| MATERIALS AND SUSTAINABLE DEVELOPMNT: MATERIALS REMANUFACTURING AND WASTE RECYCLING |
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| Research Progress of Energy-Environment-Economy Comprehensive Performance Assessment for Solid Waste Recycling |
| YANG Ming1,2, GU Yifan1,2, WU Yufeng1,2, PAN Dean1,2, GONG Yu1,2
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1 Institute of Circular Economy,Beijing University of Technology, Beijing 100124, China
2 Faculty of Materials and Manufacturing,Beijing University of Technology, Beijing 100124, China |
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Abstract As economy and urbanization continue to increase, the solid waste production should also increase, the solid waste recycling has been widely concerned. Solid waste recycling has multiple attributes, such as resource and energy saving, environmental protection and economic benefits, as many solid waste recycling technologies need to be assessed. The assessment method has become the research hotspot now. Energy-environment-economy (3E) assessment has been widely used in the study of sustainable development of energy, environment and economy, which can realize the comprehensive quantitative assessment of comprehensive performance. Because of the similar properties with solid waste recycling, we have gradually applied 3E assessment to the research of solid waste recycling performance assessment.
In recent years, some scholars have used the 3E assessment to analyze the comprehensive performance of solid waste recycling technology. However, the solid waste recycling technology differs from other forward supply chain technologies such as manufacturing. Solid waste recycling process is affected by different upstream raw materials, and the complex composition of solid waste raw materials leads to many kinds of pollutant emission. Besides, the output of the recycling process also involves resources, energy, pollutants and many other aspects. The perspective of traditional 3E assessment doesn’t involve the whole life cycle process, and the index is not suitable for solid waste recycling assessment and optimization.
Among the existing literature of 3E assessment indicators for solid waste recycling, some scholars have included electricity generation, heat generation, gas generation and other indicators into the renewable energy indicators, but renewable resource output indicators have not been involved. In addition, a single environmental index of a single process can not meet the requirements of multiple processes and indexes for solid waste recycling assessment. Therefore, using life cycle assessment to select environmental indicators is an important research direction. The factors such as environmental tax deduction and policy subsidies brought by solid waste recycling technology need to be further studied. In the research on assessment methods, the multi-attribute decision making combine subjective and objective weighting methods are currently used to turn away the subjective influence, the combination of multi-objective optimization and multi-attribute decision making can provide theoretical support for the selection and optimization of technology and process.
This paper illuminates the relationship of solid waste recycling and 3E assessment from 119 SCI researches, and analyzes the design idea of the research perspective, index system and assessment method, explores the feasibility of combining the solid waste recycling process with the 3E assessment, and puts forward the development prospect of comprehensive performance assessment of solid waste recycling, in order to provide new ideas for the solid waste recycling assessment.
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Published: 26 September 2021
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| Fund:National Natural Science Foundation of China (52070007) and National Key Research and Development Program of China (2018YFC1903603, 2018YFC1903106). |
About author:: Ming Yangreceived his B.S. degree in engineering from Beijing University of Technology in July 2018. He is currently pursuing his Ph.D. at the Faculty of Mate-rials and Manufacturing of Beijing University of Technology under the supervision of prof. Yufeng Wu. His research has focused on resources, environment and circular economy.
Yufeng Wu, a professor in the Faculty of Materials and Manufacturing of Beijing University of Technology and a Ph.D. tutor in the resources, environment and circular economy. He has long been engaged in the research of circular economy technology, policies and application models. He has presided over more than 30 projects such as the National Key Research and Deve-lopment Program,the National Natural Science Foundation. He has published more than 70 academic papers as the first or corresponding author in Journal of Cleaner Production, ACS Sustainable Chemistry & Engineering, China Industrial Economics and other domestic and foreign journals, of which more than 50 are included in SCI/CSSCI. |
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1 National Bureau of Statistics of China. China statistical yearbook, China Statistics Press, 2018(in Chinese).
