A cigarette lighter is a portable device used to generate a flame. It consists of a metal or plastic container filled with a flammable fluid or pressurized liquid gas, a means of ignition, and some provision for extinguishing the flame. A spark is created by striking metal against a flint, or by pressing a button that compresses a piezoelectric crystal (piezo ignition), generating an electric arc. In naphtha lighters, the liquid is sufficiently volatile, and flammable vapour is present as soon as the top of the lighter is opened. Butane lighters combine the striking action with the opening of the valve to release gas. The spark ignites the flammable gas causing a flame to come out of the lighter which continues until the top is closed (naphtha type), The Beney Company was founded by Robert Ernest Beney of London, England. R. E. Beney invented and marketed the first Beney mechanical lighter in 1919. Beney also designed and manufactured numerous luxury lighters and striker boxes for Alfred Dunhill of London as well as Hermes of Paris. In 1938, Beckenham based Beney Lighters was acquired, adding utility lighters and precision tools to the company's (Winn & Coates) ever growing list of products. The biggest selling line manufactured by Beney was the Economic Gas Lighter which hung on the side of housewife's gas cookers and was also used for lighting Bunsen burners in laboratories. In 1939-1940 the company moved its administration to the Beney Lighter premises in Beckenham after the Head Office at Trinity Square along with many company records were destroyed in a 'doodlebug' flying bomb attack. Beney Ltd. continued producing lighters at least through the late 1954. A green metal cigarette lighter that used fuel and a striking action arm to produce a flame .base: BENEY / COMPANION / PATENT 568897 / BRITISH MADEtobacco, cigarettes, cigarette lighters, fuels, moorabbin, cheltenham, bentleigh, early settlers, beney pty ltd, beckenham england

Program for the Kalianna School Debutante Ball held on Friday 3rd August 2007 at the Weerona Secondary College. Program is light grey with a purple sticker on an angle with the name on it. On white paper on the inside is the names of the debutantes and their partners and who they were presented to, Master of Ceremonies & Deb Set Co-ordinator, Chaperones, Compares, Music by Emu Creek Band, Flower Girl and Page Boy. Pasted on the back is a matching grey card thanking businesses and people who helped. Names are: Cr Kevin Gibbons, Debbie Gibbons, Lindy & William Lupo, Alison & Geoff Byron, Leon Scott, Debbie Price, Peter Burch, Cherryl Fyffe, Leon Scott, Emu Creek Band, Rebecca Nelson, Caleb Richardson, Charmaine Scown, Alicia Owen, Jessica Brereton, Nikita Riordan, Laura Semmens, Rebecca Apps, Chloe Gruber, Lauren Hawken, Amanda Anderson, Victoria Jelbart, Rachell Sutherland, Amy Roberts, Sally McMurtrie, Chevonne Strauch, Ben Holmes, Dean Snelson, Zac Flint, Tamati Poindestre, Brandon Kelly, Paul Drinkell, Adrian Brown, Chris Oojges, David Boyce, Josh Rosewall, Michael Semmens, John Wiktorek, Kane Wojcicki, Matthew Mitchell, Hairem Scarem, Grant Rule Menswear, Sean Walsh Photography, Mary Smith (Plant Exhibits), Anne Hastings (Deb Ball Seamstress), Debbie Price, Tracey Wojcicki, Glenys Jelbart, Pam Holmes, Rae Hall, Samantha Wearne, Kylie Salter, Cathy Brew, Judy Richards, Aileen Gilbee, Marie Loch, Noel & Lorna Thomas, Ron & Janette Moss, Tracey & Peter Wojcicki, Val & Neil Cartledge, Warwick Strauch, Kevin Salter, Grant King, Kay Tamblyn and Christine Smith.Weerona Secondary Collegeentertainment, dance, ball, peter ellis collection, kalianna school, weerona secondary college, cr kevin gibbons, debbie gibbons, lindy & william lupo, alison & geoff byron, leon scott, debbie price, peter burch, cherryl fyffe, leon scott, emu creek band, rebecca nelson, caleb richardson, charmaine scown, alicia owen, jessica brereton, nikita riordan, laura semmens, rebecca apps, chloe gruber, lauren hawken, amanda anderson, victoria jelbart, rachell sutherland, amy roberts, sally mcmurtrie, chevonne strauch, ben holmes, dean snelson, zac flint, tamati poindestre, brandon kelly, paul drinkell, adrian brown, chris oojges, david boyce, josh rosewall, michael semmens, john wiktorek, kane wojcicki, matthew mitchell, hairem scarem, grant rule menswear, sean walsh photography, mary smith (plant exhibits), anne hastings (deb ball seamstress), debbie price, tracey wojcicki, glenys jelbart, pam holmes, rae hall, samantha wearne, kylie salter, cathy brew, judy richards, aileen gilbee, marie loch, noel & lorna thomas, ron & janette moss, tracey & peter wojcicki, val & neil cartledge, warwick strauch, kevin salter, grant king, kay tamblyn, christine smith

