Research and Practice of Key Technologies for Development of Geothermal Benefits from Middle-to-deep Layers

doi:10.3969/j.issn.1002-302X.2024.04.010

Abstract

Abstract: Study of geothermal energy from middle-to-deep layers aims at development of a certain renewable clean energy to reduce dependence of fossil fuels and carbon discharge. It is an important measure for green and low-carbon transition of the energy industry. Focusing on the bottlenecks in geothermal development of the middle-to-deep layers in the Jizhong zone, such as geological identification, development plans and surface engineering, this article makes study of the key underground and surface technologies, which leads to the following results. (1) The thermal reservoirs of the middle-to-deep layers in the Jizhong zone are mainly layered sandstone and block buried hill. The bottleneck for sandstone geothermal development is the difficulty to identify the sandstone layer with a relatively poor re-injection ability. The bottleneck for buried hill geothermal development is the strong heterogeneity of the thermal reservoir requiring high drilling success rate and high designing precision of the development plan. (2) Prediction of the favorable thermal reservoir and sweet spot identification technology are able to effectively identify the sweet spot of a thermal reservoir. Combination of optimized development parameters with dynamic analysis while drilling+production-injection experiment+ five sensitivity experiment brings about high-efficiency sandstone geothermal development. (3) Combined application of geophysical data, drilling log and testing data can precisely identify the position of the buried hill thermal reservoir. The high-efficiency gravity flow buried hill development technology leads to high production based on a few wells and full pressure-free re-injection in the same layer. (4) The technology of using geothermal high temperature differential pump for warming, anti-sewage and anti-scaling improves the geothermal heat-exchanging rate and reduces the operational and maintenance cost. (5) Using geothermal energy for warming, refrigeration and steam generation according to applications based on the different scenarios further expands the range of geothermal utilization and improves the utilization rate of geothermal resources, thus bringing the resource energy into full play.

Key words: geothermal energy of middle-to-deep layers; layered sandstone; buried hill geothermal energy; estimation of resource; high temperature differential heat pump

摘要： 研究中深层地热旨在开发一种可再生的清洁能源，以减少对化石燃料的依赖，降低碳排放，是能源行业绿色低碳转型的重要抓手。针对冀中地区中深层地热效益开发中存在的地质识别、开发方案和地面工程等难题，开展了地下和地面关键技术研究，为中深层地热效益开发提供借鉴。研究取得以下认识：（1）冀中地区中深层热储主要有层状砂岩、块状潜山等，砂岩型地热开发难点是砂层识别难，回灌能力相对较差；潜山型地热开发难点是热储非均质性强，钻井成功率与开发方案设计精准率要求高。（2）有利热储预测与甜点识别技术能够有效识别热储甜点，随钻动态分析+采灌试验+五敏试验优化开发参数相结合，实现砂岩型地热高效开发。（3）地球物理、钻录测试资料等联合应用，可准确定位潜山热储位置，重力流潜山高效开发技术实现少井高产、同层无压全回灌。（4）通过地热大温差热泵供暖和防污防垢技术，提高了地热换热效率，降低了运维成本。（5）地热供暖、地热制冷和地热制蒸汽等根据不同场景组合应用，进一步拓展地热利用形式，提高地热资源利用率，使资源效能得以充分发挥。

关键词: 中深层地热；层状砂岩；潜山地热；资源评价；大温差热泵

CLC Number:

P314
TK521

Luo Ning,Yao Huan,Liu Liangde, Liang Jun. Research and Practice of Key Technologies for Development of Geothermal Benefits from Middle-to-deep Layers[J]. Petroleum Science and Technology Forum, 2024, 43(4): 66-74.

罗宁,姚欢,刘亮德,梁骏. 中深层地热效益开发关键技术研究与实践[J]. 石油科技论坛, 2024, 43(4): 66-74.

