Smart energy harvesting performance of photovoltaic roof assemblies in Canadian climate

IF 2.1 Q2 CONSTRUCTION & BUILDING TECHNOLOGY Intelligent Buildings International Pub Date : 2020-08-17 DOI:10.1080/17508975.2020.1802694
S. Molleti, M. Armstrong
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引用次数: 1

Abstract

ABSTRACT In Canada, the solar electricity sector is growing rapidly. Much of this success is based on the growth of the Ontario solar market where more than 99% of Canada’s solar electricity is generated. Ontario has developed a globally recognized solar market sector. The vast surface area of existing residential roofs across Canada represents an untapped resource for capitalizing on passive and active management of impinging solar insolation. The aim of the current research study is to evaluate the new energy harvesting technologies such as a thin-film PV integrated roof system that could serve as a conventional roofing for weather protection while generating clean solar electricity, and the new generation micro inverters that have the potential to outperform string inverters under shading and snow-cover conditions. This paper has two parts that will discuss about two smart energy harvesting technologies and their performance on residential applications in Canadian climate. Part 1 of the paper focusses on field evaluation of Roof Integrated Photovoltaic (RIPV) and Part 2 talks about the energy yield performance of integrated solar tiles and new generation micro inverters. The RIPV field trial took place at the Canadian Centre for Housing Technology (CCHT) Info Centre in Ottawa, Canada. This is a novel approach adapted from a roofing system that would typically be found on low-sloped roofs such as commercial supermarkets, industrial warehouses and school buildings. Over the eight month study period, surmounting the effects of snow cover and shadows, the RIPV system generated over 1 MWh of electricity, and had a measured system efficiency of 5.3%. The study on the new generation micro inverters for residential applications addressed the shading effects on the intermittent nature of solar energy generation. Simulating the shading conditions that are experienced by typical residential rooftop, the micro inverters were found to increase production by 1–68% relative to the conventional string inverters. The research outcome of this study has demonstrated that both these energy harvesting technologies have important incremental benefits in increasing the renewables contribution to power generation in residential homes in Canadian climatic conditions.
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加拿大气候下光伏屋顶组件的智能能源收集性能
摘要在加拿大,太阳能发电行业发展迅速。这一成功很大程度上是基于安大略省太阳能市场的增长,加拿大99%以上的太阳能发电都来自该市场。安大略省发展了一个全球公认的太阳能市场部门。加拿大各地现有住宅屋顶的巨大表面积代表了一种尚未开发的资源,可以利用被动和主动管理入射太阳辐射。当前研究的目的是评估新的能源收集技术,如薄膜光伏集成屋顶系统,该系统可以在产生清洁太阳能电力的同时作为传统屋顶进行天气保护,以及新一代微型逆变器,该逆变器在遮阳和积雪条件下有可能优于串式逆变器。本文分为两部分,将讨论两种智能能源收集技术及其在加拿大气候下的住宅应用性能。本文的第一部分重点讨论了屋顶集成光伏(RIPV)的现场评估,第二部分讨论了集成太阳能瓦片和新一代微型逆变器的能量产出性能。RIPV现场试验在加拿大渥太华的加拿大住房技术中心信息中心进行。这是一种新颖的方法,适用于商业超市、工业仓库和学校建筑等低坡屋顶上的屋顶系统。在为期八个月的研究期间,RIPV系统克服了积雪和阴影的影响,发电量超过1 MWh,测量的系统效率为5.3%。针对住宅应用的新一代微型逆变器的研究解决了阴影对太阳能发电间歇性的影响。模拟典型住宅屋顶的遮阳条件,发现微型逆变器的产量比传统的串式逆变器增加了1–68%。这项研究的研究结果表明,在加拿大的气候条件下,这两种能源收集技术在增加可再生能源对住宅发电的贡献方面都具有重要的增量效益。
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来源期刊
Intelligent Buildings International
Intelligent Buildings International CONSTRUCTION & BUILDING TECHNOLOGY-
CiteScore
4.60
自引率
4.30%
发文量
8
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