These items contained products for cooking use in the family kitchen in the 1930's - 1960. Five vintage tins and one bottle of kitchen products used in the home 1930's - 1960. 1. A small unopened Nestle' Nesco REGD. Dried Ice Cream Mix tin with powder inside. It has a yellow label with red, white and black lettering of the brand and details of product. Net weight 4oz. 2. A small McKenzie's Excelsior Baking Powder tin with a white, and gold printed paper label explaining manfacturer details and instructions for use. 4 ozs. Net. 3. Two large lidded The Colonial Sugar Refining Co. Ltd. treacle tins with red, green and silver lettering. manufacturer details are printed on the front. 2lbs nett. 4. A small tin lidded cylinder of Herb-Ox Bouillon Cubes artificially flavoured. The manufacturer details and directions for use are printed in yellow and red. Net weight 3/4 oz. 5. A small clear glass bottle with a tin screw top lid of Rawleigh's Essence of Peppermint printed on the white and brown paper label. 2 fluid oz.1. 'Nesco Dried Ice Cream Mix Nestle' Vanilla Flavour. 16.11.63' 2. 'McKenzie's Excelsior Baking Powder' 3. 'The Colonial Sugar Refining Co. Ltd.Treacle' is printed in large red print. 4. 'Herb-Ox' printed in red lettering. 5. 'Rawleigh's Essence of Peppermint A delicious Flavour'.tins, bottles, kitchen equipment, kitchen ingredients

Used for beating eggs or other cooking mixtures.Egg beater, chromed metal with wooden handlesSwift Whip. A Persinware product made in Australia.egg-beaters, whisks, kitchen equipment

Used for beating eggs or other cooking mixtures.Egg beater, chromed metal with wooden handlesSwift Whip. A Propert product made in Australia Pat. Ball drive 9033/32egg-beaters, whisks, kitchen equipment

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 bowl is an example of kitchenware used in the 19th century and still in use today.Bowl white ceramic. Crack on side. Badly stained.Backstamp very faint and unable to be read.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, mixing bowl, food preparation, kitchen equipment, ceramic

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/ This bowl is an example of kitchenware used in the 19th century and still in use today.Bowl white ceramic plain that has two sets of edging around lip. Inside bowl has plaster designed to look like cooking mixture.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, kitchen equipment, ceramic

This stove brush is shaped to fit into grooves and crevices on a cast iron stove range and fenders. A brush like this would be used in the 19th and early 290th centuries to apply a blackening agent to the metal to clean and preserve it would be polished to make it look more attractive.This object is significant as an example of an item in common use in the 19th and early 20th centuries.Stove brush, wooden with wooden raised handle and black bristles. The bristles at the ends of the brush are longer than in the centre, and flare outwards. The brush' is rounded at one end and pointed at the other.flagstaff hill, flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, cast iron stove, oven range, stove brush, blackening brush, cooking, kitchen equipment, wood fired stove

This enamel jug is a basic design that was common to households in the 19th and early 20th centuries. Enamelware dates back to 1760 in Germany.This object is significant as an example of an item in common use in the 19th and early 20th centuries.White metal enamel jug, white with navy blue handle and rim. Tapered cylindrical shape, with a pouring lip.None.flagstaff hill, flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, jug, enamel jug, kitchen equipment, liquid storage, beverage preparation

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/This bowl was made by renowned pottery company J & G Meakin of England. The firm was established in the mid-1800's. The bowl is an example of kitchenware used in the 19th century and still in use today.Bowl; white ceramic, round and tapering inwards towards base. Made by J and G Meakin England.On base, 'Ironstone China Reg SOL 391413' with symbolflagstaff hill, flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, mixing bowl, food preparation, j & g meakin, pottery, stoke-on-trent, kitchen equipment, ceramic

