Technical potential of electricity production from municipal solid waste disposed in the biggest cities in Brazil: Landfill gas, biogas and thermal treatment

Souza, Samuel Nm de; Horttanainen, Mika; Antonelli, Jhonatas; Klaus, O.; Lindino, Cléber Antônio; Nogueira, Carlos Eduardo Camargo

doi:10.1177/0734242x14552553

Cited by 39 publications

(26 citation statements)

References 31 publications

(66 reference statements)

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“…No Brasil, nota-se nos últimos anos uma maior tendência para fazer o aproveitamento energético do gás metano nos aterros sanitá-rios, principalmente pela queima em motores de combustão interna (BARROS, 2013;TIAGO FILHO;LEME et al, 2014;SOUZA et al, 2014;NADALETTI et al, 2015). O dimensionamento de projetos de aproveitamento do metano em aterros sanitários para a geração de eletricidade baseia-se normalmente em modelos cinéticos de primeira ordem exponencial (SPOKAS et al, 2006;MACHADO et al, 2009;MACIEL & JUCÁ, 2011;ABREU, 2014;WANGYAO et al, 2010).…”

Section: Evaluation Of Kinetic Parameters For Methane Generation In Aunclassified

Avaliação dos parâmetros cinéticos da geração de metano em uma célula experimental de resíduos sólidos

Candiani

Moreira

2018

Eng. Sanit. Ambient.

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RESUMO O presente trabalho avalia os parâmetros cinéticos de modelos de primeira ordem (exponenciais) para geração de metano em aterros sanitários na região subtropical de São Paulo (SP). Construiu-se uma célula experimental especialmente para esse objetivo. A função resposta temporal da célula para geração de metano devido a uma deposição de resíduos sólidos urbanos (RSU) foi obtida ao longo de 600 dias. O tempo necessário para iniciar a geração de metano foi de 190 dias. Entre o 400º e o 500º dia após a deposição dos resíduos houve uma fase de elevada taxa de geração de metano e, após o 560º dia, esta começou a diminuir de forma relevante. Os parâmetros cinéticos potencial de geração de metano (L) e constante de biodegradação para geração de metano (k) foram inferidos por meio de ajustes do modelo de primeira ordem à função resposta obtida experimentalmente e utilizando informações de composição dos RSU. Os valores obtidos para L e k para biodegradação rápida (nos primeiros 3 anos) foram, respectivamente, 1.481±1.072 mol t-1 RSU e 0,18±0,13 ano-1. Os valores obtidos para L e k considerando biodegradação rápida e lenta (até dezenas de anos) foram 3.835 mol t-1 RSU e 0,069±0,002 ano-1 e 5.027 mol t-1 RSU e 0,052±0,002 ano-1, respectivamente, dependendo da metodologia utilizada para a determinação de L. Os resultados obtidos na célula experimental indicam que a biodegradação dos RSU em Caieiras (SP) ocorre rapidamente, isto é, com valores maiores para k e menores para L do que aqueles sugeridos na literatura. Esses resultados indicam possível redução da longevidade dos projetos de aproveitamento energético do metano em aterros sanitários em regiões tropicais e subtropicais. Ao final são feitas recomendações para a escolha de L e k para dimensionamento de projetos de aproveitamento energético e para avaliações e remediações ambientais.

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Section: Evaluation Of Kinetic Parameters For Methane Generation In Aunclassified

Avaliação dos parâmetros cinéticos da geração de metano em uma célula experimental de resíduos sólidos

Candiani

Moreira

2018

Eng. Sanit. Ambient.