Theodore Jesse Hoover, brother of the 31st President of the United States, was born in West Branch, Iowa, on January 28, 1871. He attended Stanford and received the Bachelor of Arts degree in Geology and Mining in 1901. Following graduation his professional career started with the position of assayer for the Keystone Consolidated Mining Company. After one year, he became assistant manager for the Standard Consolidated Mine, and a year later he was promoted to manager of the operation. In 1907 Hoover went to London as general manager of Minerals Separation, Ltd. This company was developing the froth flotation process for recovering minerals from ores. Hoover took an active part in the development of the flotation concentration process and authored one of the first books on the concentration of ores by flotation. After four years with Minerals Separation, Ltd., Hoover entered private practice as a consulting mining and metallurgical engineer with offices in London and in San Francisco. He was very successful and held positions of consulting engineer, managing director, director, and president of many mining companies in America, Europe, Asia, Africa, and Australia. He returned to Stanford in 1919 as Professor of Mining and Metallurgy and Executive Head of the Department of Mining and Metallurgy. His experience and ability in organization made him a natural leader. He was influential in the formation of the School of Engineering at Stanford. The School was formed in 1925 and he was made dean, a position he held until his retirement in 1936. As dean of engineering, he promoted a broad fundamental training program for undergraduate engineering students. Under his guidance, emphasis was placed upon graduate work and he was responsible for developing strong graduate engineering curricula at Stanford. While dean he continued teaching and his course, "The Economics of Mining," developed into a book which was published in 1933. He became interested in the functions of engineers and, with Professor Fish, wrote a book entitled "The Engineering Profession" which was published in 1940 and revised in 1950. In addition to his academic activities he was generous in his hospitality. Faculty and students alike enjoyed the annual field day and barbecue at his Rancho del Oso, near Santa Cruz. He was widely read and had a lively interest in all the things he encountered. He speculated on the antiquity of man and man's early production processes. To verify an idea regarding flint tools, he studied their shapes and became proficient in making arrow heads. He was also interested in wild life, and was one of the founding members of the Cooper Ornithological Society. (http://engineering.stanford.edu/about/bio-hoover)Blue hard covered book of 547 pages including an index. Contents include mine valuation (sampling, ore deposits, ore reserves, financial provisions, sale of mineral product, metal prices, reports) and Mining Organization (Co-operative effort, Mining Companies, Promoting Mining Enterprises, fluctuations of share prices, valuation of mining shares, fakes and fallacies, the mining Engineer and the law) and Mine Management (Organization of staff, mine manager, efficiency, industrial relations, training and discipline, safety).inside cover 'Charles Bacon Mackay School of Mines'.mining, economics, hoover, stanford, mackay school of mines, mackay, bacon

