishment of both the NSW and Victorian Hydro Schemes was achieved from the early 1900's to the 1960's. At this point in time the need for additional power sources to quench both an industrial and domestic demand for electricity was purely an economic and not and environmental (carbon reduction) factor. This hydro scheme was instigated by "the Government of the day" as a bold move and was the major force of the World War II refugee and "technical" workforce inclusion of skilled and unskilled migration into the Australian environment. Although this mass "invasion" of workers with families was thought of in some circles as intrusive, the expansion of population post war years and its integration into the Australian rural sector, produced the multi- lingual multi-cultural diversity of later years.This protection relay is very significant to the Kiewa Valley as its use was introduced during the Kiewa Hydro Scheme. Although only a small apparatus it was part of the explosion of human resources into the valley. This influx of population transformed the region from that of a basically quiet rural region to one which evolved into both an industrial and a larger residential community. This evolution in the valley created a change, not only in the "physical" landscape but also the socio-economic expansion which permitted other "tourist" based industries into the valley.This protection relay unit has a black painted metal shell with four copper enclosed "prongs" fastened to the rear of the housing(from a bake-lite plate) . Between these "prongs" are four "empty" points allowing additional "screw on" bases. The front glass enclosed meter and recorder allows for the identification and automatic disconnection of any faulty equipment connected to the main power generator. This equipment acts similarly to a modern day circuit breaker found on the electrical circuit boards of residential homes.On the top section of the front panel "ASEA" to the left "Made in Sweden" and to the right "Frabrique en Suede" below this "RIS" below this a graph and next to it two columns of numbers and a pointer for each setkiewa hydro electricity scheme, victorian state electricity commission, relays, generators

This bowl was used by the State Electricity Commission of Victoria in their mess rooms for their workers during the construction of the Kiewa Hydro Electric Scheme. The imprint of the year "1921" was to identify the year that the SECV was formed which relieved the private VHEC (Victorian Hydro-Electric Company). As the scheme was of such a huge scope, isolated and time consuming nature, the feeding of its workers was quite demanding of cutlery and crockery. The use of sturdy English cups and saucers was essential. The period of construction and the isolation of the Kiewa Valley area placed heavy demand for "solid" crockery that could wear abusive handling. This period in time was one when crockery, whether for domestic or commercial use, was imported from "mother" England. This scenario was more so for governmental bodies such as rail, jails and electricity providers than domestic users. The influx of cheaper Asian crockery had not yet begun.This type of crockery item was used by the thousands of SEC Victorian staff and construction workers involved in the building of the Kiewa Hydro Electricity Scheme, over the extensive period (1938 to 1961). This was a period when Government bodies and other semi- government organisations were still tied to the "establishments" of "mother" England. It was a period in Australia's development when the Asian influence was very weak and the established ties to England and Europe was still very strong. The majority of heavy equipment and machinery was either made in England or Europe. Local/European expertise in dam construction and water management in alpine terrain came from migrants and specialist recruited from England and Europe. The quality of workmanship from big steel manufacturing plants in England and Europe could not be matched from anywhere else in the developed world.This item is a white ceramic State Electricity Commission of Victoria bowl. It is made in England and is of strong and durable ceramic. The 5mm thickness of the ceramic suggests this bowl (cereal/soup) belongs to a commercial kitchen environment and not domestic. The indent bottom of the bowl is 5mm deep with a side curvature ratio of 2:5. The ceramic is glazed to a commercial standard (worker's mess). See also KVHS 0128 (B to D) for other ceramic crockery. The seal of the State Electricity Commission of Victoria is imprinted on the top outside rim within a curved scroll and a raised fist with electrical "charges" extending out.. Snuggled within the borders of the scroll is a banner with the five stars of the Southern Cross . On the underside "Vitrified sold by Cafe & Hotel Supplies Pty Ltd Dunn Bennett & Co. Ltd. Burslem Made in England"ceramic crockery, plate, secv, state electricity commission of victoria, crockery, mt beauty chalet, bogong mess hall

This case 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 leather case contains a meter which 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 carry case is made from leather hide and cloth covered cardboard insert. The front side has a lockable English made suitcase fitting. It has a broken carry strap (leather) travelling from top and through leather strap holders both sides and on the bottom of the case. A State Electricity Commission of Victoria identification tag riveted onto the top lid "ELECTRICAL ENGINEERING SECTION No. 1483"sec vic kiewa hydro scheme, alternate energy supplies, alpine located electricity generators, mobile measuring equipment

