Mechanism of karst Waterlogging formation and effective control
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摘要: 岩溶内涝灾害给岩溶地区人们带来重大损失,严重威胁人们的生产生活,其综合治理已成为国家重大现实需求。内涝灾害具有周期性、群发性和突发性的特征,封闭的岩溶地貌及岩溶含水层特殊的溶隙–管道“二元”结构是产生内涝的内部因素,降雨集中的湿润季风气候是内涝发生的直接外因,不合理的工程活动造成水土大量流失阻塞地下岩溶管道,是导致内涝日趋严重的人为外部因素。严重的内涝主要分布在有地下河管道发育的峰丛谷地、洼地地貌区,补给区、径流区、排泄区具有不同内涝成因模式。目前主要采取水利工程措施对内涝进行治理,大部分工程未达到预期成效,后期应以地下河流域为单元,采取水利工程措施与生态环境措施进行综合防治,形成流域岩溶内涝综合防治体系;另外,还需开展内涝灾害形成的水文动态、水土流失动态系统观测,精细刻画洼地岩溶含水层裂隙–管道“二元”结构,明确引发内涝的降雨量阈值及变化特征,阐明内涝灾害形成水文过程和水土流失过程及控制因素,系统揭示内涝形成机制、演变规律和机理;准确掌握岩溶内涝的主控因素和可调控的因素,提出科学有效的内涝调控对策建议,实现流域岩溶内涝灾害标本兼治。Abstract:
The global karst area is about 22 million km2, accounting for 15% of the global land area. The people in karst areas are threatened to varying degrees by droughts and floods. Waterlogging is a geological hazard formed by the superposition of karst geological and geomorphological environment and human activities. The closed karst terrain combined with strong human engineering activities causes serious soil erosion. Soil leaks into the lower karst pipeline through the sinkhole, causing underground pipeline blockage , drainage obstruction, and frequent occurrence of waterlogging; With the increase of extreme weather, human activities, soil erosion in low-lying areas, and blockage of karst pipelines, if left untreated for a long time, the waterlogging time in low-lying areas will become more frequent and severe. Karst Waterlogging disasters have caused significant losses to people in karst areas, seriously threatening their production and life. The comprehensive management of these disasters has a major national demand. The characteristics of Waterlogging disasters are periodicity, group occurrence, and suddenness. The enclosed karst landform and the special "binary" structure of the karst aquifer are the internal factors that cause karst Waterlogging. The subtropical monsoon climate with concentrated rainfall is the external condition for the occurrence of karst Waterlogging. Unreasonable engineering activities have caused a large amount of soil and water loss, blocking underground karst channels, which is the human factor leading to increasingly karst Waterlogging. Severe karst Waterlogging mainly occurs in karst valleys and depressions where underground rivers and pipelines are developed. The recharge area, runoff area, and discharge area of an underground river have different mechanisms for causing internal Waterlogging. At present, there is a lack of systematic research and characterization of the "binary" structure of karst aquifers. Soil erosion leads to a decrease in the rainfall threshold for causing Waterlogging, and no relevant studies have been conducted on the impact of soil erosion on degeneration of underground pipeline water conveyance capacity. There is a lack of in-depth research on the formation mechanism of karst Waterlogging disasters, and it is even more impossible to predict the extent of karst Waterlogging disasters and the losses caused under extreme climate events, which seriously affects the effectiveness of karst Waterlogging control. In the later stage, systematic observations of the hydrological dynamics and soil erosion dynamics that lead to urban Waterlogging should be carried out, characterize the karst aquifer fracture-cave "dual" structure in detail, clarify the rainfall threshold and its changing characteristics that cause urban Waterlogging, elucidate the hydrological processes and soil erosion processes and their controlling factors that lead to the formation of karst Waterlogging disasters, analyze the relationship between reduction coefficient of outlet flow and the amount of soil erosion in low-lying areas, and systematically reveal the mechanism, evolution laws, and principles of karst Waterlogging formation, and then propose scientifically effective countermeasures for karst Waterlogging regulation. -
Key words:
- karst waterlogging /
- karst aquifer /
- underground river /
- soil and water loss /
- effective governance
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图 1 漓江峰丛片区暗嵅洼地积水深度与降雨量的关系
Figure 1. The relationship between water depth and rainfall in the Andang depression of Lijiang peak cluster area
图 2 地下河补给区内涝成因模式 [42]
Figure 2. Mechanism of karst waterlogging formation in the recharge area of the underground river
图 3 地下河径流区岩涝成因模式
Figure 3. Mechanism of karst waterlogging formation in the runoff area of the underground river
图 4 地下河排泄区内涝成因模式
Figure 4. Mechanism of karst waterlogging formation in the discharge area of the underground river
表 1 2024年6月漓江峰丛片区暗嵅洼地积水情况
Table 1. Water depth in the Andang depression of the Lijiang Peak Cluster area in June 2024
集中降雨时间 降雨量/mm 最大积水时刻 最大积水深度/m 6月9日—10日 223.2 6月11日17:30 5.22 6月12—13日 235.6 6月14日19:30 7.55 6月16—17日 97.4 6月18日6:00 7.60 6月25日 190.8 6月27日13:30 7.74 7月1—2日 91.6 7月3日3:15 7.06 
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