花岗岩地区地热开发模式:中国云南省上云地区案例研究

IF 0.7 4区 地球科学 Q4 GEOCHEMISTRY & GEOPHYSICS
Sun Yuhang,  Zhang Jinchuan,  Xu Longfei,  Li Jie,  Li Qianchao,  Chen Lei,  Zhao Xingxu,  Li Wei
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引用次数: 0

摘要

摘要 上云地区位于云南西部,地处滇藏热带,属中高温地热区。该地区花岗岩分布广泛,活动断层发育程度较高。因此,地质条件有利于地热资源的形成。根据以往的研究成果和地热钻探数据,本研究对云南上云地热系统开发的主要地质因素进行了分析。调查揭示了花岗岩地区地热活动的几个值得注意的特征,包括靠近热源、热梯度大、裂缝内有积水、深层和浅层地热现象并存以及沿广泛而深邃的断层线出现温泉。尚云地区的地热流测定值为 142.74 mW/m2,其主要热源主要受地幔高热流和位于东部地区的临沧花岗岩放射性发热的影响,平均放射性发热率为 7.6 μW/m3。储层空间主要由风化壳和断裂型储热层组成。此外,厚度在 500 至 1000 米之间、导热系数为 2.39 W/(m K)的上侏罗统泥岩也是一个有效的区域盖层。硅酸盐的溶解对地热水的成分有很大影响,主要类型是 HCO3-Na。大气降水的渗透和补给过程在很大程度上为地热系统提供了充足的水资源。根据对该地区相关电力数据的分析,可以推断供水的主要来源是东部山区。此外,还可以看出活动断层是地热水深层循环的通道。本研究全面考察了多个地热地质特征,包括热源、热储、热通道和地热水,以建立山云地区特有的地热模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Geothermal Development Model in Granite Area: a Case Study of Shangyun Area, Yunnan Province, China

Geothermal Development Model in Granite Area: a Case Study of Shangyun Area, Yunnan Province, China

Geothermal Development Model in Granite Area: a Case Study of Shangyun Area, Yunnan Province, China

The Shangyun area is classified as a medium-high temperature geothermal region situated in western Yunnan, inside the tropical zone of Yunnan and Tibet. Granites exhibit a wide distribution, while active faults demonstrate a rather advanced state of development. Consequently, the geological conditions are favourable for the creation of geothermal resources. Drawing upon previous research findings and geothermal drilling data, this study undertakes an analysis of the principal geological factors contributing to the development of the Shangyun geothermal system in Yunnan. The investigation reveals several noteworthy characteristics of geothermal activity within the granite region, including proximity to heat sources, substantial thermal gradients, water accumulation within fractures, the coexistence of deep and shallow geothermal phenomena, and the occurrence of hot springs along extensive and profound fault lines. The determined ground heat flow value in the Shangyun area is 142.74 mW/m2, with its primary heat source being predominantly influenced by high mantle heat flow and the radioactive heat generation of the Lincang granite located in the eastern region with the mean rate of radioactive heat generation of 7.6 μW/m3. The reservoir space mostly consists of weathered crust and fracture type heat storage. Additionally, the upper Jurassic mudstone, which has a thickness ranging from 500 to 1000 m and a thermal conductivity of 2.39 W/(m K), serves as an effective regional cap layer. The dissolution of silicate has a significant impact on the composition of geothermal water, with the primary type being HCO3–Na. The process of atmospheric precipitation infiltration and recharge contributes significantly to the availability of ample water resources for geothermal systems. Based on an analysis of the electrical data pertaining to the region, it can be inferred that the primary source of the water supply originates from the eastern mountain. Furthermore, it is seen that the active fault serves as the conduit for the deep circulation of geothermal water. This study presents a comprehensive examination of several geothermal geological features, including heat source, heat storage, hot channel, and geothermal water, in order to build a geothermal model specific to the Shangyun region.

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来源期刊
Geochemistry International
Geochemistry International 地学-地球化学与地球物理
CiteScore
1.60
自引率
12.50%
发文量
89
审稿时长
1 months
期刊介绍: Geochemistry International is a peer reviewed journal that publishes articles on cosmochemistry; geochemistry of magmatic, metamorphic, hydrothermal, and sedimentary processes; isotope geochemistry; organic geochemistry; applied geochemistry; and chemistry of the environment. Geochemistry International provides readers with a unique opportunity to refine their understanding of the geology of the vast territory of the Eurasian continent. The journal welcomes manuscripts from all countries in the English or Russian language.
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