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

Scales such as the subject item were used to measure commercial quantities, possibly grains and farm produce for quite large amounts of product. Bags of grain etc would have been hooked up and weighed. Salter has been a name long associated with weights and measures. The firm began life in the late 1760s in the village of Bilston, England when Richard Salter, a spring maker, began making the first spring scales in Britain. He called these scales "pocket steelyards", though they work on a different principle from steelyard balances. By 1825 his nephew George had taken over the company, which became known as George Salter & Co. George later established a manufacturing site in the town of West Bromwich, about 4 miles (7 km) from Bilston. West Bromwich Albion football club was formed from workers at this works site. From here the company produced a wide variety of scales including the UK's first bathroom scales. Other items were added to the range, including irons, mincers, potato chippers, coin-operated machines and the first typewriters made in the UK. The business thrived throughout the 1900s, and by 1950 it employed over 2000 people, still in the same area and owned by the same family.Salter is a British housewares brand developing products that span a wide range of core product categories, including scales, electrical, cookware. It is a market leader in kitchen and bathroom scales and one of the UK’s oldest consumer brands.  Established in 1760, Salter has been developing precision products for over 260 years. It was acquired by Manchester-based consumer goods giant Ultimate Products in 2021 after they had previously licensed the brand for cookware and kitchen electrical since 2011.Balance scale Salters Spring Balance consisting of a circular, bronze face engraved with measurements in pounds, with an iron hand, weighing mechanism and hanging loop. Engraved on the face: "Class III Salter's Spring Balance Silvester's Patent To Weigh 300lbs".flagstaff hill, warrnambool, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, salter balance scale, weight measuring scale, weighing dry goods

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

It took 15 years to invent the can. It took 100 more to invent a standard way to open it. In the 19th century, decades after the invention of canning, there were virtually no can openers. Canned food, such as sardines, came with its own "key" to peel back the tin lid. Birth of the can One of the oddest things about the can opener is that the can predates it by almost 150 years. Though common today, cans were once military-grade technology. In 1795, Napoleon, to whom the phrase "an army marches on its stomach" is attributed, offered 12,000 francs to anyone who could find a way to preserve food. Without any knowledge of bacteria or their role in food spoilage, scientists didn't even know where to begin. It took 15 years before a chef named Nicholas Appert claimed the prize after successfully jarring food. Soon after that, his countryman Philippe de Girard came up with a variant on Appert's method—metal tins—and sold the idea to the British. Spoiled food, and the sickness it caused, was a widespread problem. The public would have benefited from canned food, but for decades cans were almost exclusively for the army and the navy. The canning process, with its hours of boiling and steaming, its scrupulous cleanliness, its heated metal, and its need for a great deal of disposable material, made canned food far too expensive for anyone but the military. No can openers were needed or even possible. The metal of early cans was too thick to make openers practical. Soldiers and sailors had plenty of sharp objects on hand and made ample use of them when they wanted to eat. During the 19th century, the process of canning was refined and mechanised, and the metal wall of the average can slimmed down enough that a civilian could get it open—if that civilian had the right tool. No one had that tool yet, so early cans had to open themselves. In other words, they came with built-in openers. The result was a confusing but pleasing free-for-all, in terms of product engineering. Each type of food came with its own kind of can, and each kind of can came with its own kind of opener. Tinned fish and meat were often sold in rectangular cans. These cans were fitted with a "key" that would roll down the top of the can. Coffee, beans, and other types of meat were packaged in cylinders with metal strips that could be peeled back with their own kinds of built-in keys. Cans of milk, which didn't need to be completely opened, came with puncture devices. As tinned food became more common, its containers became more regular. A nice cylindrical can became the norm, and, as these cans filled kitchens, more engineers put their minds to finding a convenient way to open all of them. The first standalone can opener worked on a simple principle: point, stab, and pull. From the mid-19th century to the end of World War I, the typical can opener looked roughly like a wrench, if the lower 'jaw' of the wrench were replaced with a blade. People used the blade to puncture the top of the can near its edge, push the upper jaw against the side of the can, and drag the blade through the metal along the rim. Because meat was the first and most popular canned substance, these can openers were often shaped to look like cows and given the nickname 'bully beef can openers'. The bully beef can opener, popular in the mid-19th century, resulted in many lost fingers. Later, a corkscrew was added that was seated in the handle, and could be pulled out for use. Bully beef can openers were so common, effective, and sturdy that they are still frequently available on collectors' sites. Some are advertised as “still working,” and every last one of them is, without a doubt, soaked in the blood of our ancestors. Dragging a sharp blade along the edge of a can is certain to cause injury sooner or later. So once people got a reliable can shape and a reliable way to get the can open, the search was on for a reliable way to get a can open without the possibility of losing a finger. The answer came in 1925, from the Star Can Opener Company of San Francisco. This is probably the first can opener that resembles the one people have in their kitchens today. Instead of using a blade to pry open a metal can, buyers could clamp the edge of the can between two wheels and twist the handle of one of the wheels to move the blade around the lip. The Star can openers weren't perfect. Compared to the bully beef model, they were flimsy and breakable, but they probably prevented a few injuries. Six short years after the Star model came to market, the first electric can opener was invented. It was patented in 1931 by the Bunker Clancey Company of Kansas City, who had already been sued by the Star Can Opener Company for trying sell a double-wheeled can opener like the Star model (the case was dismissed). The electric can opener must have seemed like the wave of the future and a sure-fire seller, but it proved to be too far ahead of its time. In 1931 not that many households had electricity, and those that did weren't interested in buying can openers. The Bunker Clancey Company was subsequently bought by the Rival Company, which still makes small appliances like can openers today. It took another 25 years for electrically powered can openers to become practical. In the 1950s, Walter Hess Bodle and his daughter, Elizabeth Bodle, developed an electric can opener in the family garage. Walter came up with the opener's blades and motor, and Elizabeth sculpted the outside. Their can opener was a free-standing unit that could sit on the kitchen counter. The Udico brand of the Union Die Casting Company put it on the market in time for Christmas in 1956 and had great success with it. Over the next few years it came out in different styles and colours, and, like the bully beef can opener, has become a collector's item. Also like the bully beef model, Udico can openers often still work. They don't make 'em like they used to. Although there have been some design changes and refinements over the last sixty years, there have yet to be any more leaps forward in can opener technology. If you're resentfully opening a can, you are almost certainly doing it using the Star design, manually forcing the can between two wheels, or the Bodle design, clamping the can into a free-standing electrical opener. Whether or not you enjoy your holiday meals, at least you can be happy that you are not getting poisoned by your own food or cutting open your hand with the blade you use to get at it. That's something, right?The can opener, Bottle opener and the corkscrew are still very important and essential items in most kitchens.Metal can opener, chromed, with bottle opener, and a corkscrew seated in the handle.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, canning, can opener, corkscrew, bottle opener, kitchen equipment

