开放和封闭空间内不同间隙的竖向电缆燃烧试验研究

为了研究封闭空间对竖向电缆燃烧过程的影响,在开放空间和封闭空间内分别进行了一系列不同间隙的竖向电缆燃烧试验。通过分析开放空间和封闭空间内不同电缆间隙的竖向电缆燃烧过程中质量损失速率,得到电缆之间的间隙对竖向电缆燃烧速率有着决定性的影响。通过对比开放空间和封闭空间内竖向电缆的燃烧过程发现,封闭空间对竖向电缆燃烧过程的影响作用存在一个临界区间,该区间的临界判据是由电缆燃烧火焰对电缆的热作用和封闭空间内烟气层对电缆的热反馈决定的。基于封闭空间内的竖向温度分布,通过分析其无量纲温度梯度,得到封闭空间内竖向电缆燃烧过程存在一个特征明显的温度过渡区域。     

煤质粉末活性炭自燃和热稳定性分析

针对煤质粉末活性炭最显著的热危险特性——自燃危险性进行试验。采用粉尘层最低着火温度测定系统对煤质粉末活性炭进行自燃试验,测定煤质粉末活性炭的最低着火温度;采用SDT Q600热重分析仪测定煤质粉末活性炭在氮气和空气气氛中以20℃/min的速率升温至700℃时的热解和燃烧特性,通过TG/DTG曲线计算其着火温度,并进行热稳定性评价。粉尘层自燃试验结果表明,煤质粉末活性炭最低着火温度为400℃,具有自燃危险性,易形成阴燃;氮气气氛中热解试验表明,热解过程经历了室温~120.0℃和280.0~700.0℃两次轻缓失重阶段,646.44℃时挥发分热失重速率最大,对应热失重速率峰值为0.082 6%/℃,自燃危险性较低;空气气氛中燃烧试验表明,燃烧过程经历了室温~95.5℃和300.0~600.0℃两次剧烈失重阶段,分别为吸附水分受热蒸发和氧化生成的有机官能团分解脱附导致,565.35℃时挥发分热失重速率最大,对应热失重速率峰值为13.20%/min,粉末较强的氧气吸附效应和较低的导热系数导致其自燃倾向较高,火灾危险性较大。     

火焰引燃高速列车行李燃烧特性全尺寸试验研究

以CRH1高速列车20 kg旅客行李为研究对象,采用家具量热仪和全尺寸试验研究了不同引火源功率、不同通风量等条件下行李点燃特性、热释放速率、质量损失率、热释放总量、烟气释放速率等火灾参数,总结了其燃烧行为及特性。结果表明:高速列车20 kg旅客行李燃烧特性易受通风量、引火源功率等火场环境影响;引燃时间为1~2 min,持续燃烧时间在27~35 min;热释放速率可达347.3 k W以上,因行李压实较为紧密,燃烧不够充分,产生大量高温未完全燃烧气体,极大程度增加列车车厢回燃性;质量损失率较小,行李燃烧不充分;温升速率快,最高温度可达230℃;产烟量较大,透光率最低为35%;行李热释放总量THR随着引火源功率增加而增大,最高可达到213 MJ,控制引火源功率是减小行李热释放总量THR的关键。     

黑箱加速大气暴露试验热强化效应和相关性研究

利用温湿度测量仪监测黑箱内的温湿度变化,分析黑箱自然加速试验装置的热强化效应。以3种不同配方的丙烯酸涂料为试验对象,在江津地区高温高湿环境下开展了黑箱加速大气暴露试验和朝南45°角大气暴露试验,从模拟性和加速性2个方面研究了2种试验方法的相关性。分析结果表明,黑箱加速大气暴露试验方法与朝南45°角大气暴露试验方法之间的相关性相当高。     

野战弹药储存防热现状及温度指标论证

分析了野战弹药的储存防热现状,论证了野战弹药储存防热的温度指标。通过对火炸药储存性能参数的计算并结合我国的实际气候状况,确定了野战弹药的储存防热指标为环境温度应控制在40℃以下。最后,提出了今后野战弹药储存防热的研究方向。     

钠钙交换体对心肌保护作用的研究进展

心肌钠钙交换体是引起胞内钙超载的重要原因.简要综述了钠钙交换体的的结构特征、生理功能、病理作用以及在心肌保护方面的研究新进展.NCX反向转运的激活可能是心肌缺血预适应产生心脏保护作用的机制之一.     

