维护良性水循环的城镇化LID模式：海绵城市规划方法与技术初步探讨

doi:10.11849/zrzyxb.20151294

自然资源学报 ›› 2016, Vol. 31 ›› Issue (5): 719-731.doi: 10.11849/zrzyxb.20151294

• 专家论坛 • 下一篇

维护良性水循环的城镇化LID模式：海绵城市规划方法与技术初步探讨

刘昌明, 张永勇^*, 王中根, 王月玲, 白鹏

中国科学院地理科学与资源研究所陆地水循环及地表过程重点实验室,北京 100101

收稿日期:2015-11-24 修回日期:2016-01-04 出版日期:2016-05-20 发布日期:2016-05-19
作者简介:刘昌明（1934- ）,男,中国科学院院士,从事水文水资源理论和方法研究。E-mail:liucm@igsnrr.ac.cn *通信作者简介：张永勇（1981- ）,男,博士,副研究员,主要从事环境水文学研究。E-mail:zhangyy003@igsnrr.ac.cn
基金资助:
国家自然科学基金项目（41330529,41271005）; 中国科学院重点部署项目（KFZD-SW-301）; 中国科学院地理科学与资源研究所秉维优秀青年人才计划（2015RC201）; 中国科学院青年创新促进会（2014041）

The LID Pattern for Maintaining Virtuous Water Cyclein Urbanized Area: A Preliminary Study of Planning and Techniques for Sponge City

LIU Chang-ming, ZHANG Yong-yong, WANG Zhong-gen, WANG Yue-ling, BAI Peng

Key Laboratory of Water Cycle and Related Land Surface Processes, Institute of Geographic Sciences and Natural Resources Research, CAS, Beijing 100101, China

Received:2015-11-24 Revised:2016-01-04 Online:2016-05-20 Published:2016-05-19
Supported by:
National Natural Science Foundation of China, No.41330529 and 41271005; Key Program of the CAS, No.KFZD-SW-301; Program for “Bingwei” Excellent Talents in Institute of Geographic Sciences and Natural Resources Research, CAS, No.2015RC201; China Youth Innovation Promotion Association, CAS, No.2014041

摘要/Abstract

摘要： 海绵城市是低影响开发模式（Low Impact Development, LID）的重要途径,也是解决我国城市水问题的重要举措。论文从良性水循环理念的角度,针对城市防洪排涝、面源污染控制以及雨洪资源化利用等三大核心问题,以城市雨洪模拟技术和LID优化技术方法为重点,探讨了支撑海绵城市实施的关键技术方法,构建了具有自主知识产权的城市雨洪模型;并以首批海绵城市试点常德市为例进行了应用研究。研究得出：现状常德城区径流系数在0.33~0.81之间,平均值为0.64;按确保年径流总量控制目标的实现,采用渗、滞和蓄等多种LID消纳各地块径流,城区90%的地块均能达到控制目标,下沉式绿地、透水铺装和绿色屋顶总面积分别为496.75、 1 338.15和613.21 hm²,占各地块面积的3.9%~31.4%之间。污染负荷SS削减率在45.0%~47.7%之间,平均削减率为46.1%。常德城区通过实施LID措施,雨洪径流和污染负荷的输出量将显著降低,基本能够达到控制目标。研究为常德海绵城市规划设计提供了重要技术支撑和理论依据,为我国海绵城市规划方法和技术研究提供了参考。

关键词: 常德, 防洪排涝, 海绵城市, 面源污染, 雨洪利用

Abstract: Sponge city is an important Low Impact Development (LID) pattern, and also is a key to solve the urban water issues in China. In this study, we focus on the three core tasks including urban flood control and drainage, non-point source pollution control and urban rainfall-flood utilization, and explore the key technology and methodology to support the implementation of sponge city from the perspective of virtuous-water-cycle (e.g., the numerical simulation and LID optimization techniques), and finally develop an urban rainfall-flood model (HIMS-URBAN). This model is applied in Changde City, which is one of the first batch of sponge city. The results demonstrate that: 1) runoff coefficient in Changde City ranges from 0.33 to 0.81 in current state, with an average of 0.64. 2) Based on the objective of controlling total annual runoff, several LID measures (e.g., infiltration, storage and retention), are employed to consume the runoff from each block. By optimization, the controlling objective can be achieved in 90% of urban blocks. The areas of sunken green space, permeable pavement and green roof are 496.75, 1 338.15 and 613.21 hm², respectively, and the total area of LID measures accounts for from 3.9% to 31.4% of each block’s area. The reduction rate of pollution load SS is between 45.0% and 47.7%, with an average of 46.1%. By adopting the LID measures, the outputs of storm runoff and the pollution load in Changde urban area are remarkably reduced, and the control objective is almost achieved. This study provides great valuable results for construction of sponge city in Changde City, and also gives a good reference of theory and technology for urban planning and design.

Key words: Changde, diffuse source pollution, flood control and drainage, sponge city, stormwater utilization

中图分类号:

TV213

刘昌明, 张永勇, 王中根, 王月玲, 白鹏. 维护良性水循环的城镇化LID模式：海绵城市规划方法与技术初步探讨[J]. 自然资源学报, 2016, 31(5): 719-731.

LIU Chang-ming, ZHANG Yong-yong, WANG Zhong-gen, WANG Yue-ling, BAI Peng. The LID Pattern for Maintaining Virtuous Water Cyclein Urbanized Area: A Preliminary Study of Planning and Techniques for Sponge City[J]. JOURNAL OF NATURAL RESOURCES, 2016, 31(5): 719-731.

