X48 entered service in 1977 (Wikipedia https://en.wikipedia.org/wiki/Victorian_Railways_X_class_(diesel)) Train of Knowledge https://en.wikipedia.org/wiki/Train_of_Knowledge The Train of Knowledge was an Australian school camp on wheels, allowing students and teachers to visit multiple locations around Victoria without having to organise accommodation or transport. The train was formed originally with whatever rolling stock was available, but within a few years it had settled to a standard consist made up to carry between 80 and 90 school children, 6 teachers and four railway staff members. As of 1976, the consist used up to five of the six available E type sleeping cars, each with 20 berths, plus the shower car Carey, formerly a horsebox, Melville, a former royal carriage used to provide power for lighting, heating and cooking, 43BPL (a former sitting carriage) used as a classroom, and Avoca as the dining car for the train, with 48 seats allowing serving the whole train meals in two sittings.Digital TIFF file Scan of 35mm Ilford FP4 black and white transparencyballan, train of knowledge, x48, x-class diesel locomotive

X48 entered service in 1977 (Wikipedia https://en.wikipedia.org/wiki/Victorian_Railways_X_class_(diesel)) Train of Knowledge https://en.wikipedia.org/wiki/Train_of_Knowledge The Train of Knowledge was an Australian school camp on wheels, allowing students and teachers to visit multiple locations around Victoria without having to organise accommodation or transport. The train was formed originally with whatever rolling stock was available, but within a few years it had settled to a standard consist made up to carry between 80 and 90 school children, 6 teachers and four railway staff members. As of 1976, the consist used up to five of the six available E type sleeping cars, each with 20 berths, plus the shower car Carey, formerly a horsebox, Melville, a former royal carriage used to provide power for lighting, heating and cooking, 43BPL (a former sitting carriage) used as a classroom, and Avoca as the dining car for the train, with 48 seats allowing serving the whole train meals in two sittings.Digital TIFF file Scan of 35mm Ilford FP4 black and white transparencyballarat railway station, train of knowledge, x48, x-class diesel locomotive

X48 entered service in 1977 (Wikipedia https://en.wikipedia.org/wiki/Victorian_Railways_X_class_(diesel)) Train of Knowledge https://en.wikipedia.org/wiki/Train_of_Knowledge The Train of Knowledge was an Australian school camp on wheels, allowing students and teachers to visit multiple locations around Victoria without having to organise accommodation or transport. The train was formed originally with whatever rolling stock was available, but within a few years it had settled to a standard consist made up to carry between 80 and 90 school children, 6 teachers and four railway staff members. As of 1976, the consist used up to five of the six available E type sleeping cars, each with 20 berths, plus the shower car Carey, formerly a horsebox, Melville, a former royal carriage used to provide power for lighting, heating and cooking, 43BPL (a former sitting carriage) used as a classroom, and Avoca as the dining car for the train, with 48 seats allowing serving the whole train meals in two sittings.Digital TIFF file Scan of 35mm Ilford FP4 black and white transparencyballarat railway station, train of knowledge, x48, x-class diesel locomotive

X48 entered service in 1977 (Wikipedia https://en.wikipedia.org/wiki/Victorian_Railways_X_class_(diesel)) Train of Knowledge https://en.wikipedia.org/wiki/Train_of_Knowledge The Train of Knowledge was an Australian school camp on wheels, allowing students and teachers to visit multiple locations around Victoria without having to organise accommodation or transport. The train was formed originally with whatever rolling stock was available, but within a few years it had settled to a standard consist made up to carry between 80 and 90 school children, 6 teachers and four railway staff members. As of 1976, the consist used up to five of the six available E type sleeping cars, each with 20 berths, plus the shower car Carey, formerly a horsebox, Melville, a former royal carriage used to provide power for lighting, heating and cooking, 43BPL (a former sitting carriage) used as a classroom, and Avoca as the dining car for the train, with 48 seats allowing serving the whole train meals in two sittings.Digital TIFF file Scan of 35mm Ilford FP4 black and white transparencyballarat railway station, train of knowledge, x48, x-class diesel locomotive

X48 entered service in 1977 (Wikipedia https://en.wikipedia.org/wiki/Victorian_Railways_X_class_(diesel)) Train of Knowledge https://en.wikipedia.org/wiki/Train_of_Knowledge The Train of Knowledge was an Australian school camp on wheels, allowing students and teachers to visit multiple locations around Victoria without having to organise accommodation or transport. The train was formed originally with whatever rolling stock was available, but within a few years it had settled to a standard consist made up to carry between 80 and 90 school children, 6 teachers and four railway staff members. As of 1976, the consist used up to five of the six available E type sleeping cars, each with 20 berths, plus the shower car Carey, formerly a horsebox, Melville, a former royal carriage used to provide power for lighting, heating and cooking, 43BPL (a former sitting carriage) used as a classroom, and Avoca as the dining car for the train, with 48 seats allowing serving the whole train meals in two sittings.Digital TIFF file Scan of 35mm Ilford FP4 black and white transparencyballarat railway station, train of knowledge, x48, x-class diesel locomotive

X48 entered service in 1977 (Wikipedia https://en.wikipedia.org/wiki/Victorian_Railways_X_class_(diesel)) Train of Knowledge https://en.wikipedia.org/wiki/Train_of_Knowledge The Train of Knowledge was an Australian school camp on wheels, allowing students and teachers to visit multiple locations around Victoria without having to organise accommodation or transport. The train was formed originally with whatever rolling stock was available, but within a few years it had settled to a standard consist made up to carry between 80 and 90 school children, 6 teachers and four railway staff members. As of 1976, the consist used up to five of the six available E type sleeping cars, each with 20 berths, plus the shower car Carey, formerly a horsebox, Melville, a former royal carriage used to provide power for lighting, heating and cooking, 43BPL (a former sitting carriage) used as a classroom, and Avoca as the dining car for the train, with 48 seats allowing serving the whole train meals in two sittings.Digital TIFF file Scan of 35mm Ilford FP4 black and white transparencyballarat railway station, train of knowledge, x48, x-class diesel locomotive

X48 entered service in 1977 (Wikipedia https://en.wikipedia.org/wiki/Victorian_Railways_X_class_(diesel)) Train of Knowledge https://en.wikipedia.org/wiki/Train_of_Knowledge The Train of Knowledge was an Australian school camp on wheels, allowing students and teachers to visit multiple locations around Victoria without having to organise accommodation or transport. The train was formed originally with whatever rolling stock was available, but within a few years it had settled to a standard consist made up to carry between 80 and 90 school children, 6 teachers and four railway staff members. As of 1976, the consist used up to five of the six available E type sleeping cars, each with 20 berths, plus the shower car Carey, formerly a horsebox, Melville, a former royal carriage used to provide power for lighting, heating and cooking, 43BPL (a former sitting carriage) used as a classroom, and Avoca as the dining car for the train, with 48 seats allowing serving the whole train meals in two sittings.Digital TIFF file Scan of 35mm Ilford FP4 black and white transparencyballarat railway station, train of knowledge, x48, x-class diesel locomotive

