Archive/Study on the Synergistic Spontaneous-Combustion Effects and Critical Behavior of Polyurethane and Residual Coal Based on Large-Scale Programmed Heating Tests
Study on the Synergistic Spontaneous-Combustion Effects and Critical Behavior of Polyurethane and Residual Coal Based on Large-Scale Programmed Heating Tests
Yu Wang, Baoshan Jia, Zikun Pi et al.
7 de julio de 2026
en

Abstract

To address the major safety hazard that heat released from mining polyurethane (PU) reinforcement materials may induce spontaneous combustion of residual coal in goaf, this study selected No. 3 coal from Wangzhuang Coal Mine, Shanxi Lu’an, as the research object. A self-developed large-capacity, large-scale experimental system was used to conduct programmed heating experiments on 2.0 kg multi-particle-size coal-PU mixed samples. The effects of PU content on characteristic gas release, crossing point temperature (CPT), residue morphology, and TGA-DSC characteristic temperatures were systematically investigated, and the reaction-kinetic evolution was further analyzed using the distributed activation energy model (DAEM). The results show that coal and PU exhibit a significant synergistic enhancement effect during co-heating. As the PU content increased, the release concentrations of CO, C2H4, and C2H6 increased markedly, and their initial release temperatures decreased, whereas CH4 generation was inhibited by hydrogen-radical competition; no C2H2 was produced below 400 °C. The CPT decreased linearly with an increasing PU content, with an average decrease of approximately 8.5 °C for every 10% increase in PU content. Residue morphology showed clear critical features: glassy agglomerates appeared when the PU content exceeded 16.67%, and dense bulk coking occurred when the PU/coal mass ratio was greater than 1:10. TGA-DSC analysis showed that when the PU/coal ratio was lower than 1:10, the ignition temperature of the mixed sample was higher than that of pure coal, indicating an inhibitory synergistic effect. When the ratio exceeded 1:10, the ignition temperature decreased significantly, and the synergy shifted to promotion; increasing the heating rate shifted the characteristic temperatures to higher values and increased the reaction intensity. DAEM analysis further confirmed that when the PU ratio exceeded 1:10, the apparent activation energy of the mixed samples was lower than that of pure coal. Coal powder also acted as a physical skeleton that effectively dispersed molten PU, eliminated the activation-energy peaks of pure PU in the conversion ranges of 30–50% and 70–90%, and substantially improved combustion stability. Mechanistically, low-temperature PU melting and coating optimized heat and mass transfer, medium-temperature pyrolysis released active radicals and combustible gases that altered coal pyrolysis pathways and the radical reaction environment, and high-temperature hydrogen-radical competition reshaped the gas-product distribution. Together, these processes form a complete chain of synergistic spontaneous combustion. This study identifies key safety threshold parameters for PU reinforcement materials, recommends a PU content of ≤9.10%, and identifies CO and C2H4 as priority early-warning gases, providing direct experimental evidence for characteristic-gas-based early warning and mine fire prevention.

IPC Classification

C07H01

Keywords

synergisticspontaneous-combustioneffectscriticalbehaviorpolyurethaneresidualcoalbasedlarge-scaleprogrammedheatingtestsfireaddressmajorsafetyhazardheatreleasedminingreinforcementmaterialsinduce
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