中华人民共和国国家统计局.中国统计年鉴,中国统计出版社,2018.
2 Abdel-Shafy H I, Mansour M S M. Egyptian Journal of Petroleum, 2018, 27(4), 1275.
3 Tan S T, Ho W S, Hashim H, et al. Energy Conversion and Management, 2015, 102, 111.
4 Beccali M, Brunone S, Cellura M, et al. Renewable Energy, 2008, 33(3), 366.
5 Houshyar E, Dalgaard T, Tarazkar M H, et al. Journal of Cleaner Production,2015, 89, 99.
6 Anastaselos D, Oxizidis S, Papadopoulos A M. Energy & Buildings, 2011, 43(2), 686.
7 Xiao J, Shen L, Zhang Y, et al. Industrial & Engineering Chemistry Research, 2009, 48(22), 9999.
8 Dong J, Chi Y, Zou D, et al. Applied Energy, 2014, 114, 400.
9 Mcphail A, Griffin R, El-Halwagi M, et al. Energy & Fuels, 2014, 28(2), 1453.
10 Chen G, Wang X, Li J, et al. Science of the Total Environment, 2019, 647, 1433.
11 Yi Q, Feng J, Wu Y, et al. Energy, 2014, 66, 285.
12 Suresh M V J J, Reddy K S, Kolar A K. Energy for Sustainable Development, 2010, 14(4), 267.
13 Wang C, Chang Y, Zhang L, et al. Energy, 2017, 120, 374.
14 Angrisani G, Roselli C, Sasso M, et al. Energies (Basel), 2014, 7(10), 6741.
15 Rajendran K. Processes, 2017, 5(4), 78.
16 Bina S M, Jalilinasrabady S, Fujii H. Energy, 2017, 140, 1096.
17 Faizal M, Saidur R, Mekhilef S, et al. Energy Conversion and Management, 2013, 76, 162.
18 Faizal M, Saidur R, Mekhilef S, et al. Clean Technologies and Environmental Policy, 2014, 17(6), 1457.
19 Varun, Prakash R, Bhat I K. Renewable and Sustainable Energy Reviews, 2009, 13(9), 2716.
20 Adibhatla S, Kaushik S C. Sustainable Energy Technologies and Assessments, 2017, 21, 89.
21 Abuşka M, Şevik S. Solar Energy, 2017, 158, 259.
22 Deniz E, Çinar S. Energy Conversion and Management, 2016, 126, 12.
23 Ghaebi H, Farhang B, Rostamzadeh H, et al. International Journal of Hydrogen Energy, 2018, 43(3), 1855.
24 Adedeji M J, Ruwa T L, Abid M, et al. Energy Procedia,2017,142,916.
25 Purwanto W W, Pratama Y W, Nugroho Y S, et al. Renewable Energy, 2015, 81, 308.
26 Keoleian G A, Volk T A. Critical Reviews in Plant Sciences, 2005, 24(5-6), 385.
27 Hammond G P, Harajli H A, Jones C I, et al. Energy Policy, 2012, 40, 219.
28 Chamorro C R, Mondéjar M E, Ramos R, et al. Energy (Oxford), 2012, 42(1), 10.
29 Xu Y, Jiang N, Pan F, et al. Energy Conversion and Management, 2017, 133, 535.
30 Silva S M, Mateus R, Marques L, et al. Solar Energy Materials and Solar Cells, 2016, 156, 59.
31 Kaiser M J, Olatubi W O, Pulsipher A G. Energy Policy, 2005, 33(7), 873.
32 Faria M V, Baptista P C, Farias T L. Transportation Research Part A, 2014, 64, 110.
33 Dincer I, Rosen M A. Applied Thermal Engineering,2001,21(11),1105.
34 Atabani A E, Saidur R, Silitonga A S, et al. Applied Mechanics and Materials, 2012, 110, 3223.
35 Cascone S, Catania F, Gagliano A, et al. Energy and Buildings, 2018, 166, 83.
