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广安市铜锣山背斜三叠纪岩溶热储结构特征及热水成因研究

袁建飞 刘慧中 邓国仕 李明辉

袁建飞,刘慧中,邓国仕,等. 广安市铜锣山背斜三叠纪岩溶热储结构特征及热水成因研究[J]. 中国岩溶,2022,41(4):623-635 doi: 10.11932/karst20220410
引用本文: 袁建飞,刘慧中,邓国仕,等. 广安市铜锣山背斜三叠纪岩溶热储结构特征及热水成因研究[J]. 中国岩溶,2022,41(4):623-635 doi: 10.11932/karst20220410
YUAN Jianfei, LIU Huizhong, DENG Guoshi, LI Minghui. Structural characteristics of Triassic carbonate geothermal reservoir and genesis of thermal water in the Tongluo mountain anticline of Guang’an City, China[J]. CARSOLOGICA SINICA, 2022, 41(4): 623-635. doi: 10.11932/karst20220410
Citation: YUAN Jianfei, LIU Huizhong, DENG Guoshi, LI Minghui. Structural characteristics of Triassic carbonate geothermal reservoir and genesis of thermal water in the Tongluo mountain anticline of Guang’an City, China[J]. CARSOLOGICA SINICA, 2022, 41(4): 623-635. doi: 10.11932/karst20220410

广安市铜锣山背斜三叠纪岩溶热储结构特征及热水成因研究

doi: 10.11932/karst20220410
基金项目: 中国地质调查局项目《西南诸河澜沧江流域水文地质与水资源调查》(DD20211381);《四川广安资源环境综合地质调查》(DD20190524);中国地质调查局成都地质调查中心科技基金《川西高原高温地热流体特征组分的水文地球化学研究》(KJ201867)
详细信息
    作者简介:

    袁建飞(1983-),男,博士,高级工程师,主要从事水文地质、地热地质和水文地球化学方面的研究工作。E-mail:jianfeiyuan@163.com

  • 中图分类号: P641.3

Structural characteristics of Triassic carbonate geothermal reservoir and genesis of thermal water in the Tongluo mountain anticline of Guang’an City, China

  • 摘要: 为探讨广安市铜锣山背斜三叠纪岩溶热储特征、地热水水化学与同位素组成、热储温度及地热水循环机理,采用地热钻探、水化学与同位素取样测试、热水溶质组分图解分析等手段和方法,开展了地热水成因的研究工作。结果表明:研究区三叠纪碳酸盐岩热储结构相对完整,热储盖层、热储层和热储下部隔水层形成独立的地热水文地质单元。岩溶地热水水化学类型主要为SO4-Ca·Mg和SO4-Ca型,富含F、Sr、Li、B和SiO2物质,其水源补给为大气降水,补给区位于铜锣山以北的大巴山一带,深部地热水补给高程大于1 100 m,补给区年均温度为9 ℃。热储温度为56~76 ℃,热水循环深度为2 013~3 030 m。地热水在循环过程中,主要发生碳酸盐岩和蒸发岩溶解、冷热水混合过程,且冷水混入比例大于80%。结合区域地热地质条件,构建了研究区地热水成因概念模型。

     

  • 图  1  研究区地质构造、简易水文地质剖面及采样点分布简图

    Figure  1.  Simplified map of geological structures, hydrogeological profiles, and sampling locations in the study area

    图  2  广安市铜锣山背斜刘家沟地热井和桂花村地热井柱状图

    Figure  2.  Histogram of geothermal wells of Liujiagou and Guihua village in the Tongluo mountain anticline of Guang’an City

    图  3  研究区水样Piper三线图

    Figure  3.  Piper diagram of water samples in the study area

    图  4  研究区水样(Ca2++ Mg2+)vs.( HCO3-+ SO42-)关系图

    Figure  4.  Plot of (Ca2++ Mg2+) vs.(HCO3-+ SO42-) for water samples in the study area

    图  5  研究区水样TDS vs.(Na+/(Na++Ca+))(a)和TDS vs. (Cl/(Cl+HCO3))(b)关系图(图例同前)

    Figure  5.  Plots of TDS vs. (Na+/(Na++Ca+)) (a), and TDS vs. (Cl/(Cl+HCO3)) (b) for water samples in the study area

