Numerical investigation on performance of protective layer around large-scale chemical storage tank against impact by projectile

The protective layer of chemical storage tank has a significant effect in risk mitigation of projectile-related accidents but the research is still in infancy. In order to investigate the performance of protective layer against projectile, dynamic response process of the large-scale vertical storage tank impacted by the end-cap fragment is simulated based on the LS-DYNA. In this paper, some key factors (thickness, layering order and number of layers) affecting its performance are discussed, which can be characterized by the deformation degrees of the target tank. It is found that the anti-penetration performance is improved rapidly with the increase of thickness, and aluminum (Al) protective layer shows a higher sensitivity to thickness change compared to Ultra-High Molecular Weight Polyethylene (UHMWPE) protective layer. Three double-layered protective layers for different sequences are investigated and the Al-UHMWPE protective layer shows best performance. For the Al protective layers arranged in various combinations of equivalent total thickness, better performance is provided by monolithic structures than layered one. This study demonstrated the rational design of the protective layer around chemical storage tanks in material selection and structure configuration.     

Correction model for CO detection in the coal combustion loss process in mines based on GWO-SVM

Accurate detection of CO gas is crucial to the prevention of coal combustion. Tuneable diode laser absorption spectroscopy (TDLAS) is a reliable method for CO detection during coal combustion. The influences of temperature and pressure cause changes in the line strength and linewidth of the index gases’ absorption spectra, leading to sizable measurement errors. To correct the distortion of the CO absorption spectrum caused by temperature and pressure fluctuation, a compensation model based on the grey wolf optimizer–support vector machine (GWO–SVM) was proposed. The results were compared with those of the single SVM, the back propagation neural network (BPNN), and multiple regression analysis (MRA). MRA was revealed to result in the lowest accuracy, which indicated that MRA is not ideal for compensation in TDLAS. The hyperparameter selection of the SVM had the disadvantages of randomness and blindness, which led to instability and large errors. The BPNN achieved better correction in the training stage, but severe overfitting occurred in the testing stage. The modified results revealed that the GWO–SVM model had higher accuracy and stability than the other models. It effectively inhibited the effects of temperature and pressure on the measured concentration and greatly improved the measurement accuracy. The equipment is thus suitable for CO gas detection with the aim to preventing coal combustion loss, and it can be further applied to loss prevention in other process fields.     

基于压力与温度对损失瓦斯量影响试验研究*

为研究取芯管取芯过程中压力与温度对损失瓦斯量的影响,以及t法的偏差,利用自主研发的取芯管取芯过程模拟测试装置,基于模拟试验的相似性,开展不同加热功率下取芯过程模拟试验与室温（30 ℃）对比,以及变温条件下不同吸附压力取芯过程模拟试验。结果表明:前30 min煤芯瓦斯解吸曲线符合Qt=a+b/［1+(t/t0)c］。吸附压力一定时,取芯过程模拟测试的煤芯瓦斯解吸率均大于室温下的对比测试,3~16 min（退钻过程）温度对损失量的影响大于0~3 min（取芯过程）;随着加热功率的增加,煤芯瓦斯解吸量增大,煤芯损失瓦斯量的模拟值亦增大;t法推算值与模拟值的绝对误差随加热功率的增大而增大,相对误差在65.08%~70.79%;加热功率一定时,随着吸附压力的增加,煤芯瓦斯解吸量愈大,煤芯损失瓦斯量t法推算值增大,模拟值亦增大;t法推算值与模拟值的绝对误差随吸附压力的增大而增大,相对误差在68.21%~72.13%。     

中空结构可燃物竖直向上火蔓延特性实验研究*

为探究中空结构固体可燃物竖直向上火蔓延的特征规律,针对不同试样内径(d)的瓦楞纸圆管进行竖直向上的火蔓延实验研究,探讨试样内径对其竖直向上火蔓延特性的影响。结果表明:其火蔓延过程可以分为火焰发展、稳定蔓延和火焰衰弱3个阶段,蔓延过程中对流换热占据主导地位;平均火焰高度随d的增大先增大后略微减小,在d=70 mm时达到最大;火蔓延速率和质量损失速率均随d的增大而增大,并且质量损失速率与d存在较好的线性关系;火蔓延速率与热释放速率呈现出较好的幂次关系。可以发现在一定范围内,中空结构可燃物的内径越大其火灾危险性越高。     

煤化工废水中硝基苯胺类污染物的HPLC测定

通过试验建立了工业废水中苯胺类污染物的液相色谱测定方法,优化了试验条件.该方法吸收值与基质质量浓度之间的线性关系非常显著,苯胺和6种硝基苯胺类成分的检出限在0.000 1～0.000 3 mg/L之间,空白加标试验的相对标准偏差(RSD)在1.8％～4.8％之间,基质加标回收率在58.6％～93.8％之间.对煤化工园排...     