A honing steel, sometimes referred to as a sharpening steel, whet steel, sharpening stick, sharpening rod, butcher's steel, and chef's steel, is a rod of steel, ceramic or diamond-coated steel used to restore keenness to dulled blade edges. They are flat, oval, or round in cross-section and up to 30 centimetres (1 ft) long. The steel and ceramic honing steels may have longitudinal ridges, whereas the diamond-coated steels are smooth but embedded with abrasive diamond particles. Non-abrasive honing rods such as smooth ceramic or ribbed steel are able to remove small amounts of metal via adhesive wear. In normal use, the rod is applied to the blade at a slightly higher angle than that of the bevel, resulting in the formation of a micro-bevel. The term "hone" is associated with light maintenance performed on a blade without the effort and precision normally associated with sharpening, so the name "hone" was borrowed. In the 1980s, ceramic abrasives became increasingly popular and proved an equal, if not superior, method for accomplishing the same daily maintenance tasks; manufacturers replaced steels with ceramic (and later, manufactured diamond abrasive) sharpening "steels" that were actually hones. Use Honing steels are used by lightly placing the near edge of the blade against the base of the steel, then sliding the blade away from yourself along the steel while moving it down – the blade moves diagonally, while the steel remains stationary. This should be done with the blade held at an angle to the steel, usually about 20°, and repeating on the opposite side at the same angle. This is repeated five to ten times per side. Steeling It is often recommended that steeling be performed immediately before or after using a knife and can be done daily. By contrast, knives are generally sharpened much less frequently. A traditional smooth honing steel is of no use if the edge is blunt, because it removes no material; instead it fixes deformations along the edge of a sharp blade, technically known as burnishing. There has long been speculation about the efficacy of steeling (re-aligning the edge) vs honing (removing minor deformation with abrasives); studies tend to favour abrasives for daily maintenance, especially in high-carbide-volume "stainless" steels (such as the popular CPM S30V steel, which tends to "tear out" when steeled rather than re-forming an edge.) Small honing steel for outdoor activities Usage trends Steels have traditionally been used in the West, especially in heavy-use scenarios (e.g. butchering, where the edge deforms due to forceful contact with bone). These scenarios also lead Western trends toward blades tempered to a lower level of hardness (and thus lower brittleness). In East Asia, notably Japan, harder knives are preferred, so there is little need for steeling intra-day, as the edge does not deform as much. Instead, the blade is honed as needed on a waterstone. While tradition has kept the practice of steeling alive in Western kitchens, the majority of honing steels sold are abrasive rather than smooth, and knives are harder and more frequently made of stainless steel, which does not respond to traditional steeling techniques as well as high-carbon/low alloy tool steels.The sharpening steel is essential to maintain the sharpness of carving and other knives.Steel knife sharpener with bone handle. Part of a carving set.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, sharpening steel, carving set, kitchen equipment

From the early days of our race, the knife represented one of the first and most important tools that enabled rise of our technology, military, culture, science and all other things that brought us to this point of modern civilisation. As a vital tool for survival, combat, construction and food preparation, the knife quickly became the most basic tool from which all others were born. In those ancient times, 500,000 years ago, sharpened stones started slowly evolving, becoming more and more like their modern counterpart. Before the time when fire enabled the melting of the various metals, and forging them into modern knives, their stone counterparts received several visual upgrades. Double bladed knives were most popular, and their wooden or stone hilts were decorated with animal skins and feathers. Those knives represented a great deal of pride for the warriors and elders who owned them, and that tradition continued to be practised with the arrival of the Bronze Age. The appearance of metallurgy brought the ability to create knives from softer types of metal. Even though knives from bronze did not provide durability over longer periods of time [easily dulled, and susceptible to corrosion), their sharpness and slim designed proved to be superior to any stone knife tool. As the centuries went on, iron and then steel became commonplace across the entire world. Knives created from those materials were much more durable and easier to maintain their sharpness after prolonged use. During medieval times in Europe, steel metallurgy managed to evolve knives from small single or double-bladed edges to larger sizes - swords, spears and axes. Even with all those advancements, the use of knives as an eating utensil continued to be used in some small circles. Even as early as the 15th century, wealthy circles of people started carrying personal knives, intended for double use - both eating and defending against threats. During those times the host were not obliged to provide their guest with any kind of eating utensil in addition to plates, so wealthy males used their eating knives for cutting their own meals, and the meals of nearby female guests. Slim double-bladed knives were good for cutting and piercing foods. As the use of forks became widespread in the whole of Europe by the late 17th century, most people used this kind of small knife on a regular basis (a combination of two knives, one for stabilising and other for cutting the meal). http://www.eatingutensils.net/history-of-cutlery/knife-history/The knife is one of the most important items that has enabled the development of civilisation over thousands of years.Carving knife with wooden handle and rusted slender metal blade.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, knife, kitchen equipment, dining

