武汉阳逻砾石层砾石统计分析研究

阳逻砾石层是长江中下游新生代的一个重要的岩石地层单位,不仅具有重要的地层学意义,在长江中下游古地理和古环境研究中也具有重要价值.砾石统计分析可为阳逻砾石层研究提供重要参考,阳逻砾石层砾石统计分析表明,砾径主要是中粗砾和粗砾;砾向主要是北西和南西方向;砾性主要是石英砂岩、脉石英、硅质岩、石荚岩、砾岩和砂岩;砾态主要表现是...     

三丁基锡对中国近海常见海洋微藻的毒性效应

研究三丁基氯化锡（TBT）对中国近海常见5种硅藻和甲藻（硅藻中丹麦细柱藻（Leptocylindrus danicus）、派格棍形藻（Bacilaria paxillifera）、聚生角毛藻（Chaetoceros socialis）,甲藻中微型原甲藻（Prorocentrum minimum）、简裸甲藻（Gymnodinium simplex））的毒性效应,考察了有机锡对浮游藻光合活性（Fv/Fm）、粒径、生长的影响。结果表明：派格棍形藻、聚生角毛藻、简裸甲藻的光合活性（Fv/Fm）受TBT影响较显著;微型原甲藻、丹麦细柱藻的光合活性受TBT影响较小。高质量浓度TBT胁迫下海洋微藻峰值粒径显著减小,低质量浓度TBT对峰值粒径影响不显著。低质量浓度TBT对派格棍形藻、聚生角毛藻、简裸甲藻、微型原甲藻均有较强的毒性作用,非检测毒性浓度（NDEC）分别为1.17、1.07、0.23、3.73μg.L-1,丹麦细柱藻对TBT具有很强耐受性,NDEC为112.62μg.L-1。     

工作竖井与隧道连接处支护结构横向地震响应

建立了工作竖井与盾构隧道、明挖隧道相连的空间交叉结构三维模型,采用FLAC3D对该复杂结构进行了横向地震响应分析,得到了工作竖井与隧道连接处支护结构关键点的位移和应力响应规律。通过对地震横向激励过程中竖井与隧道连接处支护结构收敛位移和关键点主应力峰值的分析,对该结构的横向抗震性能做出了评价。     

基于多种测试平台喷雾粒径特性实验研究

目的 研究平台环境差异对喷雾液滴粒径造成的影响。方法 分别在喷嘴测试台、直流吸气式风洞、闭口回流式结冰风洞等3种测试平台上开展喷雾液滴粒径测量,并将测量结果进行对比分析。结果 各平台喷雾dMVD随水气压变化的规律性都较好,dMVD随着水压的增大而增大,随着气压的增大而减小。对于dMVD≤30 μm的工况,3种测试平台的dMVD测量结果接近,但粒径分布存在差异。对于dMVD>30 μm的工况,直流吸气式风洞和闭口回流式结冰风洞喷雾的dMVD都比喷嘴测试台大,粒径分布向大颗粒方向偏移。结论 气流温度、速度、环境湿度、湍流度以及平台构型等环境因素均对喷雾液滴粒径产生影响,多因素耦合作用使得闭口回流式结冰风洞液滴的蒸发、碰撞合并、破碎等行为都更强烈,从而造成了其与喷嘴测试台、直流吸气式风洞喷雾的粒径特性存在差异。     

煤燃烧超细微粒粒径谱演变及排放因子的实验研究

对燃煤超细微粒的排放特性进行研究,利用自行搭建的气溶胶实验平台,使用快速粒径谱仪FMPS对燃煤超细颗粒(5.6~560 nm)数量粒径谱进行了测量,同时利用颗粒物动态演变模型,通过最优化算法,得到颗粒沉积损失率和排放率随粒径的分布,并计算了燃煤颗粒的排放因子.结果表明,在颗粒生成的初始阶段,燃煤颗粒数量粒径谱是多分散的复杂谱,初始粒径谱主要由10 nm、30~40 nm及100~200 nm这3个模态组成,其中,10 nm模态颗粒数浓度较高,100~200 nm模态颗粒粒径谱呈对数正态分布,数量中位径CMD均值为16 nm.随着时间的推移,总数量浓度呈指数规律衰减,CMD先增大后逐渐趋于稳定.排放因子的计算结果显示,在室温条件下,燃煤颗粒的排放因子达到(5.54×1012±2.18×1012)个·g-1.     

Measurement and relationship between critical tube diameter and critical energy for direct blast initiation of gaseous detonations

For the explosion safety assessment in industrial setting, detonation dynamic parameters provide important information on the sensitivity and conditions whereby detonations can be favorably occurred. In this study, new measurement of the critical tube diameter and the critical energy for direct initiation of a detonation is reported for a number of hydrocarbon–oxygen mixtures. The simultaneous experimental measurement carried out in this work allows the investigation of the direct scaling between these two dynamic parameter quantities of gaseous detonations. Using the new set of data, this paper also assesses the validity of an existing semi-empirical initiation model, namely, the surface energy model by Lee, and a simplified work done model. Both phenomenological models provide a general relationship between the two dynamic detonation parameters and comparison shows a good agreement between the theoretical results and the experimental measurement. The scaling of critical tube diameter with detonation cell size in this study also confirms the results in the previous literature.     

Propagation Characteristics of Gas Explosion in Linked Vessels Based on DDT Criteria

To study the occurrence conditions and propagation characteristics of deflagration to detonation transition (DDT) in linked vessels, two typical linked vessels were investigated in this study. The DDT of the methane–air mixture under different pipe lengths and inner diameters was studied. Results showed that the CJ detonation pressure of the methane–air mixture was 1.86 MPa, and the CJ detonation velocity was 1987.4 m/s. Compared with a single pipe, the induced distance of DDT is relatively short in the linked vessels. With the increase in pipeline length, DDT is more likely to occur. Under the same pipe diameter, the DDT induction distance in the vessel–pipe–vessel structure is shorter than that in the vessel–pipe structure. With the increase in pipeline diameter, the length of the pipe required to form the DDT is reduced. For linked vessels in which detonation formed, four stages, namely, slow combustion, deflagration, deflagration to detonation, and stable detonation, occurred in the vessels. Moreover, for a pipe diameter of 60 mm and a length of 8 m, overdriven detonation occurred in the vessel–pipe–vessel structure.