Synergistic flame retardant effect of a new N-P flame retardant on poplar wood density board

•A new reactive flame retardant containing P and N elements (ATITP) was synthesized.•The gasses generated during thermal degradation were analyzed by TG-FTIR and Py-GC–MS methods.•The incorporation of ATITP flame retardant provided a fire-resistant expansive carbon.•The ATITP flame retardant was cov...

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Bibliographic Details
Published in:Polymer degradation and stability 2023-05, Vol.211, p.110331, Article 110331
Main Authors: Yan, Dong, Chen, Dong, Tan, Jia, Yuan, Liping, Huang, Zizhi, Zou, Dongfang, Sun, Penghao, Tao, Qiang, Deng, Jiyong, Hu, Yunchu
Format: Article
Language:English
Subjects:
ammonium
calorimetry
carbon dioxide
combustion
Density board
Flame retardant
flame retardants
heat
oxygen
polymers
Populus
spectrometers
Synthesis
Thermal decomposition
thermal degradation
thermogravimetry
wood
wood density
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Summary:•A new reactive flame retardant containing P and N elements (ATITP) was synthesized.•The gasses generated during thermal degradation were analyzed by TG-FTIR and Py-GC–MS methods.•The incorporation of ATITP flame retardant provided a fire-resistant expansive carbon.•The ATITP flame retardant was covalently grafted onto wood fibers through P(=O)-O-C covalent bonds, which improved the flame resistance of poplar density board. A new and efficient flame retardant consisting of Ammonium tris (2-hydroxyethyl) isocyanurate triphosphate (ATITP) was prepared by a solvent-free synthesis method for improving the flame retardancy of poplar wood density boards. The flame retardant mechanism was probed, and the mechanism of capturing combustion radicals, synergistically promoting charring and inhibiting heat was summarized. The density board treated with 20% ATITP had an ultimate oxygen index (LOI) of was up to 65.1%. In the experiment of cone calorimetry (CONE), the total heat release (THR) of flame retardant density board was reduced by 73.9% compared with the pure density board sample, while the heat release rate (HRR), CO and CO2 production were significantly reduced. In addition, the analysis with a thermogravimetric infrared coupler (TG-FTIR) and thermal cracking gas mass spectrometer (Py-GC–MS) revealed that the flame retardant exerted a gas-phase and condensed-phase flame retardant during the thermal decomposition process to alter the thermal cracking pathway of wood powder. It was demonstrated that the poplar density board treated with ATITP has good flame retardancy, which provides a simple and efficient method for flame retardant density board for building materials. [Display omitted]
ISSN:0141-3910
1873-2321
DOI:10.1016/j.polymdegradstab.2023.110331