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2022 | OriginalPaper | Buchkapitel

5. Energy Recovery from Solid Waste

verfasst von : Rosnani Alkarimiah, Muaz Mohd Zaini Makhtar, Hamidi Abdul Aziz, P. Aarne Vesilind, Lawrence K. Wang, Yung-Tse Hung

Erschienen in: Solid Waste Engineering and Management

Verlag: Springer International Publishing

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Abstract

The growing amount of solid waste (SW) and the related waste disposal problems urge the development of a more sustainable waste management practice. The organic wastes that are generated include food scraps, yard debris, paper, wood, and textile byproducts. According to most studies, almost all landfill gas is created by the breakdown of organic waste in combination with the naturally occurring bacteria in the soil that is used to cover the landfill. They are inevitably linked to the treatment and disposal of solid waste. In this instance, treatment is utilized to restore or recover important materials or energy, control waste generation, or manage trash disposal before it is deposited or discarded in landfills. A disposal site where solid trash, such as paper, glass, and metal, is buried between layers of dirt and other materials, such that land around the site is less contaminated. Waste-to-Energy (WtE) technologies are being developed globally. The essential concepts of available technologies and several specific technologies’ processes are summarized. Technologically sophisticated processes (e.g., plasma gasification) gain increased attention, with an emphasis on energy and material recovery potential. This chapter ends with a comparison of the various technologies, highlighting variables impacting their application and operational suitability. More budgetary allocation for technical support by the government is also recommended in this chapter. This will help to promote solid waste management by reducing, reusing, and recycling waste. It will also help to retain employees by providing a good wage, benefits, and training. As a result, WtE technologies have the potential to make a significant contribution to the growth of renewable energy while also reducing landfilling expenses and the associated environmental implications. However, deciding between the two options necessitates further financial, technological, and environmental examination using a life cycle assessment (LCA) methodology.

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Vorheriges Kapitel Health-Care Waste Management

Nächstes Kapitel Composting by Black Soldier Fly

Blackwater

Water used to flush toilets, along with the human waste it flushes away.

Calorific Value

The calorific value of a substance is known as the number of calories produced when a unit amount of substance is fully oxidized. This value is measured using a bomb calorimeter. The calorific value of coal is calculated using the gross calorific value (HG), which includes latent heat of water vaporization.

Fossil Fuel

Coal, petroleum, natural gas, oil shale, bitumen, tar sands, and heavy oils are all examples of fossil fuels. All are carbon-based and were created because of geologic processes operating on the remains of photosynthesis-produced organic matter.

Greywater

Wastewaters from drains, tubs, showers, dishwashers, and clothes washers.

MSW

Municipal solid waste (MSW) is classified as waste collected by the municipality or disposed of at a municipal waste disposal site. It includes residential, agricultural, institutional, commercial, and municipal waste, as well as waste from construction and demolition.

RDF

Refuse-Derived Fuel (RDF) is made from domestic and commercial waste, which contains both biodegradable and non-biodegradable materials. Non-combustible materials such as glass and metals are removed, and the resulting residue is shredded. At waste-to-energy recycling plants, refuse-derived fuel is used to produce electricity.

SRF

Solid Recovered Fuel (SRF) is a high-quality alternative to fossil fuels made primarily from commercial waste such as paper, card, wood, textiles, and plastic. Solid recovered fuel has been further processed to increase its consistency and value. It has a higher calorific value than RDF and is used in cement kilns and other similar facilities.

Waste-to-Energy

Waste-to-energy (WtE) or energy-from-waste (EfW) is a term that refers to the method of producing energy in the form of electricity and/or heat from waste that has been sorted or processed into a fuel source. WtE is a method of reclaiming resources.

Marchettini, N., Ridolfi, R., & Rustici, M. (2007). An environmental analysis for comparing waste management options and strategies. Waste Management, 27(4), 562–571.CrossRef

Tatarniuk, C. (2007). The feasibility of waste-to-energy in Saskatchewan based on waste composition and quantity. Unpublished M.Sc. Thesis, Department of Civil and Geological Engineering, University of Saskatchewan, Saskatoon.