参考文献

[1] 潘家华, 李恩平, 单菁菁, 等. 城市蓝皮书: 中国城市发展报告 [M]. 北京: 社会科学文献出版社, 2015.

[2] 中华人民共和国住房和城乡建设部, 中华人民共和国国家发展与改革委员会, 中华人民共和国财政部. 城市排水与暴雨内涝防治设施建设的指导意见 [EB/OL]. http://www.membranes.com.cn/xingyedongtai/zhengcefagui/2015-01-20/18276.html, 2012-12-26.

[3] 中华人民共和国国务院. 国家新型城镇化规划(2014—2020年) [EB/OL]. http://politics.people.com.cn/n/2014/0317/c1001-24649809.html, 2014-03-17.

[4] PATERSON G. The big shift: Welcome to the third Australian culture: Book review [J]. Geographical Education, 2002, 15: 52.
[5] ROGERS M F, JONES D R. The Changing Nature of Australia’s Country Towns [M]. Ballarat, Australia: Victorian Universities Regional Research Network Press, 2006.
[6] COUNTY P G. Low-impact Development Design Strategies: An Integrated Design Approach [M]. Department of Environmental Resources, Programs and Planning Division, Prince George’s County, Maryland, 1999.
[7] United States Environmental Protection Agency. Low impact development (LID): A literature review [R]. EPA-841-B-00-005, 2000.
[8] MARITZ M. Water sensitive urban design [J]. Australian Journal of Soil and Water Conservation, 1990, 3(3): 19-22.
[9] CIRIA. SUDS: Sustainable drainage systems: Promoting good practice—A CIRIA initiative, 2005 [EB/OL]. http://www.ciria.org/suds/background.htm. 2008-03-22.
[10] BOER F, JORRITSMA J, VAN P D. De Urbanisten and the Wondrous Water Square [M]. 010 Publishers, 2010.
[11] TAN Y S, LEE T J, TAN K. Clean, Green and Blue: Singapore’s Journey towards Environmental and Water Sustainability [M]. Institute of Southeast Asian Studies, 2009.
[12] FURUMAI H, JINADASA H K, MURAKAMI M, et al. Model description of storage and infiltration functions of infiltration facilities for urban runoff analysis by a distributed model [J]. Water Science & Technology, 2005, 52(5): 53-60.
[13] 张书函. 基于城市雨洪资源综合利用的“海绵城市”建设 [J]. 建设科技, 2015(1): 26-28.

[14] VORREITER L, HICKEY C. Incidence of the first flush phenomenon in catchments of the Sydney region [C]// Procee-dings of the National Conference Publication—Institution of Engineers 3, 1994: 359-364.
[15] SANSALONE J J, BUCHBERGER S G. Partitioning and first flush of metals in urban roadway storm water [J]. Journal of Environmental Engineering, 1997, 123(2): 134-143.
[16] DELETIC A. The first flush load of urban surface runoff [J]. Water Research, 1998, 32(8): 2462-2470.
[17] LI L Q, YIN C Q, HE Q C, et al. First flush of storm runoff pollution from an urban catchment in China [J]. Journal of Environmental Sciences, 2007, 19(3): 295-299.
[18] 李艺. 循环利用缓解水资源短缺的有效途径 [EB/OL]. http://www.h2ochina.com/news/118388.html, 2013-06-29.

[19] 刘昌明, 王中根, 郑红星, 等. HIMS系统及其定制模型的开发与应用 [J]. 中国科学(技术科学), 2008, 38(3): 350-360.

[20] WANG Y, LIANG Q, KESSERWANI G, et al. A positivity-preserving zero-Inertia model for flood simulation [J]. Computer & Fluids, 2011, 46: 505-511.
[21] 中华人民共和国住房城乡建设部. 海绵城市建设技术指南——低影响开发雨水系统构建(试行) [Z]. 2014-10-15.

[22] 常德市政府. 常德市城市总体规划(2009—2030) [EB/OL]. http://xxgk.changde.gov.cn/xxgk/jcms_files/jcms1/web1/site/art/2013/9/17/art_77_53364.html.

维护良性水循环的城镇化LID模式：海绵城市规划方法与技术初步探讨

The LID Pattern for Maintaining Virtuous Water Cyclein Urbanized Area: A Preliminary Study of Planning and Techniques for Sponge City

RichHTML

PDF (PC)

赞

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 6

Metrics

本文评价

推荐阅读 0

[1]	王孟文, 齐伟, 王鹏涛, 王卓然. 鲁东山区流域景观格局与面源污染关联关系[J]. 自然资源学报, 2020, 35(12): 3007-3017.
[2]	荆延德, 张华美. 基于LUCC的南四湖流域面源污染输出风险评估[J]. 自然资源学报, 2019, 34(1): 128-139.
[3]	欧维新, 王海洁, 郭杰, 吴未, 陶宇. 滩涂农业垦区排水沟连接度对氮磷输出的影响[J]. 自然资源学报, 2017, 32(8): 1411-1421.
[4]	杨帆, 徐建刚, 林蔚. 基于元胞自动机的低影响开发对城市内涝削减效果模拟[J]. 自然资源学报, 2017, 32(7): 1158-1169.
[5]	张广纳, 邵景安, 王金亮, 倪九派, 谢德体. 三峡库区重庆段农村面源污染时空格局演变特征[J]. 自然资源学报, 2015, 30(7): 1197-1209.
[6]	张广纳, 邵景安, 王金亮. 基于农业面源污染的三峡库区重庆段水质时空格局演变特征[J]. 自然资源学报, 2015, 30(11): 1872-1884.