黑龙江省6种乔木叶片热解特性及气体释放特征

doi:10.13287/j.1001-9332.202201.012

摘要/Abstract

摘要： 森林可燃物是森林火灾发生的基础,地表死可燃物是森林可燃物的重要组成部分,研究地表死可燃物的热解特性和气体释放对探究森林火灾对大气环境和碳平衡的影响及森林火灾的预防和扑救具有重要意义。本研究对黑龙江省6种乔木(樟子松、红皮云杉、水曲柳、胡桃楸、蒙古栎和白桦)地表凋落的叶片进行热重分析和气体释放分析,探究森林可燃物的热解过程及燃烧性,分析了热解特征、热解动力学特征和气体释放特征,并基于热解参数对其燃烧性进行四维评价。结果表明: 研究区6种乔木叶片综纤维素热解开始的温度范围为143.31～180.48 ℃,结束的温度范围为345.04～394.38 ℃;木质素热解开始的温度范围为 345.04～394.38 ℃,结束的温度范围为582.85～609.31 ℃。6种乔木叶片热解过程中综纤维素的热解影响了可燃物灰分含量及总热解的重量、温度。6种乔木叶片2个主要热解阶段的活化能分别为18.88～27.08和13.25～27.54 kJ·mol^-1,指前因子分别为3.13～26.28和1.30～22.55 min^-1,其中,红皮云杉、水曲柳、蒙古栎和白桦综纤维素热解阶段的活化能和指前因子大于木质素热解阶段,而樟子松和胡桃楸则相反。综纤维素热解阶段的CO、CO₂释放量分别为535.16～880.11、7004.97～10302.05 mg·m^-3,木质素热解阶段分别为240.31～1104.67、20425.60～33946.68 mg·m^-3,综纤维素热解阶段释放的CO和CO₂较少,重量损失却大于木质素热解阶段。6种乔木叶片的四维燃烧性排序中,点燃性最好的是白桦,剧烈性最强的是红皮云杉,持续性和消耗性最好的均是樟子松;点燃性与综纤维素的热解动力学参数呈显著正相关,持续性与木质素的热解动力学参数呈显著负相关。

关键词: 可燃物, 热重分析, 热解动力学, 气体释放, 燃烧性

Abstract: Forest fuels are the basis of fire occurrences, while ground dead fuels are an important part of forest fuels. Undestanding the pyrolysis characteristics and gas emissions of forest fuels is of great significance to explore the effects of forest fire on atmospheric environment and carbon balance, as well as to prevent and combat forest fire. In this study, the thermogravimetric analysis and gas emission analysis were conducted on leaf litter of six tree species (Pinus sylvestris var. mongolica, Picea koraiensis, Fraxinus mandshurica, Juglans mandshurica, Quercus mongolica, Betula platyphylla) in Heilongjiang Province to explore the pyrolysis process and combustibility of forest fuels, to analyze their pyrolysis characteristics, pyrolysis kinetics characteristics, gas emission characteristics. A four-dimensional evaluation of their combustibility was conducted based on pyrolysis parameters. The results showed that the pyrolysis temperature of holocellulose in the leaves of those six tree species ranged in 143.31-180.48 ℃ at the beginning and 345.04-394.38 ℃ at the end, lignin pyrolysis temperature ranged in 345.04-394.38 ℃ at the beginning and 582.85-609.31 ℃ at the end. The pyrolysis of the six kinds of arbor blades during the pyrolysis process affected fuel ash content, quality and temperature of the total pyrolysis. The activation energies of two main pyrolysis stages of leaves of six tree species were 18.88-27.08 kJ·mol^-1 and 13.25-27.54 kJ·mol^-1, respectively, and the pre-exponential factors were 3.13-26.28 min^-1 and 1.30-22.55 min^-1. The holocellulose activation energy and pre-exponential factor of the pyrolysis stage for P. koraiensis, F. mandshurica, Q. mongolica, and B. platyphylla were greater than that of the lignin pyrolysis stage, while the opposite was true for P. sylvestris var. mongolica and J. mandshurica. The release amounts of CO and CO₂ at the pyrolysis stage of the holocellulose was 535.16-880.11 mg·m^-3 and 7004.97-10302.05 mg·m^-3, and that at the pyrolysis stage of lignin was 240.31-1104.67 mg·m^-3 and 20425.60-33946.68 mg·m^-3, respectively. The release of CO and CO₂ at the pyrolysis stage of healdellulose was less, but mass loss was greater than that at the pyrolysis stage of lignin. In the four-dimensional combustibility ranking of the six tree species leaves, B. platyphylla was the best ignitable, P. koraiensis was the most combustible, and P. sylvestris var. mongolica was the most sustainable and consumable. The ignitability was significantly positively correlated with pyrolysis kinetics parameters of the holocellulose, while the sustainability was negatively correlated with that of lignin.

Key words: fuel, thermogravimetric analysis, pyrolysis kinetic, gas emission, combustibility

陈伯轩, 郭妍, 范佳乐, 李保中, 谭传巧, 李东晖, 胡海清, 胡同欣. 黑龙江省6种乔木叶片热解特性及气体释放特征[J]. 应用生态学报, 2022, 33(1): 76-84.

CHEN Bo-xuan, GUO Yan, FAN Jia-le, LI Bao-zhong, TAN Chuan-qiao, LI Dong-hui, HU Hai-qing, HU Tong-xin. Pyrolysis and gas emissions characteristics of six tree species in Heilongjiang Province, China[J]. Chinese Journal of Applied Ecology, 2022, 33(1): 76-84.

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