It took 15 years to invent the can. It took 100 more to invent a standard way to open it. In the 19th century, decades after the invention of canning, there were virtually no can openers. Canned food, such as sardines, came with its own "key" to peel back the tin lid. Birth of the can One of the oddest things about the can opener is that the can predates it by almost 150 years. Though common today, cans were once military-grade technology. In 1795, Napoleon, to whom the phrase "an army marches on its stomach" is attributed, offered 12,000 francs to anyone who could find a way to preserve food. Without any knowledge of bacteria or their role in food spoilage, scientists didn't even know where to begin. It took 15 years before a chef named Nicholas Appert claimed the prize after successfully jarring food. Soon after that, his countryman Philippe de Girard came up with a variant on Appert's method—metal tins—and sold the idea to the British. Spoiled food, and the sickness it caused, was a widespread problem. The public would have benefited from canned food, but for decades cans were almost exclusively for the army and the navy. The canning process, with its hours of boiling and steaming, its scrupulous cleanliness, its heated metal, and its need for a great deal of disposable material, made canned food far too expensive for anyone but the military. No can openers were needed or even possible. The metal of early cans was too thick to make openers practical. Soldiers and sailors had plenty of sharp objects on hand and made ample use of them when they wanted to eat. During the 19th century, the process of canning was refined and mechanised, and the metal wall of the average can slimmed down enough that a civilian could get it open—if that civilian had the right tool. No one had that tool yet, so early cans had to open themselves. In other words, they came with built-in openers. The result was a confusing but pleasing free-for-all, in terms of product engineering. Each type of food came with its own kind of can, and each kind of can came with its own kind of opener. Tinned fish and meat were often sold in rectangular cans. These cans were fitted with a "key" that would roll down the top of the can. Coffee, beans, and other types of meat were packaged in cylinders with metal strips that could be peeled back with their own kinds of built-in keys. Cans of milk, which didn't need to be completely opened, came with puncture devices. As tinned food became more common, its containers became more regular. A nice cylindrical can became the norm, and, as these cans filled kitchens, more engineers put their minds to finding a convenient way to open all of them. The first standalone can opener worked on a simple principle: point, stab, and pull. From the mid-19th century to the end of World War I, the typical can opener looked roughly like a wrench, if the lower 'jaw' of the wrench were replaced with a blade. People used the blade to puncture the top of the can near its edge, push the upper jaw against the side of the can, and drag the blade through the metal along the rim. Because meat was the first and most popular canned substance, these can openers were often shaped to look like cows and given the nickname 'bully beef can openers'. The bully beef can opener, popular in the mid-19th century, resulted in many lost fingers. Bully beef can openers were so common, effective, and sturdy that they are still frequently available on collectors' sites. Some are advertised as “still working,” and every last one of them is, without a doubt, soaked in the blood of our ancestors. Dragging a sharp blade along the edge of a can is certain to cause injury sooner or later. So once people got a reliable can shape and a reliable way to get the can open, the search was on for a reliable way to get a can open without the possibility of losing a finger. The answer came in 1925, from the Star Can Opener Company of San Francisco. This is probably the first can opener that resembles the one people have in their kitchens today. Instead of using a blade to pry open a metal can, buyers could clamp the edge of the can between two wheels and twist the handle of one of the wheels to move the blade around the lip. The Star can openers weren't perfect. Compared to the bully beef model, they were flimsy and breakable, but they probably prevented a few injuries. Six short years after the Star model came to market, the first electric can opener was invented. It was patented in 1931 by the Bunker Clancey Company of Kansas City, who had already been sued by the Star Can Opener Company for trying sell a double-wheeled can opener like the Star model (the case was dismissed). The electric can opener must have seemed like the wave of the future and a sure-fire seller, but it proved to be too far ahead of its time. In 1931 not that many households had electricity, and those that did weren't interested in buying can openers. The Bunker Clancey Company was subsequently bought by the Rival Company, which still makes small appliances like can openers today. It took another 25 years for electrically powered can openers to become practical. In the 1950s, Walter Hess Bodle and his daughter, Elizabeth Bodle, developed an electric can opener in the family garage. Walter came up with the opener's blades and motor, and Elizabeth sculpted the outside. Their can opener was a free-standing unit that could sit on the kitchen counter. The Udico brand of the Union Die Casting Company put it on the market in time for Christmas in 1956 and had great success with it. Over the next few years it came out in different styles and colours, and, like the bully beef can opener, has become a collector's item. Also like the bully beef model, Udico can openers often still work. They don't make 'em like they used to. Although there have been some design changes and refinements over the last sixty years, there have yet to be any more leaps forward in can opener technology. If you're resentfully opening a can, you are almost certainly doing it using the Star design, manually forcing the can between two wheels, or the Bodle design, clamping the can into a free-standing electrical opener. Whether or not you enjoy your holiday meals, at least you can be happy that you are not getting poisoned by your own food or cutting open your hand with the blade you use to get at it. That's something, right?The can opener is still a very important and essential item in most kitchens.Can opener, right handed, metal, upper blade section serrated, inscription 'Peerless Pat.Feb 11-90'.Peerless Pat.Feb 11-90flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, cannning, can opener, kitchen equipment

