昆明盆地地下水水质水位长序列数据特征分析

康晓莉; 周俊蓉; 高瑜; 张华

doi:10.11932/karst20230403

昆明盆地地下水水质水位长序列数据特征分析

doi: 10.11932/karst20230403

康晓莉^{1, 2, 3,},
周俊蓉^{1, 2, 3},
高瑜^{1, 2, 3},
张华^{1, 2, 3, ,}

1.
云南省高原山地地质灾害预报预警与生态保护修复重点实验室(筹), 云南昆明 650216
2.
自然资源部高原山地地质灾害预报预警与生态保护修复重点实验室,云南昆明 650216
3.
云南省地质环境监测院, 云南昆明 650216

基金项目: 广西岩溶动力学重大科技创新基地开放课题（KDL202101）、国家重点研发计划项目(2016YFC0502502)、国家地下水监测工程（WF202000PB）联合资助

详细信息

作者简介:
康晓莉（1973－），女，硕士，正高级工程师，主要从事水文、工程、环境地质调查与研究。E-mail：705443064@qq.com

通讯作者:
张华（1982－），男，高级工程师，主要从事水工环地质研究。E-mail：ybddysghs.zhh@163.com

中图分类号: P641.3
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出版历程
- 收稿日期: 2023-01-20
- 网络出版日期: 2023-11-23
- 刊出日期: 2023-11-28

Characteristics of long series data of groundwater quality and level in Kunming basin

KANG Xiaoli^{1, 2, 3
,},
ZHOU Junrong^{1, 2, 3},
GAO Yu^{1, 2, 3},
ZHANG Hua^{1, 2, 3
, ,}

1.
Yunnan Key Laboratory of Geohazard Forecast and Geoecological Restoration in Plateau Mountainous Area, Kunming, Yunnan 650216, China
2.
Key Laboratory of Geohazard Forecast and Geoecological Restoration in Plateau Mountainous Area, MNR, Kunming, Yunnan 650216, China
3.
Yunnan Institute of Geo-Environment Monitoring, Kunming, Yunnan 650216, China

摘要

摘要: 通过对昆明盆地，特别是主城区长序列水质水位监测数据对比分析，采用水文地质法、数据统计法、Piper和Matlab软件建立模型进行水质水位动态特征和变化趋势分析研究。昆明盆地地下化学类型以HCO₃-Ca和HCO₃-Ca·Mg型为主。孔隙水超标项以Mn、NH$_4^{+}$、NO$_3^{-}$、COD为主；岩溶水超标项以Mn、NH$_4^{+}$、F为主；近年来超标物项目趋于复杂，出现I、${\rm{SO}}_4^{2-}$、As、Cd等有毒有害和有机物超标，水质变化原因为工业和生活污染加剧。对地下水位20年长序列动态变化特征和趋势研究表明，昆明盆地地下水位年际变化主要受工农业生产、开采量和工程活动等影响，孔隙水2002—2009年呈下降趋势，2009年后总体呈上升趋势；岩溶水2002—2012年呈下降趋势，2012年后总体呈上升趋势；翠湖等5个降落漏斗区地下水位回升趋势较为显著，主要与昆明市限制地下水开采、封填地下水开采井的措施密切相关。基于水质、水位动态分析结果，提出保护建议。
- 地下水监测 /
- 水质 /
- 水位 /
- 趋势分析 /
- 昆明盆地
Abstract: Kunming basin is a representative of karst faulted basin, with a basin bottom area of 846.19 km² and a fluctuation of 1-82 m averaging at 19 m. With the city development, Kunming has gradually become one of the megacities in China. However, as the center of intensive human settlements and activities, the contradiction between human and land is prominent, and the problems of resources and environment are serious. Since the 1960s, the dynamic monitoring of groundwater in the urban and suburban areas of Kunming has been carried out in a comprehensive and systematic manner. In this study, hydrogeology method, data statistics method, Piper and Matlab software were used to establish models to analyze the dynamic characteristics and change of water quality and water level, based on the comparative analysis of monitoring data of water quality and level in Kunming basin, especially in the main urban area. The main underground chemical types of Kunming basin are HCO₃-Ca and HCO₃-Ca·Mg. In recent years, with the gradual increase of Na⁺+ K⁺ and ${\rm{SO}}_4^{2-} $ +Cl, the hydrochemical types have also gradually been increasing and become more complex. According to the water quality evaluation, the groundwater quality in Kunming basin has generally shown a downward trend in recent 15 years. The pore water quality is mainly of Class IV and Class V, and the proportion of Class V water has increased rapidly, from 30.2% to 62.5%. The bedrock water quality is mainly of Class III and Class IV. The proportion of Class IV water and Class V water has risen rapidly from 11.1% and 8.6% to 33.3% and 26.7%, respectively. Mn, NH$_4^{+}$, ${\rm{NO}}_3^{-}$ and COD are the main items exceeding permitted levels in pore water. Mn, NH$_4^{+}$ and F are the main items exceeding permitted levels in karst water. In recent years, I, ${\rm{SO}}_4^{2-}$, As, Cd and other toxic, harmful and organic substances have exceeded permitted levels, showing a compex tendency. The reason for the change of water quality is the intensification of industrial and domestic pollution. The results show that the interannual variation of groundwater level in Kunming basin is mainly affected by industrial and agricultural production, mining amount and engineering activities, and pore water decreased from 2002 to 2009, but increased after 2009. Karst water showed a downward trend from 2002 to 2012, and an upward one after 2012. The groundwater levels of Puji-Liangjiahe, Beijiaochang, the urban area of Kunming, Jinmasi-Guanshang and other water-rich blocks have risen significantly. The rising trend of groundwater levels in Cuihu, Heilongtan, Beijiaochang, Majie, Heilinpu and other five falling funnel areas is significant, which is closely related to the measures of restricting groundwater exploitation and sealing groundwater exploitation wells in Kunming City. Based on the dynamic analysis of water quality and water level, countermeasures and strategies to protect groundwater should be proposed through enhancing administrative management, strengthening the investigation, evaluation and monitoring of basic groundwater environment, and furthering the research on technology of preventing groundwater pollution.
- groundwater monitoring /
- water quality /
- water level /
- trend analysis /
- Kunming basin