In the high tech, fast paced society that we live in, it’s easy to take some things for granted. Case in point: the wood cutting board on which you’ll probably be preparing the evening’s dinner. Have you ever taken the time to think about the history of the cutting board? Where did it come from, and what did ancient civilizations use to cut their meats, fruits and vegetables? Wood throughout the ages Since the dawn of time, wood has been one of the most available materials used by mankind to build tools and lodgings, so it’s not really surprising to know that wood has been used in the preparation of food since the prehistoric ages. Of course, back then, cavemen probably used an unpolished slab of tree trunk to cut the kill of the day on and they probably didn’t think twice about saving it once the meal was over. Chances are they probably threw it in the fire with the rest of the wood needed to kindle it. Advances in technology Throughout the centuries, mankind evolved and started creating machines from steam, electricity and metal. When the circular saw was invented, nicer, cleaner slabs of wood were cut and used as cutting boards. Since soft wood was the most available type of wood at the time, it was the material of choice for to be used for cutting boards. Boards were made smaller since the slab of wood could now be cut to any desired size. Since they were made smaller, they were also used to eat off of and some people referred to them as trenchers. Trenchers were originally pieces of stale hard bread that were used as substitute plates. Wood trenchers quickly became the replacements of the eatable dinnerware. The butcher block: the cutting board’s larger cousin In the industrial ages, many industries rapidly developed, and the butchery industry followed this trend as well. Before the invention of the cutting board, butchers used tree rounds to carve their meat on. The rounds were often too soft and they rapidly became unsanitary. Hard maple wood butcher blocks were the preferred choice of the industry. They were made to be extremely thick and durable, so durable in fact, that a butcher could use the same block for almost his entire career. Cutting boards around the world As cutting boards began to be more and more used in kitchens around North America, the rest of the world crafted such boards from different materials. The East used thick bamboo as their material of choice. Despite its frail appearance, bamboo is quite strong and made durable cutting boards and butcher blocks. Europe used maple in the crafting of their cutting boards while Persia used flat pieces of polished wood in their kitchens. The world then saw cutting boards that were being made from other materials like plastic and they came in all shapes and sizes, but they always served the same purpose, to provide a household with a safe, clean surface on which to prepare meals for their friends and family members. https://www.woodcuttingboards.com/news/quick-history-of-the-cutting-board-47.aspxThe bread board is an example of kitchen equipment used during Victorian times and similar to those used today.Bread board. Wooden, octagonal, plain sanded light wood. Has decoration around edge and indented circular line to delineate round cutting board section.None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, bread board, cutting board, pastry board, kitchen utensil, kitchen equipment, baking equipment, food preparation