X48 entered service in 1977 (Wikipedia https://en.wikipedia.org/wiki/Victorian_Railways_X_class_(diesel)) Train of Knowledge https://en.wikipedia.org/wiki/Train_of_Knowledge The Train of Knowledge was an Australian school camp on wheels, allowing students and teachers to visit multiple locations around Victoria without having to organise accommodation or transport. The train was formed originally with whatever rolling stock was available, but within a few years it had settled to a standard consist made up to carry between 80 and 90 school children, 6 teachers and four railway staff members. As of 1976, the consist used up to five of the six available E type sleeping cars, each with 20 berths, plus the shower car Carey, formerly a horsebox, Melville, a former royal carriage used to provide power for lighting, heating and cooking, 43BPL (a former sitting carriage) used as a classroom, and Avoca as the dining car for the train, with 48 seats allowing serving the whole train meals in two sittings.Digital TIFF file Scan of 35mm Ilford FP4 black and white transparencyballarat railway station, train of knowledge, x48, x-class diesel locomotive

This photograph is part of the Caulfield Historical Album 1972. This album was created in approximately 1972 as part of a project by the Caulfield Historical Society to assist in identifying buildings worthy of preservation. The album is related to a Survey the Caulfield Historical Society developed in collaboration with the National Trust of Australia (Victoria) and Caulfield City Council to identify historic buildings within the City of Caulfield that warranted the protection of a National Trust Classification. Principal photographer thought to be Trevor Hart, member of Caulfield Historical Society. Most photographs were taken between 1966-1972 with a small number of photographs being older and from unknown sources. All photographs are black and white except where stated, with 386 photographs over 198 pages.Victorian Heritage Database - Hotham Street Road Overbridge HO116 Heritage Overlay - City of Glen Eira https://vhd.heritagecouncil.vic.gov.au/places/43557 (as of 04/07/2021) The Hotham Street road overbridge is located on the Sandringham railway line between Ripponlea and Elsternwick railway stations. It is presumed to have been built by contractors Sharp and Campbell who signed a contract on 25th . November, 1881 to construct a second line of railway between Windsor and Elsternwick. This contract was completed during 1882 and the bridge may have been designed in the year when Robert Watson took over from William Elsdon as engineer in chief for the Victorian railways. It is historically, aesthetically and technically significant. It is historically significant (Criterion A) to the extent that it demonstrates the standards of construction adopted by the Victorian Railways Department when it rebuilt the lines acquired from the private railway companies, (compare the Geelong and Melbourne Railway Co's line from Newport to Geelong, acquired in 1860). It is aesthetically significant (Criterion E) as an intact nineteenth century structure of its type, many similar girder bridges having been renewed with concrete girders in recent years. The bluestone abutments demonstrate high standards of stone masonry and are representative of Departmental work of the period. This bridge forms one of a group of historic structures on the railway to Brighton Beach and therefore contributes to the line's cultural importance as a whole. The survival of the riveted iron girders with their bellied angle iron struts is important since these elements are representative of the civil engineering practices of the Victorian Railways at the time and constitute the technical significance (Criterion F) of the structure.Page 96 of Photograph Album with three photographs (one portrait and two landscape) from Hotham Street - two external views of one house and a railway bridge.Handwritten: Hotham Street [top right] / 112 HOTHAM ST [under top left photo] / BRIDGE OVER SANDRINGHAM RAILWAY [under top right photo] / 112 HOTHAM ST CNR MELBY AVE [under bottom left photo] / 96 [bottom right]trevor hart, elsternwick, hotham street, caulfield, houses, brick, bay windows, verandahs, railway bridges, tunnels, gardens, bluestone, civil engineering, victorian railways, sharp and campbell, contractors

Paper form with text in red ink, and typed details in black. The document is a despatch Advice from the State Film Centre to the Ballarat Junior Technical School Old Boys Club.ballarat junior technical school, film, state film centre, entertainment

This is one of two cast brass nameplates of James & Alexander Brown in our collection. The Newcastle, NSW, firm was renowned for its coal mining and exporting business established in colonial Australia in 1843. The firm had an office in Melbourne and sold coal for commercial use and from the Wharf for the domestic market. The coal was then distributed along the southwest coast of Victoria in steamships or steam packets and into the regional areas of Victoria by cart and wagon. In 1890 there was a strike of coal workers but the Geelong Advertiser, September 1, 1890, announced that “a firm of coal merchants only recently received some large cargoes from Newcastle”. This supply of coal could have originated at the colliery of James & Alexander Brown. About James & Alexander Brown: - James (1816-1894), John (1823-1846) and Alexander Brown (1827-1877) migrated with their parents from Scotland to Sydney, Australia, in 1842. The next year James leased land and was assisted by his brothers Alexander and John in mining coal in the area near Maitland. The market was very competitive, with the government controlling prices. James was instrumental in a legal battle that resulted in the introduction of open competition for coal mining. James and Alexander had become business partners by 1852 and moved south of Newcastle where they established and worked a profitable mining enterprise. Their assets by 1857 included a ships’ chandlery, a fleet of steamships and an overseas trading business. They were the first firm to import rum, sugar and coffee into Newcastle. By 1892 they were exporting coal to New Zealand, China, North America, and various colonial ports. They had elaborate workshops to service their own steam engines and steamships. They were the first to use a steam collier vessel in Australian waters and they set up the second tug boat in Newcastle, the beginning of being owners of many more tug boats and performing a towing business. By 1868 James & Alexander Brown was the largest coal producer in the colony. James focused on managing the colliery and Alexander on overseas trade. It was estimated that the firm had produced over eight per cent of coal in New South Wales by 1914. James & Alexander Brown advertised in the Melbourne Herald in the early 1900s and kept an office at Queen Street, Melbourne as well as at the Wharf, stating their telephone numbers for both places. The coal was available for ‘Immediate Delivery’ for household and industrial purposes. The advertising claimed that their Pelaw Main coal was the famous household coal that met the highest test in Australia and burned bright and clean. Domestic customers could purchase the coal at the wharf or pay for delivery. Commercial customers could load their purchases into their steamships or wagons for further distribution into regional Victoria. After James’s death in 1894 his son John managed the firm, which was also known as J & A Brown. John passed away in 1930 and his sons took over. In 1931 the firm amalgamated with Abermain Seaham and the new name was J & A Brown & Abermain Seaham Collieries Ltd. commonly abbreviated to JABAS, which merged with Caledonian Collieries Ltd in 1960 and Coal & Allied Industries Ltd. was formed. The pair of nameplates is significant for its connection with the firm James & Alexander Brown. The firm was established in 1845 and became one of the largest collieries in colonial Australia. It was involved in trading within Australia and overseas. James was involved in the introduction of open competition for coal mining prices. They were the first to use a steam colliery in Australian waters and the first to import goods such as rum, sugar and coffee into New South Wales. The firm had a Melbourne office in the early 1900s, selling and distributing coal throughout Victoria, which likely included the Port of Warrnambool, which opened in 1890. The nameplates are likely to have originated from the Melbourne location.Brass Entrance Name Plate, one of a pair. Eight holes are formed through the plate; one in each corner, and four more holes are within the inscription area. The cast plate has three rows of text with the company’s name and type of business. The plate was owned by James & Alex. Brown. "JAMES & ALEXR. BROWN / COLLIERY PROPRIETORS / & STEAMSHIP OWNERS"flagstaff hill, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, nameplate, james & alexander brown, j & a brown, james & alexr brown, colliery proprietors, steamship owners, ship chandlers, coal mine, coal export, australian import, australian export, newcastle, colliers, coastal trade, steamships

