A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Recent disasters caused by the spread of fire in buildings and in transportations remind us of the importance of fire protection. Using flame-retardant materials is one important element of the firefighting strategy, which aims to prevent fire development and propagation. These materials are used in different applications, such as in textiles, coatings, foams, furniture, and cables. The development of more efficient and environmentally friendly flame-retardant additives is an active multidisciplinary approach that has attracted a great deal of interest. Studies have aimed at the development of new, sustainable, and flame-retardant additives/materials, providing high performance and low toxicity. Also studied were their properties during ageing and recycling, as well as modeling physical and chemical processes occuring before ignition and during their combustion. The development of sustainable flame retardants and understanding their modes of action provide a strong link between these topics and cover many fields from organic chemistry, materials engineering, and toxicology, to physics and mathematics.
Recent disasters caused by the spread of fire in buildings and in transportations remind us of the importance of fire protection. Using flame-retardant materials is one important element of the firefighting strategy, which aims to prevent fire development and propagation. These materials are used in different applications, such as in textiles, coatings, foams, furniture, and cables. The development of more efficient and environmentally friendly flame-retardant additives is an active multidisciplinary approach that has attracted a great deal of interest. Studies have aimed at the development of new, sustainable, and flame-retardant additives/materials, providing high performance and low toxicity. Also studied were their properties during ageing and recycling, as well as modeling physical and chemical processes occuring before ignition and during their combustion. The development of sustainable flame retardants and understanding their modes of action provide a strong link between these topics and cover many fields from organic chemistry, materials engineering, and toxicology, to physics and mathematics.
Advanced Flame Retardant Materials
Laoutid, Fouad (author)
2021-02-11
Miscellaneous
Electronic Resource
English
Q1-390 , QC1-999 , nano-SiO2 , polymer flammability , biodegradable , fracture toughness , microcalorimetry of combustion , lignin , ZIF-8@GO hybrids , poly(3-hydroxybutyrate) (PHB) , biomaterials , epoxy novolac resin , phosphorylation , PLA ROP , thermal decomposition , polyamide 11 , flame retardant , biobased materials , flame retardance , flexible , phenolic resin , condensed phase , aluminum diethylphosphinate , PLA , melamine triazine , chain extension , EVA/LLDPE blend , reactive flame retardancy , dielectric constant , clay , composites , ammonium polyphosphate , phosphorus-containing flame retardant , flame retardancy , calorimetry , pyrolysis–combustion flow calorimetry , fire reaction , DOPO , van Krevelen approach , melamine , wire and cable , cotton fabrics , organophosphorus compounds , flame-retardant , lignin nanoparticles , polylactide , group contributions , bic Book Industry Communication::G Reference , information & interdisciplinary subjects::GP Research & information: general
DDC:
624
Flame Retardant Polyolefinic Materials
| British Library Online Contents | 1998
Flame Retardant Materials and Materials Life
| British Library Online Contents | 1998
FLAME-RETARDANT MEMBER, FLAME-RETARDANT COMPOSITION, AND FLAME-RETARDANT DISPERSION LIQUID
| European Patent Office | 2018
Environmentally Safe Flame Retardant Materials
| British Library Conference Proceedings | 2010