Study and Practice of Wind and Solar Power Projects in Jilin Oilfield

doi:10.3969/j.issn.1002-302X.2024.01.015

Abstract

Abstract: Under the“ dual carbon” goal, Jilin Oilfield accelerated the green low-carbon transition, promoted integrated development of oil and gas with new energy and created a new situation of three businesses-crude oil, natural gas and new energy. Focusing on the energy-consuming characteristic and oil and gas production and the actual demand for clean replacement, the oilfield took full advantage of the regional wind and solar resources, the power grid of the oilfield’s own, electric power consumption and absorption, and land resources. Guided by the demand, consumption and absorption, the oilfield constructed the 15×10⁴kW self-consumed and absorbed wind and solar power generation project. With the construction type and installed capacity of the wind and solar power project planned reasonably, the oilfield constructed more than 400 distributed and concentrated photovoltaic spots with a total electricity volume of 7.1×10⁴kW and 18 concentrated and distributed wind-driven generators with a total electricity volume of 7.8×10⁴kW. The annual power generation capacity reached 3.6×10⁸kW·h while the proportion for replacing grid power with green electricity accounted for 29.3 percent, thus effectively improving the energy-consuming structure and dramatically reducing the energy-consuming cost. To develop the wind and solar power generation business at oilfields, it is proposed to enlarge the construction scale of the self-consumed and absorbed green power project. In the northern region of the country, it’s better avoid construction in winter. As for distributed wind and solar power generation projects, it is necessary to strengthen management of online measurement. The self-consumed and absorbed power projects should be independently evaluated to facilitate development of carbon asset.

摘要： “双碳”目标下，吉林油田加快绿色低碳转型，推进油气与新能源融合发展，着力打造原油、天然气、新能源“三分天下”新格局。针对油气生产用能特点和清洁替代实际需求，充分利用域内风光资源、油田电网、电力消纳及土地资源等优势，以需求和消纳为导向，组织建设15×10⁴kW自消纳风光发电项目。合理规划风光发电建设类型和装机规模，建成分散和集中式光伏400余处共7.1×10⁴kW，集中和分散式风机18台共7.8×10⁴kW，年发电能力3.6×10⁸kW·h，绿电替代网电比例达29.3%，有效改善了用能结构，大幅降低用能成本。油气田企业发展风光发电业务，建议提高自消纳绿电项目建设规模，北方地区尽量避免冬季施工，分散式风光发电需加大在线计量管理，自消纳项目单独论证便于开发碳资产。

关键词: 风光发电, 自消纳, 融合发展, 清洁替代, 吉林油田

CLC Number:

Jia Xuefeng, Xue Guofeng. Study and Practice of Wind and Solar Power Projects in Jilin Oilfield[J]. Petroleum Science and Technology Forum, 2024, 43(1): 115-121.

贾雪峰, 薛国锋. 吉林油田风光发电项目探索与实践[J]. 石油科技论坛, 2024, 43(1): 115-121.

References

[1] 国家能源局. 加快油气勘探开发与新能源融合发展行动方案(2023-2025 年)[EB/OL]. (2023-03-23)[2023-06-26]. https://www.gov.cn/zhengce/zhengceku/2023-03/23/content_5747955.htm.
National Energy Administration. Action plan for accelerating the integrated development of oil and gas exploration with new energy (2023-2025) [EB/OL]. (2023-03-23) [2023-06-26]. https://www.gov.cn/zhengce/zhengceku/2023-03/23/content_ 5747955.htm.
[2] 王陆新, 杨丽丽, 王永臻. 新时代我国油气行业绿色低碳发展战略与路径探析[J]. 石油科技论坛, 2023, 42(2): 67-74.
Wang Luxin, Yang Lili, Wang Yongzhen. Analysis of China’s oil and gas industrial green and low-carbon development strategies and paths in new era[J]. Petroleum Science and Technology Forum, 2023, 42(2): 67-74.
[3] 余国, 陆如泉, 刘佳, 等. 新形势下的能源转型与能源合作：“2022 年国际能源发展高峰论坛”综述[J]. 国际石油经济, 2023, 31(2): 23-29.
Yu Guo, Lu Ruquan, Liu Jia, et al. Energy transition and energy cooperation under the new situation: Review of international energy executive forum 2022[J]. International Petroleum Economics, 2023, 31(2): 23-29.
[4] 岳小文, 孔令峰, 刘秀如, 等. 石油公司油气与新能源融合发展路径与实践探索[J]. 石油科技论坛, 2023, 42(2): 75-81.
Yue Xiaowen, Kong Lingfeng, Liu Xiuru, et al. Path of oil and gas development in integration with new energy for oil companies and their practice[J]. Petroleum Science and Technology Forum, 2023, 42(2): 75-81.
[5] 中国气象局. 2022 年中国风能太阳能资源年景公报[EB/OL]. (2023-04-21) [2023-06-26]. https://www. cma. gov. cn/zfxxgk/gknr/qxbg/202304/t20230421_5454513.html.
China Meteorological Administration. China wind and solar energy resources bulletin 2022[EB/OL]. (2023-04-21) [2023-06-26]. https://www.cma.gov.cn/zfxxgk/gknr/qxbg/202304/t20230421_5454513.html.
[6] 中国电力企业联合会. 光伏发电站晶体硅光伏组件选型技术规范:T/CEC 538—2021[S]. 北京: 中国电力出版社, 2021.
China Electricity Council. Technical specifications for selection of crystalline silicon photovoltaic modules for photovoltaic power stations: T/CEC 538—2021[S]. Beijing: China Electric Power Press, 2021.
[7] 陈伟, 任静, 武新芳, 等. 雾霾条件下光伏发电量预测的迭代优化与经济分析[J]. 中国电力, 2021, 54(10): 223-230.
Chen Wei, Ren Jing, Wu Xinfang, et al. Iterative optimization and economic analysis of photovoltaic power generation forecasting under haze conditions[J]. Electric Power, 2021, 54(10): 223-230.
[8] 中华人民共和国国家质量监督检验检疫总局, 中国国家标准化管理委员会. 风力发电机组风轮叶片：GB/T 25383—2010[S]. 北京: 中国标准出版社, 2010.
General Administration of Quality Supervision, Inspection and Quarantine of the People’s Republic of China, Standardization Administration. Wind turbine generator system—Rotor blades[S]. Beijing: Standards Press of China, 2010.
[9] 中华人民共和国住房和城乡建设部, 国家质量监督检验检疫总局. 光伏发电站设计规范：GB 50797—2012[S].北京: 中国计划出版社, 2012.
Ministry of Housing and Urban-Rural Development of the People’s Republic of China, General Administration of Quality Supervision, Inspection and Quarantine of the People’s Republic of China. Code for design of photovoltaic power station: GB 50797—2012[S]. Beijing: China Planning Press, 2012.