This is one of two cast brass nameplates of James & Alexander Brown in our collection. The Newcastle, NSW, firm was renowned for its coal mining and exporting business established in colonial Australia in 1843. The firm had an office in Melbourne and sold coal for commercial use and from the Wharf for the domestic market. The coal was then distributed along the southwest coast of Victoria in steamships or steam packets and into the regional areas of Victoria by cart and wagon. In 1890 there was a strike of coal workers but the Geelong Advertiser, September 1, 1890, announced that “a firm of coal merchants only recently received some large cargoes from Newcastle”. This supply of coal could have originated at the colliery of James & Alexander Brown. About James & Alexander Brown: - James (1816-1894), John (1823-1846) and Alexander Brown (1827-1877) migrated with their parents from Scotland to Sydney, Australia, in 1842. The next year James leased land and was assisted by his brothers Alexander and John in mining coal in the area near Maitland. The market was very competitive, with the government controlling prices. James was instrumental in a legal battle that resulted in the introduction of open competition for coal mining. James and Alexander had become business partners by 1852 and moved south of Newcastle where they established and worked a profitable mining enterprise. Their assets by 1857 included a ships’ chandlery, a fleet of steamships and an overseas trading business. They were the first firm to import rum, sugar and coffee into Newcastle. By 1892 they were exporting coal to New Zealand, China, North America, and various colonial ports. They had elaborate workshops to service their own steam engines and steamships. They were the first to use a steam collier vessel in Australian waters and they set up the second tug boat in Newcastle, the beginning of being owners of many more tug boats and performing a towing business. By 1868 James & Alexander Brown was the largest coal producer in the colony. James focused on managing the colliery and Alexander on overseas trade. It was estimated that the firm had produced over eight per cent of coal in New South Wales by 1914. James & Alexander Brown advertised in the Melbourne Herald in the early 1900s and kept an office at Queen Street, Melbourne as well as at the Wharf, stating their telephone numbers for both places. The coal was available for ‘Immediate Delivery’ for household and industrial purposes. The advertising claimed that their Pelaw Main coal was the famous household coal that met the highest test in Australia and burned bright and clean. Domestic customers could purchase the coal at the wharf or pay for delivery. Commercial customers could load their purchases into their steamships or wagons for further distribution into regional Victoria. After James’s death in 1894 his son John managed the firm, which was also known as J & A Brown. John passed away in 1930 and his sons took over. In 1931 the firm amalgamated with Abermain Seaham and the new name was J & A Brown & Abermain Seaham Collieries Ltd. commonly abbreviated to JABAS, which merged with Caledonian Collieries Ltd in 1960 and Coal & Allied Industries Ltd. was formed. The pair of nameplates is significant for its connection with the firm James & Alexander Brown. The firm was established in 1845 and became one of the largest collieries in colonial Australia. It was involved in trading within Australia and overseas. James was involved in the introduction of open competition for coal mining prices. They were the first to use a steam colliery in Australian waters and the first to import goods such as rum, sugar and coffee into New South Wales. The firm had a Melbourne office in the early 1900s, selling and distributing coal throughout Victoria, which likely included the Port of Warrnambool, which opened in 1890. The nameplates are likely to have originated from the Melbourne location.Brass Entrance Name Plate, one of a pair. Eight holes are formed through the plate; one in each corner, and four more holes are within the inscription area. The cast plate has three rows of text with the company’s name and type of business. The plate was owned by James & Alex. Brown. "JAMES & ALEXR. BROWN / COLLIERY PROPRIETORS / & STEAMSHIP OWNERS"flagstaff hill, flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, nameplate, james & alexander brown, j & a brown, james & alexr brown, colliery proprietors, steamship owners, ship chandlers, coal mine, coal export, australian import, australian export, newcastle, colliers, coastal trade, steamships

.1) Foolscap typed letter outlining the Coronation portrait of King George by W.B. McInnes, and requesting the Ballarat School of Mines to purchase a framed copy. The letter is signed by the Director of the Australian War Memorial, J.L. treloar .2) blank order form re ordering a Coronation portrait of King George by W.B. McInnes,australian war memorial, king george, portrait, j.l. treloar, w.b. mcinnes

