Using Cool Roofs to Reduce Energy Use, Greenhouse Gas Emissions, and Urban Heat-island Effects: Findings from an India Experiment

H. Akbari
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引用次数: 12

Abstract

Cool roofs, cool pavements, and urban vegetation reduce energy use in buildings, lower local air pollutant concentrations, and decrease greenhouse gas emissions from urban areas. This report summarizes the results of a detailed monitoring project in India and related simulations of meteorology and air quality in three developing countries. The field results quantified direct energy savings from installation of cool roofs on individual commercial buildings. The measured annual energy savings potential from roof-whitening of previously black roofs ranged from 20 - 22 kWh/m2 of roof area, corresponding to an air-conditioning energy use reduction of 14 26percent in commercial buildings. The study estimated that typical annual savings of 13 - 14 kWh/m2 of roof area could be achieved by applying white coating to uncoated concrete roofs on commercial buildings in the Metropolitan Hyderabad region, corresponding to cooling energy savings of 10 - 19percent. With the assumption of an annual increase of 100,000 square meters of new roof construction for the next 10 years in the Metropolitan Hyderabad region, the annual cooling energy savings due to whitening concrete roof would be 13 -14 GWh of electricity in year ten alone, with cumulative 10-year cooling energy savings of 73 - 79 GWh for the region. The estimated savings for the entire country would be at least 10 times the savings in Hyderabad, i.e., more than 730 - 790 GWh. We estimated that annual direct CO2 reduction associated with reduced energy use would be 11 - 12 kg CO2/m2 of flat concrete roof area whitened, and the cumulative 10-year CO2 reduction would be approximately 0.60 - 0.65 million tons in India. With the price of electricity estimated at seven Rupees per kWh, the annual electricity savings on air-conditioning would be approximately 93 - 101 Rupees per m2 of roof. This would translate into annual national savings of approximately one billion Rupees in year ten, and cumulative 10-year savings of over five billion Rupees for cooling energy in India. Meteorological simulations in this study indicated that a reduction of 2C in air temperature in the Hyderabad area would be likely if a combination of increased surface albedo and vegetative cover are used as urban heat-island control strategies. In addition, air-temperature reductions on the order of 2.5 - 3.5C could be achieved if moderate and aggressive heat-island mitigation measures are adopted, respectively. A large-scale deployment of mitigation measures can bring additional indirect benefit to the urban area. For example, cooling outside air can improve the efficiency of cooling systems, reduce smog and greenhouse gas (GHG) emissions, and indirectly reduce pollution from power plants - all improving environmental health quality. This study has demonstrated the effectiveness of cool-roof technology as one of the urban heat-island control strategies for the Indian industrial and scientific communities and has provided an estimate of the national energy savings potential of cool roofs in India. These outcomes can be used for developing cool-roof building standards and related policies in India. Additional field studies, built upon the successes and lessons learned from this project, may be helpful to further confirm the scale of potential energy savings from the application of cooler roofs in various regions of India. In the future, a more rigorous meteorological simulation using urbanized (meso-urban) meteorological models should be conducted, which may produce a more accurate estimate of the air-temperature reductions for the entire urban area.
使用冷屋顶减少能源使用、温室气体排放和城市热岛效应:来自印度实验的发现
凉爽的屋顶、凉爽的路面和城市植被减少了建筑物的能源使用,降低了当地空气污染物的浓度,减少了城市地区的温室气体排放。本报告总结了印度一个详细监测项目的结果,以及三个发展中国家有关气象和空气质量模拟的结果。实地结果量化了在个别商业建筑上安装冷却屋顶所节省的直接能源。经过测量,以前黑色屋顶的屋顶增白每年节约的能源潜力在20 - 22千瓦时/平方米的屋顶面积之间,相当于商业建筑的空调能耗减少了14 26%。该研究估计,在海得拉巴大都会地区的商业建筑上,通过在未涂覆的混凝土屋顶上涂上白色涂料,每年可以节省13 - 14千瓦时/平方米的屋顶面积,相当于节省10% - 19%的冷却能源。假设在未来10年,海得拉巴大都会地区每年增加10万平方米的新屋顶建筑,仅在第10年,由于增白混凝土屋顶每年节省的冷却能源将为13 -14吉瓦时的电力,该地区10年累计节省的冷却能源为73 - 79吉瓦时。据估计,整个印度省下的电量至少是海德拉巴省下电量的10倍,即超过730 - 790吉瓦时。我们估计,每年与减少能源使用相关的直接二氧化碳减排将为11 - 12千克二氧化碳/平方米的平坦混凝土屋顶面积增白,而在印度,累积10年的二氧化碳减排将约为0.60 - 65万吨。电费估计为每千瓦时7卢比,空调每年节省的电费约为每平方米屋顶93 - 101卢比。这将在第10年转化为国家每年节省约10亿卢比,并在印度累积10年节省超过50亿卢比的冷却能源。本研究中的气象模拟表明,如果将增加地表反照率和植被覆盖相结合作为城市热岛控制策略,海得拉巴地区的气温可能会降低2摄氏度。此外,如果采取适度和积极的热岛缓解措施,可分别实现2.5 - 3.5℃的气温降低。大规模部署缓解措施可为城市地区带来额外的间接效益。例如,冷却室外空气可以提高冷却系统的效率,减少烟雾和温室气体(GHG)排放,并间接减少发电厂的污染——所有这些都可以改善环境健康质量。本研究证明了冷屋顶技术作为印度工业和科学界城市热岛控制策略之一的有效性,并提供了印度冷屋顶全国节能潜力的估计。这些成果可用于印度制定冷屋顶建筑标准和相关政策。在这个项目的成功和经验教训基础上进行的进一步实地研究,可能有助于进一步确认在印度各地区应用冷却器屋顶可能节省的能源规模。未来,应使用城市化(中城市)气象模式进行更严格的气象模拟,这可能会对整个城市地区的气温下降产生更准确的估计。
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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