二氧化氯制备方法研究进展

二氧化氯是一种具有高氧化性和强消毒性的化合物,介绍了二氧化氯制备的化学法、电解法以及电化学法,并对几种工艺方法的优缺点进行了分析和比较,适合工业化生产的工艺主要是化学法中的氯酸钠法和亚氯酸钠法。     

机动车尾气排放VOCs源成分谱及其大气反应活性

选取轻型汽油车、重型柴油车和摩托车等城市典型机动车种分别采用底盘测功机及实际道路实验,结合SUMMA罐采样的方法,获得了小轿车、出租车、公交车、卡车、摩托车和LPG助动车的尾气VOCs样品,利用气相色谱-质谱分析了各车型机动车尾气VOCs的浓度及其物种组成.结果表明,轻型汽油车尾气VOCs以甲苯、二甲苯等芳香烃为主,占43.38%～44.45%;重型柴油车以丙烷、n-十二烷及n-十一烷等烷烃组分为主,占46.86%～48.57%,还有13.28%～15.01%的丙酮等含氧特征组分;摩托车与LPG助动车的主要成分为乙炔,分别占39.75%和76.67%左右.各车型中,摩托车和轻型汽油车尾气VOCs的化学活性显著高于重型柴油车辆,以上海市为例,其大气化学活性贡献分别占55%和44%左右,是影响城市和区域大气氧化能力的关键污染源,其中以甲苯、二甲苯、丙烯、苯乙烯等关键活性物种的贡献最大.     

排水循环灌溉下稻田磷素时空分布特征

排水循环灌溉具有提高降水资源利用率和减少农田面源污染的潜力,为缓解我国南方地区降雨分布与水稻作物需水时间不匹配和农田磷流失污染的问题,开展了排水循环灌溉条件下稻田磷素时空分布规律研究.采用田间试验的方法,监测藕塘水和鱼塘水循环灌溉下水稻田面水和渗漏水中总磷、可溶性磷和可溶性反应磷的质量浓度,及土壤剖面总磷与Olsen-P含量的变化.结果表明,排水循环灌溉下水稻田面水和渗漏水中不同形态磷素质量浓度沿程降低,尤其渗漏水磷质量浓度的减少趋势更为显著,排水循环灌溉水源中磷质量浓度在一定范围内的变化不会增加田面水和渗漏水中的磷质量浓度.田面水和渗漏水中不同形态磷质量浓度在不同灌溉时期的变化较大,8月田面水和渗漏水的磷质量浓度明显低于其它时期.表土Olsen-P含量随距进水口的距离的增加而减少,并随排水循环灌溉水中磷质量浓度的增加而增加;土壤剖面TP含量受排水循环灌溉的影响不明显.在8月水稻需肥高峰期进行排水循环灌溉或延长灌溉水的流程,可明显改善排水循环灌溉下稻田的磷素去除效率.     

Sorption-enhanced chemical looping oxidative steam reforming of methanol for on-board hydrogen supply

Hydrogen is an indispensable energy carrier for the sustainable development of human society. Nevertheless, its storage, transportation, and in situ generation still face significant challenges. Methanol can be used as an intermediate carrier for hydrogen supplies, providing hydrogen energy through instant methanol conversion. In this study, a sorption-enhanced, chemical-looping, oxidative steam methanol-reforming (SECL-OSRM) process is proposed using CuO–MgO for the on-board hydrogen supply, which could be a promising method for safe and efficient hydrogen production. Aspen Plus software was used for feasibility verification and parameter optimization of the SECL-OSRM process. The effects of CuO/CH3OH, MgO/CH3OH, and H2O/CH3OH mole ratios and of temperature on H2 production rate, H utilization efficiency, CH3OH conversion, CO concentration, and system heat balance are discussed thoroughly. The results indicate that the system can be operated in auto-thermal conditions with high-purity hydrogen (99.50 vol％) and ultra-low-concentration CO (<50 ppm) generation, which confirms the pos-sibility of integrating low-temperature proton-exchange membrane fuel cells (LT-PEFMCs) with the SECL-OSRM process. The simulation results indicate that the CO can be modulated in a lower concentration by reducing the temperature and by improving the H2O/CH3OH and MgO/CH3OH mole ratios.     

Heat loss analysis: An approach toward the revival of parabolic dish type solar cooker

Present work investigates a noble approach toward the heat loss analysis of parabolic dish type solar cooker. Various experiments have been done on cooking pot to get the input parameter for calculation purposes. Cooking pot was kept at the focus of a parabolic dish type concentrator and repeated experiments have been done to measure solar radiation intensity (direct and Indirect) using a pyrometer, temperature at the focus of parabolic dish using a thermocouple and air velocity using hot wire anemometer to investigate the heat losses from the cooking pot. In the present article, a numerical approach has been performed to define the new parameter called performance index of the cooking pot which decides how the useful energy of working fluid inside the cooking pot approaches concentration ratio of the parabolic dish type solar cooker. The present analysis shows that the performance index varies from 15.45 to 17.66 and efficiency varies from 85.83% to 98.10% with the time of the day.