Idris, Z., Orgéas, L., Geindreau, C., Bloch, J. F., & Auriault, J. L. (2004). Microstructural effects on the flow law of power-law fluids through fibrous media. Modelling and Simulation in Materials Science and Engineering, 12, 995.CrossRef

Ray, A., & De, S. (2020). Hybrid renewable multigeneration: Low carbon sustainable solution with optimum resource utilization. Encyclopedia of Renewable and Sustainable Materials, 3, 526–533.CrossRef

Callan, S. J., & Thomas, J. M. (2013). Environmental economics and management: Theory, policy, and applications. Cengage Learning. Fifth Edition complements economic theory with timely, real-world application.

Yong, J. Y., Klemeš, J. J., Varbanov, P. S., & Huisingh, D. J. (2016). Cleaner energy for cleaner production: Modelling, simulation, optimisation and waste management. Journal of Cleaner Production, 111, 1–16.CrossRef

Adapa, P. K., Tabil, L. G., & Schoenau, G. J. (2006). Municipal solid waste – A review of classification system. Presented at the 2006 CSBE/SCGA North Central Inter-Sectional Meeting 2016, Saskatoon, SK, Oct 5-7. CSBE Paper No. MBSK 06-209.

Astrup, T. F., Tonini, D., Turconi, R., & Boldrin, A. (2015). Life cycle assessment of thermal waste-to-energy technologies: Review and recommendations. Waste Management, 37, 104–115.CrossRef

Portugal-Pereira, J., & Lee, L. (2016). Economic and environmental benefits of waste-to-energy technologies for debris recovery in disaster-hit Northeast Japan. Journal of Cleaner Production, 112, 4419–4429.CrossRef

10.

Thormak, C. (2001). Conservation of energy and natural resources by recycling building waste. Resources, Conservation and Recycling, 33(2), 113–130.CrossRef

11.

Charley, J. S. (2017). Classification and densification of municipal solid waste for biofuels applications. PhD Thesis, Department of Chemical and Biological Engineering University of Saskatchewan, Saskatoon, Canada.

12.

American Society of the International Association for Testing and Materials Standards. (2008). Standard test method for determination of the composition of unprocessed municipal solid waste. Author.

13.

EWMC (Edmonton Waste Management Centre). (2015). Waste-to-biofuels and chemicals facility: Turning garbage into fuel. Author. Retrieved April 28, 2021, from www.edmonton.ca/programs_services/garbage_waste/biofuels-facility.aspx

14.

Mainieri, T., Barnett, E. G., Valdero, T. R., & Unipan, J. B. (1997). Green buying: The influence of environmental concern on consumer behavior. The Journal of Social Psychology, 137(2), 189.CrossRef

15.

Shao, Y., & Li, C. (2019). Harmless disposal technology of Hazardous waste from thermal power plants. Paper presented at the IOP Conference Series: Earth and Environmental Science.CrossRef

16.

Kothari, R., Tyagi, V., & Pathak, A. J. R. (2010). Waste-to-energy: A way from renewable energy sources to sustainable development. Renewable & Sustainable Energy Reviews, 14(9), 3164–3170.CrossRef

17.

Fruergaard, T., & Astrup, T. (2011). Optimal utilization of waste-to-energy in an LCA perspective. Waste Management, 31(3), 572–582.CrossRef

18.

Peterson, E., Fleming, M., Saund, S., & Stephens, B. (2019). Baltimore Clean Air Act; the need for a new waste management system in Baltimore. Journal of Science Policy Governance, 14, 1.

19.

Brunner, P. H., & Rechberger, H. (2015). Waste to energy–Key element for sustainable waste management. Waste Management, 37, 3–12.CrossRef

20.

Anwar, M., Fayyaz, A., Sohail, N., Khokhar, M., Baqar, M., Yasar, A., & Rehan, M. J. (2020). CO2 utilization: Turning greenhouse gas into fuels and valuable products. Journal of Environmental Management, 260, 110059.CrossRef

21.

Rydh, C. J., & Svärd, B. (2003). Impact on global metal flows arising from the use of portable rechargeable batteries. Science of the Total Environment, 302, 167–184.CrossRef

22.

IEA/OECD. (2017). Energy and climate change, world energy outlook special report. International Energy Agency.

23.

