| Endothermic |
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| CATEGORIES ABOUT ENDOTHERMIC | |
| thermodynamics | |
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ENDOTHERMIC MATERIALS IN PASSIVE FIRE PROTECTION See Also: Passive fire protection Endothermic substances, both natural, e.g. Gypsum , and synthetic, e.g. Resin -based Intumescent s, are popular for use in heatshielding, e.g. Ablation , materials in Space Physics , fireproofing, e.g. fire-resistive coatings for LPG vessels, and compartmentalisation of fire in Building s, which is the cornerstone of passive fire protection. Typically, the technological basis is the conversion of Hydrate s, or chemically bound Water into vapour, or Steam . Steam, at a 100°C, is considered ''cold'' in Fire Protection . The aim in passive fire protection is typically to maintain the item or the side to be protected at or below either 140°C (for walls, floors and electrical circuits required to have a fire-resistance rating) or ca. 540°C, which is considered the critical Temperature for structural Steel , above which, it is in jeopardy of losing its strength, leading to collapse. Fire testing involves live fire exposures upwards of 1100°C, depending on the fire-resistance rating and duration one is after. So long as the protective endothermic layer still contains Hydrates , the temperature on the unexposed side cannot climb above the boiling point of water. As soon as all the water is spent in fire-resistance testing, the temperature on the unexposed side of fire test specimens, ''of conventional design'', typically increases ''rapidly''. Common endothermic Building Materials include Concrete and gypsum wallboard. During fire testing of concrete floor slabs, water can be seen to literally boil out of a slab. Gypsum wall board typically loses all its strength during a fire, underlining the need for stringent Bounding . The use of endothermic materials is established and proven to be sound Engineering practice. Too much water can be a problem, however. Concrete slabs that are too wet, will literally explode in a fire, which is why test laboratories insist on measuring water content of concrete and mortar in fire test specimens, before running any fire tests. SEE ALSO
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