This letter was written by Henry Davis, editor of the Warrnambool Standard, to Joseph Archibald, curator of the Warrnambool Museum. Dated 11 October 1883, it refers to Davis’s recovery of a saturated volume of ‘Longfellow’s Poems’ from the sea at Loch Ard Gorge. The retrieval of this book, and its possible connection with one of the survivors from the LOCH ARD shipwreck in 1878, prompted Archibald’s letter of 1 December 1883 to Eva Carmichael, and Eva’s reply of 21 January 1884 (No, it was not her book). Miss Carmichael’s reply to Archibald’s inquiry (2290.4) and the water-damaged book itself (541) are both in the Flagstaff Hill collection along with this letter from Davis, which connects the two. The Davis letter reads: “Dear Sir, ― This book was found by me in the waves which broke on the sands [….] the Gorge where Tom Pearce rescued Miss Carmichael after the wreck of the ill-fated ‘Loch Ard’. I ran in with the receding waves and picked up the soddened volume, and, coincidentally, the first illustrations that met my gaze, on parting its dripping pages, was that portraying the fair maiden in the ‘Wreck of the [Hersperus’.] On the Bluff, 200 feet above me, were the dead forms of Mrs and one of the Misses Carmichael, whilst [by] them, stiff and [….] were two gentlemen passengers [by] the wreck[ed] [v]essel]. Having just left them before [….] [my] capture in the Gorge, you may imagine [m]y feelings on alighting upon, under such circumstances, Longfellow’s beautiful and sympathetic poem. Yours truly, H.W. Davis.” The book referred to here is The Poetical Works of Henry Wadsworth Longfellow, 1877, Nimmo, London. It is on display under glass in the Great Circle Gallery at the Maritime Village, alongside a typed transcript of the Davis letter. A 1996 audit of the rare book collection at Flagstaff Hill notes: “Inscribed ‘Loch Ard June 1 1878’ in pencil within ― believed to be a salvage from the shipwreck”. The letter is connected to the salvaged items from the 1878 LOCH ARD shipwreck, which is of State significance ― Victorian Heritage Number S417Letter from H. Davis, editor of the Warrnambool Standard, to J. Archibald, curator of the Warrnambool Museum. It was handwritten in ink on “Standard Office, Warrnambool” letterhead note paper, and dated 11 October 1883. The cursive script appears carelessly written and the original single sheet of paper is in poor condition (torn and creased). At some stage the original document has been backed with stiff cardboard and then sealed in a clear plastic cover.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, loch ard, longfellow’s poems, eva carmichael, joseph archibald, henry davis, warrnambool standard

A stand or support for utensils before or on the fire. Usually made of wrought iron, the most common variety, from the 17th century, stands on three legs and has a circular plate with perforated decoration, often in the form of a date. Another early type, short-legged, stood in the fire to support a cast-iron pot. Later, in the second half of the 18th century, trivets designed to be hung from fire bars were made. These were of two types: an oblong, standing trivet with a handle at one end and projections to fit over the fire bars at the other, and a plate that could be attached to the fire bar. Some of the latter were hung inside the grate supporting a vessel over the fire. Large quantities of cast-brass fender trivets were manufactured at Birmingham, in England, in the last quarter of the 18th century; these were suspended from the top rails of the fender as muffin and kettle stands. Four-legged trivets that stood under the spit holding the dripping pan were made in the 18th and 19th centuries. The cat, an entirely different type of plate stand that was made in the 18th century, consisted of six spokes, three at the top and three at the bottom; it could be used either way up. The term trivet is also used in reference to a metal stand with short feet, used on a table to support a hot dish. https://www.britannica.com/topic/trivet Trivets have been used since the invention of iron and are essential for placing hot items on surfaces.Metal stand for hot items, black painted metal. Heart-shaped with three supports. Now quite rusty.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, wrought iron, trivet

This Zinc Cap Porcelain Liner was recovered from the (1908) shipwreck site of the FALLS OF HALLADALE. The purpose of cap liners was to assist with the safe preserving and storage of perishable foodstuffs in an age when refrigeration was generally unavailable. These round, coarse-glass inserts formed part of the screw lids used with the Ball Mason style of canning fruit jars. The liner was placed inside the zinc cap to stop the contents of the jar reacting with the zinc. It prevented the metallic tainting of food as well as the corrosion of the metallic lid. On March 30, 1869, Lewis R Boyd was issued with patent # 88439 for an “Improved Mode of Preventing Corrosion in Metallic Caps”. From the 1870s to the 1950s, large quantities of these liners were produced by a number of glass manufacturing companies. They are consequently difficult to date or identify. “It is assumed that most of the earlier versions of these liners have the name ‘BOYD’S’ or ‘BOYD’ embossed on them. Later versions may or may not have the name included in the lettering”. (http://www.glassbottlemarks.com). Only a few were made of porcelain, the great majority being made first of transparent and later of translucent or opaque glass. The different emblems of triangles, circles, and crosses embossed on the front face of the liners are assumed to signify mould or model types rather than the company that produced them. This particular artefact is one of 14 cap liners that were retrieved from the shipwreck site and are now part of the Flagstaff Hill Maritime Village collection. The Maltese Cross and “BOYD’S GENUINE PORCELAIN LINED” lettering are unique to this piece. However, it is evident from the markings and materials of the other cap liners, that they originally formed sets or series. Six are larger (8 mm depth x 85mm diameter), of greenish hue with ground glass texture, and support the raised emblem of a compass needle. Two are medium-sized (75mm diameter) with two raised dots in a central circle and the lettering “Patd. APR 25.82”. This particular cap liner is likely to have also been one of a mass-produced line being imported from America. The iron-hulled sailing ship FALLS OF HALLADALE was a bulk carrier of general cargo en route from New York to Melbourne and Sydney. In her hold, along with 56,763 tiles of unusual beautiful green American slates (roofing tiles), 5,673 coils of barbed wire, 600 stoves, 500 sewing machines, 6500 gallons of oil, 14400 gallons of benzene, and many other manufactured items, were 117 cases of crockery and glassware. The FALLS OF HALLADALE came aground on a reef off the Peterborough headland at 3 am on the morning of the 15th of November, 1908. The captain and 29 crew members all survived, but her valuable cargo was largely lost, despite two salvage attempts in1908-09 and 1910. The iron-hulled, four-masted barque, the Falls of Halladale, was a bulk carrier of general cargo. She left New York in August 1908 on her way to Melbourne and Sydney. In her hold, along with 56,763 tiles of unusual beautiful green American slates (roofing tiles), 5,673 coils of barbed wire, 600 stoves, 500 sewing machines, 6500 gallons of oil, 14400 gallons of benzene, and many other manufactured items, were 117 cases of crockery and glassware. Three months later and close to her destination, a navigational error caused the Falls of Halladale to be wrecked on a reef off the Peterborough headland at 3 am on the morning of the 15th of November, 1908. The captain and 29 crew members all survived, but her valuable cargo was largely lost, despite two salvage attempts in 1908-09 and 1910. ABOUT THE ‘FALLS OF HALLADALE’ (1886 - 1908) Built: in1886 by Russell & Co., Greenock shipyards, River Clyde, Scotland, UK. The company was founded in 1870 (or 1873) as a partnership between Joseph Russell (1834-1917), Anderson Rodger and William Todd Lithgow. During the period 1882-92 Russell & Co., they standardised designs, which sped up their building process so much that they were able to build 271 ships over that time. In 1886 they introduced a 3000 ton class of sailing vessel with auxiliary engines and brace halyard winches. In 1890 they broke the world output record. Owner: Falls Line, Wright, Breakenridge & Co, 111 Union Street, Glasgow, Scotland. Configuration: Four masted sailing ship; iron-hulled barque; iron masts, wire rigging, fore & aft lifting bridges. Size: Length 83.87m x Breadth 12.6m x Depth 7.23m, Gross tonnage 2085 ton Wrecked: the night of 14th November 1908, Curdies Inlet, Peterborough south west Victoria Crew: 29 The Falls of Halladale was a four-masted sailing ship built-in 1886 in Glasgow, Scotland, for the long-distance cargo trade and was mostly used for Pacific grain trade. She was owned by Wright, Breakenridge & Co of Glasgow and was one of several Falls Line ships, all of which were named after waterfalls in Scotland. The lines flag was of red, blue and white vertical stripes. The Falls of Halladale had a sturdy construction built to carry maximum cargo and able to maintain full sail in heavy gales, one of the last of the ‘windjammers’ that sailed the Trade Route. She and her sister ship, the Falls of Garry, were the first ships in the world to include fore and aft lifting bridges. Previous to this, heavily loaded vessels could have heavy seas break along the full length of the deck, causing serious injury or even death to those on deck. The new, raised catwalk-type decking allowed the crew to move above the deck stormy conditions. This idea is still used today on the most modern tankers and cargo vessels and has proved to be an important step forward in the safety of men at sea. On 4th August 1908, with new sails, 29 crew, and 2800 tons of cargo, the Falls of Halladale left New York, bound for Melbourne and Sydney via the Cape of Good Hope. The cargo on board was valued at £35,000 and included 56,763 tiles of American slate roofing tiles (roof slates), 5,673 coils of barbed wire, 600 stoves, 500 sewing machines, 6,500 gallons of oil, 14,400 gallons of benzene, plumbing iron, 117 cases of crockery and glassware and many other manufactured items. The Falls of Halladale had been at sail for 102 days when, at 3 am on the night of 14th November 1908, under full sail in calm seas with a six knots breeze behind and misleading fog along the coast, the great vessel rose upon an ocean swell and settled on top of a submerged reef near Peterborough on south-west Victoria’s coast. The ship was jammed on the rocks and began filling with water. The crew launched the two lifeboats and all 29 crew landed safely on the beach over 4 miles away at the Bay of Islands. The postmistress at Peterborough, who kept a watch for vessels in distress, saw the stranding and sent out an alert to the local people. A rescue party went to the aid of the sailors and the Port Campbell rocket crew was dispatched, but the crew had all managed to reach shore safely by the time help arrived. The ship stayed in full sail on the rocky shelf for nearly two months, attracting hundreds of sightseers who watched her slowly disintegrate until the pounding seas and dynamiting by salvagers finally broke her back, and her remains disappeared back into deeper water. The valuable cargo was largely lost, despite two salvage attempts in 1908-09 and 1910. Further salvage operations were made from 1974-1986, during which time 22,000 slate tiles were recovered with the help of 14 oil drums to float them, plus personal artefacts, ship fittings, reams of paper and other items. The Court of Marine Inquiry in Melbourne ruled that the foundering of the ship was entirely due to Captain David Wood Thomson’s navigational error, not too technical failure of the Clyde-built ship. The shipwreck is a popular site for divers, about 300m offshore and in 3 – 15m of water. Some of the original cargo can be seen at the site, including pieces of roof slate and coils of barbed wire. The Falls of Halladale shipwreck is listed on the Victorian Heritage Register (No. S255). She was one of the last ships to sail the Trade Routes. She is one of the first vessels to have fore and aft lifting bridges. She is an example of the remains of an International Cargo Ship and also represents aspects of Victoria’s shipping industry. The wreck is protected as a Historic Shipwreck under the Commonwealth Historic Shipwrecks Act (1976). A circular translucent glass disc in good condition with raised upper case lettering around 8mm rim – “BOYD’S GENUINE PORCELAIN LINED” - and a raised central emblem of a Maltese Cross. On the reverse face in the centre of the disc, there is a raised numeral “3”. falls of halladale, wright, breakenridge & co of glasgow, unusual beautiful green american slates (roofing tiles), warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, shipwrecked-artefact, zinc cap porcelain liner, boyd’s genuine porcelain lined, glass lid, opaque disc, food preserving, fruit bottling, cap liner, shipwrecked coast, flagstaff hill maritime museum, shipwreck artefact, 1908 shipwreck

