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循环经济在城市固废处理园区中的应用研究 被引量:6
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作者 徐长勇 陈昊 +1 位作者 段怡彤 张媛 《环境卫生工程》 2014年第4期78-80,共3页
阐述了循环经济与城市固废处理园区的含义、发展及内容,研究循环经济在城市固废处理园区中的应用机制,并选取国内某固废循环经济产业园区作为实例具体分析。
关键词 循环经济 城市固废处理园区 “3R”原则
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城市固废处理园区中循环经济的应用 被引量:4
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作者 陈建民 《化工设计通讯》 CAS 2019年第2期226-228,共3页
针对城市固废处理园区建设现状,进行科学有效的分析,并详细介绍城市固废处理园区中合理应用循环经济的重要性、循环经济发展的三条技术途径,如资源高效利用、资源循环利用、废弃物无害排放等,提出循环经济在城市固废处理园区中的应用要... 针对城市固废处理园区建设现状,进行科学有效的分析,并详细介绍城市固废处理园区中合理应用循环经济的重要性、循环经济发展的三条技术途径,如资源高效利用、资源循环利用、废弃物无害排放等,提出循环经济在城市固废处理园区中的应用要点。将循环经济应用到城市固废处理园区中,不仅能够保证城市固废废弃物得到更加高效的处理,而且有效改善了城市生态环境。 展开更多
关键词 城市固废处理园区 循环经济 应用要点
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低碳理念下城市固废处理模式探究 被引量:1
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作者 罗欣 《区域治理》 2020年第27期36-36,共1页
文章介绍城市固废分类和危害,总结常用的城市固废处理模式,基于目前城市固废处理过程中存在的问题,提出了低碳理念下的城市固废处理和综合利用策略,以供参考。
关键词 低碳理念 城市固废处理 问题 对策
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探索城市固废处理技术现状及发展趋势 被引量:1
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作者 叶玲芝 刘璐琦 陈卫 《石河子科技》 2022年第6期48-49,共2页
自“十三五”规划启动以来,我国固体废物处理技术越来越受到重视。目前城市固废处理技术主要有:焚烧、填埋、生物处理与热解,随着垃圾分类的推进、原生垃圾“近零填埋”的提出,原生垃圾填埋方式在大中城市逐渐被弱化,垃圾减量化、资源... 自“十三五”规划启动以来,我国固体废物处理技术越来越受到重视。目前城市固废处理技术主要有:焚烧、填埋、生物处理与热解,随着垃圾分类的推进、原生垃圾“近零填埋”的提出,原生垃圾填埋方式在大中城市逐渐被弱化,垃圾减量化、资源化、无害化等技术应用增多,文章通过对城市固废处理技术现状及发展趋势进行论述,以期有助于环保产业发展。 展开更多
关键词 城市固废处理技术 现状 发展趋势
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Geotechnical behavior of the MSW in Tianziling landfill
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作者 朱向荣 金建明 方鹏飞 《Journal of Zhejiang University Science》 EI CSCD 2003年第3期324-330,共7页
The valley shaped Tianziling landfill of Hangzhou in China built in 1991 to dispose of municipal solid waste (MSW) was designed for a service life of 13 years. The problem of waste landfill slope stability and expansi... The valley shaped Tianziling landfill of Hangzhou in China built in 1991 to dispose of municipal solid waste (MSW) was designed for a service life of 13 years. The problem of waste landfill slope stability and expansion must be considered from the geotechnical engineering point of view, for which purpose, it is necessary to understand the geotechnical properties of the MSW in the landfill, some of whose physical properties were measured by common geotechnical tests, such as those on unit weight, water content, organic matter content, specific gravity, coefficient of permeability, compressibility, etc. The mechanical properties were studied by direct shear test, triaxial compression test, and static and dynamic penetration tests. Some strength parameters for engineering analysis were obtained. 展开更多
关键词 Municipal solid waste (MSW) Engineering properties Laboratory test In situ test
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An Analysis of Solid Waste Generation and Characterization in Thika Municipality of Kiambu County, Kenya
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作者 Mugo Ephantus Kinyua Robert Njogu Paul 《Journal of Environmental Science and Engineering(B)》 2015年第4期210-215,共6页
The rapid increase in population in Thika has led to increase in municipal solid waste generation, which has posed challenges in the waste disposal and management. This study was carried out to quantify and characteri... The rapid increase in population in Thika has led to increase in municipal solid waste generation, which has posed challenges in the waste disposal and management. This study was carried out to quantify and characterize the waste generated within Thika municipality. Six months data (between March 2014 and August 2014) of waste stream at the dumpsite was reviewed and analyzed. The survey indicated that 66.95% ± 0.34% of the total waste dumped originated from the municipal council ofThika (MCT). It constitutes of domestic, commercial and institutional waste. 33.05% is industrial waste. Sixty eight percent (68%) of the waste consisted primarily of four components: paper, plastic, organics and food. Food accounted for 15.51% ± 0.95%, paper 18.31% ± 1.7%, plastics 17.89% ± 0.81% and organics other than food 16.51% ±1.01%, respectively obtained at 95% confidence level. Each of the components has some level of recovery. Some of the reusable and recyclable materials were being recovered, food waste had the highest recovery rate of 23% ± 1.7% and was used as animal feed, while plastic (soft plastic) 17% ± 0.93% was sold to recyclers. Recovery of materials for recycling and composting was estimated at 10.21 tonnes or 11.35% of daily generation, leaving 76.44 tonnes per day that can be converted into useful energy. The study shows waste in this dumpsite can be exploited to by converting it to energy thus a good solution for waste management. 展开更多
关键词 Municipal solid waste municipal solid waste management waste to energy Thika municipality.
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Gasification of Municipal Solid Waste for Power Generation in Brazil, a Review of Available Technologies and Their Environmental Benefits
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作者 Diego Mauricio Yepes Maya Angie Lizeth Espinosa Sarmiento +2 位作者 Cristina Aparecida Vilas Boas de Sales Oliveira Electo Eduardo Silva Lora RubenildoVierira Andrade 《Journal of Chemistry and Chemical Engineering》 2016年第6期249-255,共7页
This article reviews the literature on thermochemical processing of municipal solid waste as the final disposal in Brazil, explores recent publications in the field of solid waste generated, its origin, characteristic... This article reviews the literature on thermochemical processing of municipal solid waste as the final disposal in Brazil, explores recent publications in the field of solid waste generated, its origin, characteristics and removal mechanisms currently employed, in the same way, available technologies for the thermochemical treatment of MSW with an emphasis on gasification and clean technology are evaluated, highlighting the current technical and reported in the literature in order to identify indicators of efficiency and flexibility of the technology. From the review it is concluded that gasification is a technically feasible option for the thermochemical conversion of municipal solid waste and subsequent power generation, besides being a technology that meets the applicable emission limits. Some of the main advantages of gasification of municipal solid waste are: (a) the sharp reduction in the waste mass (about 70-80%) and volume (approximately 80-90%); (b) the drastic reduction in land use, 1:3000; (c) destruction of organic pollutants and other halogenated hydrocarbons; (d) concentration and immobilisation of inorganic contaminants so that they can be used effectively and safely removed; (e) use recyclables, such as ferrous metals, ferrous ash and slag materials; (f) reducing emissions of greenhouse gases by anaerobic decomposition of organic waste and (g) power generation. 展开更多
关键词 MSW waste to energy GASIFICATION thermo-chemical conversion environmental advantage.
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