Cast iron stoves burn solid fuel such as wood or coal, and are used for cooking and warmth. The stoves have a firebox with a grate where the fuel is burned. The hot air flows through flues and baffles that heat the stove top and the oven. Before cast iron stoves were invented, cooking and heating were carried out in outdoor open fires, and later, in fireplaces inside the home. In 1642 the first cast iron stove was manufactured in Lynn, Massachusetts, where molten cast iron was poured into a sand mould to make rectangular plates that were then joined together to make a box. Benjamin Franklin invented the more efficient Pennsylvania stove in 1744, and this efficient design is still used today. After the mid-19th century cast iron stoves were produced with burners in different positions, giving varied temperatures, so a wide variety of foods could be cooked at the same time at the most suitable heat, from slow cooking to baking scones. In contemporary times people the new wood-burning stoves had to meet the anti-pollution standards now in place to protect our environment. By the 1920s gas cookers were being introduced for domestic use, and by the 1930s electric home cookers were being offered to householders. PLANET STOVES In August 1925 the firm Cox and Rizzetti, Stove Works, and also Sydney Road, South Melbourne, advertised in the Brunswick and Coburg Leader of November 11, 1925 as "formerly with Harnwell and Sons" and as "specialists in solid cast iron Planet stoves ... which merit an inspection from builders and householders". The firm continued in business and was mentioned as sponsors in the King Island News in 1971. Harnwell and Sons was listed in the Victorian Government Gazette of 1894. It is curious that the firm was mentioned in an article in the Sunrasia Daily of June 14, 1934 titled 'Planet Stoves' as a manufacturer of Planet Stoves. This Planet No 3 stove is an uncommon example of cooking equipment used in kitchens in the early 20th century, as the firebox is above the oven rather than beside it. The cast iron combustion stove is significant as part of the evolution of domestic cooking. Previously cooking was mostly carried out in outdoors in open fires, and later in fireplaces indoors. Cast iron stoves are still used today and have additional features such as thermostats to monitor and maintain temperature, water heating pipes connected, and environmentally approved anti-pollution fittings. Stove; a compact, blackened cast iron combustion cooker, installed within a fireplace and enclosed by bricks on both sides. The upright rectangular stove has a flat top with three round, removable cook plates and a flue connected at the back. The front has three doors with round knob handles; a swing-down firebox door above a sliding ashtray, and two side-hinged oven doors above a sliding opening. Inside on the side walls are two pairs of runners. Behind the pair of doors is an oven with two pairs of rails and two removable metal shelves. The stove has cast inscriptions on the chimney flue and on the front of the right hand side stove door. The model of the stove is The Planet No 3, made in Melbourne.Chimney flue, "[within rectangle] THE / PLANET" Stove door, "(within oval) PLANET / No 3"flagstaff hill, flagstaff hill maritime museum and village, warrnambool, maritime museum, maritime village, great ocean road, shipwreck coast, stove, cast iron stove, combustion stove, wood-burning stove, wood stove, wood oven, solid fuel stove, cooker, the planet, planet, planet no. 3, kitchen equipment, baking, domestic cooking, cooking equipment, food preparation, planet stove, planet cooker, cooking range, slow combustion stove, antique, range cooker, cox and rizzetti, harnwell and sons, melbourne manufacturer

