Zero-energy buildings in cities with different climates and urban densities: energy demand, renewable energy harvest on-site and off-site and total land use for different renewable technologies

U. Dietrich
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Abstract

Zero-energy buildings (ZEBs) have no fossil energy consumption; this is achieved by optimizing the building and balancing the remaining energy needs by renewables. If this energy can be harvested onsite, on the building’s envelope and its estate, a net-ZEB is reached. If supplementary renewable energy has to be produced off-site on compensating land, the ZEB can be reached with such compensating measures (ZEB_CM). Climate and urban density determine how far a ZEB is possible. Temperatures out of comfort range, lack of daylight and overheating by solar radiation may cause energy demand while high insolation or wind speed delivers good preconditions to produce renewable energy on less land. A high urban density avoids urban sprawl and saves land outside of the cities that can be used for other purposes (agriculture and energy production, among others). But, at a certain density, net-ZEB cannot be realized furthermore, and compensating land is necessary. The paper investigates these effects for 15 selected cities around the globe, covering all main climatic conditions. Based on design rules out of literature and own experiences, a prototypical optimized building is derived for each location, and its energy demand is simulated. Standard assumptions for the efficiency of renewable energy systems are used to determine the need of land to cover it. For different urban densities, it can be concluded how far net-ZEB is possible; if necessary, the need for compensating land is calculated. The results show that for cities with moderate climates, the total land use (city plus compensating land) can decrease with increasing urban density if the technology used off-site has high efficiency (like PV). On the other hand, the total land use may increase remarkably with increasing urban density if the used technology off-site has a low efficiency (like the wind for electricity and especially wood pellets for heating). The final understanding is that cities should meet the energy needs on-site by optimized buildings and structures plus renewable energy production (PV on the building’s roofs, geothermal systems, etc.).
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不同气候和城市密度的城市中的零能源建筑:能源需求、现场和场外可再生能源收获以及不同可再生技术的总土地使用
零能源建筑没有化石能源消耗;这是通过优化建筑和平衡可再生能源的剩余能源需求来实现的。如果这些能量能够在现场、建筑的外壳及其地产上获得,那么就达到了净ZEB。如果必须在补偿土地上场外生产补充可再生能源,则可以通过此类补偿措施(ZEB_CM)达到ZEB。气候和城市密度决定了ZEB的可能性。温度超出舒适范围、缺乏日光和太阳辐射过热可能会导致能源需求,而高日照或风速为在较少的土地上生产可再生能源提供了良好的先决条件。高城市密度避免了城市扩张,并节省了城市以外可用于其他目的(农业和能源生产等)的土地。但是,在一定密度下,净ZEB无法进一步实现,需要补偿土地。本文调查了全球15个选定城市的这些影响,涵盖了所有主要的气候条件。根据文献中的设计规则和自己的经验,推导出每个位置的原型优化建筑,并模拟其能源需求。可再生能源系统效率的标准假设用于确定覆盖该系统的土地需求。对于不同的城市密度,可以得出净ZEB可能达到的程度;如有必要,计算补偿土地的需求。结果表明,对于气候温和的城市,如果场外使用的技术(如光伏)具有较高的效率,则总土地利用(城市加补偿土地)可以随着城市密度的增加而减少。另一方面,如果场外使用的技术效率较低(比如风能发电,尤其是木屑发电),总土地利用率可能会随着城市密度的增加而显著增加。最终的理解是,城市应该通过优化建筑和结构以及可再生能源生产(建筑屋顶的光伏、地热系统等)来满足现场能源需求。
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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来源期刊
International Journal of Energy Production and Management
International Journal of Energy Production and Management Social Sciences-Sociology and Political Science
CiteScore
2.20
自引率
0.00%
发文量
24
审稿时长
26 weeks
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