Geels, F. W., Sovacool, B. K., Schwanen, T., & Sorrell, S. (2017). Sociotechnical transitions for deep decarbonization. Science, 357(6357), 1242–1244.CrossRef

24.

De Wit, M., Hoppe, T., & Faaij, A. (2011). Productivity developments in European agriculture: Relations to and opportunities for biomass production. Renewable and Sustainable Energy Reviews, 15(5), 2397–2412.CrossRef

25.

Soares de Silva, D., & Horlings, L. G. (2020). The role of local energy initiatives in co-producing sustainable places. Sustainability, 15, 363–377.CrossRef

26.

Pellegrini, L. F., & de Oliveira, S., Jr. (2011). Combined production of sugar, ethanol and electricity: Thermoeconomic and environmental analysis and optimization. Energy, 36, 3704–3715.CrossRef

27.

Sameeroddin, M., Deshmukh, M. K. G., Viswa, G., & Abdul Sattar, M. (2021). Renewable energy: Fuel from biomass, production of ethanol from various sustainable sources by fermentation process. Materials Today: Proceedings.

28.

Warbroek, B., Hoppe, T., Bressers, H., & Coenen, F. (2019). Testing the social, organizational, and governance factors for success in local low carbon energy initiatives. Energy Research & Social Science, 58, 101269.CrossRef

29.

Zakir Hossain, H. M., Hossain, Q. H., Uddin Monira, M. M., & Ahmed, M. T. (2014). Municipal solid waste (MSW) as a source of renewable energy in Bangladesh: Revisited. Renewable and Sustainable Energy Reviews, 39, 35–41.CrossRef

30.

Jenkins, S. D. (2006). Conversion technologies. Earthscan. James & James. Retrieved April 28, 2021, from www.earthscan.co.uk/news/article

31.

Biffa. (2005). Thermal methods of municipal waste treatment. In Mass balance studies. Biffa Waste Services Ltd. Retrieved from www.biffa.co.uk

32.

Gartner, L. (2004). New and emerging residual waste management technologies update. Report prepared for Regional District of Nanaimo, B.C. Gartner Lee Ltd.

33.

Mor, S., Ravindra, K., Visscher, A., Dahiya, R., & Chandra, A. (2006). Municipal solid waste characterization and its assessment for potential methane generation: A case study. Science of the Total Environment, 371, 1–10.CrossRef

34.

ETC/RWM. (2007). Environmental outlooks: Municipal waste. Working Paper no 1/2007, European Topic Centre on Resource and Waste Management. Retrieved from http://waste.eionet.europa.eu/publications

35.

Sawatdeenarunat, C., Surendra, K. C., Takara, D., Oechsner, H., & Khanal, S. K. (2015). Anaerobic digestion of lignocellulosic biomass: Challenges and opportunities. Bioresource Technology, 178, 178–186.CrossRef

36.

Hu, F., & Ragauskas, A. (2012). Pretreatment and lignocellulosic chemistry. Bioenergy Research, 5, 1043–1066.CrossRef

37.

Pu, Y., Zhang, D., Singh, P. M., & Ragauskas, A. J. (2008). The new forestry biofuels sector. Biofuels, Bioproducts and Biorefining, 2, 58–73.CrossRef

38.

Mosier, N., Wayman, C., Dale, B., Elander, R., Lee, Y. Y., Holtzapple, M., & Ladisch, M. (2005). Features of promising technologies for pretreatment of lignocellulosic biomass. Bioresource Technology, 96(6), 673–686.CrossRef

39.

Lynd, L. R., Weimer, P. J., & Van Zyl, W. H. (2002). Pretorius IS: Microbial cellulose utilization: Fundamentals and biotechnology. Microbiology and Molecular Biology Reviews, 66, 506–577.CrossRef

40.

Laser, M., Schulman, D., Allen, S. G., Lichwa, J., Antal, M. J., Jr., & Lynd, L. R. (2002). A comparison of liquid hot water and steam pretreatments of sugar cane bagasse for bioconversion to ethanol. Bioresource Technology, 81(1), 33–44.CrossRef

41.

Kadam, K. L., Rydholm, E. C., & McMillan, J. D. (2004). Development and validation of a kinetic model for enzymatic saccharification of lignocellulosic biomass. Biotechnology Progress, 20(3), 698–705.CrossRef

42.