The book was used by Charles Bacon who studied at the University of Nevada in the late 1930s/early 1940s. Bacon worked at Bunker Hill Mines and Kellogg Idaho, before arriving in Australian in 1951. He worked for CN Myers, a company involved with paper converting. CN Myers was a family business (on Charles Bacon's maternal line). The Mackay School of Mines, Nevada was established in 1908. At the time of writing this mook T.J. Hoover was Professor of Mining and Metallurgy and Dean of the School of Engineering at Stanford University. Theodore Jesse Hoover, brother of the 31st President of the United States, was born in West Branch, Iowa, on January 28, 1871. He attended Stanford and received the Bachelor of Arts degree in Geology and Mining in 1901. Following graduation his professional career started with the position of assayer for the Keystone Consolidated Mining Company. After one year, he became assistant manager for the Standard Consolidated Mine, and a year later he was promoted to manager of the operation. In 1907 Hoover went to London as general manager of Minerals Separation, Ltd. This company was developing the froth flotation process for recovering minerals from ores. Hoover took an active part in the development of the flotation concentration process and authored one of the first books on the concentration of ores by flotation. After four years with Minerals Separation, Ltd., Hoover entered private practice as a consulting mining and metallurgical engineer with offices in London and in San Francisco. He was very successful and held positions of consulting engineer, managing director, director, and president of many mining companies in America, Europe, Asia, Africa, and Australia. He returned to Stanford in 1919 as Professor of Mining and Metallurgy and Executive Head of the Department of Mining and Metallurgy. His experience and ability in organization made him a natural leader. He was influential in the formation of the School of Engineering at Stanford. The School was formed in 1925 and he was made dean, a position he held until his retirement in 1936. As dean of engineering, he promoted a broad fundamental training program for undergraduate engineering students. Under his guidance, emphasis was placed upon graduate work and he was responsible for developing strong graduate engineering curricula at Stanford. While dean he continued teaching and his course, "The Economics of Mining," developed into a book which was published in 1933. He became interested in the functions of engineers and, with Professor Fish, wrote a book entitled "The Engineering Profession" which was published in 1940 and revised in 1950. In addition to his academic activities he was generous in his hospitality. Faculty and students alike enjoyed the annual field day and barbecue at his Rancho del Oso, near Santa Cruz. He was widely read and had a lively interest in all the things he encountered. He speculated on the antiquity of man and man's early production processes. To verify an idea regarding flint tools, he studied their shapes and became proficient in making arrow heads. He was also interested in wild life, and was one of the founding members of the Cooper Ornithological Society. (http://engineering.stanford.edu/about/bio-hoover) Blue hard covered book of 547 pages including an index. Contents include mine valuation (sampling, ore deposits, ore reserves, financial provisions, sale of mineral product, metal prices, reports) and Mining Organization (Co-operative effort, Mining Companies, Promoting Mining Enterprises, fluctuations of share prices, valuation of mining shares, fakes and fallacies, the mining Engineer and the law) and Mine Management (Organization of staff, mine manager, efficiency, industrial relations, training and discipline, safety). Inside front cover 'Charles Bacon Mackay School of Mines"charles bacon, mining engineering, metallurgy, university of nevada, mackay school of mines, stanford, bacon, mining, economics, divining, theodore hoover

A magazine with a yellow cover and red print. It contains on the front cover the college motto 'Per Ardua Ad Astra Bendigo' and 'Bendigo College of Advanced Education Teacher Education Graduates 1984.' This magazine contains photos and social notes related to the activities of the students during the year. It also has contributions from Science Majors, Music Majors, Physical Education Majors, Social Science Majors, Maths Majors Art Majors and English Majors. Photos; page (a )in the centre of the magazine - Felicity Tomlinson, Linda Steele, Noelene Stock, Margaret Hawksworth (Madge), Janine Benson, Peter Fleming (Flem), Wendy Hawking, Jenny Soule, Stephen Bolton (Bolthead) and Catriona Webster. Page (b) Jo Monagatti (Mum), Matthew Itter, katy Morris (Crazy Kath), Julie Whitfield, Steve Rogers, Jaylea Mayhew-Stone, Jenni Mandersloot, Jenni Lanyon, Lou Nethersole, Ken Smith, Sharon Scanlan (Scanners) and Dave Douglass. Page (c) Tracy Pollesel (Stretch, Olive Oyl), Terri Anne Haebich, Jo A'Beckett, Carolyn Tavener, Sue Burgess, Donna Walker, Pamela Thorpe, Carolyn Coles, Robyn Proud and Evelyn Kristenson. Page (d) Lex Johnstone, Karen English, Sally Broadbent, Kristen Moore, Valma Bailey, Kerry Watson, Deva Guna, Bernie Conlan, Wendy Hicks, Colleen Maher (Pubes), Diana Sherwood. Page (e) Neville Avery, Sandy Olsen, Jennie Sali, Kate Elder, Carol Bourchier (Snourchier), Jim Chamouris, Sue Opie (Slopes), Lynne Nichols, Debbie Tupper, Anne Hubber (Hubs) and Mary Murphy (Murph). Page (f) Debbie Turvey, Maria Aloizos, Jo Van Heek, Christine Smith, Patricia McCormack, Chris McBain, Fay Stevenson, Barb Salatheil, Corrine McNally, Carol Humbert and Jan Bradley. Page (g) Tricia Wright, Andrew Williams (Big Man, Mad Dog), Roslyn Boys, Kerry Tighe, Debbie Joy Head, Carolyn Thornton, Sue McMurray, Carolyn Uebergang (Banger), Rita Nolen, Jane Mangan, Karen Atkinson and Tracy Kerridge. Page (h) Meredith Walters, Mick Belardinelli, Jackie Smith, Mary Cullen, Jeanine Gitters, Marg Tope (Topey), Don Baker, Karen Weightman (Wackers), Lyn Deary, Stuart Bolt, Annie Koehn and Debbie Flint.bendigo, education, bendigo college of advanced educati, la trobe university bendigo collection, collection, bendigo teachers' college, bendigo, education, teaching, teachers, students, magazines, bendigo college of advanced education, bendigo college of advanced education graduation, tertiary education, students, staff, graduation, graduates, graduands

