IMPACT OF PERMEABLE BRICK PAVEMENT ON STORMWATER RUNOFF THERMAL POLLUTION

XU Wei-tong; WANG Jian-long; WU Yan-jie; LV Yun-jie; LI Jun-qi

doi:10.13205/j.hjgc.202006023

Volume 38 Issue 6

Aug. 2020

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Article Navigation > ENVIRONMENTAL ENGINEERING > 2020 > 38(6): 143-148,207

XU Wei-tong, WANG Jian-long, WU Yan-jie, LV Yun-jie, LI Jun-qi. IMPACT OF PERMEABLE BRICK PAVEMENT ON STORMWATER RUNOFF THERMAL POLLUTION[J]. ENVIRONMENTAL ENGINEERING , 2020, 38(6): 143-148,207. doi: 10.13205/j.hjgc.202006023

Citation:

XU Wei-tong, WANG Jian-long, WU Yan-jie, LV Yun-jie, LI Jun-qi. IMPACT OF PERMEABLE BRICK PAVEMENT ON STORMWATER RUNOFF THERMAL POLLUTION[J]. ENVIRONMENTAL ENGINEERING , 2020, 38(6): 143-148,207. doi: 10.13205/j.hjgc.202006023

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IMPACT OF PERMEABLE BRICK PAVEMENT ON STORMWATER RUNOFF THERMAL POLLUTION

doi: 10.13205/j.hjgc.202006023

1. Beijing Engineering Research Center of Sustainable Urban Sewage System Construction and Risk Control, Beijing University of Civil Engineering and Architecture, Beijing 100044, China;
2. Beijing Advanced Innovation Center for Future Urban Design, Beijing University of Civil Engineering and Architecture, Beijing 100044, China;
3. Beijng General Municipal Engineering Design & Research Institute Co., Ltd, Beijing 100082, China

Received Date: 2020-01-17

Abstract

Abstract

With the rapid development of sponge city, permeable brick pavement has been widely used in practical engineering, but its impact on stormwater runoff thermal pollution is in shortage of systematic research. The artificial simulated rainfall method was used to study the stormwater runoff temperature reduction effect of the permeable brick paving system by using the impervious asphalt pavement as comparison. The research content include the runoff temperature of the permeable brick paving surface, the temperature of the permeate water, and the thermal transfer characteristics of each structural layer. The experimental results show that when P=5 a and the initial temperature of the permeable brick paving surface is 35, 42, 47 ℃, compared with impervious asphalt, the runoff temperature of the permeable brick paving surface can be reduced by 1.4~1.8 ℃, and the higher the initial temperature of the paving surface, the higher the temperature of the stormwater runoff, and the higher the temperature of the permeate water. The permeable brick paving structure layer can reduce the temperature of the permeable part of the stormwater runoff. The permeate water temperature is reduced by 3.5~4.9 ℃ compare to the runoff temperature. The rainfall return period has a significant effect on the runoff temperature, but its effect on the temperature of the permeate water is slight. Therefore, permeable brick paving can reduce urban stormwater runoff thermal pollution effectively.
- permeable brick paving,
- stormwater runoff,
- thermal pollution,
- temperature

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References

叶斌,盛代林,门小瑜.城市内涝的成因及其对策[J].水利经济,2010,28(4):62-65

,78.

张枭雄.我国城市道路面源污染途径及特点[J].居舍,2019(30):196.

赵玉坤,梅生成.太湖流域城市地表径流污染物浓度及污染特征分析[J].环境科技,2019,32(4):52-59.

朱英杰,杜晓丽,于振亚,等.道路雨水径流溶解性有机物对生物滞留系统重金属截留过程的影响[J].环境化学,2019,38(1):51-58.

JONES M P, HUNT W F, WINSTON R J. Effect of urban catchment composition on runoff temperature[J]. Journal of Environmental Engineering, 2012, 138(12):1231-1236.

SPRONKEN-SMITH R A, OKE T R. The thermal regime of urban parks in two cities with different summer climates[J]. International Journal of Remote Sensing, 1998, 19(11):2085-2104.

方彦红.缓解城市热岛效应沥青混合料分析[J].四川建材,2019,45(1):180,182.

BUREN M A V, WATT W E, MARSALEK J, et al. Thermal enhancement of stormwater runoff by paved surfaces[J]. Water Research, 2000, 34(4):1359-1371.

HERB W R, JANKE B, MOHSENI O, et al. Thermal pollution of streams by runoff from paved surfaces[J]. Hydrological Processes, 2010, 22(7):987-999.

吴烨. 浅层地热能开发的地质环境问题及关键技术研究[D].武汉:中国地质大学(武汉),2014.

JONES M P, HUNT W F. Bioretention impact on runoff temperature in trout sensitive waters[J]. Journal of Environmental Engineering, 2009, 135(8):577-585.

林欣,杨雪,许嘉鑫,等.渗透铺装对径流污染物的逐层削减效应研究[J].市政技术,2019,37(4):186-190.

李志辉,李星,杨艳玲,等.透水铺装去除污染效能及清洗特性研究[J].给水排水,2018,54(9):62-67.

WARDYNSKI B J, WINSTON R J, HUNT W F. Internal water storage enhances exfiltration and thermal load reduction from permeable pavement in the north carolina mountains[J]. Journal of Environmental Engineering ASCE, 2013, 139(2):187-195.

WANG J S, MENG Q L, TAN K H, et al. Experimental investigation on the influence of evaporative cooling of permeable pavements on outdoor thermal environment[J]. Building & Environment, 2018, 140:184-193.

FLOWER W, BURIAN S J, POMEROY C A, et al. Surface temperature and heat exchange differences between pervious concrete and traditional concrete and asphalt pavements[C]//Low Impact Development International Conference (LID), 2010.

北京市水利科学研究所. 透水砖路面施工与验收规程: DB11/T 686—2009[S]. 北京, 2009.

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