地热能源开发的经验——以冰岛为例

IF 0.9 Q4 ENERGY & FUELS
V. A. Butuzov
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引用次数: 0

摘要

冰岛地热资源基地的数据:25个高温(底部温度超过200°C)和250个低温(150°C)矿床。指出了冰岛和俄罗斯堪察加边疆区热水取水口的地质条件和主要特征的相似性。分析了冰岛地热能源的法律支持,以及国家机构Orkustofnun在许可、地热矿床研究和建立世界上最大的地热文献图书馆方面的活动。介绍了Krafla火山脚下超临界流体参数(SCP)下IDDP状态钻井测试方案的实施过程。给出了8座地热发电厂(GeoPP)的主要特点,总容量为753兆瓦,2021年发电量为6208吉瓦时,并描述了热方案和循环。据指出,冰岛最强大的地质震源是hellisheei - yi (303 МW),其地热冷却剂供应给距其19.5公里的雷克雅未克。该站配备了一个已安装的系统,用于将二氧化碳利用到碳酸盐岩地下岩石中。采用二元循环的动力装置在两个geopp上建造:Kalina循环的Husavik (2 MW)和使用有机冷却剂的Svartsergi (7 × 1.2 MW)。值得注意的是,冰岛拥有世界上最大的地热发电量(2373兆瓦,9340吉瓦时(2021年)),其中供暖占主导地位(1650兆瓦;6840 GW h(2021))。雷克雅未克是该国乃至世界上最强大的供热系统,其容量为1150兆瓦,长度为2230公里。数据提出了在养鱼场,游泳池,温室和二氧化碳利用厂地热水的非能源使用。结论是,冰岛的经验对俄罗斯地热能的开发具有特别重要的意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Experience of the Development of Geothermal Energy on the Example of Iceland

Experience of the Development of Geothermal Energy on the Example of Iceland

Data on the geothermal resource base of Iceland are presented: 25 high-temperature (temperature over 200°C at the bottom) and 250 low-temperature (150°C) deposits. The similarity of the geological conditions and the main characteristics of thermal water intakes in Iceland and Kamchatka krai of Russia is noted. The analysis of the legal support of geothermal energy in Iceland, as well as the activities of the state institution Orkustofnun for licensing, research of geothermal deposits, and the creation of the world’s largest library of geothermal literature, was carried out. The process of implementation of the IDDP state program for drilling and testing wells at the foot of the Krafla volcano at supercritical parameters (SCP) of fluids is described. The main characteristics of eight geothermal power plants (GeoPP) with a total capacity of 753 MW with electricity generation in 2021 of 6208 GW h are given and thermal schemes and cycles are described. It is indicated that the most powerful GeoPP in Iceland is Hellisheiði (303 МW), the geothermal coolant of which is supplied to Reykjavik, located at a distance of 19.5 km from it. This station is equipped with an installed system for the utilization of carbon dioxide into carbonate underground rocks. Power units with binary cycles were built at two GeoPPs: Husavik (2 MW) in the Kalina cycle and Svartsergi (7 × 1.2 MW) with organic coolant. It is noted that Iceland has the world’s largest geothermal heat generation (2373 MW, 9340 GW h (2021)), with heating predominating (1650 MW; 6840 GW h (2021)). The most powerful heat-supply system in the country and in the world, in Reykjavik, is described: its capacity is 1150 MW and the length is 2230 km. Data are presented on the nonenergy use of geothermal water in fish farms, swimming pools, greenhouses, and carbon dioxide utilization plants. It is concluded that the experience of Iceland is especially significant for the development of geothermal energy in Russia.

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CiteScore
1.30
自引率
20.00%
发文量
94
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