我国废塑料回收和进口现状浅析

废塑料是我国四大再生资源品种之一．废塑料国内回收和进口数量大、种类多。对我国废塑料国内产生和进口的种类、数量和地域,以及国内废塑料的回收渠道和方式进行了阐述。     

VOC气体检测仪在进口废塑料检验中的应用

针对挥发性有机化合物(VOC)气体在现实中的危害,对废物原料检验的标准进行了探讨,对废物原料检验中如何进行VOC检测进行分析并提出建议。     

2009年天津口岸进口废塑料环保不合格情况分析

就2009年天津口岸进口废塑料环保不合格情况进行分析,归纳了其不合格原因、来源国家、境外供货企业及国内收货人的分布特点,结合天津东港检验检疫局对废物原料的监管和措施,对降低进口废物原料环保项目不合格率提出建议。     

我国进口可再生利用废塑料的现状与发展

论述了进口可再生利用废塑料在环保、节能减排等国民经济领域中的重要意义。通过分析统计数据,阐明了我国由于资源匮乏,进口可再生利用废塑料的必要性和迫切性,并简述了我国政府对废塑料进口的监管措施。     

进口废塑料清洁程度定量化合格评定方法的探讨

目前国内对进口废塑料清洁程度的合格评定,长期以来一直采取感官检验的定性方法,引起了较多争议.以<进口可用作原料的固体废物环境保护控制标准--废塑料>(GB16487.12)为依据,分析了GB16487.12对进口废塑料清洁程度进行规定的原因,并在此基础上探讨了对进口废塑料清洁程度采取定量化的合格评定原理,提出参照<一般工业固体废物贮存、处置场污染控制标准>(GB18599)和<生活垃圾填埋污染控制标准>(GB16889)对进口废塑料清洁程度制定定量化限量要求,并建议尽快修订现行国家标准<进口可用作原料的固体废物环境保护控制标准--废塑料>.     

发达国家废塑料再生利用现状及对我国的影响

工业发达国家在废塑料再生利用方面起步较早,积累了丰富的经验,拥有较高的技术和先进的设备,政府和民众都具有较强的节能和环保意识.从立法、系统工程、技术创新、节能环保意识等诸多方面探讨了世界上主要工业发达国家在废塑料再生利用方面的发展现状;根据各国统计数据对其做出定量分析;指出,我国与工业发达国家在循环经济方面有较大的差距和很强的互补性.     

废塑料再生产业园的规划及环境影响评价

论述了我国废塑料再生行业存在的问题和废塑料再生产业园的规划特点。探讨了产业园的合理选址、系统规划布局、同步环境影响评价在废塑料再生产业园建设中的重要性,介绍了环境影响分析和园区清洁生产与循环经济等内容。指出建立废塑料再生产业园,必须通过合理规划布局并及时开展环境影响评价工作,这是保护环境、防控污染的有效措施。     

走出国门：可回收利用废塑料进口企业的最佳选择

近年来,我国的可回收利用废塑料进口企业面临困境,国际贸易企业进口困难,致使使用厂缺乏原料.论述了废塑料回收加工企业前往国外产地办厂的必要性和可行性,分析了我国业内企业走出国门的优势,并对废塑料的收集和加工品种、成本核算、采购目标等方面提出建议.     

新税收政策对再生资源行业的影响及调整建议

《财政部国家税务总局关于再生资源增值税政策的通知》（财税[2008]157号）下发后,为了贯彻文件精神,明确退税程序,部分省市陆续出台了再生资源增值税退税审核审批操作办法。经实践运作,并针对我国再生资源行业现状、税收政策的历史演变,归纳总结出新税收政策对再生资源行业带来的多方面影响,并提出相应调整建议。     

日本容器包装废塑料再生利用现状及对我国的启示

介绍了日本“容器包装再生法”的相关规定和实施过程,以及日本容器包装废塑料的回收、再生利用状况,并借鉴其先进经验,结合我国实际情况,指出发展我国废塑料循环利用的重要性,并提出具体建议措施。     

废旧塑料的再生及其在制管行业中的应用

总结了再生、降解、焚烧及填埋等几种废旧塑料处置方式的特点,指出对于品种单一、老化程度低的废旧塑料应优先选择再生利用.重点介绍了废旧聚氯乙烯塑料、聚乙烯塑料、聚丙烯塑料、氯化聚氯乙烯塑料的再生及其在制管行业中的利用情况进展.     

Utilization of red mud as catalyst in conversion of waste oil and waste plastics to fuel

The aim of this study was to investigate the possibilities of using a by-product (red mud) from alumina production as a catalyst for recovery of waste. The conversion of waste mineral oil (WMO) and waste mineral oil/municipal waste plastic (WMO/MWP) blends over red mud (RM), a commercial hydrocracking catalyst (silica–alumina), and a commercial hydrotreating catalyst (Ni–Mo/alumina) to fuel has been studied. The effect of the catalyst and the temperature on the product distribution (gas, liquid, and wax) and the properties of liquid products were investigated. In the case of hydrotreatment of WMO, the liquids obtained over RM at both 400° and 425°C had larger amounts of low-boiling hydrocarbons than that of thermal or catalytic treatment with hydrotreating catalyst. Gas chromatography and nuclear magnetic resonance analysis of the liquid products showed that RM had hydrogenation and cracking activity in hydrotreatment of WMO. In coprocessing of WMO with municipal waste plastics, temperature had an important effect as well as the amount of MWP in the blend and the catalyst type. The hydrocracking at 400°C produced no liquid product. In hydrocracking at 425°C, the product distribution varied with catalyst type and MWP amount. The commercial hydrocracking catalyst had more cracking ability in the conversion of WMO/MWP to liquid and gas fuel than RM. In the case of hydrocracking over RM, the largest amount of liquid having satisfactory quality was obtained only from the blend containing 20% MWP.     