Heitz, M., Capek-Menard, E., Koeberle, P. G., Gagne, J., & Chomet, E. (1991). Fractionation of Populus tremuloides at the pilot plant scale: Optimization of steam pretreatment conditions using the STAKE II technology. Bioresource Technology, 35, 23–32.CrossRef

43.

De Bari, I., Viola, E., Barisano, D., Cardinale, M., Nanna, F., & Zimbardi, F. (2002). Ethanol production at flask and pilot scale from concentrated slurries of steam-exploded aspen. Industrial & Engineering Chemistry Research, 41, 1745–1753.CrossRef

44.

Vlasenko, E. Y., Ding, H., Labavitch, J. M., & Shoemaker, S. P. (1997). Enzymatic hydrolysis of pretreated rice straw. Bioresource Technology, 59, 109–119.CrossRef

45.

Sun, Y., & Cheng, J. Y. (2002). Hydrolysis of lignocellulosic materials for ethanol production: A review. Bioresource Technology, 83, 1–11.CrossRef

46.

Fan, L. T., Gharpuray, M. M., & Lee, Y. H. (1987). Cellulose hydrolysis biotechnology monographs. Springer.CrossRef

47.

Liu, J., Bao, Z., Yi Cui, Y., Dufek, E. J., Goodenough, J. B., Khalifah, P., Li, Q., et al. (2019). Pathways for practical high-energy long-cycling lithium metal batteries. Nature Energy, 4, 180–186.CrossRef

48.

Ibikunle, R. A., Titiladunayo, I. F., Akinnuli, B. O., Dahunsi, S. O., & Olayanju, T. M. A. (2019). Estimation of power generation from municipal solid wastes: A case Study of Ilorin metropolis, Nigeria. Energy Reports, 5, 126–135.CrossRef

49.

Bosmans, A., & Helsen, L. (2010). Proceedings Venice 2010, Third International Symposium on Energy from Biomass and Waste Venice, Italy, 8–11 November 2010.

50.

Helsen, L. (2000). Low-temperature pyrolysis of CCA treated wood waste. Ph.D. Thesis, Heverlee, Belgium, K.U. Leuven.

51.

UBA. (2001). Draft of a German report with basic information for a BREF-Document “Waste Incineration”. Umweltbundesamt. Retrieved from http://193.219.133.6/aaa/Tipk/tipk/4_kiti%20GPGB/63.pdf

52.

EBARA. (2003). EUP - EBARA UBE Process for gasification of waste plastics. Author. Retrieved May 2010, from http://www.ebara.ch/

53.

Huang, H., & Tang, L. (2007). Treatment of organic waste using thermal plasma pyrolysis technology. Energy Conversion and Management, 48(4), 1331–1337.CrossRef

54.

Ahola, S., Turon, X., Osterberg, M., Laine, J., & Rojas, O. (2008). Enzymatic hydrolysis of native cellulose nanofibrils and other cellulose model films: Effect of surface structure. Langmuir, 24, 11592–11599.CrossRef

55.

Asif, M., & Muneer, T. (2007). Energy supply, its demand and security issues for developed and emerging economies. Renewable and Sustainable Energy Reviews, 11(7), 1388–1413.CrossRef

56.

Lavric, E. D., Konnov, A., & DeRuyck, J. (2004). Dioxin levels in wood combustion—A review. Biomass and Bioenergy, 26(2), 115–145.CrossRef

57.

Samarasiri, B. K. T., Samarakoon, S. W. S., Rathnasiri, P. G., & Gunawerdana, S. H. P. (2017). Mechanistic model for electricity generation via biomethane production through anaerobic digestion of organic fraction of municipal solid waste generated in Sri Lanka. In Moratuwa Engineering Research Conference (MERCon). IEEE.

58.

Negi, P. S., Pandey, C. P., & Singh, N. (2019). Black carbon aerosols in the ambient air of Gangotri Glacier valley of north-western Himalaya in India. Atmospheric Environment, 214, 116879.CrossRef

59.

Chen, W. H., Peng, J., & Bi, X. T. (2015). A state-of-the-art review of biomass torrefaction, densification and applications. Renewable and Sustainable Energy Reviews, 44, 847–866.CrossRef

60.