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

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

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

In the high tech, fast paced society that we live in, it’s easy to take some things for granted. Case in point: the wood cutting board on which you’ll probably be preparing the evening’s dinner. Have you ever taken the time to think about the history of the cutting board? Where did it come from, and what did ancient civilizations use to cut their meats, fruits and vegetables? Wood throughout the ages Since the dawn of time, wood has been one of the most available materials used by mankind to build tools and lodgings, so it’s not really surprising to know that wood has been used in the preparation of food since the prehistoric ages. Of course, back then, cavemen probably used an unpolished slab of tree trunk to cut the kill of the day on and they probably didn’t think twice about saving it once the meal was over. Chances are they probably threw it in the fire with the rest of the wood needed to kindle it. Advances in technology Throughout the centuries, mankind evolved and started creating machines from steam, electricity and metal. When the circular saw was invented, nicer, cleaner slabs of wood were cut and used as cutting boards. Since soft wood was the most available type of wood at the time, it was the material of choice for to be used for cutting boards. Boards were made smaller since the slab of wood could now be cut to any desired size. Since they were made smaller, they were also used to eat off of and some people referred to them as trenchers. Trenchers were originally pieces of stale hard bread that were used as substitute plates. Wood trenchers quickly became the replacements of the eatable dinnerware. The butcher block: the cutting board’s larger cousin In the industrial ages, many industries rapidly developed, and the butchery industry followed this trend as well. Before the invention of the cutting board, butchers used tree rounds to carve their meat on. The rounds were often too soft and they rapidly became unsanitary. Hard maple wood butcher blocks were the preferred choice of the industry. They were made to be extremely thick and durable, so durable in fact, that a butcher could use the same block for almost his entire career. Cutting boards around the world As cutting boards began to be more and more used in kitchens around North America, the rest of the world crafted such boards from different materials. The East used thick bamboo as their material of choice. Despite its frail appearance, bamboo is quite strong and made durable cutting boards and butcher blocks. Europe used maple in the crafting of their cutting boards while Persia used flat pieces of polished wood in their kitchens. The world then saw cutting boards that were being made from other materials like plastic and they came in all shapes and sizes, but they always served the same purpose, to provide a household with a safe, clean surface on which to prepare meals for their friends and family members. https://www.woodcuttingboards.com/news/quick-history-of-the-cutting-board-47.aspxThe bread board is an example of kitchen equipment used during Victorian times and similar to those used today.Bread board wooden round with carved inner circle and carving an outer rim in old English lettering "Bread"None.flagstaff hill, warrnambool, shipwrecked-coast, flagstaff-hill, flagstaff-hill-maritime-museum, maritime-museum, shipwreck-coast, flagstaff-hill-maritime-village, chopping board, cooking, kitchen equipment

Early settlers in Moorabbin Shire brought cutlery and other domestic items with them when travelling from England 19thC. This carving set; knife, fork and knife sharpener was used by a pioneer family.This carving set; knife, fork and knife sharpener is typical of the cutlery used by early settlers in Moorabbin Shire c1900 A set of carving implements with ivory handles with chased and repousse silver plate caps and collars; Knife, Fork and Knife sharpener. The Fork has a flip up thumb guard. On Knife: Joseph Elliot & Sons, Cutlers, Sheffield" with the mirror "C"s and Maltese cross mark used after 1825 On knife sharpener: CAST STEELcutlery, cast steel, kitchen equipment, early settlers, moorabbin, cheltenham, ormond, bentleigh

Early settler women in Moorabbin Shire c1900, were skilled in crochet and made these doilies to cover milk jugs, and other food containers, to protect the contents from flies and other insects while on the kitchen table.The women of the early settler families in Moorabbin Shire c1900, were very skilled with craftwork, crochet, knitting, sewing, needlework.A crocheted cotton doily with raised decoration of a cup and saucer. Coloured beads anchor the points to add weight to keep the doily in place when protecting contents of a cup or jugpioneers, earley settlers, haberdashery, craftwork, crochet, doileys, kitchen equipment, moorabbin shire, bentleigh, moorabbin, ormond, cheltenham,

White enamel jugs with graduated measurements were use by early settler women when measuring liquids for cooking and preserving foodA Measuring jug used by early settlers in Moorabbin Shire c1900A white enamel jug with graduated measurements to 40oz / 2pintsSWEDENkitchen equipment, cooking, crockery, casserole, stewed meat, vegetables, early settlers , market gardeners, moorabbin shire, bentleigh, cheltenhsm,

A typical enamel jug used by families in City of Moorabbin for measuring liquids for cooking and preserving c1970A typical enamel measuring jug used by families in City of Moorabbin c1970A cream enamel jug with a green rim graduated measurements 40 oz, 2 pints, 1000gramsInside jug graduated measurements 40oz, 2 pints 1000gms kitchen equipment, cooking, crockery, casserole, stewed meat, vegetables,post world war 11 settlers, moorabbin estates c1970, early settlers , market gardeners, moorabbin shire, bentleigh, cheltenham,