36 Entchev E, Yang L, Ghorab M, et al. Alexandria Engineering Journal, 2018, 57(1), 455.
37 Saidur R, Rahim N A, Hasanuzzaman M, et al. Clean Technologies and Environmental Policy, 2012, 14(2), 195.
38 Saidur R. Energy Education Science and Technology Part A-Energy Science and Research, 2010, 25(1-2), 1.
39 Ziogou I, Michopoulos A, Voulgari V, et al. Journal of Cleaner Production, 2017, 168, 346.
40 Habibi Khalaj A, Scherer T, K. Halgamuge S. Applied Energy, 2016, 183, 1528.
41 Tantisattayakul T, Pharino C, Chavalparit O, et al. Energy for Sustai-nable Development, 2016, 34, 88.
42 Dixit M, Arora A, Kaushik S C. Clean Technologies and Environmental Policy, 2017, 19(9), 2215.
43 Shekarchian M, Zarifi F, Moghavvemi M, et al. Energy Conversion and Management, 2013, 71, 51.
44 Sheykhi M, Chahartaghi M, Balakheli M M, et al. Energy conversion and management, 2019, 180, 183.
45 Wang H, Wu J, Zhu X, et al. Applied Energy, 2016, 171, 314.
46 Gil-Lopez T, Gimenez-Molina C. Applied Energy, 2013, 101, 572.
47 Silvestre J D, de Brito J, Pinheiro M D. Energy & Buildings, 2013, 64, 199.
48 Hazi A, Hazi G. Environmental Engineering and Management Journal, 2017, 16(5), 1041.
49 Yao J. Sustainability (Basel, Switzerland), 2014, 6(2), 602.
50 Scoccia R, Toppi T, Aprile M, et al. Journal of Building Engineering, 2018, 16, 94.
51 Pergola M, Favia M, Palese A M, et al. Scientia Horticulturae, 2013, 162, 380.
52 Anastaselos D, Giama E, Papadopoulos A M. Energy and Buildings, 2009, 41(11), 1165.
53 Abdel-Salam A H, Simonson C J. Applied Energy, 2014, 116, 134.
54 Mousavi-Avval S H, Rafiee S, Sharifi M, et al. Journal of Cleaner Production, 2017, 140, 804.
55 Winebrake J J, Corbett J J, Falzarano A, et al. J Air Waste Manag Assoc, 2008, 58(8), 1004.
56 Nabavi-Pelesaraei A, Rafiee S, Mohtasebi S S, et al. Energy (Oxford), 2019, 169, 1259.
57 Li Z, Gao D, Chang L, et al. Chemical Engineering Research and Design, 2010, 88(1), 73.
58 Fathollahi H, Mousavi-Avval S H, Akram A, et al. Journal of Cleaner Production, 2018, 182, 852.
59 Sivaraman D, Pacca S, Mueller K, et al. Journal of Industrial Ecology, 2007, 11(3), 77.
60 Larsson M, Wang C, Dahl J. Applied Thermal Engineering, 2006, 26(13), 1353.
61 Spayde E, Mago P J, Luck R, et al. Energies (Basel), 2018, 11(2), 276.
62 Ferreira J, Barata E, Ramos P N, et al. Energy Policy, 2014, 66, 411.
63 Singh R J, Meena R L, Sharma N K, et al. Environ Monit Assess, 2016, 188(2), 79.
64 Li Y, Davis C, Lukszo Z, et al. Applied Energy, 2016, 173, 535.
65 Rasouli M, Akbari S, Simonson C J, et al. Energy & Buildings, 2014, 69, 112.
66 Chen Q, Ja M K, Li Y, et al. Energy (Oxford), 2018, 151, 387.
67 Stolarski M J, Krzyžaniak M, Warmiński K, et al. Energy & Buildings, 2013, 66, 395.
68 Saidur R, Mahlia T M I. Energy Policy, 2010, 38(8), 4617.
