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Quote from: lightarrow on 12/09/2007 20:12:24Quote from: Bored chemist on 12/09/2007 19:57:49"In 1669, phosphorous was discovered by evaporation of urine. "No it wasn't, there's more to it than just evaporation."The point about metallic sodium is that there was a precondition which was required, and access to such a precondition (the discovery of electricity) has such wide implications in other technologies that would have changed the entire technological base of the civilisation"The sort of furnace you need to get phosphorus would have showed up nearly as well in the historical record as electricity would. It is possible (at least thermodynamicly) to reduce sodium carbonate to sodium with charcoal. The temperature required is less than that needed to produce phosphorus. Using the standard industrial process, yes (calcium phosphate + charcoal + silica), but I wonder if it's difficult the same (in terms of temperatures needed) using other phosphates. What kind of temperatures are we talking about, and how does this relate to the temperatures that would have been commonplace in metal ore reduction?
Quote from: Bored chemist on 12/09/2007 19:57:49"In 1669, phosphorous was discovered by evaporation of urine. "No it wasn't, there's more to it than just evaporation."The point about metallic sodium is that there was a precondition which was required, and access to such a precondition (the discovery of electricity) has such wide implications in other technologies that would have changed the entire technological base of the civilisation"The sort of furnace you need to get phosphorus would have showed up nearly as well in the historical record as electricity would. It is possible (at least thermodynamicly) to reduce sodium carbonate to sodium with charcoal. The temperature required is less than that needed to produce phosphorus. Using the standard industrial process, yes (calcium phosphate + charcoal + silica), but I wonder if it's difficult the same (in terms of temperatures needed) using other phosphates.
"In 1669, phosphorous was discovered by evaporation of urine. "No it wasn't, there's more to it than just evaporation."The point about metallic sodium is that there was a precondition which was required, and access to such a precondition (the discovery of electricity) has such wide implications in other technologies that would have changed the entire technological base of the civilisation"The sort of furnace you need to get phosphorus would have showed up nearly as well in the historical record as electricity would. It is possible (at least thermodynamicly) to reduce sodium carbonate to sodium with charcoal. The temperature required is less than that needed to produce phosphorus.
Do you have any ideas as to what technical developments happened between 670 and 1669 to allow this increase in furnace temperature?
Quote from: another_someone on 12/09/2007 22:07:53What kind of temperatures are we talking about, and how does this relate to the temperatures that would have been commonplace in metal ore reduction?The industrial process happens in electric oven, so the temperatures are higher than 2000°C, but reducing (still with C) other phosphates, the temperatures should be much less, around 900°C, according to some informations taken from the web (don't know if true).QuoteDo you have any ideas as to what technical developments happened between 670 and 1669 to allow this increase in furnace temperature?Always been bad in hystory...
What kind of temperatures are we talking about, and how does this relate to the temperatures that would have been commonplace in metal ore reduction?
The oldest known blast furnaces in the West were built in Dürstel in Switzerland, the Märkische Sauerland in Germany, and Sweden at Lapphyttan where the complex was active between 1150 and 1350. At Noraskog in the Swedish county of Järnboås there have also been found traces of blast furnaces dated even earlier, possibly to around 1100. These early blast furnaces, like the Chinese examples, were very inefficient compared to those used today. The iron from the Lapphyttan complex was used to produce balls of wrought iron known as osmonds, and these were traded internationally - a possible reference occurs in a treaty with Novgorod from 1203 and several certain references in accounts of English customs from the 1250s and 1320s. Other furnaces of the 13th to 15th centuries have been identified in Westphalia.Knowledge of certain technological advances was transmitted as a result of the General Chapter of the Cistercian monks, including the blast furnace, as the Cistercians are known to have been skilled metallurgists. According to Jean Gimpel, their high level of industrial technology facilitated the diffusion of new techniques: "Every monastery had a model factory, often as large as the church and only several feet away, and waterpower drove the machinery of the various industries located on its floor." Iron ore deposits were often donated to the monks along with forges to extract the iron, and within time surpluses were being offered for sale. The Cistercians became the leading iron producers