City hazardous gas monitoring network

In our today's societies, many dangerous chemicals are produced and transported. Due to the vast use of chemicals, more chemical accidents are taking place with huge losses. In this study a city hazardous gas monitoring network was designed to detect the dispersion of toxic and combustible gases in the primary stages. The network could cover hazardous chemical facilities, important hazardous chemical routes, warehouses and special locations which may be the targets of terrorist attacks. The network is consisted of several local networks and a central control panel complex. Each local network has a local control panel in the center and many detectors and sounders around it at distances less than 3000 m that communicate with the local control panels wirelessly. In each location there are two types of gas detectors, toxic and combustible, and a sounder which are equipped with a wireless, radio frequency modem allowing the units to communicate readings and other information on a real-time basis with a remotely located local control panel. High sensitive Photo Ionization Detectors, PIDs, are used to provide fast and low-level on-site screening for chemicals contamination. Combustible gas detectors are the second choice to sense the combustible gas and verify the readings of PIDs in this regard. The central panel consists of several connected control panels work uniquely helping a computer set and the appropriate software and communicate with local control panels via telephone lines. All of the network components are shown on the monitor of central panel with special symbols by geographical information system program. The system is fully addressable so that the high level detection of a detector produces a blinking color double-circle around its symbol in GIS plan. In case of high level gas detection, a team of experts who are fully equipped with different portable detectors depart to the site to test the field to identify the chemicals. All readings of detectors are saved in a data bank and then analyzed to find any chemicals spills and leakages. The network was simulated by a special program so that the components of local networks and the central panel are shown in separate windows. By clicking on one detector on environmental window the formerly designed responses will be activated in central panel window.     

The indirect involvement of buses in traffic accident processes

The involvement of buses in accidents usually is assessed implicitly on the basis of the direct involvement of the bus in the collision or in injury production. This paper deals with the scope and forms of indirect involvement of buses (as a sight obstruction, for example). Accidents were selected by identifying the presence of the term ‘bus’ or synonyms in the text parts of complete police reports (testimonies, statements by the persons involved, etc.) available in electronic form, then analysed in detail. Direct or indirect involvement of a bus is found in 3.6% of traffic injury accidents reported by the police in the community studied (direct involvement: 1.4%; indirect involvement: 2.2%). The different forms of indirect involvement are then described, and some possibilities of preventive measures are discussed.     

2016—2020年全国化工和危险化学品事故分析研究*

为分析“十三五”期间（2016—2020年）我国化工和危险化学品事故发生情况，统计“十三五”期间化工和危险化学品事故数量及死亡人数，从发生月份、发生区域、行业分布等方面分析事故特征，从事故类别、事故环节、关键作业等方面分析事故原因，总结2011—2020年我国化工和危险化学品事故发展趋势，按照全国4大经济区域研究2013—2020年事故特征。结果表明:“十三五”期间我国化工和危险化学品事故数量呈下降趋势，死亡人数出现波动，总体形势较为平稳。2011—2020年化工和危险化学品事故风险向中西部转移趋势明显，东北、西部地区事故死亡率普遍高于东部地区。研究结果可为相关行业从业者及监管部门提供决策参考。     

重庆市突发环境事件时空格局及影响研究

基于2009年-2015年重庆市突发环境事件统计数据,研究了重庆市近7年突发环境事件的动态变化趋势、空间分布格局及污染影响特征,讨论了引发突发环境事件内外部因素之间的关系.结果表明:重庆市7年内共发生突发环境事件134起,且呈波动下降趋势,春季和夏季为交通事故和自然灾害高发期;突发环境事件空间上主要集中在主城九区及相邻的区县,渝西、渝东南及渝东北各区县发生次数较少.道路交通事故、设备故障和操作不当是导致突发环境事件的主要因素,主要发生形式为泄漏.污染类型主要为水污染和水气复合污染,污染物出现频率大小为:油类>酸碱类>液氨>苯及其化合物>减水剂>其他各种污染物.     

