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1.
Duohong Chen Xinhui Bi Jinping Zhao Laiguo Chen Jihua Tan Bixian Mai Jiamo Fu Minghung Wong 《Environmental pollution (Barking, Essex : 1987)》2009,157(3):1051-1057
Diurnal air samples were collected from the E-waste dismantling region Guiyu and the underwear industry region Chendian. This was the first report to present the diurnal variation of PBDEs in the atmosphere. The average concentrations of 11 PBDE congeners were 11,742 pg m−3 in the daytime, and 4830 pg m−3 at night in Guiyu, while the concentrations were lower in Chendian with 376 pg m−3 in the daytime, and 237 pg m−3 at night. BDE-209 accounted for 22% and 31.3% of the total PBDEs in Guiyu and Chendian, respectively. The diurnal variation trends of BDE-47, -99, -153, -183, and -209 were also analyzed in detail in the two regions. 相似文献
2.
选取南方某典型电子垃圾拆解区不同作业区为研究对象,重点研究了拆解地大气中二噁英的污染特征、气相-颗粒相分配及呼吸暴露风险。通过对5个采样点(包括1个背景点)的研究发现,电子垃圾拆解作业区颗粒相ΣPCDD/Fs的质量浓度为:20.64-56.14 pg·m^-3,毒性当量为:I-TEQ 0.293-1.490 pg·m^-3;气相ΣPCDD/Fs的质量浓度为:3.861-19.29 pg·m^-3,毒性当量为:I-TEQ 0.384-2.150 pg·m^-3。背景点大气中二噁英浓度相对较低,颗粒相和气相样品中质量浓度值分别为:3.734 pg·m^-3和2.637 pg·m^-3,毒性当量仅为I-TEQ 0.176-0.267 pg·m^-3;要明显低于电子垃圾拆解区。基于污染物气相-颗粒相分配系数与蒸汽压的关系对二噁英的气-固分配行为研究显示,除了拆解混合作业区有较好的分配系数(-0.64)外,其它监测点位二噁英的气-固平衡状态较弱(-0.27--0.03),更多的是以低分子量的单体化合物赋存于气相样品中。对拆解区二噁英呼吸暴露风险研究结果表明,儿童呼吸暴露风险要高于成年人;同时无论是儿童还是成年人,其二噁英的呼吸暴露量均要高于国内外城市报道的二噁英人体呼吸暴露量,说明本次监测的电子垃圾拆解区存在的潜在健康风险不容忽视。 相似文献
3.
With the increasing number of recycling mishaps in connection with waste electronic and electrical equipment (WEEE) in the People's Republic of China, it is imperative that the handling and recycling of WEEE be sufficiently regulated in China. Regulations covering three major issues, namely, take-back issues, controls on hazardous substances in WEEE and the assurance of good environmental management in WEEE plants, were promulgated between 2006 and 2008. The evaluation in this country report shows that few of these regulatory measures have performed satisfactorily in terms of enforcement, of public acceptance and of environmental concerns. In brief, the take-back requirements and the associated financial responsibilities are only vaguely defined; the control on hazardous substances and the so-called "environmental expiry date" requirements cannot be properly enforced, and the resources needed to ensure the satisfactory enforcement of the environmental abatement and pollution control requirements in WEEE plants are overwhelming. In addition, the use of a "multiple enforcement body" approach to the control of hazardous substances in WEEE is an indication that the Chinese government lacks the determination to properly enforce the relevant legal requirements. 相似文献
4.
Current status and research on E-waste issues in Asia 总被引:2,自引:1,他引:2
Atsushi Terazono Shinsuke Murakami Naoya Abe Bulent Inanc Yuichi Moriguchi Shin-ichi Sakai Michikazu Kojima Aya Yoshida Jinhui Li Jianxin Yang Ming H. Wong Amit Jain In-Suk Kim Genandrialine L. Peralta Chun-Chao Lin Thumrongrut Mungcharoen Eric Williams 《Journal of Material Cycles and Waste Management》2006,8(1):1-12
Rapid economic growth in Asia and the increasing transboundary movement of secondary resources will increasingly require both
3R endeavors (reduce, reuse, recycle) in each country and appropriate control of international material cycles. Recently,
managing electrical and electronic waste (E-waste) has become an important target for domestic and international material
cycles from the viewpoints of environmental preservation and resource utilization efficiency. To understand the current status
of E-waste issues in the context of international material cycles and to discuss the future tasks related to achieving 3R
in the region, we organized the National Institute for Environmental Studies (NIES) E-waste Workshop in December 2004. This
article reviews past studies on E-waste and briefly describes the topics presented and discussions held at the workshop. The
topics at the workshop included E-waste generation, recycling systems, international trade, and environmental impacts. In
addition, we discussed various issues such as terminology, current environmental concerns, and possible solutions. Transboundary
shipments of E-waste should be conducted taking into consideration the concept of sustainable development. The direction of
future research and possible collaborations are also discussed. 相似文献