in Champagne, France, from the mid-13th century to the 17th century, also using the phosphate-rich slag from their furnaces as an agricultural fertilizer.Archaeologists are still discovering the extent of Cistercian technology. At Laskill, an outstation of Rievaulx Abbey and the only medieval blast furnace so far identified in Britain, the slag produced was low in iron content. Slag from other furnaces of the time contained a substantial concentration of iron, whereas Laskill is believed to have produced cast iron quite efficiently. Its date is not yet clear, but it probably did not survive Henry VIII's Dissolution of the Monasteries in the late 1530s, as an agreement (immediately after that) concerning the 'smythes' with the Earl of Rutland in 1541 refers to blooms. Nevertheless, the means by which the blast furnace spread in medieval Europe has not finally been determined.Early modern blast furnaces: origin and spreadThe direct ancestor of those used in France and England was in the Namur region in what is now Belgium. From there, they spread first to the Pays de Bray on the eastern boundary of Normandy and from there to the Weald of Sussex, where the first furnace (called Queenstock) in Buxted was built in about 1491, followed by one at Newbridge in Ashdown Forest in 1496. They remained few in number until about 1530 but many were built in the following decades in the Weald, where the iron industry perhaps reached its peak about 1590. Most of the pig iron from these furnaces was taken to finery forges for the production of bar iron.The first British furnaces outside the Weald were not built until the 1550s, but many were built in the remainder of that century and the following ones. The output of the industry probably peaked about 1620, and was followed by a slow decline until the early 18th century. This was apparently because it was more economic to import iron from Sweden and elsewhere than to make it in some more remote British locations. Charcoal that was economically available to the industry was probably being consumed as fast as the wood to make it grew.
Archaeologists and historians debate whether bloomery-based ironworking ever spread to China from the Middle East. Around 500 BC, however, metalworkers in the southern state of Wu developed an iron smelting technology that would not be practiced in Europe until late medieval times. In Wu, iron smelters achieved a temperature of 1130°C, hot enough to be considered a blast furnace which could create cast iron. At this temperature, iron combines with 4.3% carbon and melts. As a liquid, iron can be cast into molds, a method far less laborious than individually forging each piece of iron from a bloom.Cast iron is rather brittle and unsuitable for striking implements. It can, however, be decarburized to steel or wrought iron by heating it in air for several days. In China, these ironworking methods spread northward, and by 300 BC, iron was the material of choice throughout China for most tools and weapons. A mass grave in Hebei province, dated to the early third century BC, contains several soldiers buried with their weapons and other equipment. The artifacts recovered from this grave are variously made of wrought iron, cast iron, malleabilized cast iron, and quench-hardened steel, with only a few, probably ornamental, bronze weapons.During the Han Dynasty (202 BC–AD 220), Chinese ironworking achieved a scale and sophistication not reached in the West until the eighteenth century. In the first century, the Han government established ironworking as a state monopoly and built a series of large blast furnaces in Henan province, each capable of producing several tons of iron per day. By this time, Chinese metallurgists had discovered how to puddle molten pig iron, stirring it in the open air until it lost its carbon and became wrought iron. (In Chinese, the process was called chao, literally, stir frying.) By the 1st century BC, Chinese metallurgists had found that wrought iron and cast iron could be melted together to yield an alloy of intermediate carbon content, that is, steel. According to legend, the sword of Liu Bang, the first Han emperor, was made in this fashion. Some texts of the era mention "harmonizing the hard and the soft" in the context of ironworking; the phrase may refer to this process. Also, the ancient city of Wan (Nanyang) from the Han period forward was a major center of the iron and steel industry. Along with their original methods of forging steel, the Chinese had also adopted the production methods of creating Wootz steel, an idea imported from India to China by the 5th century AD
I heard back in medieval times they used a incendiary called Greek fire which is either fired by bow or catapult. it is lit then fired and after its fired it cannot be put out with water. in fact it makes it worse i would like to know what and how this is made and how they extinguished it if they couldn't use water .
From Wikipedia Others have posited a flammable liquid that floated on water, possibly a form of naphtha or another low-density liquid hydrocarbon, as petroleum was known to Eastern chemists long before its use became widespread in the 1800s.