水专项"十三五"时期辽河流域水环境管理研究思路初探

以水专项在辽河流域实施的阶段性成果及辽河流域水环境管理现状为基础,分析"十三五"时期辽河流域水环境管理的需求,提出构建成套流域水环境管理技术体系和管理大平台、全面建设并优化水生态环境监测网络、实行水环境管理的动态调节机制和建立健全流域水环境管理长效机制的水环境管理研究思路,并指出研究应密切结合地方管理,充分发挥地方环境管理的责任主体地位,为水专项第三阶段"综合调控"战略目标的实现提供有力支撑.     

青藏高原淡水湖泊水化学组成特征及其演化

青藏高原淡水湖具有高生态价值和高脆弱性并存的特点.以海拔5 080 m±10 m的打加芒错湖水为研究对象,测试及分析了湖水化学组分,探讨了其主要离子来源、控制因子和湖泊水化学演化趋势.结果表明,湖水阳离子以Ca2+和Na+为主,阴离子以HCO3-为主,为HCO3-Ca型水;TDS为71.2～199.8 mg·L-1,矿化度低;受地表径流的稀释作用和富铝贫钙的地质背景约束湖区东南部水体的EC、Ca2+和HCO3-浓度均较低.湖水的Na+/(Na++Ca2+)为0.08～0.75,Cl-/(Cl-+HCO3-)为0.11～0.35,Ca/Na值为0.58,Mg/Ca值为0.12,HCO3/Na值为1.46,据Gibbs模型和元素化学计量分析表明,其化学组成主要受硅酸盐岩风化控制.湖区流域参与风化的矿物岩石包括斜长石(钙长石、钠长石)、钾长石、云母、石膏、盐岩等,但以斜长石风化为主,湖水的K/Na值平均为0.059,表明流域钾长石风化程度较低.湖水中方解石、白云石、石英、石膏等矿物饱和指数(SI)大于0,石盐的SI则小于0,揭示了青藏高原上淡水湖泊演变成咸水湖的变化趋势.     

石化企业危险化学品重大危险源风险评估

阐述了定量风险评价的个人风险和社会风险指标,并从前期准备、资料数据搜集、危险辨识、失效频率分析、失效后果分析、风险计算和风险评估等环节对某石化企业液化气一级重大危险源进行了定量风险评估。评估结果显示该重大危险源的个人风险和社会风险值基本符合安监总局40号令的要求。     

溢油鉴别数字化判定在船舶油污事故调查中的应用

本文以一起船舶油污事故的溢油源调查为例,简述了重复性限法、t检验法两种方法的判定原则及判定流程,具体介绍了两种方法在船舶油污事故溢油源鉴定中的应用。应用结果表明,重复性限法、t检验法是两种值得在船舶溢油事故鉴定中推广应用的判别方法,诊断比值的准确性是影响两种判定方法应用的一个重要因素。     

生产安全事故责任认定定量化方法的探讨

当前,我国生产安全事故的责任认定是在事故调查组分析调查事故原因后,对事故责任者承担的责任进行定性的责任认定,受一定的主观因素影响。为了避免主观因素的影响,本文提出了一种责任认定定量化方法,该方法首先从安全管理、安全技术和职业健康卫生三方面建立了完善的事故影响因素集;然后在分析事故原因后采用专家打分法(德尔菲法)确定各影响因素的影响度,并计算出与事故相关的责任者的累加影响度,即责任大小;最后根据事故造成的人员伤亡和经济损失情况对事故责任者作出处理。此方法对生产安全事故责任认定更加公正客观。     

主成分分析法在煤矿事故统计分析中的应用

为了研究我国煤矿各类事故之间的相互关系,运用主成分分析法对我国煤矿事故数据进行了统计分析,计算得到煤矿事故类型的第一主成分和第二主成分,并进一步分析了煤矿事故的主要类型以及各类事故之间的相互联系,对制定相应的煤矿事故预防措施具有一定的指导作用。