A dorade is a type of ventilator that permits the passage of air in and out of the cabin or engine room of a boat while keeping rain, spray, and sea wash out. The basic form is a low, rectangular box fixed to the deck or cabin top, fitted with interleaving vertical baffles. The baffles alternate to be free at the floor of the box, or free at the ceiling, forming a series of chambers. A horn-shaped ventilation cowl is usually fitted facing forward to a large hole at the top of the chamber at one end of the box with another large hole opening down into the boat from the chamber at the other end. Limber holes perforate the wall of the box at the floor of each chamber. Dorade boxes operate on the principle that air can pass relatively freely through the chambers, yet rain or sea wash will be trapped in successive chambers and drain out the small holes in the sides of the box. The first appearance of Dorade boxes was on the Olin Stephens-designed Dorade, a yacht built in 1929 for ocean racing. As originally built, the Dorade's vents led directly below, but this was found to allow water below, and the vents were modified in the early 1930s.An early piece of marine equipment from the 1930s and 40s that still is in use today on smaller vessels and ships.Dorade Cowl (Ventilator), brass casting with wide open mouth twisted to side. Painted red inside.warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, dorade (ventilator), dorade, ventilator, marine equipment, ships fittings

Negretti and Zambra 1850-1980s were optical instrument makers and mathematical instrument makers based in London, England. The firm of Negretti and Zambra was established in 1850 by Henry Negretti and Joseph Zambra who had formed a partnership. Their skill was immediately apparent when exhibiting at the 1851 Great Exhibition at Hyde Park, they were the only English instrument makers to receive a prize medal for meteorological instruments, resulting in their appointment as instrument makers to the queen, Greenwich observatory, and the British Meteorological Society. In 1853, when the Crystal Palace was re-erected in Sydenham, Negretti and Zambra became the official photographers of the Crystal Palace Company, which allowed them to photograph the interior and grounds of the new building. The firm made use of this access to produce a number of stereographs. Between 1855 and 1857 Negretti and Zambra commissioned photographer Pierre Rossier to travel to China to document the Second Opium War. Although Rossier subsequently was unable to accompany to Anglo-French forces in that campaign, he nevertheless produced a number of stereographs and other photographs of China, Japan, the Philippines and Siam (now Thailand), which Negretti and Zambra published and that represented the first commercial photographs of those countries. In 1856 Negretti and Zambra sponsored a photographic expedition to Egypt, Nubia and Ethiopia conducted by Francis Firth. In 1864 Negretti and Zambra (themselves) photographed Shakespeare's House at Stratford on Avon. A sepia photograph was then pasted onto card 4" × 2.5". This was then presented to visitors to the Crystal Palace to enable them to compare it with the model erected by Mr E. T. Parr in the Centre Transept. The card itself is headed "Crystal Palace April 23rd 1864." That year they also published a book, titled A Treatise on Meteorological Instruments, (which was reprinted in 1995). Throughout World War One Negretti and Zambra were entirely engaged in the production of various instruments for the Ministry of Munitions. They developed many instruments for the Air Ministry including a mercury-in-steel distance thermometer for taking the oil and air temperatures in aircraft which was patented in 1920. In 1946 the company went private and in 1948 the company was made public, and by 1950 Negretti and Zambra had 821 employees in Britain. In order to increase production and to safeguard future development in 1964, they purchased a modern factory at Aylesbury for all their production. In 1981 Negretti and Zambra were taken over by a group of financial institutions in the form of Western Scientific Instruments and in 1985 the company was acquired by Meggitt Holdings.The subject compass is just one type of the many marine and scientific, optical items this company produced over it’s life time. Negretti and Zambra were prolific manufactures of types of items as well as being very prominent in photography pioneering new innervation's and sponsoring expeditions to little known countries to document peoples daily lives and culture through photography.Azimuth compass on tripod in a fitted wooden box with a round spirit level included, lid of box has three indented circles where the legs of the compass fit when it is set up for use. Stamped "C.M.O. 9" on with Maker Negretti & Zambra London.flagstaff hill, warrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, azimuth compass, nautical instrument, negretti & zambra london, navigational instrument, compass