Thapa, B., Gupta, D., & Yadav, A. (2019). Corrosion Inhibition of Bark Extract of Euphorbia royleana on Mild Steel in 1M HCl. Journal of Nepal Chemical Society, 40, 25–29.CrossRef

61.

Ramachandra, T. V., Bharat, H. A., Kulkarni, G., & Han, S. S. (2018). Municipal solid waste: Generation, composition and GHG emissions in Bangalore, India. Renewable and Sustainable Energy Reviews, 82(Part 1), 1122–1136.CrossRef

62.

Nazimudheen, G., Sekhar, N. C., Sunny, A., Kallingal, A., & Hasanath, B. (2021). Physiochemical characterization and thermal kinetics of lignin recovered from sustainable agrowaste for bioenergy applications. International Journal of Hydrogen Energy, 46(6), 4798–4807.CrossRef

63.

Cui, C., Yong Liu, Y., Xia, B., Xiaoyan Jiang, X., & Skitmore, M. (2020). Overview of public-private partnerships in the waste-to-energy incineration industry in China: Status, opportunities, and challenges. Energy Strategy Reviews, 32(2020), 100584.CrossRef

64.

Kaza, S., Yao, L., Bhada-Tata, P., & Van Woerden, P. (2018). What a waste 2.0: A global snapshot of solid waste management to 2050. World Bank.CrossRef

65.

Traven, L., Kegalj, I., & Sebelja, I. (2018). Management of municipal solid waste in Croatia: Analysis of current practices with performance benchmarking against other European Union member states. Waste Management & Research: The Journal for a Sustainable Circular Economy, 36(8), 663–669.CrossRef

66.

Gardiner, R., & Petr Hajek, P. (2020). Municipal waste generation, R&D intensity, and economic growth nexus – A case of EU regions. Waste Management, 114, 124–135.CrossRef

67.

Zafar, M. W., Shahbaz, M., Hou, F., & Sinha, A. (2019). From nonrenewable to renewable energy and its impact on economic growth: The role of research & development expenditures in Asia-Pacific Economic Cooperation countries. Journal of Cleaner Production, 212, 1166–1178.CrossRef

68.

Klass, D. L. (2003). A critical assessment of renewable energy usage in the USA. Energy Policy, 31, 353–367.CrossRef

69.

Aydin, M., & Pata, U. K. (2020). Are shocks to disaggregated renewable energy consumption permanent or temporary for the USA? Wavelet based unit root test with smooth structural shifts. Energy, 207, 118245.CrossRef

70.

Mohd Chachuli, F. S., Mat, S., Ahmad Ludin, N., & Sopian, K. (2021). Performance evaluation of renewable energy R&D activities in Malaysia. Renewable Energy, 163, 544–560.CrossRef

71.

Aziz, H. A., Amr, S. S. A., Vesilind, P. A., Wang, L. K., & Hung, Y. T. (2021). Introduction to solid waste management. In L. K. Wang, M. H. S. Wang, & Y. T. Hung (Eds.), H. A. Aziz (Consulting Ed.) Solid waste engineering and management (Vol. 1, pp. 1–86). Springer Nature.

72.

Excoffier, G., Toussaint, B., & Vignon, M. R. (1991). Saccharification of steam-exploded poplar wood. Biotechnology and Bioengineering, 38, 1308–1317.CrossRef

73.

Van Walsum, G. P., Alien, S. G., Spencer, M. J., Laser, M. S., Antal, M. J., Jr., & Lynd, L. R. (1996). Conversion of lignocellulosics pretreated with liquid hot water to ethanol. Applied Biochemistry and Biotechnology, 57/58, 157–170.CrossRef

Titel: Energy Recovery from Solid Waste
verfasst von: Rosnani Alkarimiah
Muaz Mohd Zaini Makhtar
Hamidi Abdul Aziz
P. Aarne Vesilind
Lawrence K. Wang
Yung-Tse Hung
Verlag: Springer International Publishing
Buch: Solid Waste Engineering and Management
Print ISBN: 978-3-030-96988-2

Electronic ISBN: 978-3-030-96989-9

Copyright-Jahr: 2022
DOI: https://doi.org/10.1007/978-3-030-96989-9_5