Experimental study of the burning characteristics of typical aircraft cabin materials at various pressures
LIU Quanyi1, SUN Zhongzheng1, LÜ Zhihao1, JIA Xuhong1, ZHI Maoyong1, ZHANG Hui2
1. College of Civil Aviation Safety Engineering, Civil Aviation Flight University of China, Guanghan 618307, China; 2. Institute of Public Safety Research, Tsinghua University, Beijing 100084, China
Abstract:The burning characteristics of aircraft cabin materials must be well characterized to enable prevention and early detection of in-flight fires. This study characterized two aircraft cabin materials for the seat and the interior wall at Kangding Airport in Sichuan Province where the atmospheric pressure is 61.0 kPa and at Guanghan where the pressure is 96.0 kPa. The experiments measured the mass loss ratio, smoke density, smoke components, and flame shape to examine the effect of low pressure on the burning characteristics. The results show that both materials have higher mass loss ratios at 96.0 kPa than at 61.0 kPa. However, the smoke density increases rapidly and changes more at 61.0 kPa. The smoke density peaks for both materials at 61.0 kPa are twice those at 96.0 kPa. Although the times to reach the peak concentrations of CO and CO2 are nearly the same, the concentrations of CO and CO2 are quite different for the two pressures.
刘全义, 孙中正, 吕志豪, 贾旭宏, 智茂永, 张辉. 不同压力条件下典型机舱材料燃烧特征的实验研究[J]. 清华大学学报(自然科学版), 2019, 59(6): 432-437.
LIU Quanyi, SUN Zhongzheng, LÜ Zhihao, JIA Xuhong, ZHI Maoyong, ZHANG Hui. Experimental study of the burning characteristics of typical aircraft cabin materials at various pressures. Journal of Tsinghua University(Science and Technology), 2019, 59(6): 432-437.
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