基于生命周期评价的海绵城市建设碳排放核算及碳减排效益探讨

doi:10.3969/j.issn.1000-5641.2025.06.011

摘要/Abstract

摘要：

基于全生命周期视角, 结合排放因子法与《安徽省海绵城市建设碳排放量核算技术导则》, 系统运用了适应海绵城市工程特征的碳排放核算方法, 以国家海绵示范城市芜湖为例, 评估了2022年4类典型海绵项目的碳排放和碳减排量, 并以建筑小区为例, 结合NSGA-Ⅱ多目标算法, 探讨了通过优化多类型海绵设施配置实现协同减碳目标的策略. 结果表明: ① 芜湖市海绵项目的碳排放主要集中在建设阶段, 总排放量为11 438.6 t, 其中材料生产与运输环节分别占比53%和36%, 存在较大的减排潜力. ② 海绵城市在运行阶段多依赖自然过程持续发挥作用, 碳减排效应相对集中, 该阶段总排放量约为 –242.3 t. 假设在维持既有运行状态、无新增设施的条件下, 海绵设施预计在30年生命周期内累计可实现碳减排量为7 269.7 t. 表明其年碳减排量相对有限, 但长期运行可逐步抵消建设阶段的碳排放, 展现出较强的碳中和潜力. ③ 就具体设施而言, 建设阶段中植草沟 (4.95 kg/m²) 和下凹式绿地 (11.35 kg/m²) 等绿色雨水设施的碳排放强度普遍较低, 而运行阶段海绵设施的碳减排效益则显著受其功能类型和建设规模影响. ④ 以建筑小区为例, 结合小区年径流总量控制率要求, 通过合理配置下凹式绿地、透水铺装、雨水花园和植草沟的规模, 可提升海绵设施的协同减碳能力.

关键词: 海绵城市, 碳减排, 生命周期评价 (LCA), 非支配排序遗传算法 (NSGA-Ⅱ)

Abstract:

In response to the new requirements for systematic sponge city development under China’s “carbon peaking and carbon neutrality” strategy, scientifically evaluating the carbon emissions and carbon emission reduction benefits of sponge city construction holds significant theoretical and practical value. This study took Wuhu, a national sponge demonstration city, as an example. Taking on the perspective of the whole life cycle, and combining the emission factor method and the Technical Guidelines for Carbon Emission Accounting for Sponge City Construction in Anhui Province, this study utilized the carbon emission accounting method for sponge cities that is applicable to engineering in practice, and evaluated the carbon emission and emissions reduction results of four types of typical sponge projects in 2022. Based on this, the study took a residential community as a representative example and employed the NSGA-Ⅱ algorithm to explore strategies for achieving synergistic carbon emissions reduction by optimizing the configuration of multiple types of sponge facilities. The results indicate the following. (1) The carbon emissions from sponge city projects in Wuhu are primarily concentrated in the construction phase, with total emissions of 11438.6 t. Among these, material production and transportation account for 53% and 36%, respectively, indicating considerable potential for emissions reduction. (2) During the operational phase, sponge cities largely rely on sustained natural processes to function, with the carbon reduction effects being relatively concentrated in this stage. The total carbon emissions during this phase are approximately –242.3 t. Assuming that existing operational conditions are maintained without any new facilities, sponge facilities are expected to achieve a cumulative carbon reduction of 7269.7 t in 30 years. Although the annual carbon reduction is relatively limited, long-term operation can gradually offset carbon emissions from the construction phase, demonstrating strong carbon neutrality potential. (3) In terms of specific facility types, green stormwater infrastructure such as grassed swales (4.95 kg/m²) and sunken green spaces (11.35 kg/m²) exhibit relatively low carbon emissions intensities during the construction phase. The carbon reduction benefits of sponge facilities in the operation stage are significantly influenced by their functional characteristics and the scale of implementation. (4) Taking a residential community as an example, and based on the annual total runoff control rate requirement, the coordinated carbon reduction capacity of sponge facilities can be enhanced by reasonably adjusting the scales of sunken green spaces, permeable pavements, rain gardens, and grassed swales. This study provides a quantitative evaluation of multi-facility sponge city systems from a holistic perspective, offering methodological support and a theoretical reference for the development of low-carbon urban drainage systems.

