兖州矿区深部奥灰水反向水文地球化学模拟研究

doi:10.11799/ce201602027

煤炭工程 ›› 2016, Vol. 48 ›› Issue (2): 87-90.doi: 10.11799/ce201602027

兖州矿区深部奥灰水反向水文地球化学模拟研究

韩永¹,刘德民¹,尹尚先¹,²,王广才³

1. 华北科技学院
2.
3. 中国地质大学（北京）水资源与环境学院

收稿日期:2015-10-12 修回日期:2015-10-23 出版日期:2016-02-10 发布日期:2016-03-07
通讯作者: 韩永 E-mail:hanyongzh@163.com

Study on the inverse hydrogeochemical modeling of the deep Ordovician limestone groundwater in Yanzhou Coalmine，North China

Received:2015-10-12 Revised:2015-10-23 Online:2016-02-10 Published:2016-03-07

摘要/Abstract

摘要： 为了分析深部奥灰水的主要水-岩作用，进而解释水文地球化学演化，基于流场和水化学场综合方法选出反应路径，进而进行兖矿奥灰水水化学模拟，结果表明：方解石、白云石在地下水中具有沉淀趋势；石膏、硬石膏和岩盐在水中处于非饱和状态，沿着水流路径继续溶解；主要水-岩作用为白云石、石膏和岩盐的溶解，方解石沉淀，阳离子交换和二氧化碳气体溶解或逸出等，与定性分析的结果非常一致；奥灰水中含Ca、Mg、Na、SO4及Cl的矿物相发生溶解，且溶解迁入比率大于沉淀析出比率。

关键词: 兖州矿区, 奥灰水, 水文地球化学模拟, 水-岩作用

Abstract: In order to analyze the water-rock interaction in the deep “Ordovician Limestone Groundwater” and explain the hydrogeochemical evolution, the hydrogeochemistry simulation of Ordovician limestone groundwater in Yanzhou Coalfield was finished, based on choosing the reaction paths by an integrated approach of water flow and geochemical field. The simulation results showed that: the calcite and dolomite tended to precipitate; the gypsum, anhydrite and halite were unsaturated and tended to dissolve in groundwater; the major water - rock interactions are the dissolution of dolomite, anhydrite and halite, calcite precipitation, cation exchange, and dissolution or escape of carbon dioxide, and the results are very consistent with the qualitative analysis; the dissolution of the mineral phases containing Ca, Mg, Na, SO4 and Cl in “Ordovician Limestone Groundwater” occurred, and the dissolution rate was greater than the precipitation rate.

中图分类号:

TD741

韩永，刘德民，尹尚先，王广才. 兖州矿区深部奥灰水反向水文地球化学模拟研究[J]. 煤炭工程, 2016, 48(2): 87-90.

0
/ / 推荐

导出引用管理器 EndNote|Reference Manager|ProCite|BibTeX|RefWorks

链接本文: http://www.coale.com.cn/CN/10.11799/ce201602027

http://www.coale.com.cn/CN/Y2016/V48/I2/87

参考文献

[1] Gastmans D, Chang H K, Hutcheon I. Groundwater geochemical evolution in the northern portion of the Guarani Aquifer System (Brazil) and its relationship to diagenetic features [J]. Applied Geochemistry, 2010, 25(1): 16-33.
[2] Soumya B S, Sekhar M, Riotte J, et al. Inverse models to analyze the spatiotemporal variations of chemical weathering ?uxes in a granito-gneissic watershed: Mule Hole, South India [J]. Geoderma, 2011, 165(1): 12-24.
[3] Han Y, Wang GC, Charles A, et al. Hydrogeochemical evolution of Ordovician limestone groundwater in Yanzhou, North China [J]. Hydrological Processes, 2013, 27(16): 2247–2257.
[4] Belkhiri L, Mouni L, Tiri A. Water-rock interaction and geochemistry of groundwater from the Ain Azel aquifer, Algeria [J]. Environmental Geochemistry and Health, 2012, 34(1): 1-13.
[5] Locsey K L, Grigorescu M, Cox M E. Water-rock interactions: an investigation of the relationships between mineralogy and groundwater composition and flow in a subtropical basalt aquifer [J]. Aquatic Geochemistry, 2000, 18(1): 45-75.
[6] Pacheco F, vanderWeijden C H. Contributions of water-rock interactions to the composition of groundwater in areas with a sizeable anthropogenic input: A case study of the waters of the Fundao area, central Portugal [J]. Water Resources Research, 1996, 32(12): 3553-3570.
[7] Jeelani G, Bhat N A, Shivanna K, et al. Geochemical characterization of surface water and spring water in SE Kashmir Valley, western Himalaya: Implications to water-rock interaction [J]. Journal of Earth System Science, 2011, 120(5): 921-932.
[8] Mande S L A S, Liu M Z, Liu F, et al. Factor analysis as an example of qualitative and quantitative method for modeling hydrogeochemical processes of coastal sedimentary basin of Togo [J]. African Journal of Microbiology Research, 2011, 5(31): 5554-5559.

兖州矿区深部奥灰水反向水文地球化学模拟研究

Study on the inverse hydrogeochemical modeling of the deep Ordovician limestone groundwater in Yanzhou Coalmine，North China

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 4

编辑推荐

Metrics

本文评价

[1]	李泽民，王毅. 下峪口煤矿11#煤层带压开采可行性研究[J]. 煤炭工程, 2018, 50(9): 8-11.
[2]	黄辅强,孙国忠. 平朔井工一矿导水陷落柱注浆加固治理技术[J]. 煤炭工程, 2018, 50(4): 51-54.
[3]	张建,吴洪申. 巨厚火成岩与奥灰水双重胁迫下矿井防治水技术研究[J]. 煤炭工程, 2018, 50(1): 62-65.
[4]	杨海新,王永华,才向军,冯光俊,张军建. 开滦矿区林西矿隐蔽致灾因素及防治措施研究[J]. 煤炭工程, 2016, 48(12): 59-62.