地下煤火阴燃自维持特性与热浮力驱动供氧能耗研究OA
Study on self-sustaining characteristics and buoyancy-driven oxygen supply energy consumption of underground coal smoldering fires
地下煤火是一种全球性的重大灾害,其可以在自身产生的高温烟气引发的热浮力驱动作用下保持长期的自维持阴燃,这种自维持特性是地下煤火持久致灾、极难防控的根本原因,如何理解这种自维持特性仍是尚未解决的科学难题.从能量分析的角度探索地下煤火的自维持特性原理,通过搭建小尺度实验装置开展热浮力驱动地下煤火物理相似实验,利用不同厚度的多孔泡沫构建不同的热浮力驱动供风条件,结合数值模拟获得了不同热浮力驱动供风条件下地下煤火阴燃过程中烟气温度、热浮力及其引起的风速变化,并进一步分析了热浮力驱动供氧能耗与烟气排出能量之间的关系.结果表明:随着泡沫厚度的增加,烟气温度逐渐降低,热浮力及其引发的风速均逐渐减小,地下煤火阴燃强度逐渐减弱,热浮力驱动供氧能耗逐渐减少,但其相对于烟气排出能量的比值变化不大;热浮力驱动供氧能耗相对于烟气排出能量的比值随地裂缝深度增加而增大,但总体比值极小,随地裂缝深度变化在 10-5~10-3 区间内变化;相对于烟气排出能量,仅需耗费极小比例(可低至十万分之一)便可以实现热浮力驱动下的地下煤火自维持蔓延,这也是地下煤火极难防控的根本原因之一.
Underground coal fire is a kind of global major disaster,which can maintain long-term self-sustained smoldering under the thermal buoyancy driven by the high-temperature flue gas generated within the fire.This self-sustaining characteristic is the fun-damental reason for the persistent,disastrous,and highly challenging nature of underground coal fire control.However,understand-ing the mechanism behind this self-sustaining behavior remains an unresolved scientific challenge.This study aims to explore the principle of self-sustaining characteristics of underground coal fires from the perspective of energy analysis.A small-scale experi-mental device is set up to carry out physical similarity experiments of underground coal fires driven by thermal buoyancy.Porous foams with different thicknesses are used to construct different thermal buoyancy driven airflow conditions.Combined with numeric-al simulations,the study examines variations in flus gas temperature,thermal buoyancy,and the resulting airflow under different smoldering conditions.Furthermore,the relationship between oxygen supply energy consumption driven by thermal buoyancy and the energy of smoke exhaust is analyzed.The results show that with the increase of foam thickness,the flus gas temperature gradully decreases,thermal buoyancy and the wind speed caused by it decrease,the smoldering intensity of underground coal fire decreases,and the energy consumption driven by thermal buoyancy decreases,but the ratio of thermal buoyancy to the exhaust energy of flus gas changes little.The ratio of oxygen supply energy to flue gas emission energy of thermal buoyancy drive increases with increas-ing crack depth,but the overall ratio is very small,and the change of crack depth varies within the range of 10-5-10-3.Research shows that compared with flue gas discharge energy,only a very small proportion(as low as one in a hundred-thousand)can be used to realize the self-sustaining spread of underground coal fires driven by thermal buoyancy,which is one of the fundamental reasons why underground coal fires are extremely difficult to control.
戴仁坤;宋泽阳;芦星;肖旸;邓军
西安科技大学 安全科学与工程学院,陕西 西安 710054西安科技大学 安全科学与工程学院,陕西 西安 710054西安科技大学 安全科学与工程学院,陕西 西安 710054西安科技大学 安全科学与工程学院,陕西 西安 710054西安科技大学 安全科学与工程学院,陕西 西安 710054
矿业与冶金
地下煤火阴燃热浮力自维持能量分析
underground coal firesmolderingthermal buoyancyself-sustainingenergy analysis
《煤矿安全》 2026 (2)
43-49,7
陕西省博士后科研资助项目(2023BSHYDZZ155)陕西省自然科学基础研究计划资助项目(2024JC-YBQN-0422)国家自然科学基金面上资助项目(52474247)
评论