Early settler women were skilled craft workers and crocheted doilies and other napery for their household. This Doiley is a cover for a jug or cup, with the glass beads providing the weight to secure it, to protect the contents from flies, insects and dust while on the kitchen table.Early settler women were skilled in dressmaking, crochet, knitting as they made clothes, furnishings, drapery and tableware for their families c1900A cotton, crocheted doily with a teapot pattern and green beads at edges to keep it in place when protecting contents of a jug or cupkitchen equipment, crochetwork, napery, doilies, milk jugs, early settlers, market gardeners, cooking utensils, kitchenware, castiron cooking pots, blacksmiths, slow cooking, moorabbin shire, bentleigh, mckinnon, highett, cheltenham,

The sections of this wardrobe can be lifted apart so that it can be transported easily and when assembled provides suitable hanging and storage space for the clothes and bed covers of an early settler family This wardrobe is of a type commonly used by early settler families in Moorabbin Shire c1900Wooden Wardrobe with 3 sections- top, hanging space with a central oval glass window, a shallow central drawer and 2 doors with key locks, and drawer section with 2 deep drawers early settlers, market gardeners, poultry farmers, mechanics institutes, furniture, kitchen equipment, clothing, drapery, haberdashery, green pederson carol, city of moorabbin, county of bourke, moorabbin roads board, parish of moorabbin, shire of moorabbin, henry dendy's special survey 1841, were j.b.; bent thomas, highett william, ormond francis, maynard dennis,

In 1873 James Griffiths migrated to Melbourne in order to start a tea Business. James lived in the Dandenongs at The Basin where he experimented with growing tea. Griffiths made tin canisters in the 2lbs size for their tea with common kitchen consumables listed on the front . The tins, when emptied, became useful kitchen canisters and helped promote the brand. Example of the names include Flour, Rice, Sugar, Sago, Candied Peel, Tapioca, Spices, Starch, Biscuits, Currants, Barley, String and of course Tea .Food storage rectangular tin, with a hinged lid. The outside is printed in cream and red with the name 'Griffith's Teas' and the word 'SAGO'. The text is set against a cream panel which is bordered with a decorative border of Australian native flora. The whole is set against a dark green background.On each other side of the tin is a different native Australian flower. The lid is impressed with a flannel flower.Printed on the front 'SAGO', also printed on the front and repeated on the top 'USE / GRIFFITHS' Teas / SYDNEY / MELBOURNE. ADELAIDE. BRISBANE'. On the front is the image of a train signal with the words 'SIGNAL / TRADE MARK'tea, james griffiths, canisters, city of moorabbin, cheltenham, melbourne, moorabbin, grocery stores, kitchen equipment

Old sepia photograph of the inside setting up in the Schwerkolt cottage kitchen post 1965schwerkolt cottage, kitchen equipment

This vintage meat press would have been used for pressed tongue in the 1950's. A vintage 1950's three piece Cook-N-Press CastAlloy brand metal rectangular meat press. It has a flat detachable metal plate at the top which when screwed presses the food within. It was used as a tongue press. 'Cook-n-Press A Product of CastAlloy Ltd'kitchen equipment, kitchenware, food press, meat press

A vintage weighing machine used by merchants or grocers or in kitchens for food sale or preparation. It came from the home of Mr Thomas Gaudion and was used in the 1920's.An antique blue and white speckled cast iron and metal balance scale and weights for weighing food. On one side is a dish shaped oval tray sitting on a claw frame for holding food items and opposite is a smaller plate for holding the steel weights: 4lb, 2lb, 2x 1lb, 8oz, 4oz and 1oz. There are seven in total.'....Ters' with an indecipherable ....'Watters Sydney'kitchen equipment, kitchenware, cooking, scales

This vintage food press may have been used for pressed tongue and other foods. A small vintage round clip on lidded aluminium food press possibly used for pressed tongue. The clip has the manufacturer's name on it with the Patent No. The clip on the lid has a strong thick steel bar threaded through it which is screwed tight to press the food within. It has a very heavy round concrete weight inside.FOOD PRESS WHITTINGSLOWE Product PAT APPN Number 187.....745kitchen equipment, kitchenware, food press, meat press