Stevenson screens were first introduced in Australia in the 1880s and were widely installed by 1910. The screens have been used to shelter and protect thermometers and other meteorological instruments from rain and direct heat while the holes and double-louvre walls allowed air to flow around them. Sometimes other meteorological instruments were included in the weather stations, so there were different Stevenson Screen sizes. This authentic, original Stevenson screen was previously owned by the Australian Bureau of Meteorology and was used for many years for weather readings at the Cape Otway Light Station in southwest Victoria. The Lighthouse Keepers recorded the readings for minimum and maximum temperatures at 9 a.m. every day from January 1865 until April 1994. The equipment was sheltered in a Stevenson Screen from 1902 until April 15 1994, when the mercury thermometer was replaced by a platinum resistance probe within an Automatic Weather Station (AWS). This Stevenson screen is one of the two screens that then became redundant. The other Stevenson screen was kept to display to visitors. Lightkeepers were no longer required at the Cape Otway Light station either, due to the automated system. The meteorological instruments donated with the screen were used for measuring temperature and humidity. They are mounted on a metal bracket that fits across the screw holes on the screen’s internal frame. The glass-covered Relative Humidity (RH) sensor was made by the renowned precision instrument maker, Rotronic AG of Switzerland, which was founded in 1965. The firm made its first electronic temperature and humidity instrument in 1967. Meteorological records have been collected in Australia from the 1800s. The records were collated, published and used as a basis for weather forecasts. Many sectors, such as maritime and agriculture industries, have relied on these figures for making important decisions. The quality and placement of the meteorological instruments used to measure temperature and humidity are of utmost importance for accuracy. In early colonial times, there were no national standards for meteorological instruments that would allow for accurate figures and comparisons. Once the Bureau of Meteorology was established (around 1908 to 1910) the department installed Stevenson screens throughout Australia, many at lighthouses and light stations, and the measuring instruments were standardised. The Stevenson Screen was named after its inventor, Scottish Civil Engineer Thomas Stevenson (1818-1887) who was also the father of Robert Louis Stevenson, author. Stevenson developed the small thermometer screen around 1867. It had double-louvred walls around the sides and a top of two asbestos sheets with an air space between them and was thickly painted with a white coating that reflected the sun’s rays. This design was modified in 1884 by Edward Mawley of the Royal Meteorological Society. Standards were set for the locations of the screens and instruments, including their distance above ground level and the direction the door faced.Stevenson screens played a significant part in providing a standardised shelter for all meteorological instruments used by the Australian Bureau of Meteorology from about 1910 until 1994. The readings from the instruments gave the meteorological statistics on which weather forecasts throughout Australia were based. This Stevenson screen was used locally at Cape Otway, along the Great Ocean Road in southwest Victoria, so contributed towards our local forecasts and weather warnings.Stevenson screen, original, from the Australian Bureau of Meteorology’s weather station at the Cape Otway Lighthouse. The screen is a white wooden cupboard with a slanted cover raised above the top. The top has ten drilled ventilation holes, and the sides and door are made of downward-slanting double louvres. Two brass hinges join the door to the lower edge of the screen and a metal fitting at the top edge allows for a padlock closure. The screen is supported on four short legs, each with a hole drilled from side to side for fitting to a frame. Inside the screen are two wooden frames fitted with hooks and screws. The floor has three boards; one across the back and one across the front at the same level, and a board wider than the space between these boards is fitted higher, overlapping them slightly. Inside the screen, a pair of electronic instruments with short electric cables is mounted on a metal bracket with drilled holes in it. One of the instruments is a Relative Humidity (RH) probe. It is 26 cm long and is a glass tube with a filter on one end and an electrical connection on the other. It has inscriptions on its label, showing that was made by Rotronic AG, Switzerland. The other instrument is a Resistance Temperature Device (RTD) thermometer. It is 22.5 cm long and has a narrow metal probe joined to a hexagonal metal fitting. A brass plate on the front of the screen has impressed inscriptions. The screen is Serial Number 01/C0032, Catalogue Number 235862.Stamped into brass plate "CAT. NO. / 253862 / SERIAL NO. 01/C0032" On instrument’s electrical fitting; “CD2” [within oval ‘+’ above S] “Serie693 op65 / 220/380V~16A” On instrument’s glass; “rotronic ag” “SWISS MADE” “CE / CH-8303 / Bassersdorf” Symbol for [BARCODE] “ART NO MP 101A_T4-W4W” “POWER 4.8.30VDC“ “OP. RANGE: 0-100%RH/-40+60° C” “OUT H 0-100% 0-1V” “OUT T -40+60°C -0.4..+0.6V” “SERIE NO 19522 009”flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, cotton region shelter, instrument shelter, thermometer shelter, thermoscreen, thermometer screen, measuring instruments, meteorological instrument, weather recording, weather station, lighthouse equipment, light station equipment, stevenson screen, marine instruments, mercury thermometer, platinum resistance probe, aws, automatic weather station, rotronic ag, swiss made, meteorological device, weather forecast, weather prediction, weather records, meteorological forecast, meteorological record, australian bureau of meteorology, bureau of meteorology, bureau, bom, relative humidity, rh, relative humidity probe, resistance temperature device, rtd, thermometer, temperature, humidity, cape otway, cape otway lighthouse, cape otway light station, rotronic, switzerland, swiss instrument, thomas stevenson, double-louvered walls, edward mawley, royal meteorological society, 01/c0032, serial number, cat. no. 235862, serial no. 01/c00323

