Current Status of Brazil’s New Energy and Green Low-carbon Practices in Deep-water Oil Fields

全文: PDF(3065 KB)
输出: BibTeX | EndNote (RIS)

	服务

	把本文推荐给朋友
	加入引用管理器
	E-mail Alert
	RSS
	作者相关文章

Abstract：Brazil possesses abundant new energy resources such as solar energy, wind energy, and biomass energy, and is at the forefront of the world in the development and utilization of new energy, becoming a pioneer in energy transition and low-carbon development. Renewable energy accounts for nearly half of Brazil’s primary energy consumption, with the share in the power sector exceeding 75%. Brazil has achieved its carbon peak and is still actively promoting carbon and emission further reduction and the development of new energy. Brazil’s onshore wind power technology and market are mature, and the potential for offshore wind power is enormous, but it has not yet been commercially developed. Solar photovoltaic growth is rapid, and distributed photovoltaics has become mainstream. Biomass energy production and technology are world-leading and undergoing upgrades. The prospects for the hydrogen energy industry are broad, and it will develop in coordination with offshore wind power. Brazil is actively promoting new energy policies and the concept of green and low-carbon development in various sectors, with green development of offshore oil fields emerging as a new benchmark for low-carbon development in the deep-water oil and gas industry. Deep-water oil fields are concentrated in the southeastern seas of Brazil, featuring vast reserves and production scales. They are primarily developed using the FPSO+subsea production system method. This development approach incorporates the separation and reinjection of associated CO2 through CCUS-EOR, fully utilizing the matured WAG technique during the process. Additionally, there is active ongoing research and development in new technologies and equipment, such as AMS, CMS, and HISEP. Carbon emissions during FPSO operations are primarily reduced by replacing diesel with natural gas and enhancing fuel gas efficiency. At the same time, Brazil is also actively developing new energy sources such as offshore wind power, while simultaneously digitalizing and enhancing the intelligence of the oil fields. These efforts aim to achieve the electrification and decarbonization of deep-water oil fields.

出版日期: 2025-01-13

引用本文:

. [J]. 中国油气, 2024, 31(4): 10-19.
Qiu Zhaojun, Zhang Yuelei, Zhao Jian, Feng Jian, Yang Yihan. Current Status of Brazil’s New Energy and Green Low-carbon Practices in Deep-water Oil Fields. China Oil & Gas, 2024, 31(4): 10-19.

链接本文:

http://www.coag.com.cn/CN/ 或 http://www.coag.com.cn/CN/Y2024/V31/I4/10

[1]	ANP. The oil and gas sector in Brasil. https://www.gov.br/anp/pt-br. 2023.
[2]	ANP. Consultas Públicas - CPL. https://cdp.anp.gov.br/ords/r/cdp_apex/ consulta-dados-publicos-cdp/principal? clear=34&session=9285468267143&cs =3UlYfpZ_MvxjjCBHeB-eBe8hWNV qnRx8rHi9wLc_0CN9PiSYDoWFnyVa 9KnaCPRLdyPhV_uFF2ZlllbPiJiA9dg. 2024.
[3]	Azevedo, S S P d, Pereira Junior, A. O., Silva, N. F. d., et al. Assessment of offshore wind power potential along the Brazilian coast. Energies, 13(10), 2557. https://doi.org/10.3390/en13102557. 2020.
[4]	BP. Our World in Data based on BP Statistical Review of World Energy, BP Statistical Review of World Energy 2020[R]. 2022.
[5]	CCS Brasil. 1st Annual CCS Report in Brazil. Carbon Credit Markets. https:// www.carboncreditmarkets.com/single-post/launched-the-1st-annual-ccs-report-in-brazil. 2023.
[6]	Empresa de Pesquisa Energética (EPE). Brazilian Energy Balance 2023. Ministério de Minas e Energia, Governo Federal Brasil. 2023.
[7]	Empresa de Pesquisa Energética (EPE). Summary Rep o r t 2 0 2 3 : Reference Year 2022. Ministério de Minas e Energia, Brasil. 2023.
[8]	Global CCS Institute. Global status of CCS 2021, Melbourne: Global CCS Institute. https://ourworldindata.org/co2- and-greenhouse-gas-emissions. 2022.
[9]	IEA. Energy system of Brazil. https:// www.iea.org/countries/brazil. 2022.
[10]	IEA. Executive summary, electricity demand rose moderately in 2023 but is set to grow faster through 2026. https:// www.iea.org/reports/electricity-2024/ executive-summary. 2024.
[11]	José R M, Viviane R, Sabine F, et al. BECCS potential in Brazil: Achieving negative emissions in ethanol and electricity production based on sugar cane bagasse and other residues. Applied Energy, 2016, 179, 55-63.
[12]	Mario Orestes Aguirre González, Andressa Medeiros Santiso, David Cassimiro de Melo, et al. Regulation for offshore wind power development in Brazil. Energy Policy, 2020, 145, 111756.
[13]	Ministério de Minas e Energia. Ten-Year Energy Expansion Plan - PDE. Secretaria de Planejamento e Desenvolvimento Energético. https://www.epe.gov.br/en/press-room/news/ mme-launches-english-version-of-the-ten-year-energy-expansion-plan-pde-2031. 2021.
[14]	Ministério de Minas e Energia. Brazilian Energy Review 2023 Edition. 2023.
[15]	Ministério de Minas e Energia. Three-Year Work Plan (2023-2025) of the National Hydrogen Program (PNH2). https://www.h2verdebrasil.com.br/en/noticia/national-hydrogen-program-is-moving-towards-transforming-brazil-into-a-global-player-in-renewable-energy-production/. 2023.
[16]	Pasqualino R, Cabello A, Pereira M C, et al. Energy Transition in Brazil: Innovation, Opportunities, and Risks. EEIST. 2024.
[17]	Petrobras. Climate Change Supplement. http://www.petrobras.com.br/climate-change-supplement. 2023.
[18]	Petrobras. Sustainability Report 2022. https://sustentabilidade.petrobras.com.br/. 2023.
[19]	Petrobras. Strategic Action Plan 2024-2028. http://news.cnpc.com.cn/system/2024/ 03/12/030126900.shtml. 2024.
[20]	Petrobras. Petrobras Santos Basin Pre-Salt Oil Field CCUS. CSLF: 2023 Technical Group Mid-Year Meeting. 2023.
[21]	SEEG. Total Emissions. https://plataforma.sceg.eco.br/total_emission. 2023.
[22]	Zhao J, Zhao J, Ren K, et al. Distribution and main controlling factors of CO2 in Santos Basin, Brazil. Earth Science, 2021, 46(9), 3217-3229.
[23]	Zhao J, Feng J, Yang Y, et al. Status and Trends of International Cooperation in the Field of New Energy in Brazil, International Petroleum Economics, 2023, 31(5), 47-55, 62.
[24]	Zhang Z. Sustainability Study of Biomass Energy Development in BrazilLatin American Studies, 2018, 40(3), 130-153, 158.
[25]	Wang L. Policies and Practices of Clean Energy Development in BrazilGlobal Science, Technology and Economic Outlook, 2017, 32(10), 13-17.
[26]	José Roberto Moreira, Viviane Romeiro, Sabine Fuss, et al. BECCS potential in Brazil: Achieving negative emissions in ethanol and electricity production based on sugar cane bagasse and other residues. Applied Energy, 2016, 179, 55-63.
[27]	Sara Restrepo-Valencia, Arnaldo Walter. BECCS opportunities in Brazil: Comparison of pre and post-combustion capture in a typical sugarcane mill. International Journal of Greenhouse Gas Control, 2023, 124, 103859.
[28]	Brazil Government. Future Fuel Law. People’s Daily Online. https://paper.people.com. cn/rmrb/html/2023-11/20/nw.D110000renmrb_20231120_3-17.htm. 2023.
[29]	ApexBrasil. Brazil is a Protagonist in the Production of Sustainable Aviation Fuel, Says MME. https://portal.datagro.com/en/2/sugar-ethanol/836391/brazil-is-a-protagonist-in-the-production-of-sustainable-aviation-fuel-says-mme. 2024.
[30]	ABEEólica. Brazilian Wind Energy Sector: Opportunities and Challenges for Offshore Wind Energy \| Pathway for Value Chain. ABEEólica – Brazilian Association of Wind Energy and New Technologies. 2023.
[31]	ABSOLAR. Solar Photovoltaic Energy in Brazil: ABSOLAR’s Infographic. Brazilian Solar Photovoltaic Energy Association. Retrieved from. 2024.