The timber on this captain's chair has been worn smooth across the backrest. It is of solid construction. A captain's chair is typically a wooden armchair with a back that curves around to form the armrests. The style of chair was used in the 19th century and was a statement of status aboard a ship. This captain's chair is an example of the type of furniture used onboard a ship in the 19th and early 20th centuries.Captain's chair; an oak armchair with a low curved back that forms the armrests. It has six turned spindles, a fretted back, a solid saddle seat and is supported on four turned legs. The timber backrest feels smooth and well-worn. Circa 1900.flagstaff hill, flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, wooden chair, captain's chair, armchair, 19th century furniture, nautical furniture, seating

Bullets for early firearms were made as lead balls in iron scissor moulds. The moulds had scissor action, with ends shaped as a hollow half-sphere that formed a ball when the handles closed. Melted lead was poured into a small filling hole in the top of the closed mould. When the lead was set the handles were opened and the ball was released from the mould. Excess lead was trimmed using the cutting edge of the mould. The task of pouring the melted lead into the mould had to be performed slowly so that air pockets didn’t form. The shot would have a join line around it, which would make it inaccurate; the join needed to be carefully filed to make the ball into a smooth sphere. Larger quantities of lead shot were often cast in a multi-bullet mould that was used in a similar way. Lead shot mould; cast iron, scissor type metal object with sphere shaped mould at end used to make lead shot balls for a shotgun. Mould has a cutting edge to trim off excess lead.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, firearms, bullet, cast bullet, lead ball, lead shot, scissor mould

