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A platform for research: civil engineering, architecture and urbanism
Fire suppression and thermal behavior of biobased rigid polyurethane foam filled with biomass incineration waste ash
Currently, there is great demand to implement circular economy principles and motivate producers of building materials to integrate into a closed loop supply chain system and improve sustainability of their end-product. Therefore, it is of great interest to replace conventional raw materials with inorganic or organic waste-based and filler-type additives to promote sustainability and the close loop chain. This article investigates the possibility of bottom waste incineration ash (WA) particles to be used as a flame retardant replacement to increase fire safety and thermal stability under higher temperatures. From 10 wt.% to 50 wt.% WA particles do not significantly deteriorate performance characteristics, such as compressive strength, thermal conductivity, and water absorption after 28 days of immersion, and at 32 °C WA particles improve the thermal stability of resultant PU foams. Furthermore, 50 wt.% WA particles reduce average heat release by 69% and CO2 and CO yields during fire by 76% and 77%, respectively. Unfortunately, WA particles do not act as a smoke suppressant and do not reduce smoke release rate.
Fire suppression and thermal behavior of biobased rigid polyurethane foam filled with biomass incineration waste ash
Currently, there is great demand to implement circular economy principles and motivate producers of building materials to integrate into a closed loop supply chain system and improve sustainability of their end-product. Therefore, it is of great interest to replace conventional raw materials with inorganic or organic waste-based and filler-type additives to promote sustainability and the close loop chain. This article investigates the possibility of bottom waste incineration ash (WA) particles to be used as a flame retardant replacement to increase fire safety and thermal stability under higher temperatures. From 10 wt.% to 50 wt.% WA particles do not significantly deteriorate performance characteristics, such as compressive strength, thermal conductivity, and water absorption after 28 days of immersion, and at 32 °C WA particles improve the thermal stability of resultant PU foams. Furthermore, 50 wt.% WA particles reduce average heat release by 69% and CO2 and CO yields during fire by 76% and 77%, respectively. Unfortunately, WA particles do not act as a smoke suppressant and do not reduce smoke release rate.
Fire suppression and thermal behavior of biobased rigid polyurethane foam filled with biomass incineration waste ash
Kairytė, Agnė (author) / Kremensas, Arūnas (author) / Vaitkus, Saulius (author) / Czlonka, Sylwia (author) / Strąkowska, Anna (author)
2020-01-01
Polymers, Basel : MDPI AG, 2020, vol. 12, iss. 3, art. no. 683, p. 1-13 ; eISSN 2073-4360
Article (Journal)
Electronic Resource
English
DDC:
690
Fire resistance of rigid polyurethane foam
Engineering Index Backfile | 1966
Fire and Ecotoxicological Aspects of Polyurethane Rigid Foam
| Online Contents | 2001