تعداد نشریات | 31 |
تعداد شمارهها | 748 |
تعداد مقالات | 7,108 |
تعداد مشاهده مقاله | 10,240,417 |
تعداد دریافت فایل اصل مقاله | 6,898,009 |
An overview to current status of waste generation, management and potentials for waste-to-energy (Case study: Rasht City, Iran) | ||
Caspian Journal of Environmental Sciences | ||
دوره 19، شماره 1، فروردین 2021، صفحه 159-171 اصل مقاله (1.06 M) | ||
نوع مقاله: Research Paper | ||
شناسه دیجیتال (DOI): 10.22124/cjes.2021.4506 | ||
نویسندگان | ||
Adel Bakhshipour* 1؛ Iraj Bagheri1؛ Cnstantinoso Psomopoulos2؛ Hemad Zareiforoush1 | ||
1Department of Agricultural Mechanization Engineering, Faculty of Agricultural Sciences, University of Guilan, Rasht, Iran | ||
2Department of Electrical and Electronics Engineering, University of West Attica, Athens, Greece | ||
چکیده | ||
This paper presents an overview of the current municipal solid waste (MSW) management in Rasht City, Guilan Province, Iran, followed by evaluating the potential for waste-to-energy. The data of different MSW functional elements were collected from previous works, available reports, interviews and meetings with specialists in the field. About 800 tons MSWs are generated in Rasht per day, of those, over 75% are organic wastes followed by paper and cardboard comprising 5.9%. The daily theoretical energy contained in the city MSWs was estimated to be over 591.62 megawatt hour (MWh, over 215942.54 MWh per year). Almost 500 tons of daily MSWs are directly transferred to Saravan as the biggest landfill in north of Iran with an area of about 30 ha, while the remaining portion is treated in the Guilan composting plant. Landfill mining calculations showed that we could recycle about 3008947, 36793, 61443 and 18366 tons of plastics, textile, wood and rubbers collected from Saravan landfill respectively. A simple assessment of waste-to-energy potentials from organic wastes using operational conversion coefficients revealed that by employing the combination of waste-to-energy and gas turbine technology, an estimated energy of 227.668 MWh can be produced from the Rasht daily food wastes. Although MSW management in Rasht has been improved over the last decade owing to the establishment of waste recycling and composting organization, however it is still far from the standard situation due to lack of comprehensive waste management planning, financial resources and infrastructures | ||
کلیدواژهها | ||
Municipal solid wastes؛ Landfill mining؛ Waste management؛ Waste-to-Energy | ||
مراجع | ||
Abduli, MA, Bidhendi, GN, Nasrabadi, T & Hoveidi, H 2007, Municipal Solid Waste Management on the South Coastline of the Caspian Sea (Golestan, Mazandaran, and Guilan Provinces of Iran). Journal of Environmental Health, 70: 34-37. Al-Khatib, IA, Monou, M, Zahra, ASFA, Shaheen, HQ & Kassinos, D 2010, Solid waste characterization, quantification and management practices in developing countries. A case study: Nablus district–Palestine. Journal of Environmental Management, 91: 1131-1138. Alamu, SA 2011, Sustainable Composting for Environmental Protection and Economic Development in Nigeria. African Environmental Perspectives-Volume 1: An Academia for Green Africa Publication, 1: 71. Annepu, RK 2012, Sustainable solid waste management in India, Columbia University, New York, 2, 189 p. Anonymous 2019, Giant landfill in Iran creates thousands of litres of contaminated water. https://observers.france24.com/en/20160614-iran-pollution-environment-water-landfill. Anttila, A 2017, Non-Ferrous Metals in Waste Incineration Bottom Ash. Helsinki Metropolia University of Applied Sciences, 19 p. Asadollahfardi, G, Joghatayi, F & Safari, E 2010, Methane reduction possibility Study in Rasht city landfills considering green development mechanism. Indian Journal of Environmental Education, 10: 45-54. Azimi, N 2003, Process of urban development and its environmental impacts on the Southern Caspian Sea region. Caspian