Can blue-green infrastructure counteract the effects of climate change on combined sewer overflows? study of a swiss catchment

Giovan Battista Cavadini, Mayra Rodríguez, Trang Nguyen, Lauren M. Cook
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Abstract

Combined sewer overflows (CSOs), the discharge of untreated sewage mixed with stormwater into surface waters, are expected to increase under climate change as a result of more extreme rainfall. Blue-green infrastructure (BGI), such as bioretention cells and porous pavements, can help to reduce the amount of stormwater entering combined sewer systems, thus reducing CSO discharge. However, our understanding of the potential for BGI to mitigate CSOs in a future climate is still lacking, as performance is typically evaluated for individual BGI elements with fixed implementation areas under historical climate conditions or limited future scenarios. In response, this study investigates the performance of 30 combinations of BGI elements and implementation rates to prevent increases in CSOs under a range of future climate scenarios in an urban catchment near Zurich, Switzerland. Median total annual rainfall, projected to increase by as much as 46%, could double the median annual CSO volume and increase median annual CSO frequency by up to 52%. Four BGI combinations that include bioretention cells show the most promise to prevent increases in CSO volume and frequency in a future climate; and given the diverse responses of BGI elements to distinct rainfall patterns, their combinations can enhance CSO discharge reduction across varying climate patterns. BGI is also likely to become more cost-effective under future climatic conditions as projected increases in total rainfall led to larger CSO volume reductions obtained through BGI. However, there is a trade-off between robustness to climate change and cost-effectiveness, since CSO volume reduction capacity scales with BGI implementation rate but cost-effectiveness declines. Our study illustrates the effectiveness of various BGI combinations to prevent increases in CSOs in a future climate, calling for a range of BGI elements and implementation areas to be considered for urban drainage adaptation.
蓝绿基础设施能否抵消气候变化对下水道合流溢流的影响? 对瑞士集水区的研究
下水道合流溢流(CSOs)是指未经处理的污水与雨水混合后排入地表水体,预计在气候变化的情况下,由于极端降雨量增加,CSOs 的排放量将会增加。蓝绿基础设施(BGI),如生物滞留池和多孔路面,有助于减少进入合流制下水道系统的雨水量,从而减少 CSO 排放。然而,我们对蓝绿基础设施在未来气候条件下缓解 CSO 的潜力仍缺乏了解,因为我们通常是在历史气候条件或有限的未来情景下,对具有固定实施区域的单个蓝绿基础设施进行性能评估。为此,本研究在瑞士苏黎世附近的一个城市集水区调查了 30 种 BGI 要素组合和实施率的性能,以防止在一系列未来气候情景下 CSO 的增加。预计年降雨总量中位数将增加 46%,这将使年 CSO 量中位数增加一倍,并使年 CSO 频率中位数增加 52%。在未来气候条件下,包括生物滞留细胞在内的四种 BGI 组合最有希望防止 CSO 量和频率的增加;鉴于 BGI 元素对不同降雨模式的反应各异,它们的组合可在不同气候模式下增强减少 CSO 排放的效果。在未来气候条件下,BGI 还可能更具成本效益,因为预计总降雨量的增加会导致通过 BGI 减少更多的 CSO 排放量。然而,气候变化的稳健性与成本效益之间存在权衡,因为随着 BGI 实施率的提高,CSO 量减少能力也会提高,但成本效益却会下降。我们的研究说明了各种 BGI 组合在未来气候条件下防止 CSO 增加的有效性,呼吁在城市排水适应中考虑一系列 BGI 要素和实施领域。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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