References

[1] 董月霞, 黄红祥, 任路, 等. 渤海湾盆地北部新近系馆陶组地热田特征及开发实践: 以河北省唐山市曹妃甸地热供暖项目为例[J]. 石油勘探与开发, 2021, 48(3): 666-675.
Dong Yuexia, Huang Hongxiang, Renlu, et al. Geology and development of geothermal field in Neogene Guantao Formation in northern Bohai Bay Basin: A case of the Caofeidian geothermal heating project in Tangshan, China[J]. Petroleum Exploration and Development, 2021, 6(1): 666-675.
[2] 王学鹏, 刘欢, 蒋书杰, 等. 沉积盆地砂岩热储回灌试验研究: 以山东禹城市为例[J]. 地质论评, 2020, 66(2): 485-492.
Wang Xuepeng, Liu Huan, Jiang Shujie, et al. Reinjection experimental research on sedimentary basin sandstone reservior--A case study of Yucheng City, Shandong[J]. Geological Review, 2020,66(2): 485-492.
[3] 曹倩, 方朝合, 李云, 等. 国内外地热回灌发展现状及启示[J]. 石油钻采工艺, 2021, 43(2): 203-211.
Cao Qian, Fang Chaohe, Li Yun, et al. Development status of geothermal reinjection at home and abroad and its enlightenment[J].Oil Drilling & Production Technology, 2021, 43(2): 203-209.
[4] 仝红伟，陈正国，孔登锋. 基于林甸地热田砂岩孔隙热储回灌的初步分析[J]. 黑龙江水利科技, 2011, 39(5): 10-12.
Tong Hongwei, Chen Zhengguo, Kong Dengfeng. Primary analysis of sandstone pore geothermal reserve reinjection based on Lindian geothermal field[J]. Heilongjiang Science and Technology of Water Conservancy, 2011, 39(5): 10-12.
[5] 张光辉, 李卓, 严明疆, 等. 冀中平原深部地下热水资源可更新特征与依据: 以辛集馆陶组地下热水系统为例[J]. 地球学报, 2016, 37(5):637-644.
Zhang Guanghui, Li Zhuo, Yan Mingjiang, et al. Renewal characteristics and basis of the geothermal water resources in middle Hebei plain: A case study of the Guantao Formation underground geothermal water system[J]. Acta Geoscientia Sinica, 2016, 37(5):637-644.
[6] 崔刚, 吕传炳, 杨莹莹, 等. 潜山油藏开发后期驱油、储气及地热利用协同联动探索[J]. 石油科技论坛, 2023, 42(5): 64-72.
Cui Gang, Lv Chuanbing, Yang Yingying, et al. Research on synergy of oil displacement, gas storage and geothermal utilization in later-on development stage of buried-hill oil reservoir[J]. Petroleum Science and Technology Forum, 2023, 42(5): 64-72.
[7] 陈宇, 刘亮德, 陈情来. 油区中低温地热发电技术经济分析[J]. 石油工程建设, 2020, 46(4): 11-14, 20.
Chen Yu, Liu Liangde, Chen Qinglai. Technical economy analysis of power generation from mid-low temperature geothermal resources in oilfields[J]. Petroleum Engineering Construction, 2020, 46 (4): 11-14, 20.
[8] 樊梦芳, 刘亮德, 李云. 油田采出水热泵应用技术研究[J]. 天然气与石油, 2021, 39(3): 108-112.
Fan Mengfang, Liu Liangde, Li Yun. Research on heat pump technology application on oil field produced water[J]. Natural Gas and Petroleum, 2021, 39 (3): 108-112.
[9] 雷宏武, 白冰, 崔银祥, 等. 高温地热生产井碳酸钙结垢定量评价: 水文地球化学—— 以西藏羊八井为例[J]. 地球科学, 2023, 48(3):935-945.
Lei Hongwu, Bai Bing, Cui Yinxiang, et al. Quantitative assessment of calcite scaling of a high temperature geothermal production well: Hydrogeochemistry-Application to the Yangbajing Geothermal Fields,Tibet[J]. Earth Science, 2023, 48(3): 935-945.
[10] 杨全毅, 刘亮德, 刘向薇, 等. 中低温地热(采出水)管道腐蚀及结垢研究[J]. 化学与粘合, 2020, 42(6): 469-473.
Yang Quanyi, Liu Liangde, Liu Xiangwei, et al. The research on the corrosion and scaling of medium and low temperature geothermal (produced water) pipeline[J]. Chemistry and Adhesion, 2020, 42 (6):469-473.
[11] 汪集暘, 庞忠和, 程远志, 等. 全球地热能的开发利用现状与展望[J].科技导报, 2023, 41(12): 5-11.
Wang Jiyong, Pang Zhonghe, Cheng Yuanzhi, et al. Current state, utilization and prospective of global geothermal energy[J]. Science & Technology Review, 2023, 41(12): 5-11.
[12] 施亦做, 沙秋, 张训华, 等. 石油企业有效开发利用地热资源的问题与建议[J]. 石油科技论坛, 2024, 43(1): 31-39.
Shi Yizuo, Sha Qiu, Zhang Xunhua, et al. Problems concerning effective development and utilization of geothermal resources by petroleum enterprises and related suggestions[J]. Petroleum Science and Technology Forum, 2024, 43(1): 31-39.
[13] 韩送军. 基于MVR 蒸发工艺的废水处理方案研究[J]. 山西化工,2024, 44(2): 221-223.
Han Songjun. Research on wastewater treatment scheme based on MVR evaporation process[J]. Shanxi Chemical Industry, 2024, 44(2):221-223.
[14] 陈光明, 丁亚琪. 开式吸收式热泵系统的研究及应用进展[J]. 制冷学报, 2023, 44(2): 1-17.
Chen Guangming, Ding Yaqi. State-of-the-art open absorption heat pump systems and their applications[J]. Journal of Refrigeration, 2023,44 (2): 1-17.
[15] 宜兴市人民政府市发展和改革委员会. 关于调整我市蒸汽价格的通知[EB/OL]. (2024-07-25)[2024-07-27]. https://www.yixing.gov.cn/doc/2024/07/25/1245409.shtml.
Municipal Development and Reform Committee of The People’s Government of Yixing City. Circular of the adjustment of the city’s steam price[EB/OL]. (2024-07-25) [2024-07-27]. https://www. yixing.gov.cn/doc/2024/07/25/1245409.shtml.