A retrospective study of green infrastructure for alleviating urban waterlogging—A case study of Sponge City retrofit in Jiangbinxincun NO.2 Neighborhood of Zhenjiang City,Jiangsu Province
ZHONG Xiaolin
Shanghai Landscape-architecture Design And Research Institute Co., Ltd., Shanghai 200001
Abstract:Since the implementation of Sponge City construction in China, there has been vigorous debate on whether green infrastructure (GI) can alleviate urban floods caused by extreme storm events, but there are few practical cases. This paper provides an example of applying low impact development(LID) approach to plan and design the redevelopment of old residential areas to alleviate urban floods. It also discusses how to transform an old and ultra-dense low- income community into one that is resilient to climate change. The main conclusions of this paper include: waterlogging control should be considered from the beginning when designing GI; try to mimic the pre-development hydrological characteristics of the site; residents should be communicated about maintenance from the beginning;the performance of GI facilities should be continuously monitored.
仲笑林. 绿色基础设施对于缓解城市内涝的回顾性研究——以江苏镇江市江滨新村二区海绵城市改造为例[J]. 中国防汛抗旱, 2023, 33(5): 1-7.
ZHONG Xiaolin. A retrospective study of green infrastructure for alleviating urban waterlogging—A case study of Sponge City retrofit in Jiangbinxincun NO.2 Neighborhood of Zhenjiang City,Jiangsu Province. journal1, 2023, 33(5): 1-7.
[1] National Bureau of Statistics of China(NBSC). China statistical yearbook 2016[M].Beijing:National Bureau of Statistics Press, 2016. [2] National Bureau of Statistics of China(NBSC). China statistical yearbook 2016[M].Beijing:National Bureau of Statistics Press, 2021. [3] Ma Q,He,C,Wu J,et al. Quantifying spatiotemporal patterns of urban imperious surfaces in china:an improved assessment using night time light data[J].Landscape Urban Planning,2014,130:36-49. [4] Yin J,Ye M,Yin Z,et al.A review of advances in urban flood risk analysis over China[J].Stochastic Environmental Research and Risk Assessment,2015,29:1063-1370. [5] Chen Y,Zhou H,Zhang H,et al.Urban flood risk warning under rapid urbanization[J]. Environmental Research,2015,139:3-10. [6] Hossain F,Arnold J,Beighley E,et al. Local-to-regional landscape drivers of extreme weather and climate:implications for water infrastructure resilience[J]. Journal of Hydrologic Engineering, 2015,20(7):02515002. [7] 住房和城乡建设部. 海绵城市建设技术指南:低影响开发雨水系统构建(试行)[R].2014. [8] Driscoll E,Palhegyi G,Strecker E,et al. Analysis of Storm Event Characteristics for Selected Rainfall Gauges throughout the United States[R].Prepared for the U.S. Environmental Protection Agency(EPA). Oakland,CA:Woodward-Clyde Consultants,1990. [9] United States Environmental Protection Agency (USEPA). national water quality inventory,2000 report,EPA-841-R-02-001[R]. 2002. [10]Wang H,Mei C,Liu J,et al. A new strategy for integrated urban water management in china:sponge city[J].Science China Technological Sciences,2018,61:317-29. [11]Zhong X L,Zhang L J,Chen H,et al.Converting traditional landscape into resilient landscape in Zhenjiang City to manage stormwater runoff:a case study[C]//the IOP Conference Series Earth and Environmental Science,2019,344:012146. [12]Chen X,Yang Q,Yang K. Construction approaches of urban spongy park based on low impact development[J].Journal of Landscape Research,2016,8:27-30. [13]Akagwu M,Fadamiro J A,Ayeni D A. Evaluation of environmental aesthetics of residential plots,through low impact development strategies,in satellite town,Lagos,Nigeria[J].International Journal of Development Research,2017,7:12102-12107. [14]Ministry of Housing and Rural-Urban Development of China. Standard for design of outdoor wastewater engineering[R].2021. [15]佘年,谢映霞,李迪华. 对中国海绵城市建设再出发的若干问题反思[J].景观设计学,2021,9:82-91. [16]Washington State University Pierce County Extension.Bioretention soil mix review and recommendations for western Washington (Technical memorandum)[EB/OL].(2020-01-30)[2022-04-23]. https://nwcore.org/Downloads/Soil-GuidelinesFinal.pdf. [17]Chahal M K,Shi Z,Flury M. Nutrient leaching and copper speciation in compost-amended bioretention systems[J].Science of the Total Environment,2016,556:302-559. [18]Logsdon S D. Nutrient leaching when soil is part of plant growth media[J].Water,2017,9(7):501. [19]Stephanie H,Paliza S,Amanda C. Nutrient leaching from compost:implications for bioretention and other green stormwater infrastructure[J].Journal of Sustainable Water in the Built Environment,2017,3(3):04017006. [20]Liu J,Sample D J,Owen J S,et al. Assessment of selected bioretention blends for nutrient retention using mesocosm experiments[J]. Journal Of Environmental Quality,2014,43:1754-1763. [21]Jamshidia A,Kurumisawa K,White G,et al. State-of-the-Art of interlocking concrete block pavement technology in Japan as a postmodern pavement[J].Construction and Building Materials,2019, 200:713-755. [22]Kuroiwa Y,Aiko E,Matuzawa Y.Development of the interlocking block for drainable pavements[C]//the 6th International Conference on Concrete Block Paving,Tokyo,Japan,2000:522-529. [23]Shackel B. Design of permeable paving subject to traffic[C]//The 8th International Conference on Concrete Block Paving,San Francisco,USA,2006:51-60. [24]Zhao H T,Zou C L,Zhao J,et al. Role of Low-Impact Development in generation and control of urban diffuse pollution in a pilot sponge city:a paired-catchment study[J].Water,2018,10:852. [25]She N,Pang J. Physically based green roof model[J].Journal of Hydrologic Engineering,2010,15:458-464. [26] NYC Mayor's Office of Resiliency.New York City stormwater resilient plan:helping new yorkers understand and manage vulnerabilities from extreme rain[R].2021.
2023, Vol. 33 