69 Papadopoulos A M, Oxizidis S, Papandritsas G. Energy & Buildings, 2008, 40(3), 224.
70 Feng L, Mears L, Beaufort C, et al. Energy Conversion and Management, 2016, 117, 454.
71 Gil-Lopez T, Sanchez-Sanchez A, Gimenez-Molina C. Applied Energy, 2014, 113, 622.
72 Torchio M F, Santarelli M G. Energy, 2010, 35(10), 4156.
73 González Palencia J C, Araki M, Shiga S. Applied Energy, 2016, 181, 96.
74 Jain V, Sachdeva G, Kachhwaha S S. Energy, 2015, 91, 816.
75 Reddy K S, Sharon H. Energy Conversion and Management, 2017, 151, 259.
76 Dias A M, Barros J, Serrano L. Advanced Materials Research,2010, 107, 129.
77 Miguel G S, Corona B, Ruiz D, et al. Journal of Cleaner Production, 2015, 94, 93.
78 Las-Heras-Casas J, López-Ochoa L M, Paredes-Sánchez J P, et al. Journal of Cleaner Production, 2018, 176, 590.
79 Rubio-Aliaga Á, García-Cascales M S, Sánchez-Lozano J M, et al. Renewable Energy, 2019, 138, 174.
80 Mazzeo D. Energy (Oxford), 2019, 168, 310.
81 Lollini, Barozzi, Fasano, et al. Building and Environment, 2006, 41(8), 1001.
82 Rad E A, Fallahi E. Construction & Building Materials,2019,205,196.
83 Qin X, Wei Q, Wang L, et al. International Journal of Photoenergy, DOI: 10.1155/2015/926235.
84 Pergola M, D'Amico M, Celano G, et al. Journal of Environmental Mana-gement, 2013, 128, 674.
85 Nabavi-Pelesaraei A, Rafiee S, Mohtasebi S S, et al. Journal of Cleaner Production, 2019, 217, 742.
86 Xu D, Qu M. Energy & Buildings, 2013, 67, 176.
87 Wang L, Lu J, Wang W, et al. Applied Energy, 2016, 183, 874.
88 Torchio M F. Energy Conversion and Management, 2015, 92, 114.
89 Sibilio S, Rosato A, Ciampi G, et al. Renewable and Sustainable Energy Reviews, 2017, 68, 920.
90 Lissén J M S, Rodríguez L R, Parejo F D, et al. Sustaina-bility (Basel, Switzerland), 2018, 10(11), 4082.
91 Rosato A, Sibilio S, Ciampi G, et al. Energy Procedia,2017,111,699.
92 Rosato A, Sibilio S, Ciampi G. Applied Thermal Engineering, 2013, 59(1-2), 599.
93 Mago P J, Chamra L M, Hueffed A. International Journal of Energy Research, 2009, 33(14), 1252.
94 Mago P J, Chamra L M. Energy and Buildings, 2009, 41(10), 1099.
95 Lazzaretto A, Toffolo A. Energy, 2004, 29(8), 1139.
96 Kang L, Yang J, Deng S, et al. Energy Procedia, 2016, 88, 510.
97 Iodice P, D'Accadia M D, Abagnale C, et al. Applied Thermal Enginee-ring, 2016, 95, 330.
98 Gargari S G, Rahimi M, Ghaebi H. Energy Conversion and Management, 2019, 185, 816.
99 Esrafilian M, Ahmadi R. Desalination, 2019, 454, 20.
100 Ershadi H, Karimipour A. Energy (Oxford), 2018, 149, 286.
101 Ehyaei M A, Mozafari A. Energy & Buildings, 2010, 42(2), 259.
102 Di Gregorio F, Zaccariello L. Energy, 2012, 42(1), 331.
103 Ciampi G, Rosato A, Scorpio M, et al. Energy Procedia,2015,78,1141.
104 Yu S, Tao J. Applied Energy, 2009, 86(1), S178.
