Evaluating the stormwater management model for hydrological simulation of infiltration swales in cold climates

IF 2.3 Q3 ENVIRONMENTAL SCIENCES Blue-Green Systems Pub Date : 2023-12-02 DOI:10.2166/bgs.2023.044
C. Bosco, Elhadi Mohsen Hassan Abdalla, T. Muthanna, K. Alfredsen, Britt Rasten, Heidi Kjennbakken, E. Sivertsen
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Abstract

The Stormwater Management Model (SWMM) is a widely used tool for assessing the hydrological performance of infiltration swales. However, validating the accuracy of SWMM simulation against observed data has been challenging, primarily because well-functioning infiltration swales rarely produce surface runoff, especially over short monitoring periods. This study addresses this challenge by using measured subsurface water storage levels for calibration and validation. The study evaluated three SWMM modules, namely, the snowpack, aquifer, and low-impact development (LID) modules, to simulate subsurface water storage levels of an infiltration swale located in a cold climate region during snow and snow-free periods. Global sensitivity analysis was used to identify influential parameters within these modules. The findings revealed that only a few parameters significantly influenced model outputs. Moreover, the aquifer module outperformed the LID module in simulating subsurface water storage due to limitations in setting the initial saturation of the LID module. Furthermore, simulation accuracy was better during snow-free periods due to challenges in simulating snow dynamics during snow periods with the snowpack module. The calibrated models offer valuable insights into the long-term hydrological performance of infiltration swales, enabling practitioners to identify events that trigger flooding in these systems.
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评估雨水管理模型在寒冷气候条件下对渗透沼泽的水文模拟作用
雨水管理模型(SWMM)是一种广泛使用的用于评估入渗河沟水文性能的工具。然而,根据观测数据验证SWMM模拟的准确性一直具有挑战性,主要是因为功能良好的入渗沟槽很少产生地表径流,特别是在较短的监测期内。本研究通过使用测量的地下蓄水水平进行校准和验证来解决这一挑战。该研究评估了三个SWMM模块,即积雪、含水层和低影响发展(LID)模块,以模拟位于寒冷气候地区的入渗沼泽在降雪和无降雪期间的地下蓄水水平。使用全局敏感性分析来确定这些模块中的影响参数。研究结果表明,只有少数参数显著影响模型输出。此外,由于LID模块初始饱和度设置的限制,含水层模块在模拟地下水储存方面优于LID模块。此外,由于积雪模块在模拟雪期积雪动力学方面存在挑战,因此在无雪期的模拟精度更好。校准后的模型为渗透沟槽的长期水文性能提供了有价值的见解,使从业者能够识别引发这些系统中洪水的事件。
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Blue-Green Systems
Blue-Green Systems Multiple-
CiteScore
8.70
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0.00%
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