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利用ICP-MS定量测定了温岭市电子垃圾拆解地区的大灰藓及樟树叶中的12种金属元素的含量,对比分析了两种指示生物对不同金属元素的富集情况.结果显示,不同地区样品中的所有金属含量呈现污染区对照区的趋势,其中苔藓中As、Cr、Mn、Se、V和Cd,樟树叶中Cr、Cu、Ni、Se、Sb和Cd的含量呈现重污染区轻度污染区对照区的趋势.拆解区中樟树叶中除Mn以外的金属总含量(所有金属含量之和)要低于苔藓.除Mn、Cr和Se以外的其它9种金属在苔藓中的含量要显著高于樟树叶中的金属含量(p0.05),但苔藓中金属含量的标准偏差要大于樟树叶.由污染因子(pollution factor)的结果表明苔藓及树叶样品中的金属Sn、Sb及Cd的污染因子最高;另外,研究通过比较树叶样品的不同预处理过程对最终含量测定的影响,发现经超纯水清洗的树叶样品中所有金属浓度要明显低于未经清洗的样品,并且标准偏差较低,数值稳定性好.主成分分析结果表明,Co、Cr、Ni、Pb、Sn及Cd为密切相关的一类元素,主要来源于电子废弃物拆解行为,而Mn、As及Se为第二类元素,主要来源于地质因素. 相似文献
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R. Cayumil R. Khanna M. Ikram-Ul-Haq R. Rajarao A. Hill V. Sahajwalla 《Waste management (New York, N.Y.)》2014,34(10):1783-1792
The rapid consumption and obsolescence of electronics have resulted in e-waste being one of the fastest growing waste streams worldwide. Printed circuit boards (PCBs) are among the most complex e-waste, containing significant quantities of hazardous and toxic materials leading to high levels of pollution if landfilled or processed inappropriately. However, PCBs are also an important resource of metals including copper, tin, lead and precious metals; their recycling is appealing especially as the concentration of these metals in PCBs is considerably higher than in their ores. This article is focused on a novel approach to recover copper rich phases from waste PCBs. Crushed PCBs were heat treated at 1150 °C under argon gas flowing at 1 L/min into a horizontal tube furnace. Samples were placed into an alumina crucible and positioned in the cold zone of the furnace for 5 min to avoid thermal shock, and then pushed into the hot zone, with specimens exposed to high temperatures for 10 and 20 min. After treatment, residues were pulled back to the cold zone and kept there for 5 min to avoid thermal cracking and re-oxidation. This process resulted in the generation of a metallic phase in the form of droplets and a carbonaceous residue. The metallic phase was formed of copper-rich red droplets and tin-rich white droplets along with the presence of several precious metals. The carbonaceous residue was found to consist of slag and ~30% carbon. The process conditions led to the segregation of hazardous lead and tin clusters in the metallic phase. The heat treatment temperature was chosen to be above the melting point of copper; molten copper helped to concentrate metallic constituents and their separation from the carbonaceous residue and the slag. Inert atmosphere prevented the re-oxidation of metals and the loss of carbon in the gaseous fraction. Recycling e-waste is expected to lead to enhanced metal recovery, conserving natural resources and providing an environmentally sustainable solution to the management of waste products. 相似文献
9.
典型电子垃圾拆解区大气颗粒物中元素污染的季节变化特征 总被引:1,自引:0,他引:1
分别在典型电子垃圾拆解区(E)和其参考区(S)采集了大气总悬浮颗粒物(TSP)样品,利用等离子体电感耦合质谱(ICP-MS)检测了13种元素。结果表明,E地区大气TSP中各元素含量均高于对照区,特别是污染元素Zn、Cu、Cd、Sn和Pb。E地区和S地区TSP中元素质量浓度的季节变化趋势相似,TSP中地壳元素质量浓度夏季高于冬季,而污染元素冬季高于夏季。E地区和S地区TSP中Cu、Zn、Sn和Pb的富集因子(EF)100,E地区EF值高于对照区,说明这些元素主要来源于电子垃圾处理过程;而Mg、K、Ca、Ti、V、Mn、Fe、Co和Cd的EF值为1~10,说明元素主要为自然来源。 相似文献
10.
Environmental impacts and use of brominated flame retardants
in electrical and electronic equipment 总被引:3,自引:0,他引:3
Sunil Herat 《The Environmentalist》2008,28(4):348-357
Management of waste electrical and electronic equipment (WEEE) or e-waste is becoming a major issue as around 20–50 million
tons of such waste is generated worldwide and increasing at a higher rate than other solid waste streams. Electrical and electronic
equipment (EEE) contains over 1,000 materials of which brominated flame retardants (BFRs) such as polybrominated biphenyls
(PBBs) and polybrominated diphenyl ethers (PBDEs) have been the target of the regulators forcing manufacturers to adopt halogen-free
flame retardants. As far as these alternatives are concerned, key consideration should be its performance during the whole
life cycle through design, use and end-of-life management. The global halogen-free flame retardant movement has reached a
point of no return. The most important issue as far as the environment is concerned, for which the transformation to halogen-free
retardants was initially targeted, is to make sure that life span of the EEE using the alternatives to BFRs is not shortened
thereby resulting in unforeseen increases in e-waste to deal with. The aim of this article is to investigate the environmental
issues and current developments related to the use of BFRs in EEE manufacture. It describes the sources, toxicity and human
exposure of BFRs, EOL management such as recycling and thermal treatments, exposure of BFRs from e-waste processing facilities
and the environment around them and examines the developments and feasibility of the alternatives to BFR in EEE manufacture. 相似文献