Journal of Environmental Sciences, 1: 1-7. Bag, S, Dubey, R & Mondal, N 2017, Solid waste to energy status in India: A short review. Discovery, 2: 283-289. Behrooznia, L, Sharifi, M, Alimardani, R & Mousavi-Avval, S H 2018, Sustainability analysis of landfilling and composting-landfilling for municipal solid waste management in the north of Iran. Journal of Cleaner Production, 203: 1028-1038. Behrooznia, L, Sharifi, M & Hosseinzadeh-Bandbafha, H 2020, Comparative life cycle environmental impacts of two scenarios for managing an organic fraction of municipal solid waste in Rasht-Iran. Journal of Cleaner Production, 268: 1-16. Bhushan, A, Tripathi, A & Gupta, AK 2017, Methane Emission Estimation from Managed and Unmanaged Municipal Solid Waste Dumping Sites of Dehradun, Uttarakhand. Indian Journal of Forestry, 40: 389-395. Boonpa, S & Sharp, A 2017, Waste-to-energy policy in Thailand. Energy Sources, Part B: Economics, Planning, and Policy, 12: 434-442. Branchini, L 2015, Waste-To-Energy and Gas Turbine: Hybrid Combined Cycle Concept. Waste-to-Energy. Springer, 57-70. Charnnok, B, Kirirat, P & Chaiprapat, S 2014, Published. Potential conversion of plastic waste in old landfill to fuel. Trans Tech Publications Ltd, 2014. Trans Tech Publications Ltd, 844-848. Collivignarelli, C, Sorlini, S & Vaccari, M 2014, Solid wastes management in developing countries. Proceedings of ISWA 2004 World Congress, October, 2004. 17-21. Damghani, AM, Savarypour, G, Zand, E & Deihimfard, R 2008, Municipal solid waste management in Tehran: Current practices, opportunities and challenges. Waste Management, 28: 929-934. Dhar, H, Kumar, S & Kumar, R 2017, A review on organic waste to energy systems in India. Bioresource Technology, 245: 1229-1237. El-Fadel, M, Findikakis, AN & Leckie, JO 1997, Environmental impacts of solid waste landfilling. Journal of Environmental Management, 50: 1-25. El-Salam, MMA & Abu-Zuid, GI 2015, Impact of landfill leachate on the groundwater quality: A case study in Egypt. Journal of Advanced Research, 6: 579-586. Ghanbari, F, Sharee, FA, Monavari, M & Zaredar, N 2012, A new method for environmental site assessment of urban solid waste landfills. Environmental Monitoring and Assessment, 184: 1221-1230. Ghinea, C, Spranceana, A, Comanita, DE, Constantinescu, G & Gavrilescu, M 2016, Assessment of environmental impacts of municipal solid waste management in Iasi, Romania. Food and Environment Safety Journal, 14: 171-180. Gonçalves, ATT, Moraes, FTF, Marques, GL, Lima, JP & Lima, RdS 2018, Urban solid waste challenges in the BRICS countries: a systematic literature review. Revista Ambiente & Água, 13: 1-20. Government of India, 2017, Waste to Wealth, a ready reckoner for selection of technologies for management of municipal waste. Ministry of Housing and Urban Affairs, 116 p. Gupta, N, Yadav, KK & Kumar, V 2015, A review on current status of municipal solid waste management in India. Journal of Environmental Sciences, 37: 206-217. Henry, RK, Yongsheng, Z & Jun, D 2006, Municipal solid waste management challenges in developing countries–Kenyan case study. Waste Management, 26: 92-100. Jha, AK, Singh, S, Singh, G & Gupta, P K 2011, Sustainable municipal solid waste management in low income group of cities: a review. Tropical Ecology, 52: 123-131. Joseph, K, Esakku, S & Nagendran, R 2007, Mining of compost from dumpsites and bioreactor landfills. International Journal of Environmental Technology and Management, 7: 317-325. Karija, MK, Shihua, Q & Lukaw, YS 2013, The impact of poor municipal solid waste management practices and sanitation status on water quality and public health in cities of the least developed countries: the case of Juba, South Sudan. International Journal of Applied Science and Technology, 3. Karimpour-Fard, M 2018, Rehabilitation of Saravan dumpsite in Rasht, Iran: geotechnical characterization of municipal solid waste. International Journal