Key words: sponge city, carbon emissions reduction, life cycle assessment (LCA), non-dominated sorting genetic algorithms (NSGA-Ⅱ)

中图分类号:

TU992
X321

包兴燕, 程锐辉, 谢胜, 吴兆康, 蒯海艳, 张博笑, 吕博文, 杨凯. 基于生命周期评价的海绵城市建设碳排放核算及碳减排效益探讨[J]. 华东师范大学学报（自然科学版）, 2025, 2025(6): 94-105.

Xingyan BAO, Ruihui CHENG, Sheng XIE, Zhaokang WU, Haiyan KUAI, Boxiao ZHANG, Bowen LYU, Kai YANG. Carbon emissions accounting and carbon emissions reduction benefits of sponge city construction based on life cycle assessment[J]. J* E* C* N* U* N* S*, 2025, 2025(6): 94-105.

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编号	项目名称	海绵设施	规模/m²
P1	五一小区老旧小区改造项目	透水铺装	884.5
P2	鸠江区清水街道竹苑小区老旧小区配套基础设施项目	下凹式绿地	1275.5
P3	弋江区澛东新园老旧小区配套基础设施建设项目	透水铺装	1600.0
		下凹式绿地	1624.0
		雨水花园	1206.0
P4	伟星湖山云著小区海绵化新建项目	透水铺装	1649.8
		下凹式绿地	3481.6
		雨水花园	183.6
		调蓄池	64.0
P5	官陡城东片区 (扁担河以东) 成片开发建设项目	透水铺装	11457.4
		下凹式绿地	24.5
		雨水花园	178.0
		调蓄池	360.0
P6	湾沚区航空二、三、四路海绵城市改造项目	透水铺装	6180.0
P7	楚江大道 (和谐大道-吴越路) 海绵城市建设项目	透水铺装	11273.0
P7	楚江大道 (和谐大道-吴越路) 海绵城市建设项目	下凹式绿地	36205.0
P8	港一路 (银湖路-长江路) 拓宽改造工程	透水铺装	4884.0
P9	芜湖北站北侧围合区域水系治理工程	透水铺装	3671.8
		下凹式绿地	1692.7
		植草沟	791.8
		雨水花园	3842.8
P10	胜利渠 (银湖南路-赭山西路段) 海绵城市建设项目	植草沟	159.5
P10	胜利渠 (银湖南路-赭山西路段) 海绵城市建设项目	雨水花园	287.5
P11	神山智慧体育生态公园 (二标段) 建设项目	透水铺装	2602.5
		绿色屋顶	260.2
		调蓄池	240.0
P12	朱家桥尾水净化生态公园二期工程	透水铺装	40133.0
		下凹式绿地	1183.0
		雨水花园	2071.0
		人工湿地	85900.0

过程	碳排放强度
过程	透水铺装	雨水花园	调蓄池	植草沟	下凹式绿地	人工湿地	绿色屋顶
材料生产	41.84	6.65	69.04	1.31	3.38	27.26	22.43
材料运输	8.71	13.31	12.38	3.21	7.34	34.02	0.97
建造施工	12.58	0.71	2.51	0.43	0.63	1.61	9.51
总计	63.13	20.67	83.93	4.95	11.35	62.89	32.91

途径	碳减排强度
途径	透水铺装	雨水花园	调蓄池	植草沟	下凹式绿地	人工湿地	绿色屋顶
径流削减	–0.03	–0.59	–0.06	0	0	0	0
污染物削减	–0.99	–16.82	–1.73	0	0	–28.19	0
绿地固碳	0	–1.60	0	–1.60	–1.60	–3.62	–1.60
雨水利用	0	0	–0.53	0	0	0	0
热岛效应	0	0	0	0	0	0	–6.57
总计	–1.02	–19.01	–2.32	–1.60	–1.60	–31.81	–8.17

海绵设施	单位面积调蓄容积/(m³/m²)	海绵设施	单位面积调蓄容积/(m³/m²)
下凹式绿地	0.116	雨水花园	0.224
透水铺装	0.048	植草沟 (传输型)	0

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