典型济南泉域强渗漏带的保护开发与评价

doi:10.16843/j.sswc.2018.03.013

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摘要兴隆片区是距济南市趵突泉、黑虎泉、五龙潭、珍珠泉4大泉群直线距离最近、面积最大的典型性强渗漏补给带。在城市化进程中，其部分区域逐渐由近自然型向覆盖性强渗漏带过渡。基于强渗漏带保护策略和低影响开发理念，对兴隆强渗漏带不同开发情景进行了分析模拟，提出了兴隆强渗漏带保护性开发措施。结果表明：在较少考虑保护和低影响开发的原规划A情景下，建设后地表径流的增加量约6.5万m³/（a·km²），增幅为36.29%；入渗补给量减少约8.8万m³/（a·km²），降幅为46.86%。在充分考虑保护和低影响开发的调整规划B情景下，比A情景减少地表径流约16.17%，增加入渗补给约41.20%，保护效果明显；但与近自然态相比，入渗补给量仅恢复至原水平的75%。开发建设强烈改变了下垫面的原有性质，损坏了强渗漏带地下水补给功能，即便采取低影响开发，也无法完全消除因工程建设导致的地下水补给量减少；因此以全流域生态修复和调水补源为核心的C情景的入渗补给功能可恢复并增加至现状的129.85%，是最为理想有效的保护措施。

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	马良
	王晓军
	吴恩江
	邢金龙
	姜广辉

关键词 ：低影响开发, 城市化, 水土保持, 入渗, 地下水补给区

Abstract：[Background] Xinglong is a typical strong seepage recharge zone with the nearest and largest trait from the four spring groups named Baotu Spring, Black Tiger Spring, Five Dragon Pool and Pearl Spring in Jinan city. In the process of urbanization, some partial region of Xinglong area gradually transit from nearly natural type to strong cover leakage zone. Its strong leakage recharge function or supply of spring water gradually reduced.[Methods] 1) With the aid of remote sensing, geographic information systems and other technical means, as well as site investigation, the information of geology, meteorology, hydrology, soil, vegetation and settlements were collected and sorted out in the studied area. A database of natural and socioeconomic data was established. 2) By taking on-the-spot geophysical (5 electrical sounding profiles, 32 physical points), drilling (165 holes, total footage 83.07 m), seepage pressure test (4 layers 4 times water seepage test, 3 layers 3 times water pressure test), drilling core observation (4 groups of drilling core, respectively 11, 15, 19 and 10, a total of 55) and other methods, the hydro-geological parameters of the strong seepage zone were obtained. 3) Combined with the groundwater hydrodynamic theory, the Xinglong groundwater infiltration-seepage numerical model was constructed. According to the land use, the hardening rate and other indicators under different development scenarios, as well as the geological, geomorphological and hydrogeological conditions of the studied area, the computational partitions were divided into three types, including Commercial District (N), Residential District (F) and Park District (E). On this basis, the groundwater recharge analysis and simulation were conducted to find out the changing rules of groundwater recharge in Xinglong Strong Seepage Zone. 4) Based on the strategies of strong seepage zone protection and low impact development, the protective development measures for the Xinglong Strong Seepage Zone were put forward.[Results] The research showed that the increase of surface runoff per square kilometer after construction was about 65 000 m³/a, an increase of 36.29%, and the infiltration recharge reduced by about 88 000 m³ under the situation that original planning scenario A considered less protection and low-impact development(LID), a decrease of 46.86%. With full consideration of protection and LID and adjustment, i.e., scenario B, the reduction of surface runoff by about 16.17% over the scenario A and the increase of infiltration and recharge by about 41.20% resulted in a significant protection effect. However, compared with the near-natural state, infiltration recharge only recovered to 75% of the original level. In the scenario C, by more actions such as delimiting the scope of protected areas, the construction of ecologically clean small watersheds, ditch protection and treatment, restoration of damaged mountains, ecological transformation of old villages, and inter-basin water diversion, the infiltration recharge functions of the Xinglong Strong Seepage Zone can be improved to 129.85% of the status quo according to modeling.[Conclusions] It can be seen that the development and construction have strongly changed the original properties of the underlying surface and damaged the groundwater recharge function in the strong seepage zone. Even if the low-impact development is adopted, the groundwater recharge due to the project construction will not be completely eliminated. More actions as described in scenario C are needed, and it has become the most desired and effective scheme at present.

Key words： low impact development urbanization water and soil conservation infiltration groundwater supply district

收稿日期: 2017-01-20

PACS:

P333.5

基金资助:山东省重点研发计划（公益性科技公关类）"流域水土流失阻控及面源污染防治关键技术研究"（GG201709250007）；山东省重大水利科研与技术推广项目"生态河道治理植物配置技术研究"（SDSLKY201504）；国家自然科学基金"农村居民点用地内部结构演变及其配置标准改进"（41671519）

通讯作者: 王晓军(1966-),男,副教授。主要研究方向:环境演变与灾害防治,河道生态与文化地理。E-mail:stu_wangxj@ujn.edu.cn E-mail: stu_wangxj@ujn.edu.cn

作者简介: 马良(1980-),男,博士,高级工程师。主要研究方向:土壤侵蚀,生态水文及对气候变化响应。E-mail:maleung@163.com

引用本文:

马良¹, 王晓军², 吴恩江², 邢金龙³, 姜广辉⁴. 典型济南泉域强渗漏带的保护开发与评价[J]. 中国水土保持科学, 2018, 16(3): 103-111.
MA Liang, WANG Xiaojun, WU Enjiang, XING Jinlong, JIANG Guanghui. Protective exploitation and evaluation of a typical strong seepage zone in Jinan, the city of springs. SSWC, 2018, 16(3): 103-111.

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http://journal12.magtechjournal.com/Jweb_stbc/CN/10.16843/j.sswc.2018.03.013 或 http://journal12.magtechjournal.com/Jweb_stbc/CN/Y2018/V16/I3/103

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