Estudo bibliométrico e bibliográfico sobre otimizações nos processos de recuperação de líquido de gás natural (LGN)

Autores

  • Ana Paula Meneguelo Universidade Federal do Espírito Santo
  • Daniel Ribeiro Universidade Federal do Espírito Santo
  • Rodrigo de Freitas Universidade Federal do Espírito Santo
  • Samuel Franco Universidade Federal do Espírito Santo

DOI:

https://doi.org/10.33448/rsd-v8i2.673

Palavras-chave:

Gás natural; Simulação; Hysys.

Resumo

O contexto de crescente necessidade mundial por energia somado à demanda por gás natural, que possui vantagem econômicas e ambientais em relação aos demais combustíveis fósseis, formam um estímulo a aplicar eficiência energética no processamento de gás natural. Este trabalho investigou a produção científica relacionada à otimização dos processos de recuperação de Líquidos de gás natural (LGN) com uso do simulador software comercial chamado Aspen Hysys. Vários autores incumbiram-se não só de análises energética, exergética, de sensibilidade, econômica e ambiental, mas também de estratégias de configuração e integração para reduzir o consumo de energia e maximizar a lucratividade. Percebeu-se que a maioria absoluta dos trabalhos selecionados foram de países do Oriente Médio, o que significa uma oportunidade para que brasileiros avancem estudos que contemplem a realidade das plantas nacionais.

Referências

ABDULRAHMAN, R. K.; ZANGANA, M. H. S.; SEBASTINE, I. M. Optimal NGL Recovery from Natural Gas Using Turboexpander: A Case Study and Simulation. Chemistry and Technology of Fuels and Oils, 2015.

ALNOUSS, A.; IBRAHIM, M.; AL-SOBHI, S. A. Potential energy savings and greenhouse gases (GHGs) emissions reduction strategy for natural gas liquid (NGL) recovery: Process simulation and economic evaluation. Journal of Cleaner Production, 2018.

ANSARINASAB, H.; MEHRPOOYA, M. Evaluation of novel process configurations for coproduction of LNG and NGL using advanced exergoeconomic analysis. Applied Thermal Engineering, 2017.

ASPEN TECHNOLOGY. A User Guide Manual for Aspen Physical Property V7.1. Aspen Tech HYSYS. Operation Guide. Cambridge: [s.n.]., 2009.

ASPENTECH. Aspen Process Economic Analyzer. Disponível em: http://www.aspentech.com/products/economic-evaluation/aspen-process-economic-analyzer/ . Acesso em: 15 out. 2018.

CAMPBELL R.E., WILKINSON J.D. Hydrocarbon gas processing. U.S. Patent 4,278,457. 1981.

CAMPBELL R.E., WILKINSON J.D., HUDSON H.M. Hydrocarbon gas processing. U.S. Patent 4,889,545. 1989.

CHEBBI, R. et al. Optimum ethane recovery in conventional turboexpander process. Chemical Engineering Research and Design, 2010.

CHEBBI, R.; KHERBECK, L. Optimizing ethane recovery in turboexpander processes. Journal of Industrial and Engineering Chemistry, 2015.

DIAZ, S.; BRIGNOLE, E. A.; BANDONI, A. Flexibility study on a dual mode natural gas plant in operation. Chemical Engineering Communications, 2002.

ELLIOT, D. et al. Benefits of Integrating NGL Extraction and LNG Liquefaction Technology. 2005, [S.l: s.n.], 2005.

EPE - EMPRESA DE PESQUISA ENERGÉTICA. Demanda de Energia 2050. Rio de Janeiro, Janeiro de 2016. Disponível em <http://epe.gov.br/sites-pt/publicacoes-dados-abertos/publicacoes/PublicacoesArquivos/publicacao-227/topico-202/DEA 13-15 Demanda de Energia 2050.pdf>. Acesso em: 15 out. 2018.

GAMS. General Algebraic Modeling System: Integrated Development Environment. Washington, DC: GAMS Development Corporation, 2007.

MESFIN, G.; SHUHAIMI, M. A chance constrained approach for a gas processing plant with uncertain feed conditions. Computers and Chemical Engineering, 2010.

GETU, M. et al. Techno-economic analysis of potential natural gas liquid (NGL) recovery processes under variations of feed compositions. Chemical Engineering Research and Design, 2013.

GETU, M. et al. Risk-based optimization for representative natural gas liquid (NGL) recovery processes by considering uncertainty from the plant inlet. Journal of Natural Gas Science and Engineering, 2015.

GHORBANI, B. et al. Simulation and optimization of refrigeration cycle in NGL recovery plants with exergy-pinch analysis. Journal of Natural Gas Science and Engineering, 2012.

GHORBANI, B. et al. Cascade refrigeration systems in integrated cryogenic natural gas process (natural gas liquids (NGL), liquefied natural gas (LNG) and nitrogen rejection unit (NRU)). Energy, 2016.

GHORBANI, B. et al. Implementing absorption refrigeration cycle in lieu of DMR and C3MR cycles in the integrated NGL, LNG and NRU unit. International Journal of Refrigeration, 2017.