105 Wang Z, Calderon M M, Lu Y. Biomass and Bioenergy, 2011, 35(7), 2893.
106 Pimentel D. Natural Resources Research, 2003, 12(2), 127.
107 Moraes B S, Junqueira T L, Pavanello L G, et al. Applied Energy, 2014, 113, 825.
108 Michopoulos A, Skoulou V, Voulgari V, et al. Energy Conversion and Management, 2014, 78, 276.
109 Hu Z, Tan P, Yan X, et al. Energy, 2008, 33(11), 1654.
110 Hu Z, Pu G, Fang F, et al. Renewable Energy, 2004, 29(14), 2183.
111 Fasahati P, Liu J J. Energy (Oxford), 2015, 93, 2321.
112 de Carvalho A L, Antunes C H, Freire F. Applied Energy, 2016, 181, 514.
113 Song J, Yang W, Li Z, et al. Energy Conversion and Management, 2016, 114, 168.
114 Pergola M, Piccolo A, Palese A M, et al. Journal of Cleaner Production, 2018, 172, 3969.
115 Ogorure O J, Oko C O C, Diemuodeke E O, et al. Energy Conversion and Management, 2018, 171, 222.
116 Nizami A, Rehan M, Naqvi M, et al. Energy Procedia, 2017, 142, 910.
117 Li H, Jin C, Mundree S. Journal of Cleaner Production, 2017, 153, 131.
118 Hublin A, Schneider D R, Džodan J. Waste Management & Research, 2014, 32(7), 626.
119 Fei F, Wen Z, Huang S, et al. Journal of Cleaner Production, 2018, 178, 731.
120 Carneiro M L N M, Gomes M S P. Energy Conversion and Management, 2019, 179, 397.
121 Ayodele T R, Alao M A, Ogunjuyigbe A S O. Resources, Conservation & Recycling, 2018, 134, 165.
122 Li L N. Several typical types of methods about multiple attribute decision making. Master’s Thesis, Southwest Jiaotong University, China, 2013(in Chinese).
李丽娜. 几种典型类型的多属性决策方法. 硕士学位论文,西南交通大学, 2013.
123 Wu Y J, Su Y Q, Cheng L X. Electrical & Energy Management Technology, 2015(16), 63(in Chinese).
吴英俊, 苏宜强, 成乐祥. 电器与能效管理技术, 2015(16), 63.
124 Guo J Y, Zhang Z B, Sun Q Y. China Safety Science Journal, 2008(5), 148(in Chinese).
郭金玉,张忠彬,孙庆云. 中国安全科学学报, 2008(5), 148.
125 Guo J W, Pu X Q, Gao X, et al. Journal of Xidian University, 2014, 41(6), 118(in Chinese).
郭金维,蒲绪强,高祥,等. 西安电子科技大学学报,2014,41(6),118.
126 Song D M, Liu C X, Shen C, et al. Journal of Shandong University(Engineering Science), 2015, 45(4), 1(in Chinese).宋冬梅,刘春晓,沈晨,等. 山东大学学报(工学版),2015,45(4),1.
127 Hofstetter P, Braunschweig A, Mettier T, et al. Journal of Industrial Ecology, 1999, 3(4), 97.
128 Zhou G, Gu Y, Yuan H, et al. Resources, Conservation and Recycling, 2020, 161, 104881.
129 Gu Y F. Theory and demonstration of resource & environment value compensation between primary and secondary industries. Ph.D. Thesis, Beijing University of Technology, China, 2018(in Chinese).
顾一帆. 原生与再生产业间资源环境价值补偿理论与实证研究. 博士学位论文,北京工业大学, 2018.
130 Yang Y R, Hou X L. Modern Economic Information, 2013(15), 80(in Chinese).
杨颖蓉,侯学良. 现代经济信息, 2013(15), 80.
131 Gu Y, Wu Y, Xu M, et al. Journal of Cleaner Production, 2016, 127, 331. |
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2021, Vol. 35 