HTML

图 1 昆明盆地地下水水化学类型Piper三线图

Figure 1. Piper ternary map of groundwater hydrochemistry types in Kunming basin

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图 2 监测离子变化曲线图

Figure 2. Curve of ion change monitoring

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图 3 孔隙水水位、降雨量年均变化图

Figure 3. Diagram of annual variation of pore water level and rainfall

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图 4 岩溶水水位、降雨量年均变化图

Figure 4. Diagram of annual variation of karst water level and rainfall

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图 5 昆明市主要降落漏斗中心水位M-K趋势检验

Figure 5. M-K trend test of water level in the center of main falling funnel in Kunming City

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图 6 昆明市主要富水块段水位变化趋势图

Figure 6. Water level variation of main water-rich blocks in Kunming City

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图 7 九龙池泉域水文地质剖面图（据参考文献[10]修编）

1-黏性土孔隙弱含水层 2-砂砾土孔隙较弱含水层 3-玄武岩裂隙弱含水层 4-白云岩岩溶较强含水层 5-碎屑岩弱含水层 6-石灰岩岩溶强含水层 7-监测孔,孔底数据为孔深(m),q为单位涌水量[L·(s·m)⁻¹] 8-上升泉群 9-地下水位线 10-地层界线 11-断层及编号 12-溶洞及充填溶洞 13-地下水流向 14-地层产状

Figure 7. Hydrogeological cross section in the Jiulongchi spring group (Revised according to reference [10])

1. Clay pore with weak aquifer; 2. Sandy gravel soil pore with relatively weak aquifer; 3. Basalt fissure with weak aquifer; 4. Dolomite karst with relatively strong aquifer; 5. Clastic rock with weak aquifer; 6. Limestone karst with strong aquifer; 7. Monitoring hole, and the hole bottom data is hole depth (m); q is unit inflow[L·(s·m)⁻¹]; 8. Ascending spring group; 9. Phreatic line; 10. Stratigraphic boundary; 11. Fault and numbering; 12. Karst caves and filling caves; 13. Groundwater flow direction; 14. Attitude of stratum

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表 1 昆明市5个主要降落漏斗中心水位统计表

Table 1. Statistics of central water level of 5 main falling funnels in Kunming City

地段名称	黑龙潭	北教场	马街	翠湖	黑林铺
原始水位/m	1 911.44	1 895.24	1 886.68	1 889.61	1 883.21
2002年水位	1 907.33	1 859.46	1 886.29	1 880.69	1 861.24
2021年水位	1 910.897	1 894.04	1 889.038	1 887.24	1 880.852

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