火灾科学
火災科學
화재과학
FIRE SAFETY SCIENCE
2012年
3期
131-136
,共6页
陈景鹏%韩斯宇%孙克%栾骁
陳景鵬%韓斯宇%孫剋%欒驍
진경붕%한사우%손극%란효
TNT当量模型%TNO多能模型%摩尔百分比%爆炸%危害性%设防距离
TNT噹量模型%TNO多能模型%摩爾百分比%爆炸%危害性%設防距離
TNT당량모형%TNO다능모형%마이백분비%폭작%위해성%설방거리
TNT equivalent model%TNO model%Mole percentage%Blast%Risk%Fortification
针对航天发射场一旦发生低温推进剂泄漏而导致火箭爆炸,会对人员和财产造成重大损失的问题,采用TNT当量模型和TNO(The Netherlands Organization)多能模型计算不同摩尔百分比的氢氧推进剂混合反应时产生爆炸冲击波的危害性,并模拟爆炸冲击波造成的事故影响范围,然后对两种模型的仿真结果加以对比分析,根据最不利原则选取出最终需要的结果,最后划分出安全设防距离。由仿真结果可知,不同的氢氧混合摩尔百分比造成的爆炸后果不同,同时TNT当量模型在爆炸近场处高估了爆炸超压值,在爆炸远场处低估了爆炸超压值,而TNO多能模型在理论上有效地对这一缺陷进行了弥补。对航天发射场的安全布局起到了一定的参考价值。
針對航天髮射場一旦髮生低溫推進劑洩漏而導緻火箭爆炸,會對人員和財產造成重大損失的問題,採用TNT噹量模型和TNO(The Netherlands Organization)多能模型計算不同摩爾百分比的氫氧推進劑混閤反應時產生爆炸遲擊波的危害性,併模擬爆炸遲擊波造成的事故影響範圍,然後對兩種模型的倣真結果加以對比分析,根據最不利原則選取齣最終需要的結果,最後劃分齣安全設防距離。由倣真結果可知,不同的氫氧混閤摩爾百分比造成的爆炸後果不同,同時TNT噹量模型在爆炸近場處高估瞭爆炸超壓值,在爆炸遠場處低估瞭爆炸超壓值,而TNO多能模型在理論上有效地對這一缺陷進行瞭瀰補。對航天髮射場的安全佈跼起到瞭一定的參攷價值。
침대항천발사장일단발생저온추진제설루이도치화전폭작,회대인원화재산조성중대손실적문제,채용TNT당량모형화TNO(The Netherlands Organization)다능모형계산불동마이백분비적경양추진제혼합반응시산생폭작충격파적위해성,병모의폭작충격파조성적사고영향범위,연후대량충모형적방진결과가이대비분석,근거최불리원칙선취출최종수요적결과,최후화분출안전설방거리。유방진결과가지,불동적경양혼합마이백분비조성적폭작후과불동,동시TNT당량모형재폭작근장처고고료폭작초압치,재폭작원장처저고료폭작초압치,이TNO다능모형재이론상유효지대저일결함진행료미보。대항천발사장적안전포국기도료일정적삼고개치。
Leakage of cryogenic propellants at a space launch center may lead to rocket explosion, causing great losses. In this paper, we use the TNT equivalent model and the TNO (The Netherlands Organization) model to evaluate the risk of shock wave for different mole percentages of reaction in hydrogen and oxygen propellant mixed. The effects of the accident caused by the blast are also simulated. The simulation results of the two models are analyzed and compared. The results are determined by the principles of most unfavorable conditions. Finally the fortification distance is partitioned. The simulation results show that different molar percentages of hydrogen and oxygen mixed cause different consequences of explosion. It is found that the TNT equivalent model overestimates the value of explosion overpressure in the blast near-field and underestimates the explosion overpressure in the blast far-field. The TNO multi-energy model, however, can overcome these limitations effectively in theory.
