安全与环境学报
安全與環境學報
안전여배경학보
JOURNAL OF SAFETY AND ENVIRONMENT
2009年
6期
116-120
,共5页
季经纬%郝耀华%王玉%张敬瑶%李金鸽
季經緯%郝耀華%王玉%張敬瑤%李金鴿
계경위%학요화%왕옥%장경요%리금합
安伞工程%着火性能%木材%线性增长热流%复合判据
安傘工程%著火性能%木材%線性增長熱流%複閤判據
안산공정%착화성능%목재%선성증장열류%복합판거
safety engineering%flammability%wood%linear increased heat flux%combined criterion
为探索木材在热流变化时的着火特点并提出着火判据,通过试验研究了木材在线性增长热流条件下的自发着火性能,测定了泡桐、椿木、榆木和刺槐4种木材的点燃时间、木材表面的入射热流以及试样内部的温度.结果表明.当热流增长率大于等于0.199kw/(m~2·s)时,试验的所有木材均可以被点燃,点燃这些木材的临界热流增长率介于0.065~0.103 kw/(m~2·s).建立了木材着火的计算模型,计算得出木材自发着火时的表面温度约为500℃.根据试验和计算的结果提出了-结合表面温度和临界热流增长率的木材自发着火复合判据.
為探索木材在熱流變化時的著火特點併提齣著火判據,通過試驗研究瞭木材在線性增長熱流條件下的自髮著火性能,測定瞭泡桐、椿木、榆木和刺槐4種木材的點燃時間、木材錶麵的入射熱流以及試樣內部的溫度.結果錶明.噹熱流增長率大于等于0.199kw/(m~2·s)時,試驗的所有木材均可以被點燃,點燃這些木材的臨界熱流增長率介于0.065~0.103 kw/(m~2·s).建立瞭木材著火的計算模型,計算得齣木材自髮著火時的錶麵溫度約為500℃.根據試驗和計算的結果提齣瞭-結閤錶麵溫度和臨界熱流增長率的木材自髮著火複閤判據.
위탐색목재재열류변화시적착화특점병제출착화판거,통과시험연구료목재재선성증장열류조건하적자발착화성능,측정료포동、춘목、유목화자괴4충목재적점연시간、목재표면적입사열류이급시양내부적온도.결과표명.당열류증장솔대우등우0.199kw/(m~2·s)시,시험적소유목재균가이피점연,점연저사목재적림계열류증장솔개우0.065~0.103 kw/(m~2·s).건립료목재착화적계산모형,계산득출목재자발착화시적표면온도약위500℃.근거시험화계산적결과제출료-결합표면온도화림계열류증장솔적목재자발착화복합판거.
This paper intends to present our investigation and experimentation results of our study on auto-ignition characteristics of wooden material at a variable heat flux so as to disclose the auto-ignition mechanism. For our research purpose, we have also observed and tested the auto-ignition behaviors of wood under the conditions of a variable linear increase of the heat-flux with the device for fire performance at the early stage (DEPES) . In our study, the output power of the radiation plate in the DFPES were adjusted to 30% , 40% , 50% , 60%, 70% , 80% and 100% so as to form a sequence of variable heat flux with an increasing rate from 0.065 kW/(m~2·s) to 0.968 kW/(m~2·s) . When we did our experiments, we were trying to use four kinds of wood, I. E. Paulownia, toon, elm and acacia, with the ignition time, the incident heat flux and interior temperature being measured carefully. The heat flux to be introduced to the sample surface was measured by a non-water-cooled heat-flux gauge and the interior temperature was checked by three thermocouples which were inserted in the sample before the test. Test results of ours show that all of the samples can be ignited if the heat flux increasing rate is greater than 0.199 kW/(m~2·s). But if the heat flux increasing rate is less than 0.199 kW/(m~2·s), some of the samples used would fail to get ignited. Thus, the experimental facts we have found prove that the critical heat flux increase rate for wood ignition is between 0.065 kW/(m~2·s) and0.103 kW/(m~2·s). Based on the heat conduction model, a numerical model has been developed to calculate the variation of the wood temperatures. Since the wood ignition time can be measured in the tests, the surface ignition temperature can be worked out with the help of the numerical model, with the value of the autoignition temperature being about 500 °C for wood. And, finally, a comprehensive autoignition criteria, including the surface temperature and the critical heat flux increasing rate can be shown in accordance with the testing and calculation results.