The discovery of the first telescope in 1608 can be attributed to Hans Lippershey of the Netherlands when he discovers that holding two lenses up some distance apart bring objects closer. He applies for a patent on his invention and this becomes the first documented creation of a telescope. Then in 1668, Newton produces the first successful reflecting telescope using a two-inch diameter concave spherical mirror. This opened the door to magnifying objects millions of times far beyond what could ever be obtained with a lens. It wasn’t until 1729 that Chester Moor Hall develops an achromatic lens (two pieces of glass with different indices of light refraction combined produce a lens that can focus colours to almost an exact point resulting in much sharper images but still with some distortion around the edges of the image. Then in 1729 Scottish instrument maker James Short invents the first parabolic and elliptic, distortion-less mirror ideal for reflecting telescopes. We now come to John Dollond who improves upon the achromatic objective lens by placing a concave flint glass lens between two convex crown glass lenses. This had the effect of improving the image considerably. Makers Information: John Dollond (1707-1761) London England he was a maker of optical and astronomical instruments who developed an achromatic (non-colour distorting) refracting telescope and practical heliometer. A telescope that used a divided lens to measure the Sun’s diameter and the angles between celestial bodies. The son of a Huguenot refugees Dollond learned the family trade of silk weaving. He became proficient in optics and astronomy and in 1752 his eldest son, Peter joined his father in an optical business, in 1753 he introduced the heliometer. In the same year, he also took out a patent on his new lenses. He was elected a fellow of the Royal Society in May 1761 but died suddenly in November and his share in the patent passed to his son Peter. In subsequent squabbles between Peter and the many London opticians who challenged his patent, Peter’s consistent position was that, whatever precedents there may have been to his achromatic lenses, his father had independently reached his practical technique on the basis of his theoretical command of Newtonian optics. As a result of maintaining his fathers patent, Dollond s became the leading manufacturer of optical instruments. For a time in the eighteenth and nineteenth century the word 'Dollond' was almost a generic term for telescope rather like 'Hoover; is to vacuum cleaner. Genuine Dollond telescopes were considered to be amongst the best. Peter Dollond (1731-1820) was the business brain behind the company which he founded in Vine Street, Spitalfields in 1750 and in 1752 moved the business to the Strand London. The Dollonds seem to have made both types of telescopes (reflecting and refracting), possessing the technology to produce significant numbers of lenses free of chromatic aberration for refracting telescopes. A Dollond telescope sailed with Captain Cook in 1769 on his voyage to observe the Transit of Venus. Thomas Jefferson and Admiral Lord Nelson were also customers of the Dollonds. Dollond & Co merged with Aitchison & Co in 1927 to form Dollond & Aitchison, the well-known high street chain of opticians, now fully part of Boots Opticians. They no longer manufacture but are exclusively a retail operation.    John Dollond's experiments in optics and how different combinations of lenses refract light and colour gave a better understanding of the divergent properties of lenses. That went on to inform and pave the way for the improvement of our understanding of optics that are represented today. Dollond was referred to in his time as the "Father of practical optics" as a leader in his field he received many prestigious awards. The telescope in the collection is a good example of one of Dollonds early library telescopes and its connection with one of England's 18th-century pioneers in optical development is in itself a significant and an important item to have within the collection. One tube ships day & Night Telescope brass inner tube with timber main tube covered in leather. Unavailable to inspect Inscriptions to determine authenticity.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, telescope, dolland, shipwreck-coast, flagstaff-hill-maritime-village, royal national life boat institution