of Environmental Science and Technology, 16: 4419-4436. Kaushal, RK, Varghese, GK & Chabukdhara, M 2012, Municipal solid waste management in India-current state and future challenges: A review. International Journal of Engineering Science and Technology, 4: 1473-1489. Kaveh, M, Jahanbakhshi, A, Abbaspour‐Gilandeh, Y, Taghinezhad, E & Moghimi, MBF 2018, The effect of ultrasound pre‐treatment on quality, drying, and thermodynamic attributes of almond kernel under convective dryer using ANNs and ANFIS network. Journal of Food Process Engineering, 41: e12868. Kondusamy, D & Kalamdhad, AS 2014, Pre-treatment and anaerobic digestion of food waste for high rate methane production–A review. Journal of Environmental Chemical Engineering, 2: 1821-1830. Krook, J, Svensson, N & Eklund, M 2012, Landfill mining: A critical review of two decades of research. Waste Management, 32: 513-520. Lakshmi, D, Muthukumar, P, Layek, A & Nayak, PK 2019, Performance analyses of mixed mode forced convection solar dryer for drying of stevia leaves. Solar Energy, 188: 507-518. Lam, SS, Liew, RK, Jusoh, A, Chong, CT, Ani, FN & Chase, HA 2016, Progress in waste oil to sustainable energy, with emphasis on pyrolysis techniques. Renewable and Sustainable Energy Reviews, 53: 741-753. Late, A & Mule, M 2013, Composition and Characterization Study of Solid Waste from Aurangabad City. Universal Journal of Environmental Research & Technology, 3: 55-60. Lemus‐Mondaca, R, Vega‐Gálvez, A, Moraga, NO & Astudillo, S 2015, Dehydration of S tevia rebaudiana B ertoni Leaves: Kinetics, Modeling and Energy Features. Journal of Food Processing and Preservation, 39: 508-520. Lombardi, L, Carnevale, E & Corti, A 2012, Analysis of energy recovery potential using innovative technologies of waste gasification. Waste Management, 32: 640-652. Lombardi, L, Carnevale, E & Corti, A 2015, A review of technologies and performances of thermal treatment systems for energy recovery from waste. Waste Management, 37: 26-44. López-Cano, I, Cayuela, ML, Mondini, C, Takaya, CA, Ross, AB & Sánchez-Monedero, MA 2018, Suitability of different agricultural and urban organic wastes as feedstocks for the production of biochar—Part 1: Physicochemical characterisation. Sustainability, 10: 2265. Medina, M 2010, Solid wastes, poverty and the environment in developing country cities: Challenges and opportunities. WIDER Working paper, World Institute for Development Economics Research, 18 p. Menegaki, M, Damigos, D, Benardos, A & Kaliampakos, D 2018, Finding the Right Time to Mine: A Real Options Analysis of Landfill Mining Projects. Symposium on Environmental Issues and Waste Management in Energy and Mineral Production, Springer, 257-267. Moghadam, MA, Mokhtarani, N & Mokhtarani, B 2009, Municipal solid waste management in Rasht City, Iran. Waste Management, 29: 485-489. Mohanty, C, Mishra, U & Beuria, P 2014, Municipal solid waste management in Bhubaneswar, India-A review. International Journal of Latest Trends in Engineering and Technology, 3: 303-312. Moya, D, Aldás, C, López, G & Kaparaju, P 2017, Municipal solid waste as a valuable renewable energy resource: a worldwide opportunity of energy recovery by using waste-to-energy technologies. Energy Procedia, 134: 286-295. Münster, M & Lund, H 2010, Comparing Waste-to-Energy technologies by applying energy system analysis. Waste Management, 30: 1251-1263. Ngoc, UN & Schnitzer, H 2009, Sustainable solutions for solid waste management in Southeast Asian countries. Waste Management, 29: 1982-1995. Oloruntade, A, Adeoye, P & Alao, F 2014, Municipal solid waste collection and management strategies in Akure, South-Western Nigeria. The Journal of Solid Waste Technology and Management, 40: 24-32. Oloruntade, A, Adeoye, P & F Alao, F 2013, Municipal solid waste collection and management strategies in Akure, South-Western Nigeria. Caspian Journal of Environmental Sciences, 11: 1-10. Pavlas, M & Touš, M 