The Logic Analyser was purchased by the Ballarat College of Advanced Education Physics Department in the early 1980s. At the time it was a state of the art piece of test equipment used for fault finding and programming diagnostics for 8 bit computers. It was later used by the Electrical Engineers, after Physics merged with Engineering in the mid 1990s. The device monitored the 16 bit Address buss and 8 bit Data buss of an 8 bit computer. This device continually samples the 24 bits simultaneously and looks for a preset pattern. When the pattern is matched the logic analyser continues for a set number of steps thus allowing an operator to examine the data and address information both leading up to and after an event. This was particularly useful for diagnosing unusual programming and hardware errors. Logic analyzers are used in debugging and troubleshooting in mini- and microcomputers. The HP analyzers collect information through 24 (1615A) or 32 (1610B) inputs leads, connected to the computer's address, data and/or control lines. The logic state flow is shown on a display in a number of traces, a single data line or an appropriate combination of data lines providing a trigger signal. Captured data can be stored for detailed analysis. (http://http://www.science.uva.nl/museum/hp1610.php)Grey Analog computer. Includes keys and small screen.computer, logic analyzer, physics

Small rectangle box (cigar box), with wooden roll, covered in copper wire,brass bar, with wooden peg which meets copper wire on roll, 2 metal pegs on outside of box, which could attach to power leads (could be crystal set) or something to do with early morse code transmission. There is a lever that can be disconnected from an electrical force, that could produce a morse code"EARTH" & "ARIEL" hand carved on one end "PHONES" (hard to decifier) on other endballarat, radio, inventions, inventor, ariel, crystal set, electricity, electronics