This Dollond Day or Nigh telescope was designed to be used in any light conditions, as its name implies. Telescopes are optical instruments designed to make objects appear to be larger or closer. The discovery of the first telescope in 1608 can be attributed to Hans Lippershey of the Netherlands when he discovers that holding two lenses up some distance apart bring objects closer. He applies for a patent on his invention and this becomes the first documented creation of a telescope. Then in 1668, Newton produces the first successful reflecting telescope using a two-inch diameter concave spherical mirror. This opened the door to magnifying objects millions of times far beyond what could ever be obtained with a lens. It wasn’t until 1729 that Chester Moor Hall develops an achromatic lens (two pieces of glass with different indices of light refraction combined produce a lens that can focus colours to almost an exact point resulting in much sharper images but still with some distortion around the edges of the image. Then in 1729 Scottish instrument maker James Short invents the first parabolic and elliptic, distortion-less mirror ideal for reflecting telescopes. We now come to John Dollond who improves upon the achromatic objective lens by placing a concave flint glass lens between two convex crown glass lenses. This had the effect of improving the image considerably. Makers Information: John Dollond (1707-1761) London England he was a maker of optical and astronomical instruments who developed an achromatic (non-colour distorting) refracting telescope and practical heliometer. A telescope that used a divided lens to measure the Sun’s diameter and the angles between celestial bodies. The son of a Huguenot refugees Dollond learned the family trade of silk weaving. He became proficient in optics and astronomy and in 1752 his eldest son, Peter joined his father in an optical business, in 1753 he introduced the heliometer. In the same year, he also took out a patent on his new lenses. He was elected a fellow of the Royal Society in May 1761 but died suddenly in November and his share in the patent passed to his son Peter. In subsequent squabbles between Peter and the many London opticians who challenged his patent, Peter’s consistent position was that, whatever precedents there may have been to his achromatic lenses, his father had independently reached his practical technique on the basis of his theoretical command of Newtonian optics. As a result of maintaining his fathers patent, Dollond s became the leading manufacturer of optical instruments. For a time in the eighteenth and nineteenth century the word 'Dollond' was almost a generic term for telescope rather like 'Hoover; is to vacuum cleaner. Genuine Dollond telescopes were considered to be amongst the best. Peter Dollond (1731-1820) was the business brain behind the company which he founded in Vine Street, Spitalfields in 1750 and in 1752 moved the business to the Strand London. The Dollonds seem to have made both types of telescopes (reflecting and refracting), possessing the technology to produce significant numbers of lenses free of chromatic aberration for refracting telescopes. A Dollond telescope sailed with Captain Cook in 1769 on his voyage to observe the Transit of Venus. Thomas Jefferson and Admiral Lord Nelson were also customers of the Dollonds. Dollond & Co merged with Aitchison & Co in 1927 to form Dollond & Aitchison, the well-known high street chain of opticians, now fully part of Boots Opticians. They no longer manufacture but are exclusively a retail operation.    John Dollond's experiments in optics and how different combinations of lenses refract light and colour gave a better understanding of the divergent properties of lenses. That went on to inform and pave the way for the improvement of our understanding of optics that is represented today. Dollond was referred to in his time as the "Father of practical optics" as a leader in his field he received many prestigious awards. The telescope in the collection is a good example of one of Dollond's early library telescopes. Its connection with one of England's 18th century pioneers in optical development makes it a significant and an important item to have within the collection.Telescope: Dollond's Telescope, Day or Night model navigational instrument. Telescope is mounted on wooden tripod stand that has folding legs. Brass telescope with leather sheath over barrel, adjustable angle fitting with brass wing nuts that join the legs to the top frame, which is then joined to the telescope pole by an adjustable screw fitting. Manufactured by Dollond, London. Inscription reads "Dollond London, Day or Night" and "DOLLOND LONDON"flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, telescope, dollond, dollond london, day & night telescope, floor-standing telescope, optical instrument, john dollond, peter dollond, achromatic telescope, heliometer, light refraction, instrument maker, lens, transit of venus, astronomical telescope, concave lens, library telescope, dollond telescope, day or night, day or night telexcope, scientific instrument, navigation, navigational instrument, astronomy