Experimental investigation of open core downdraft biomass gasifier for food processing industry

This paper deals with field related experience of a low temperature industrial heat application through biomass gasification. The gasification system is essentially consists of an open top down draft reactor lined with ceramic. The experiment reveals that 6.5 kg of liquefy petroleum gas (LPG) is fully replaced by 38 kg of sized wood on hourly basis. The maximum temperature attained was 367°C in 130 min at 100.7 Nm³ h⁻¹ gas flow rate. This system has resulted a saving of about 19.5 tons of LPG over 3,000 h of operation, implying a saving of about 33 tons of CO₂ emission, thus a promising candidate for clean development mechanism. Fuel economic analysis of gasifier system showed that the saving was about 13,850 US$ for 3,000 h of baking operation.     

One-step estimation method and nomogram to predict safety distances of pressurized gas pipelines from blast sources

Pressurized gas pipelines may be endangered by accidental or intentional activities causing excess ground vibrations leading to failure. Thus, many papers have been published on this issue, yet most of these efforts suffer from complexity and inability to ascertain that all engaged factors are taken into account. These factors are attributed, namely, to explosion source, explosion-ground interaction, energy transfer through the ground, ground-pipeline interaction, and response of the pipeline. The deterministic method developed previously by the author has derived useful prediction mathematical formulas that can be used to calculate, either the stand-off distance of purposefully used explosives, or the maximum quantity of explosives to be used at a given distance, or the equivalent stress of a pipeline induced by an explosive charge at a given standoff distance. The method can also be applied to accidental blast events in factories or other activities. Yet, the complex formulas developed are hard to be used in the field and a simpler approach is needed to facilitate and accelerate in-field estimations. Thus, a nomogram was prepared to make the safety estimations easy and fast and taking into account all engaged critical factors starting from the explosion source through the integrity of the structure.     

Insight into the safety distance of ground and underground installations in typical petrochemical plants

Petrochemical plants are continuously turning into large-size corporations, the installations of facilities show a developing trend from ground to underground because of the difference in land using rate. In this regard, the safety distance of petrochemical equipment buried in both ground and underground cases were investigated based on risk assessment. As a case study, gasoline tank and LPG tank set on the ground and underground are singled out to compare the risks involved. The research showed that the setting case of installation had a great influence on safety distance. Two cases have 80% reduction of equivalent safety distance compared with the rest of the cases. It was found that when the gasoline storage tank was placed underground alone, the PLL value decreased by 36.7%. Only LPG tank was placed underground, and the PLL decreased by 6.33%, and the gasoline and LPG storage tanks were placed underground simultaneously, the PLL value declined by 42.3%. Thus, the layout of plants could be further optimized, which can greatly improve the performances of land use efficiency and safety. In addition, this paper, the selection of embedding methods and the sensitivity of underground case to overpressure was resumed from two aspects: soil properties and burial depth. For the soil properties, it was found that the water saturated sandy soil with high air content and the low density unsaturated sandy soil had better effects on weakening overpressure. Such properties are particularly beneficial to reducing the occurrence rate of accidents. In terms of burial depth, it can be observed that as the burial depth was changed from 0.5m to 1.1m, the value of overpressure has dropped dramatically. When the burial depth was 2m, the damage to personnel and buildings has been greatly reduced beyond 2m from the explosion center.     

Waste‐to‐energy recovery potential: A case study at Jaipur railway station

A study was conducted at the Jaipur railway station in Jaipur, India, to give the perspectives of the actual waste management practices there. Required information was collected from the stakeholders by means of semi‐structured questionnaires, individual and group interviews, and recorded, official data regarding waste generation, collection, transportation, and disposal. Further quantitative and compositional analyses were performed by means of surveys and measurements. Field visits were made for collection of waste samples for quantification and for the study of its management. The field data were compiled and analyzed by sorting the waste into different components. It was found that 1.8 tons of solid waste is collected per day, and a considerable percentage of it comprises paper, plastic, and glass. Excluding the inerts, which are irrelevant from the point of view of energy saving and recovery potential, the average moisture content was found to be 3.38%. From the perspective of life cycle analysis, the option of composting or recycling would give savings of 28.33 gigajoules (GJ) per day over landfilling, while combustion would give savings of 2.97 GJ per day in comparison to landfilling. Analysis based on a compositional model gives a heat value of 8,157.87 kilojoules per kilogram, which amounts to 14.68 GJ of energy per day.