X-Rays were first discovered on 08 November 1895. By 18 July 1896 staff members of the Ballarat School of Mines (SMB), were experimenting with the exciting new discovery. The history of x-rays began on 08 November 1895 at the University of Wurzburg in Bavaria. The discovery was officially announced on 25 December 1895. The first radiographs in Ballarat were taken at the School of Mines in July 1896 according to the Ballarat School of Mines (SMB) Annual Report. Frederick J. Martell, the Registrar of SMB arranged for the importation of tubes, while John M. Sutherland, an electrician, conducted most of the experiments giving 6 inch, 12 inch and 16 inch sparks respectively. In a short time brilliantly successful results were obtained, with some SMB Roentgen negatives taken at this time still in existence today. Samuel Ernest Figgis, H. R. W. Murphy, D. McDougall, and Frederick J. Martell carried out experiments at the SMB on Saturday evening 18 July 1896, producing 'perfect' negatives of a hand and wrist. A Roentgen Tube and an induction coil giving a two inch spark, the coil being sparked by the SMB's dynamo, were used to obtain these results. The Courier reported that 'the exposure of five minutes was ample' but concluded that 'the length of the exposure will be shortened as experiments proceed.' The Ballarat Courier reported on 20 July 1896 that: "Thanks to the energy of the staff of The School of Mines, Ballarat, and particularly to Messers F.J. Martell and D. McDougall, the assistance of Rontgen X-rays will soon be available, for the relief of suffering humanity, at this institution." Martell was an ardent amateur photographer, and Duncan McDougall's experience as an electrician has enabled the two gentlemen to carry their experiments on to a perfectly successful issue. At first these gentlemen, together with Professor Purdie and Mr W. Huey Steele, conducted a series of experiments by the aid of a Bonetti glass-plate induction machine which had been constructed by Mr McDougall. The results were very good, the various bones of the hand being distinctly visible. The following people were among those who witnessed the first X-ray experiments to be carried out in Ballarat. Andrew Anderson, President of the School of Mines, a large number of ladies and gentlemen, the medical profession Dr Edward Champion (1867-1929) Dr Gerald Eugene Cussen (1888-1943) Dr William Edward Davies (1868-1928) Dr Charles William Henry hardy (1861-1941) Dr Edward Kenneth Herring(1864-1922) Dr Joseph Lalor (1859-1907) Dr James Thomas Mitchell (1856-1945) Dr Edward Graham Ochiltree (1857-1896) Dr Robert Denham Pinnock (1849-1902) Dr Joseph Francis Usher (c1832-1909) Dr Grace Vale (nk-1933). The staff of SMB Professor Alfred Mica Smith Professor D. J. Dawbarn Mr. F. J. Martell. (http://guerin.ballarat.edu.au/aasp/is/library/collections/art_history/honour-roll/honourroll_X-Ray_pioneers.shtml) "Seven patients of the doctors who were present were treated. In each case the patient was suffering from the effects of an old wound or some other injury to other a hand or foot. One patient, a boy had a finger broken some years earlier and when xray plate of the injury was developed it indicated plainly the fracture on one of the joints of the third finger. In another case a woman had a foot had a foot X-rayed and the photograph revealed the seat of an earlier imjury to it. Likewise an injury to the bones of a hand of an elderly man was revealed by an x-ray photograph. Every X-ray photograph that evening showed the importance of this new development in electrical science and the doctors present agreed the "the results of the experiments on their patients, by showing the exact seat of the injury and its present condittion, would materially assist them iin supporting cures." (Warren Perry, The Ballarat School of Mines and Industries Ballarat, p 146.)A number of photographic xrays as taken by the Ballarat School of Mines in 1896. The xrays include bones, hands, feet, shoes and more. ballarat school of mines, scientific equipment, x-ray, xray, photography, foto, roentgen tube

In 1911 R. Maddern was President of the Ballarat School of Mines. Contents of this booklet are: Asssociateship, Calendar, Certificate Courses, Departmental Regulations, Discipline, Discipline Board, Examination Results, Fees, Full Certificates Issued, General Regulations, Introduction, Junior Technical School, Officer Bearers, Professors and Lecturers, Subjects of Instruction - Department of Chemistry and Metallurgy, Geological Department, Engineering Department, Electrical Engineering Department, Department of Mathematics and Physics, Practical, Plane and Solid Geometry, Photography, Subscriptions and Donations 1910. Plan of Buildings and Grounds Engineers with qualifications from the Ballarat School of Mines were sought by mines throughout the world. Blue soft covered book of 64 pages titled the Ballarat School of Mines Calendar. The book includes images of the Engineering Room, the Maddern Roasting Furnace, Museum, Junior Chemical Laboratory, Plan of Buildings and Ground, Chemical Laboratory, Concentration Floor, Linkenbach Table, Engineering Laboratory, Experimental Steam Engine, Chemical Lecture Room, Physics Instruction Room, Newtonian Telescopy, Ballarat Observatory, Instructor's Laoratory, Wilfrey Table, Chlorination plant, Cyanide House and R. Maddern. ballarat school of mines, scientific equipment, engineering, classroom, desks, gas lighting, calendar, r. maddern, j. m. bickett, w. h. middleton, j. d. woolcott, w. nixon, daniel. walker, fred j. martell, professor a. mica smith, hubert r. murphy, charles a. deane, arthur garrard, professor t. s. hart, professor a. d. gilchrist, a. e. c. kerr, j. brittain, e. j. a. mcconnon, john m. sutherland, bertram whitington, h. j. hall, e. gutheil, charles campbell, t. williams, d. e. mullins, sir redmond barry, judge rogers, r. m. sergeant, thomas bath, andrew anderson, general regulations, discipline, discipline board, associateship and final certificates, mining engineering, metallurgy, geology, electrical engineering, certificate courses, junior technical school, fees, subjects of instruction, chemistry, geological department, engineering department, electrical engineering department, department of mathematics and physics, practical, plane and solid geometry, photography, full certificates issued, supplementary examination results - may 1910, supplementary examination results - april 1908, subscriptions and donations 1910