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

Born in 1911, Cecil Alan Sonsee lived at Springmount near Creswick, and taught natural history at the Ballarat Teachers' College for 30 years. His teaching career stretched over a 48 year period. He spent six years as a student teacher before reaching the position of first class teacher. He had the distinction of never attending a teachers' college, but spending half his teaching career training students to become teachers. At the time of his retirement Mr Sonsee said during his years at the college, "the training had changed from a one year course to a two year course, followed by a three year course, and now a four year course was offered." He recalled "in the early days all country schools had eight grades and a child finished with a merit certificate. Today [1976], children went to high schools from sixth grade and most of the country schools had disappeared.' Alan Sonsee spent 10 years on a television program on BTV6 answering questions sent by viewers regarding aspects of plant and animal live. Mr Sonsee was a life member of both Creswick and Ballarat Field naturalists Clubs. Alan Sonsee died in 1985.1) Foolscap Department of Victoria Ballarat newsletter titled Education 'Regional Views'. The newsletter depicts an image of Alan Sonsee and outlines his career at the time of his retirement on 20 July 1976. The author of the newsletter is unknown. .2) newspaper article on the retirement of Alan Sonsee dated 25 August 1976 (probably from the Ballarat Courier).1) Mr "Nature Man" Retires After a quiet celebration, Mr C.A. Sonsee, a well-known staff member at Ballarat State College, retired from the Victorian Education Department on 20th July, 1976. Alan was the longest serving primary teacher seconded to the State College (Formerly the Ballarat teachers' College), probably the best known and certainly one of the most highly respected educationalists in this region. Leaving Ballarat high School in 1927, he spent the following years teaching at Smeaton, Willowvale, Lawrence (originally called Jerusalem) and Kooroocheang primary schools. However, during the last twenty-nine years, his fame and his influence spread further and further afield. From 1947 to 1976, under a number of principals, Alan endeared himself to thousands of students undergoing their tertiary preparation for teaching. And thousands is the word! Hundreds and hundreds of practising teachers of all ages came to this great teacher again and again for assistance in understanding natural phenomena, a broad field in which he is an acknowledged expert. What undoubtedly made him so accessible to the young and the no-so-young alike was his ready willingness to share with them is rich experience. The warmth of his nature, his kindliness, his dry humour enriched and enlivened the gifts he lavished liberally on all who needed help. Nor did he spare himself in the process. During his ling period of service to teachers, students and some two generations or so of school children, Field Naturalists also, within and well beyond Ballarat, profited from his participation and guidance. A car trip from Ballarat to Lancefield was made unforgettable by Alan's running and lively commentary; the time spent with him viewing and fossicking in an aboriginal flint area is still vivid, thouhg many moons have waxed and waned since then. And who can ever forget his palcid, home;y handling of "Mr nature Man" programmes on BTV 6 for over ten years? his name became a hose-hold word over an existence viewing area in Western Victoria - as his mail bag showed. Mr T. Turner was closely associated with C.A.S. for some twenty-three years as colleague and college principal. Recently tome said, "Alan was highly esteemed by staff and students, When I saw him lecturing I would be struck by the depth and breadth of his knowledge, and by the smooth, almost deceptively simple way he shared what he knew with others. I remember, too, his consideration for the views and the feelings of others; for the tolerance and range of his understanding of human nature. But, above all else, I remember him as a friend." All who know him in any way at all will want to say, "Thanks you, Alan, for everything you did for us. Thank you, Alan for what you are."alan sonsee, ballarat teachers' college, ballarat state college, education, teaching, ballarat field naturalists, creswick field naturalists, aborigines, lancefield flint, smeaton primary school, willowvale primary school, lawrence primary school, jerusalum primary school, kooroocheang primary school, nature studies, mr nature man

North bound lane closure. Born Digitalbolton street, bolton street upgrade, eltham, streets, flint street

ill, maps, p.32.non-fictionA short history of 3'6" sugar cane railway from the Fairymead sugar mill and the Isis branch line in the Bundaberg area of Queensland. Based on the 1948-1956 experience of QR Driver G.C.Rose.sugar tramways - australia - history, narrow gauge railroads - australia - history

ill, maps, p.140.non-fictionA history of dieselizing the sugar can tramways of Queenslandsugar tramways - australia - history, narrow gauge railroads - australia - history

ill, maps, p.123.non-fictionA history of dieselizing the sugar can tramways of Queenslandsugar tramways - australia - history, narrow gauge railroads - australia - history

ill, maps, p.131.non-fictionA history of dieselizing the sugar can tramways of Queenslandsugar tramways - australia - history, narrow gauge railroads - australia - history

ill, maps, p.135.non-fictionA history of dieselizing the sugar can tramways of Queenslandsugar tramways - australia - history, narrow gauge railroads - australia - history

index, ill, maps, p.210.non-fictionA list of the steam and diesel locomotives that worked on the narrow gauge Fairymead sugar mill railways near Bundaberg in Queensland between 1882 & 2004.sugar tramways - queensland - history, industrial railroads - australia - history