东营市化工聚集区地下水TOC污染空间分布特性

为掌握东营市化工聚集区地下水受有机污染的总体程度,对该市三县两区96个调查点位的地下水TOC进行了监测。结果表明:化工聚集区地下水TOC质量浓度分布范围为1.5~19.6 mg/L,87.5%的数据集中在2~10 mg/L区段,其中2~4 mg/L的区段数据最密集,数据分布呈对数正态分布。受区域内外部因素共同影响,地下水超标率和异常值比率分别达到62.5%和18.8%,且由南向北呈明显上升趋势;存在浓度均值超标和异常突变数据的化工聚集区数量分别占调查总量的75%和62.5%。地下水TOC受环境地质分布影响显著,黄泛平原区比山前平原区污染范围和程度更高;河口区和广饶井罐区分别是东营市和广饶县地下水污染最严重的地区,广饶县西北部是东营市地下水TOC水质最好的地区。     

化工园区应急物资需求决策模型研究

为实现化工园区高效应急救援,针对化工园区应急物资需求及特点,从基本物资需求量、应急物资消耗量、应急物资损耗量3个方面,构建化工园区应急物资需求优先级指标体系;基于TOPSIS方法对各应急物资需求进行重要性分级排序,设计求解出应急物资需求量的BP神经网络预测模型。以化工园区历史事故案例进行分析,结果表明,BP神经网络应急物资需求预测结果和实际应急物资需求量相差很小,结合TOPSIS方法后的应急物资需求分级决策方案,能有效辅助应急物资的组织和调度,最大限度地发挥应急效用。     

氧化剂对土壤中石油污染物去除率的影响

以FeSO_4-柠檬酸为催化剂,探讨了不同氧化剂的类型、浓度、与催化剂的比例等因素对土壤中石油污染物去除率的影响。实验结果表明:各氧化剂体系的石油去除率大小顺序为KMnO_4CaO_2≥H_2O_2K_2S_2O_8;随着反应时间的延长,各体系的石油去除率均呈现出先快速增涨、再缓慢增加后略有降低的趋势;在氧化剂浓度相同条件下,H_2O_2体系和Na_2S_2O_8体系的石油去除率分别比对照增加了145.5%~238.7%和112.6%~167.5%;在催化剂用量相同条件下,H_2O_2体系和Na_2S_2O_8体系达到最高石油去除率时的n(氧化剂)∶n(催化剂)分别为50∶1和100∶1;H_2O_2体系对残油族组分的去除率大小顺序为非烃芳烃饱和烃沥青质。     

国内外煤化工行业污染物排放标准研究及启示

系统分析了煤化工行业的产排污情况,梳理了国内外相关排放标准。结果表明:国内仅焦化等部分工序有行业排放标准,其余工序目前执行水或大气的综合排放标准,其污染物项目不能全面反映煤化工行业的污染特征,急需制定煤化工行业污染物排放标准;国外相关标准情况与国内类似,无直接借鉴意义。建议:合理界定煤化工排放标准的适用范围,与其他排放标准协调配套,控制整个行业的污染物排放;针对大气污染物,明确各排放口的特征污染物,结合综合指标和高毒性物质指标进行挥发性有机物的排放控制;针对水污染物,引入综合毒性指标以有效控制废水中有毒有害污染物排放的环境风险。     

煤化工废水中硫酸盐还原菌的分离及鉴定

从煤化工废水和厌氧污泥中分离出2株高效的硫酸盐还原菌,通过革兰氏染色、扫描电子显微镜观察其形态,通过16S r DNA序列分析法鉴定其种属,并研究其生长特性和硫酸盐还原性能。实验结果表明:菌株SRB-1为革兰氏阴性柠檬酸杆菌;菌株SRB-2为革兰氏阳性丁酸梭菌;两种菌株在最佳条件下培养4 d,菌液菌量均可达到1×106个/m L的水平;在SO2-4质量浓度为1 360 mg/L的条件下,两种菌株的SO2-4去除率分别达到93%和95%。     

