Chemical characteristics and circulation process of geothermal water beneath Longchuan basin, western Yunnan
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摘要: 通过对陇川盆地开展地热地质调查,查清其地热资源分布:盆地内共出露地热点11处,热储结构类型为带状型和层状型,盆地中部为层状型,两侧盆地边缘为带状型,其中北西部受断裂控制明显,南东部受节理裂隙控制明显。其储热层为变质岩及新近系芒棒组的花岗质砂砾岩、细砂岩;地热水受大气降水影响明显,循环深度都在1 600 m以上,大部分在1 800~2 400 m之间,主要来源于深部热源,通过断裂、裂隙及砂砾石孔隙作为导水、储水上涌通道,接收来自山区补给的地下水混合出露于地表,补给距离在1.5 km以上,如南宛河温泉温度最高,地下水循环深度最深,补给距离最远,达10 km;盆地北东和西部水温高,循环深度深。Abstract: A survey of geothermic geology has been conducted to clarify the distribution of geothermal resources beneath the Longchuan basin. Results show that geothermal sources are exposed at 11 sites in this basin, in which heat reservoirs are zonal and layered type structures. Of them, the layered type appears in the central part of the basin, and the edges of each side of the basin are of zonal type. In the northwest of the basin, the heat reservoirs are obviously controlled by faults, while in the southeast joints and cracks have profound influence on the geothermal sources. The host rocks of these thermal reservoirs include metamorphic rocks, granitic glutenite and fine sandstone of Neogene Manban formation. Hydrochemical analysis suggests that geothermal water is obviously affected by atmospheric precipitation, and its circulation depth is above 1,600 m, mostly between 1,800 and 2,400 m, mainly from the surrounding mountains, with recharge distance over 1.5 km. The Nanwanhe hot spring has the highest temperature and the deepest groundwater circulation, with the longest recharge distance up to 10 km. Overall the water temperature is relatively high and water circulation is deep in the northeast and west of the basin. The heat of the geothermal water comes from the deep thermal source. It is a mixed type of geothermal water that receives groundwater recharge from mountainous areas and surface water through faults, fissures and sand and gravel pores as upwelling channels for water diversion and storage.
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