The Process of Making Pottery Decorating, Firing, Glazing, Making, Technical There is a rhythm and flow to clay. It can’t be done all at once! Even the making process! It can take weeks to get everything done, especially if you can only work on your pottery once a week! Even though we have three hour classes, it’s often just not enough time! Here is an overview of some of the processes so you have a bit more grasp on some of the technical stuff! Step One – Design There are SO many ideas out there for making stuff in clay! From delicate porcelain jewellery, through to heavy sculptural work and everything in between. Deciding your direction is sometimes not that easy – when you first start, try everything, you will naturally gravitate to the style that you enjoy! The options and variations are endless and can get a wee bit overwhelming too! Check in with me before you start to ensure your ideas will work, what order you might do things, how you could achieve the look you are seeking and any other technical data required! Step Two – Making Clay is thixotropic. This means that as you work with it, the clay first gets sloppier and wetter, before is begins to dry in the atmosphere. For most things, you simply can’t do all parts of the project at once. An example of work order might look like: Get last weeks work out from the shelves Prepare clay for today’s work – roll your clay, prepare balls for throwing, make the first stage of a pinch pot) Clean up last week’s work and put it on the shelf for bisque firing Check that you have any glazing to do – and do enough of it that you will have time to finish your main project Do the next step of your next project – there might be a further step that can’t be complete immediately, in that case, wrap your work well and put onto the shelves. Letting your work rest for a while can really help keep your work clean and professional looking. Many things require bagging under plastic to keep it ready for work the next week – put your name on the outside of the bag so you can find your work easily. We have stickers and markers. Consider how you want to decorate your work – coloured slip can be applied at a fairly wet stage (remembering that it will make your work even wetter!). Trying to apply slip to dry clay won’t work! If you want to do sgraffito – you will need to keep the work leather hard (a state of dryness where you can still work the clay with a little effort and a little water and care). Step Three – Drying Most of the time your work can go into the rack uncovered to let it dry out for the following week. If you want to continue forming or shaping you will need to double bag your work – put your work on a suitable sized bat and put the bat in a bag so the base of the bag is under the bat, then put another bag over the top of the work and tuck the top of the bag under the bat. If you want to trim (or turn) your thrown work the following week, it should also be double bagged. If your work is large, delicate, or of uneven thicknesses, you should lightly cover your work for drying. When considering the drying process, bare in mind the weather, humidity and wind! The hotter and dryer, the faster things dry and work can dry unevenly in the shelves – this can lead to cracking – another time to lightly cover your work for drying. Step Four – Trimming and Cleaning Up Your work is dry! It is called greenware now and it is at it’s most fragile! Handle everything with two hands. I often refer to soft hands – keep everything gentle and with your fingers spread as much as possible. Try to not pick up things like plates too much, and always with both hands! Before your work can be bisque fired it should be “cleaned up”. You work won’t go into the kiln if it has sharp edges – when glazed, sharp edges turn into razor blades! Use a piece of fly wire to rub the work all over – this will scratch a little so be light handed. Use a knife or metal kidney to scrape any areas that require a bit more dynamic treatment than the fly wire offers! Finally, a very light wipe over with a slightly damp sponge can help soften and soothe all of your edges and dags! Trimming thrown work: If you are planning to trim (or turn) your thrown work (and you should be), make sure you bag it well – your work should be leather hard to almost dry for easiest trimming. Use this step to finish the work completely – use a metal kidney to polish the surface, or a slightly damp sponge to give a freshly thrown look. Wipe the sponge around the rim after trimming, and check the inside of the pot for dags! Trimming slip cast work: Usually I will trim the rims of your work on the wheel the following day to make that stage easier, however you will still need to check your work for lumps and bumps. Last but not least – check that your name is still clearly on the bottom of your work. Step Five – Bisque Firing When the work is completely dry it can go into the bisque kiln. The bisque kiln is fired to 1000°C. This process burns off the water in the clay as well as some of the chemically bound water. The structure of the clay is not altered that much at this temperature. Inside the bisque kiln, the work is stacked a little, small bowl inside a larger bowl and onto a heavy plate. Smaller items like decorations or drink coasters might get stacked several high. Consideration is paid to the weight of the stack and shape of the work. A bisque kiln can fire about one and a half times the amount of work that the glaze kiln can fire. The firing takes about 10 hours to complete the cycle and about two days to cool down. Once it has been emptied the work is placed in the glaze room ready for you to decorate! Step Six – Glazing Decorating your work with colour can be a lot of fun – and time consuming! There are three main options for surface treatment at this stage: Oxide Washes Underglazes Glazes Washes and underglazes do not “glaze” the work – It will still need a layer of glaze to fully seal the clay (washes don’t need glaze on surfaces not designed for food or liquid as they can gloss up a little on their own). Underglazes are stable colourants that turn out pretty much how they look in the jar. They can be mixed with each other to form other colours and can be used like water colours to paint onto your work. Mostly they should have a clear glaze on top to seal them. Oxides are a different species – the pink oxide (cobalt) wash turns out bright blue for instance. They don’t always need a glaze on top, and some glazes can change the colour of the wash! The glazes need no other “glaze” on top! Be careful of unknown glaze interactions – you can put any combination of glaze in a bowl or on a plate, but only a single glaze on the outside of any vertical surface! Glazes are a chemical reaction under heat. We don’t know the exact chemicals in the Mayco glazes we use. I can guess by the way they interact with each other, however, on the whole, you need to test every idea you have, and not run the test on a vertical surface! Simply put, glaze is a layer of glass like substance that bonds with the clay underneath. Clay is made of silica, alumina and water. Glaze is made of mostly silica. Silica has a melting point of 1700°C and we fire to 1240°C. The silica requires a “flux” to help it melt at the lower temperature. Fluxes can be all sorts of chemicals – a common one is calcium – calcium has a melting point of 2500°C, however, together they both melt at a much lower temperature! Colourants are metal oxides like cobalt (blue), chrome (green through black), copper (green, blue, even red!), manganese (black, purple and pink) iron (red brown), etc. Different chemicals in the glaze can have dramatic effects. for example, barium carbonate (which we don’t use) turns manganese bright pink! Other elements can turn manganese dioxide brown, blue, purple and reddish brown. Manganese dioxide is a flux in and of itself as well. So, glazes that get their black and purple colours, often interact with other glazes and RUN! Our mirror black is a good example – it mixes really well with many glazes because it fluxes them – causes them to melt faster. It will also bring out many beautiful colours in the glazes because it’s black colouring most definitely comes from manganese dioxide! Glaze chemistry is a whole subject on it’s own! We use commercial Mayco glazes on purpose – for their huge range of colour possibilities, stability, cool interactions, artistic freedom with the ability to easily brush the glazes on and ease of use. We currently have almost 50 glazes on hand! A major project is to test the interactions of all glazes with each other. That is 2,500 test tiles!!!! I’m going to make the wall behind the wheels the feature wall of pretty colours! Step Seven – Glaze (Gloss or sometimes called “Glost”) Firing Most of the time this is the final stage of making your creation (but not always!) The glaze kiln goes to 1240°C. This is called cone 6, or midrange. It is the low end of stoneware temperatures. Stoneware clays and glazes are typically fired at cone 8 – 10, that is 1260 – 1290°C. The energy requirement to go from 1240°C to 1280°C is almost a 30% more! Our clay is formulated to vitrify (mature, turn “glass-like”) at 1240°, as are our glazes. A glaze kiln take around 12 hours to reach temperature and two to three days to cool down. Sometimes a third firing process is required – this is for decoration that is added to work after the glaze firing. For example – adding precious metals and lustres. this firing temperature is usually around 600 – 800°C depending upon the techniques being used. There are many students interested in gold and silver trims – we will be doing this third type of firing soon! After firing your work will be in the student finished work shelves. Remember to pay for it before you head out the door! There is a small extra charge for using porcelain clay (it’s more than twice the price of regular clay), and for any third firing process! Once your work has been fired it can not turn back into clay for millennia – so don’t fire it if you don’t like it! Put it in the bucket for recycling. https://firebirdstudios.com.au/the-process-of-making-pottery/The form of the jug has been in use for many centuries.Stoneware jug. Two tone brown glaze with pierced lip behind spout. Spout chipped.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, jug, ceramic jug