连云港经济技术开发区危废处置情况的调查研究

通过对连云港市经济技术开发区内医药企业危废产生及库存等情况进行调查,针对目前危废处理处置过程中存在问题,提出解决对策及建议。     

危险化学品分类体系现状及在海洋环境应急监测中的应用

综述了国内外危险化学品分类体系,以苯乙烯为例,参考欧盟SEBC体系,建立了危险化学品海洋环境应急监测信息卡,内容包括分类、索引号及纳入名录,理化性质及行为特征判断,健康危害及防护要求,检测方法及评价标准等4类信息。建议进一步筛选海洋污染事故涉及的典型或高危化学品,细化SEBC体系,加强快速检测技术研究,构建适应我国海洋环境应急监测需求的危险化学品分类体系和数据库。     

烟台市PM2.5空间分布特征与来源解析

2016—2017年,选取烟台市3个代表性点位采集了PM_(2.5)样品,分析了其质量浓度和化学组成特征,并利用化学质量平衡(CMB)模型对环境空气受体进行了来源解析。结果表明:PM_(2.5)浓度呈现出盛泉工业园点位[(68.9±30.5)μg/m~3]福山环保局点位[(64.5±25.5)μg/m~3]百盛商城点位[(58.8±19.2)μg/m~3]的空间分布特征。水溶性离子、碳组分(OC和EC)和地壳类元素表现出不同的分布特征,与各点位所代表的不同功能区有关。形成机制上,NO~-_3在福山环保局点位主要以NH_4NO_3形式存在,而在盛泉工业园点位存在一定的Ca(NO_3)_2形式占比。源解析结果显示,3个点位均受到海盐源的影响,福山环保局点位二次颗粒物污染最为严重(43.9%),盛泉工业园点位燃煤源贡献突出(16.4%)。     

Case study on the catastrophic explosion of a chemical plant for production of m-phenylenediamine

On March 21, in Xiangshui County, Yancheng city, China, a catastrophic explosion occurred at Tianjiayi Chemical Co., Ltd. that caused 78 deaths and injured more than 617 individuals, with a property loss of as much as US$ 100 million. An explosion crater with a diameter of 98 m was generated. An extensive consequence analysis based on the crater size and physical effects for the estimation of the quantity of exploded dinitrobenzene (DNB) was performed. By using the position recorded in the satellite photo and the layout of the plant, the crater site was determined to be located near a warehouse where dinitrobenzene was stored. From the scaling law associating the TNT equivalent with crater diameter, the TNT equivalent of exploded ditrobenzene was determined to be approximately 708 tons. Based on the results of the consequence analysis performed by three methodologies, it can be concluded that the Tianjiayi Chemical Co. warehouse not only stored a substantially large quantity of dinitrobenzene but was also located too close to adjacent structures without an adequate separation distance. Judging by the effect of explosive blast on personnel, a fatality radius was determined to be about 400 m from the explosion center.     

Safety evaluation of different acids in high-density polyethylene container loading

To reduce costs, high-purity chemical suppliers wash and reuse HDPE containers collected from users. To determine the lifetime of a container, the appearance of that container and the manufacturer's recommendations for its lifetime are generally considered. Guidelines for determining the lifetime of an HDPE container have not been clearly defined. The lack of these specifications may result in the leakage of high-purity chemicals in the storage, transportation and use of HDPE containers. To understand the effects of using high-purity chemicals (sulfuric acid (H₂SO₄) and nitric acid (HNO₃)) on HDPE, this study revealed its effects by mechanical and thermal performance tests. According to the mechanical properties test results, the ductility and tensile strength of HDPE soaked H₂SO₄ and HNO₃ decreased. HDPE immersed in HNO₃ exhibited the lowest thermal stability by thermal performance testing. In summary, the degradation of HDPE is affected by storage conditions. For this study, HDPE only needs 60 days of immersion in HNO_3, and its ductility and tensile strength will decline obviously. This study shows that when these containers are used for long-term storage of high purity chemicals, the mechanical properties (including ductility, ductility, and tensile strength) of HDPE containers tend to decrease. To decrease accidental leakage of chemicals due to aging of HDPE, comprehensive and approved regulations should be established for the loading, transport, and storage of HDPE containers.