    图  6  研究区水样δD和δ18O关系图

    Figure  6.  δD-δ18O diagram for water samples in the study area

    图  7  研究区地热水Na/1000-K/100-Mg0.5三角图

    Figure  7.  Ternary diagram of Na/1000-K/100-Mg0.5 for geothermal water in the study area

    图  8  广安铜锣山背斜地热水中冷水混入比例与温度的关系图

    Figure  8.  Relationship of water temperatures and mixing ratios of cold groundwater for geothermal groundwater in the Tongluo mountain anticline in Guang’an City

    图  9  研究区地热水成因概念模型图

    Figure  9.  Conceptual diagram of the genetic model for geotherm groundwater in the study area

    表  1  铜锣山背斜水样的物理—化学和同位素组分分析结果

    Table  1.   Physical-chemical and isotopic compositions of water samples in the Tongluo mountain anticline

    编号类型水温pHTDSHCO3ClSO42−NO3K+Na+Ca2+Mg2+FSrSiO2LiBδDδ18O补给
    高程
    补给区
    温度
    GW01地热井427.203242208.0018.302091.002.6812.8028.60678.00177.003.0012.8026.320.270.72−64.53−9.5812519
    GW02地热井297.163064223.0012.002004.009.6518.20609.00157.002.9513.4024.850.020.13−62.94−9.61119810
    GW03地热井427.063230208.0020.902067.0012.8033.80702.00156.002.4012.2026.470.240.63−64.38−9.5212469
    GW04地热井267.241002335.002.80401.002.284.32186.0048.200.964.7015.230.030.02−50.32−8.1477714
    HW01a温泉307.331800265.00264.00858.0094.60100.00293.0070.6412.050.86−50.1−8.1877014
    HW02b温泉457.121680183.0034.001643.000.5630.1228.75578.00120.3212.4612.11−59.5−8.84108311
    GW05浅孔267.331733198.001.381044.003.592.53388.0072.701.848.4416.390.060.19−56.05−8.5396812
    KW01岩溶泉187.76317349.507.4938.3037.634.695.67102.8128.720.260.129.690.000.04−44.76−7.2459216
    KW02岩溶泉186.74232333.401.0844.401.131.032.2489.1028.600.170.3711.040.02−44.15−7.2057216
    KW03暗河167.13455298.002.5022.5012.341.641.47100.007.680.130.447.540.000.00−43.29−7.3354316
    KW04暗河177.29450281.002.5028.2011.591.612.7098.708.770.101.807.850.000.01−44.38−7.5257916
    R01河水186.24140186.102.1633.501.372.472.8449.1014.500.110.1410.010.02−41.09−7.33
    R02河水186.74121109.806.9238.307.943.318.9440.506.420.070.4312.410.03−40.74−6.93
    注:水温和补给区温度单位为℃;pH无量纲;δD和δ18O单位为‰;补给高程单位为m;化学组分单位为mg·L−1;“—”为未检出或未分析;a引自[25],b引自[26]等文献数据。
    下载: 导出CSV

    表  2  铜锣山背斜地热水热储温标计算结果

    Table  2.   Calculated results of geothermal reservoirs of the Tongluo mountain anticline

    编号tT1T2T3T4
    GW014274787576
    GW022972767374
    GW034274797576
    GW042654605356
    GW052656625658
    注:t为地热井或泉口水温;T1=1309/(5.19−lgSiO2)-273.15,为无蒸汽损失的石英温度计算式;T2=1522/(5.75-lgSiO2)−273.15,为最大蒸汽损失的石英温度计算式;T3=−44.119+0.24469S−1.7414×10−4×S2+79.305lgS,为改进的玉髓温标计算式;T4为T1、T2和T3的平均值;上述温度单位为℃。
    下载: 导出CSV

    表  3  深部热水温度、焓值和SiO2含量[34]

    Table  3.   Values of temperature, enthalpy and SiO2 in deep thermal water

    温度/
    焓值/
    J·g−1
    SiO2/
    mg·L−1
    温度/
    焓值/
    J·g−1
    SiO2/
    mg·L−1
    温度/
    焓值/
    J·g−1
    SiO2/
    mg·L−1
    5050.013.5150151.0125.0250259.2486.0
    7575.026.6175177.0185.0275289.0614.0
    100100.148.0200203.6265.0300321.0692.0
    125125.180.0225230.9365.0
    下载: 导出CSV
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  • 收稿日期:  2022-03-18
  • 刊出日期:  2022-08-31

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