A Crookes tube is an early experimental electrical discharge tube, invented by English physicist William Crookes and others around 1869-1875, in which cathode rays, streams of electrons, were discovered. Wilhelm Röntgen discovered X-rays using the Crookes tube in 1895. The term is also used for the first generation, cold cathode X-ray tubes, which evolved from the experimental Crookes tubes and were used until about 1920.(http://en.wikipedia.org/wiki/Crookes_tube)Glass vacuum tube with a metal maltese cross inside. The tube is on a timber stand.scientific instruments, crookes tube, science, maltese cross, scientific objects

During the 1890s the Ballarat School of Mines started teaching photography.Handwritten invoice on printed letterhead. The invoice was for chemicals and apparatus for the Ballarat School of Mines, including items for the Chemical Laboratory, Photography Laboratory, Electrical Laboratory and Cyanide.walter cornell, ballarat school of mines, laboratory, chemist, pharmacy, photography electricity, photographic equipment

A flare, also sometimes called a fusee, is a type of pyrotechnic that produces a bright light or intense heat without an explosion. Flares are used for distress signalling, illumination, communication or defensive countermeasures in civilian and military applications. Flares may be ground pyrotechnics, projectile pyrotechnics, or parachute-suspended to provide maximum illumination time over a large area. Projectile pyrotechnics may be dropped from aircraft, fired from rocket or artillery, or deployed by flare guns or hand held percussive tubes. Signalling flares have been in use by all branches of the military services since the 1920s also by the maritime services to signal other ships or for distress purposes. The earliest recorded use of gunpowder for signalling purposes was the 'signal bomb' used by the Chinese Song Dynasty as the Mongol-led Yuan Dynasty besieged Yangzhou in 1276. These soft-shelled bombs, timed to explode in mid-air, were used to send messages to a detachment of troops far in the distance. Another mention of the signal bomb appears in a text dating from 1293 requesting their collection from those still stored in Zhejiang. A signal gun appears in Korea by 1600. The (Wu I Thu Phu Thung Chih or Illustrated Military Encyclopedia) written in 1791 depicts a signal gun in an illustration. The item was used to carry and store flares for signalling use as the inscription on the canvas cover suggests. Given the method of storing flares is in a wicker basket that is non conducting of an electrical charge that may accidentally set of explosive materials. The writer assumes the basket was used from the early 20th century and most likely by maritime or military services to store it's flares.Basket cane square with metal locks & rope handles each end. Canvas reinforced on vertical sides with a canvas cover on top. Canvas cover has leather straps. Stencilled on canvas in white paint "SIGNALLING STORES" flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, basket, cane basket, signalling stores

In 1832 William McGeoch & Co., Ltd was established, by William McGeoch senior at 113 Argyle St Glasgow as hardware merchants and exporters, and later were manufacturers of lamps and electrical fittings for ship, railway and domestic use. In the 1900s the company had expanded and had offices at 28 West Campbell Street Glasgow with a factory and warehouse located at the Warwick Works, 46 Coventry Rd, Birmingham. In 1922 the company had expanded and were employing 400 to 500 people. William seniors three sons had joined their father in establishing the business around 1888. The business was run by William McGeoch senior with Williams three sons Alexander, William and Andrew also taking an active part in the day to day running of the company. The company had expanded to such a degree that they were now manufacturing a variety of ships' hardware. This included metal cabin furnishings, signal lamps, ships' oil and candle lamps, motor lamps, switches, switchboards, electrical accessories and fittings. In 1982 William McGeoch & Co., Ltd was acquired by Bowthorpe Holdings Ltd.A lamp made by a significant manufacturer of marine equipment that made fittings for many famous ships including the Titanic.Marine oil Lamp with glass panels. Front panel missing. Access through glass panel door at side flat metal back. Metal fuel reservoir and no burner. Metal rounded chimney on top. Embossed McGeogh Maker Glasgowwarrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, lamp, ships lamp, wm mc geoch ltd, hardware merchants, ships outfitters