2009, Efficient waste-to-energy system as a contribution to clean technologies. Clean Technologies and Environmental Policy, 11: 19-29. Perrot, J-F & Subiantoro, A 2018, Municipal waste management strategy review and waste-to-energy potentials in New Zealand. Sustainability, 10: 1-12. Pham, TPT, Kaushik, R, Parshetti, GK, Mahmood, R & Balasubramanian, R 2015, Food waste-to-energy conversion technologies: current status and future directions. Waste Management, 38: 399-408. Psomopoulos, C, Bourka, A & Themelis, N 2009, Waste-to-energy: A review of the status and benefits in USA. Waste Management, 29: 1718-1724. Rajkumar, N, Subramani, T & Elango, L 2010, Groundwater contamination due to municipal solid waste disposal-A GIS based study in Erode city. International Journal of Environmental Sciences, 1: 39-55. Rajput, R, Prasad, G & Chopra, A 2009, Scenario of solid waste management in present Indian context. Caspian Journal of Environmental Sciences, 7: 45-53. Riya, S, Suzuki, K, Meng, L, Zhou, S, Terada, A & Hosomi, M 2018, The influence of the total solid content on the stability of dry-thermophilic anaerobic digestion of rice straw and pig manure. Waste Management, 76: 350-356. Rogoff, MJ & Screve, F 2011, Waste-to-energy: technologies and project implementation, William Andrew, 179 p. RTOUF 2014, Improvement of Saravan landfill, Phase 1: Basic studies. Research and Technology Office of University of Guilan (in persian), 97 p. RWMOR report, 2007, Statistics of Waste Management Organization of Rasht. Rasht Waste Management Organization, Rasht, Iran. http://www.rasht-bazyaft.ir. RWMOR report, 2017, Statistics of Waste Management Organization of Rasht. Rasht Waste Management Organization, Rasht, Iran. http://www.rasht-bazyaft.ir. Sadi, M & Arabkoohsar, A 2019, Modelling and analysis of a hybrid solar concentrating-waste incineration power plant. Journal of Cleaner Production, 216: 570-584. Saidan, MN, Drais, AA & Al-Manaseer, E 2017, Solid waste composition analysis and recycling evaluation: Zaatari Syrian Refugees Camp, Jordan. Waste Management, 61: 58-66. SCI 2020, Statistical Center of Iran, https://www.amar.org.ir/english, (accessed 2020). Stehlík, P 2009, Contribution to advances in waste-to-energy technologies. Journal of Cleaner Production, 17: 919-931. Suocheng, D, Tong, KW & Yuping, W 2001, Municipal solid waste management in China: using commercial management to solve a growing problem. Utilities Policy, 10: 7-11. Tan, ST, Ho, WS, Hashim, H, Lee, CT, Taib, MR & Ho, CS 2015, Energy, economic and environmental (3E) analysis of waste-to-energy (WTE) strategies for municipal solid waste (MSW) management in Malaysia. Energy Conversion and Management, 102: 111-120. Tang, P, Florea, M, Spiesz, P & Brouwers, H 2015, Characteristics and application potential of municipal solid waste incineration (MSWI) bottom ashes from two waste-to-energy plants. Construction and Building Materials, 83: 77-94. Tavakoli, B & Bagheri Zonoz, F 2014, Effect of cash subsidy on the quantity of domestic waste (Case study: Rasht, North of Iran). Caspian Journal of Environmental Sciences, 12: 147-153. Themelis, N 2006, Energy recovery from global waste-to-energy. Summer Review Issue of Waste Management World, 1-9. Ttsgroup 2019, http://ttsgroup.ir/En/projects.aspx?id=10002, (accessed 2019). Tun, M, Juchelková, D, Raclavská, H & Sassmanová, V 2018, Utilization of biodegradable wastes as a clean energy source in the developing countries: A case study in Myanmar. Energies, 11: 3183. Wagner, TP & Raymond, T 2015, Landfill mining: Case study of a successful metals recovery project. Waste Management, 45: 448-457. Williamson, I 2011, Could gasification power cars?. Renewable Energy Focus, 12: 14-16. WorldData 2020, Energy consumption in Iran, https://www.worlddata.info/asia/iran/energy-consumption.php, (accessed 2020). | ||
آمار تعداد مشاهده مقاله: 1,161 تعداد دریافت فایل اصل مقاله: 1,267 |