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“…In Mexicali and Tijuana (Mexico), the generation of energy from landfill gas could compensate for 6-40% of the demand for lighting, respectively [64]. In São Paulo and Rio de Janeiro (Brazil), the calculation by Souza et al [66] shows that the production of biogas could compensate for approximately 7% of the electrical energy.…”

Section: Biogasmentioning

confidence: 99%

“…The use of incineration technologies currently presents technical or economic difficulties, while gasification and pyrolysis are not available on a commercial scale [86]. Using incineration techniques to produce fuel recovered from waste or municipal solid waste can increase the production of energy two and four times, respectively, with respect to the biochemical processes [66].…”

Section: Incinerationmentioning

confidence: 99%

“…São Paulo (Brazil) 7.30% 8723.6 GWh/year Landfill biogas [66] Performs an analysis of the technical potential for the production of electricity using urban solid waste. Rio de Janeiro (Brazil) 6.73% 5481 GWh/year Tartu (Estonia) 54.5% 1.29 million liters of diesel 0.14 tons of natural gas Fuel for transport [59] The biogas potential of greening waste was calculated.…”

Section: Renewable Energy In the Citiesmentioning

confidence: 99%

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The Role of Renewable Energy in the Promotion of Circular Urban Metabolism

2017

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Cities are human creations requiring large amounts of materials and energy. Constant consumption of resources exerts pressure on the environment not only due to its exploitation, but also because once processed, the resources produce waste, emissions or effluents. Cities are responsible for more than three quarters of the emissions of greenhouse gases. It is anticipated that the urban population will increase by up to 80% by the mid-21st century, which will make the current energy model unsustainable, as it is based on the intensive use of fossil resources. A change in urban planning is required to meet the energy requirements of cities. Several studies mention that renewable energy must be used in cities, but they do not identify the resources and technologies that can be used to promote circular urban metabolism. A review of the literature establishes that there are eleven renewable technologies with different degrees of maturity that could reduce the import of energy resources, which would contribute to changing the metabolic linear model into a circular model. However, the applicability of the different possibilities is conditional upon the availability of resources, costs, policies and community acceptance.

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“…In Mar del Plata, Argentina, it was established that the use of forest residues (from pruning urban trees and garden maintenance) could supply 4·36% of the energy demand (Roberts et al, 2015). In Tijuana, Mexico, it was estimated that landfill gas can provide 40% of the required electricity for public lighting services (Aguilar-Virgen et al, 2014), whereas in Rio de Janeiro, Brazil, 25% of the city's energy could be supplied by burning urban solid waste (de Souza et al, 2014). In Wageningen, the Netherlands, it is estimated that 12% of the electrical energy demand can be covered by wind power (Agudelo-Vera et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Electricity production using renewable resources in urban centres

Barragán-Escandón

Terrados-Cepeda

Zalamea-León

et al. 2018

Proceedings of the Institution of Civil Engineers - Energy

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Previous research has identified 11 technologies that use resources that are available in or come from cities. It has been established that using these technologies, the flows from energy carriers required by cities could be reduced. These carriers can be electricity or fuels. Of the identified technologies, eight can produce electricity: biomass, biodigestor biogas, landfill biogas, waste incineration, tidal, small wind, small hydroelectric and photovoltaic technologies. The use of these technologies depends on the existence of resources and technical, economic and social or environmental factors. This research proposes the use of multiple-criteria techniques to select the most appropriate options for promoting renewable energy in cities. This approach was applied to the medium-sized city of Cuenca in Ecuador. Ecuador is a developing country, is an oil producer and has important water resources. The authors concluded that studies of the potential for implementing hydroelectric and solar photovoltaic energy and energy from landfill gas should be extended. The results coincide with the existing resources, implemented projects and the expectations of local professionals.

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Technical potential of electricity production from municipal solid waste disposed in the biggest cities in Brazil: Landfill gas, biogas and thermal treatment

Cited by 39 publications

References 31 publications

Avaliação dos parâmetros cinéticos da geração de metano em uma célula experimental de resíduos sólidos

Avaliação dos parâmetros cinéticos da geração de metano em uma célula experimental de resíduos sólidos

The Role of Renewable Energy in the Promotion of Circular Urban Metabolism

Electricity production using renewable resources in urban centres

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