GHORBANI, B. et al. A comprehensive approach toward utilizing mixed refrigerant and absorption refrigeration systems in an integrated cryogenic refrigeration process. Journal of Cleaner Production, 2018.

GHORBANI, B.; HAMEDI, M. H.; AMIDPOUR, M. Development and optimization of an integrated process configuration for natural gas liquefaction (LNG) and natural gas liquids (NGL) recovery with a nitrogen rejection unit (NRU). Journal of Natural Gas Science and Engineering, 2016.

JIBRIL, K.L., AL-HUMAIZI, A.L., IDRISS, A.A., IBRAHIM, A. A. Simulation study determines optimum turboexpander process for NGL recovery. Oil Gas J., v. 104, p. 58–62, 2006.

JIN, C.; LIM, Y. Economic evaluation of NGL recovery process schemes for lean feed compositions. Chemical Engineering Research and Design, 2018.

KHAN, M. S. et al. Energy saving opportunities in integrated NGL/LNG schemes exploiting: Thermal-coupling common-utilities and process knowledge. Chemical Engineering and Processing: Process Intensification, 2014.

LEE, R.J., JAME, Y.Z., JUH, J.Y., ELLIOT, D.G. Internal refrigeration for enhanced NGL recovery. U.S. Patent 2006/0,150,672 A1. 2006.

LYNCH, J.T., CAIRO, C., HUDSON, H.M., WILKINSON, J.D. Unique Design Challenges in the Aux Sable NGL Recovery Plant. 81st Annual Convention of the Gas Processors Association, Dallas, TX. 2002.

MEHRPOOYA, M.; VATANI, A.; ALI MOUSAVIAN, S. M. Introducing a novel integrated NGL recovery process configuration (with a self-refrigeration system (open-closed cycle)) with minimum energy requirement. Chemical Engineering and Processing: Process Intensification, 2010.

MEHRPOOYA, M.; VATANI, A.; MOOSAVIAN, S. M. A. Introducing a new parameter for evaluating the degree of integration in cryogenic liquid recovery processes. Chemical Engineering and Processing: Process Intensification, 2011.

MEHRPOOYA, M., TIRANDAZI, B., VATANI, A. A novel process configuration for co-production of NGL and LNG with low energy requirement. Chemical Engineering and Processing, 2013.

MEHRPOOYA, M., LAZEMZADE, R., SADAGHIANI, M. S., PARISHANI, H. Energy and advanced exergy analysis of an existing hydrocarbon recovery process. Energy Conversion and Management, 2016.

MEHRPOOYA, M., GHORBANI, B., SHIRMOHAMMADI, R. A novel energy efficient LNG/NGL recovery process using absorption and mixed refrigerant refrigeration cycles – Economic and exergy analyses. Applied Thermal Engineering, 2018.

MOKHATAB, S., POE, W. A., SPEIGHT, J. G. Handbook of Natural Gas Transmission and Processing. Gulf Professional Publ., Elsevier Inc., 2006.

RAHAMAN, A.A., YUSOf, A.A., WILKINSON, J.D., TYLER, L.D. Improving ethane extraction at the PETRONAS gas GPP-A facilities in Malaysia. 83rd Annual Convention of the Gas Processors Association, New Orleans, LA. 2004.

SAGERS, M. J. Natural Gas Liquids and the Soviet Gas Processing Industry, Soviet Economic Studies Branch, Moscow, 1986.

SAYED, A., ASHOURB, I., GADALLA, M. Integrated process development for an optimum gas processing plant. Chemical Engineering Research and Design, 2017.

SPEIGHT, J. G. The Chemistry and Technology of Petroleum, 4 Ed., CRC Press, Boca Raton, 2006.

SPEIGHT, J. G. Handbook of Industrial Hydrocarbon Processes. Gulf Professional Publ., Oxford, 2011.

STEWART, M., ARNOLD, K. Gas Sweetening and Processing Field Manual, Gulf Professional Publ., Waltham, 2011.

UWITONZE, H., LEE, I., HWANG, K. S. Alternatives of integrated processes for coproduction of LNG and NGLs recovery. Chemical Engineering and Processing, 2016.

WANG, W.B. Optimization of Expander Plants. PhD dissertation, University of Tulsa. 1985.

WANG M., KHALILPOUR R., ABBAS A. Thermodynamic and economic optimization of LNG mixed refrigerant processes. Energy Convers Manage, 2014.

YAO J., CHEN J.J., ELLIOT, D.G. Enhanced NGL recovery processes. United States. patent number: 5,992,175. 1999.

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Publicado

01/01/2019

Como Citar

MENEGUELO, A. P.; RIBEIRO, D.; FREITAS, R. de; FRANCO, S. Estudo bibliométrico e bibliográfico sobre otimizações nos processos de recuperação de líquido de gás natural (LGN). Research, Society and Development, [S. l.], v. 8, n. 2, p. e2382673, 2019. DOI: 10.33448/rsd-v8i2.673. Disponível em: https://rsdjournal.org/index.php/rsd/article/view/673. Acesso em: 17 jul. 2024.

Edição

v. 8 n. 2

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Artigos de Revisão

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