Siebe Gorman & Company Ltd was a British company that developed diving equipment and breathing equipment and worked on commercial diving and marine salvage projects. The company advertised itself as 'Submarine Engineers'. It was founded by Augustus Siebe, a German-born British engineer chiefly known for his contributions to diving equipment. Siebe Gorman traded as an engineering firm for over 180 years from 1819 to 1999. The early success of the business was due to its founder, the Prussian immigrant Christian 'Augustus' Siebe (1788-1872). For business reasons, he applied for and was granted British citizenship in 1856. He was a gifted engineer who was able to translate theoretical problems into practical, working products. During the industrial Victorian period, the business traded as 'A. Siebe' at 145 High Street Holborn London, but in 1828 new premises were acquired at 5 Denmark Street, Soho. The family firm produced a wide range of manufactured goods including paper-making machinery, measuring machinery, water pumps, refrigeration equipment, and diving apparatus. Augustus Siebe specialised in submarine engineering early on and the company gained a reputation for the manufacture of safe, reliable diving apparatus. Augustus Siebe is best remembered for the development and manufacture of the ‘closed’ Diving Dress based on the ideas of Charles and John Deane, George Edwards, and Charles Pasley. Apart from some small modifications to valves and diver communications, the basic 12 bolt ‘closed’ diving dress remained relatively unchanged after the 1870s. Later company successes were also based on innovation, with new products that could be successfully developed and manufactured to high standards. This was largely attributed to the inventive nature, foresight, engineering, and entrepreneurial skills of Robert Henry Davis (1870-1965). In 1882, RH Davis joined the company of 'Siebe & Gorman' as a young 11-year-old office boy and he was to remain with the company until he died in 1965. Augustus Siebe retired in 1869 and handed over the company to a new partnership of Henry H. Siebe (1830-1885) and William A. O'Gorman (1834-1904). The new firm traded as 'Siebe & Gorman' (1870-1879) from premises in and around Mason Street, Westminster Bridge Road, Lambeth, London. The two partners soon recognised the potential of R.H. Davis and in 1894, aged 24, he became General Manager of Siebe & Gorman. Davis increasingly ran the company until the surviving partner (W.A. Gorman) died in 1904. The firm was disposed of to the Vickers (armaments) family and a new company 'Siebe Gorman & Co. Ltd.' (1905-1998) was formed. Under the chairmanship of Albert Vickers, R.H. Davis was kept on as Managing Director, and the company forged ahead. However, after WW1, the Great Depression caused manufacturing output and share prices to slump. In 1924 Robert Davis made a deal with the Vickers Board and acquired control of the company through majority shares. Under his leadership, the Siebe Gorman Company flourished and within time, four of his sons also joined the firm. The company gained a worldwide reputation for the manufacture of diving apparatus, decompression and observation chambers, and safety breathing apparatus of all types for use on the land, in the air, and under the sea (including mine rescue, tunneling, aircraft, diving, submarine escape and in other hazardous environments). Close research and development links with the MOD (especially the Admiralty), also provided a lucrative outlet for the company products. In 1932, Robert Davis was knighted by King George V, principally for his invention of the ‘Davis Submerged Escape Apparatus’ (D.S.E.A.). Siebe Gorman essentially remained a family firm from the beginning (under A.Siebe) until it became a public company for the first time in 1952. However, following WW2, British manufacturing stagnated through stifled investment and post-war austerity, and there was little innovation. Siebe Gorman's fortunes began to decline as an aging Sir Robert Davis failed to invest, or change the company's business and management practices. In 1959, Siebe Gorman was acquired by the “Fairy Group” and the ailing Sir Robert was made Life President. Consequently, nothing changed and the slow decline continued until Sir Robert's death in March 1965. Around 1960, Siebe Gorman acquired the diving apparatus manufacturer C E Heinke, and for a brief period, it manufactured some diving equipment under the combined name of Siebe Heinke. Around 1964, Mr E. 'Barry' Stephens was appointed as the new Managing Director to modernise Siebe Gorman. Changes were made, including a move to a new factory in Wales in 1975. The new company concentrated on fire-fighting breathing apparatus and escape equipment, and the move coincided with the loss of many of the older, traditional craft skills. Between 1985 and 1998, Siebe expanded through acquisitions, and several other companies were acquired. The Siebe Gorman (diving apparatus) company has therefore traded as A. Siebe (1819-1870); Siebe & Gorman (1870-1879); Siebe Gorman & Co (1880-1904); Siebe Gorman & Co. Ltd (1905-1998). (For information regards the diving helmet & Frank King see Notes Section at the end of this document)The items are very significant as a snapshot into marine history and the development of diving equipment generally especially that used for salvage operations before and during WW2. The company that made the equipment was a leading inventor,developer and innovator of marine equipment with its early helmets and other items eagerly sought after today for collections around the world. The items in the Flagstaff Hill collection give us an insight as to how divers operated and the dangers they faced doing a very necessary and dangerous job. Frank Kings' diving helmet and compressor (communication pipe stored separately). Compressor is hand cranked. US Navy diving helmet, Mark V. Two maker's plates attached. Made in 1944.On rear "WATER SUPPLY" On front 'PATENT" " Logo: Images (Lion, Crown, Horse, Shield within an oval) "SIEBE, GORMAN & Co. Ltd. SUBMARINE ENGINEERS, LONDON.flagstaff hill, warrnambool, maritime museum, great ocean road, us navy diving helmet, commonwealth government salvage, diving helmet, marine salvage, frank king, diver, siebe. gorman & co ltd, submarine equipment, diving equipment, communication under water, hand cranked, diving compressor

A dorade is a type of ventilator that permits the passage of air in and out of the cabin or engine room of a boat while keeping rain, spray, and sea wash out. The basic form is a low, rectangular box fixed to the deck or cabin top, fitted with interleaving vertical baffles. The baffles alternate to be free at the floor of the box, or free at the ceiling, forming a series of chambers. A horn-shaped ventilation cowl is usually fitted facing forward to a large hole at the top of the chamber at one end of the box with another large hole opening down into the boat from the chamber at the other end. Limber holes perforate the wall of the box at the floor of each chamber. Dorade boxes operate on the principle that air can pass relatively freely through the chambers, yet rain or sea wash will be trapped in successive chambers and drain out the small holes in the sides of the box. The first appearance of Dorade boxes was on the Olin Stephens-designed Dorade, a yacht built in 1929 for ocean racing. As originally built, the Dorade's vents led directly below, but this was found to allow water below, and the vents were modified in the early 1930s.An early piece of marine equipment from the 1930s that still is in use today on smaller vessels to improve below deck ventilation. Dorade Ventilator Cowl brass casting with wide open mouth twisted to side with swivel base. Box and baffles missingNonewarrnambool, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, ventilator, dorade, maritime equipment, ships fittings, ventilator box

The Burse (AKA a "corporas-case") is a type of folder used to carry the corporal to and from the altar. It is made out of two square pieces of cardboard laid one on top of the other, then bound together along one edge to form a hinge. Sometimes, an extra purificator may be placed inside the pall. The other item is a Chalice Veil which is placed over the chalice, paten, and purificator when the vessels are prepared for the Eucharist and placed on the altar; it is removed before the Consecration. Both are Red with gold embroidered cross and trim (Holy Week, Pentecost and feasts of martyred saints).flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, burse, chalice veil

The Burse (AKA a "corporas-case") is a type of folder used to carry the corporal to and from the altar. It is made out of two square pieces of cardboard laid one on top of the other, then bound together along one edge to form a hinge. Sometimes, an extra purificator may be placed inside the pall. The other item is a Chalice Veil which is placed over the chalice, paten, and purificator when the vessels are prepared for the Eucharist and placed on the altar; it is removed before the Consecration. Both are Green with gold embroidered cross and trim (Epiphany and Ordinary Time).flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, burse, chalice veil

The Burse (AKA a "corporas-case") is a type of folder used to carry the corporal to and from the altar. It is made out of two square pieces of cardboard laid one on top of the other, then bound together along one edge to form a hinge. Sometimes, an extra purificator may be placed inside the pall. The other item is a Chalice Veil which is placed over the chalice, paten, and purificator when the vessels are prepared for the Eucharist and placed on the altar; it is removed before the Consecration. Both are White with gold trim (Christmas, Easter and some Holy Days).flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, burse, chalice veil

The Burse (AKA a "corporas-case") is a type of folder used to carry the corporal to and from the altar. It is made out of two square pieces of cardboard laid one on top of the other, then bound together along one edge to form a hinge. Sometimes, an extra purificator may be placed inside the pall. The other item is a Chalice Veil which is placed over the chalice, paten, and purificator when the vessels are prepared for the Eucharist and placed on the altar; it is removed before the Consecration. Both are Purple with white embroidered cross and trim (Lent or Advent).flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, burse, chalice veil