Development of a catalytic dehalogenation (Cl,Br) process for municipal waste plastic-derived oil

Dehalogenation is a key technology in the feedstock recycling of mixed halogenated waste plastics. In this study, two different methods were used to clarify the effectiveness of our proposed catalytic dehalogenation process using various carbon composites of iron oxides and calcium carbonate as the catalyst/sorbent. The first approach (a two-step process) was to develop a process for the thermal degradation of mixed halogenated waste plastics, and also develop dehalogenation catalysts for the catalytic dehydrochlorination of organic chlorine compounds from mixed plastic-derived oil containing polyvinyl chloride (PVC) using a fixed-bed flow-type reactor. The second approach (a single-step process) was the simultaneous degradation and dehalogenation of chlorinated (PVC) and brominated (plastic containing brominated flame retardant, HIPS–Br) mixed plastics into halogen-free liquid products. We report on a catalytic dehalogenation process for the chlorinated and brominated organic compounds formed by the pyrolysis of PVC and brominated flame retardant (HIPS–Br) mixed waste plastics [(polyethylene (PE), polypropylene (PP), and polystyrene (PS)], and also other plastics. During dehydrohalogenation, the iron- and calcium-based catalysts were transformed into their corresponding halides, which are also very active in the dehydrohalogenation of organic halogenated compounds. The halogen-free plastic-derived oil (PDO) can be used as a fuel oil or feedstock in refineries.     

Studies on the dechlorination and oil-production technology of waste plastics

 Recycle technology for waste plastics containing polyvinyl chloride (PVC) has been developed in the Hokkaido National Industrial Research Institute for the production of solid and liquid fuel, and has established a recycling process which includes a dechlorination process for PVC plastics, and a two-stage catalytic pyrolysis process for plastics using zeolite catalysts. The dechlorination equipment consists of a two-axis screw extruder with a heating element, which can remove chlorine up to 99.9 wt. % from PVC containing plastics as hydrogen chloride. The product had about 44 000 kJ/kg calorific value and was fed into the next oil production process, although it could also be used as a solid fuel. Natural and synthetic zeolite were used as catalysts for the two-stage catalytic process, which produced a light oil with a boiling point which was between those of kerosene and gasoline. The yield of this oil reached 82 wt. %. The chemical type was analyzed using liquid chromatography, and was found to have many aromatic compounds. These technologies make it possible to produce a nonpolluting, high-calorie solid fuel and a liquid fuel very efficiently. Received: July 19, 2000 / Accepted: September 21, 2000     

餐厨废弃油脂处理管理和资源化利用探讨

“地沟油”的不当处理不仅影响城市水环境,而且威胁着人们的身体健康。餐厨废弃油脂的管理已经成为广受关注的食品安全的重大问题。介绍了餐厨废弃油脂处理管理的重要意义,并对上海的管理实践和经验进行了分析总结,提出了对餐厨废弃油脂回收处理管理和资源化利用的若干建议。     

生活垃圾分类背景下对广州市废玻璃回收利用的思考

废玻璃是一种载能节能、低碳环保、可重复利用和再生利用的再生资源,广州市通过补贴政策、两网融合等手段,促进废玻璃回收利用,随着生活垃圾分类纵深推进,为了进一步提高废玻璃回收利用,从废玻璃回收利用现状入手,对比了北京、上海生活垃圾中废弃玻璃的占比情况,针对目前存在问题,提出废玻璃回收利用分析与建议.     

高效石油烃降解菌的筛选及其对原油污染土壤的修复

从陕北原油污染土壤中筛选出7株高效石油烃降解菌,其中黄杆菌属CC-2、不动细菌属SC-5、假单胞菌属SC-6表现出较强的石油烃降解能力。通过单因素试验和正交试验考察总石油烃(TPH)降解效果的影响因素,得出各因素对TPH降解率影响程度的大小次序为:溶液p H降解温度降解菌接种量摇床转速,且在降解菌接种量为7%(φ)、溶液p H为7、降解温度为30℃、摇床转速为150 r/min的最适处理条件下,菌株SC-6的TPH降解率可达61.23%。原油污染土壤生物修复实验结果表明:高效石油烃降解菌的投加有利于土壤TPH降解率和酶活性的提高;"菌株SC-6+营养剂"组修复处理42 d后的TPH降解率可达57.59%。     

风电行业废玻璃钢资源化处置研究

我国风电行业每年产生大量热固性玻璃钢废弃物,这些废弃的热固性复合材料叶片、机舱罩等,在处置过程中广泛存在资源浪费和环境污染问题。对风电行业废玻璃钢的来源、产生量进行分析,概述废玻璃钢的生态毒性,阐述当前玻璃钢废弃物资源化处置技术及其优缺点,并提出风电行业废玻璃钢资源化处置技术的未来发展方向。