Kempthorne Lighting Pty. was established as Coffey Lanterns in East Malvern, Melbourne Victoria in 1931 by brothers Selwyn and Owen Coffey. They manufactured lighting fixtures and fittings including oil lamps for marine use as well as for the domestic market. In early 1936 two other brothers, Erle and Terence had joined the company which was renamed Kempthorne Lantern Works Pty., Ltd. In 1946 Kempthorne joined with a small design team who had developed a domestic fan to form the subsidiary, Mistral fans. The company previously known as Kempthorne Holding Ltd was listed on the stock exchange in 1968. In 1977-1979 Kempthorne Mistral Ltd. Was a holding company comprising of Kempthorne Lighting Pty., Ltd. & Mistral Fans Pty., Ltd. An early Australian made marine lamp by a significant manufacturer that is still in business today making electrical equipment. The item is an important artefact that was made by an early Australian business that started in the 1930s. Over the years this company has demonstrated many innovations to the manufacturer of electrical items. Marine copper Lamp, round with brass makers lozenge and rounded hollow lugs set on either side of the lamp. Heavy metal handle with brass locking pin. Lid with catch on top. Made by Kempthorne Pty Ltd Melb. 1941flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, lamp, copper ship lamp, ship lamp, kempthorne pty ltd

he subject item is a pedal-powered rip saw with a tilting table made in the USA by W.F. & John Barnes Co. of Rockford, Illinois, between 1874 and 1890. The saw's blade moves rapidly in a circular motion and is driven by a pedal that spins a heavy flywheel with a leather belt attached to a gear drive that in turn drives the circular saw blade. The operator holds a wood workpiece on the table and moves it forward so the blade cuts it to the desired width and length. Company History: WF & John Barnes Co. was established in 1869, by making a formal partnership between William F. Barnes and John Barnes in 1872, and then incorporating in 1884. This company was an early manufacturer of pedal-powered equipment. By 1881 they were also making powered machinery such as lathes and pedestal drills. Many companies were making lightweight foot-powered equipment, but Barnes and the Seneca Falls Co. were the only ones to also make professional-grade workshop machines. From the beginning of their existence, they focused on pedal-powered machinery and specialised in making scroll saws. By 1937 the company focus had completely shifted to automotive assembly machinery, and custom-built machinery, machine tools, electrical, hydraulic, and mechanical controls and systems, including nuclear hardware. their production of foot-powered machinery had ceased. In the intervening years, they have got out of manufacturing completely. After a series of ownership changes, their equipment parts and stock were purchased in 1998 by LeBlond Ltd. of Amelia, Ohio. An item that although incomplete gives a snapshot into the manufacture and use of early woodworking machinery before the introduction of electricity or electric motors to power machines.A Treadle powered tilting table saw benchWF & J Barnes, Rockford Ill USA flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village

Used in the Ballarat School of Mines Electrical Engineering from around 1930-1936.Round glass fronted brass dial mouned on timber stand. Postive and negative terminals below dial. Simi-circular scale, non-linear graduations: 40-80 voltsvoltmeter, scientific instrument, ballarat school of mnes, arthur senior, nalder brothers

The Universal Acoustic Coupler was made and would have been used to connect a telephone to dial a computer remotely. The control panel is under the wooden flap. There is a power switch, full duplex switch, 500 Ma Fuse, CCITT Port. When not in use it can be folded up into a small timber carry case with handle.Wooden box with two sections that open. Top section hinged and folds back. inside are controls and cables for connecting to a computer. Instructions for use are on the lid. Front section has clips and folds down to a phone to placed in "speakers". English maker's plate and Melbourne supplier's plate with A.P.O. Permit No. C74/8/903 Serial No. 775326 moore reed, universal acoustic coupler, telephone, remote connection, computer connection

Used to teach physics students - introduction to principles of electric powerA teaching / demonstration model with large scale and transparent panels. Polished wood frameBlack tape on front panel - "PHYSICS"scientific instrument, physics, electric power, voltmeter, ammeter

Scales such as the subject item were used in a domestic situation. Salter has been a name long associated with weights and measures especially in the home kitchen. The firm began life in the late 1760s in the village of Bilston, England when Richard Salter, a spring maker, began making the first spring scales in Britain. He called these scales "pocket steelyards", though they work on a different principle from steelyard balances. By 1825 his nephew George had taken over the company, which became known as George Salter & Co. George later established a manufacturing site in the town of West Bromwich, about 4 miles (7 km) from Bilston. West Bromwich Albion football club was formed from workers at this works site. From here the company produced a wide variety of scales including the UK's first bathroom scales. Other items were added to the range, including irons, mincers, potato chippers, coin-operated machines and the first typewriters made in the UK. The business thrived throughout the 1900s, and by 1950 it employed over 2000 people, still in the same area and owned by the same family.Salter is a British housewares brand developing products that span a wide range of core product categories, including scales, electrical, cookware. It is a market leader in kitchen and bathroom scales and one of the UK’s oldest consumer brands.  Established in 1760, Salter has been developing precision products for over 260 years. It was acquired by Manchester-based consumer goods giant Ultimate Products in 2021 after they had previously licensed the brand for cookware and kitchen electrical since 2011."Scale Salter's Spring Balance brass cylinder with ring at one end and a hook at the otherSalter trademark stamped on front. Made in England stamped on back. Weighs 0 to 4LBS showing ¼lb increments.flagstaff hill, warrnambool, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, salter balance scale, weight measuring scale, weighing dry goods, domestic object, kitchen scale