Sun, shade and natural daylight in South African town planning, with emphasis on Pretoria

IF 0.6 Q4 REGIONAL & URBAN PLANNING
D. Conradie
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引用次数: 3

Abstract

A bioclimatic analysis of different South African towns and cities indicates that, if the correct mix of passive design principles is used, they all have a significant passive design potential. Of all such measures, solar protection and shading is the single most important passive design measure to reduce energy usage and to improve internal comfort for buildings in all South African climatic regions. The correct design of public open spaces and streets facilitates, to a great extent, energy-efficient buildings, whilst at the same time providing functional and comfortable urban open spaces and streets. Passive solar buildings aim to maintain interior thermal comfort throughout the sun’s diurnal and annual cycles, whilst reducing the requirement for active heating and cooling systems. The aim of this article is to investigate the effect of climate zones on passive design potential, of which shading design is an integral part, using Pretoria as a case study. This includes the effect of street width, building height, street layout, orientation, and the amount of sunlight available for trees and plants in the urban environment. The Spatial Planning and Land Management Act (2013), City of Tshwane Land Use Management By-law (2016) and the Tshwane Town-Planning Scheme 2008 (Revised 2014) were used as regulatory framework. To support the research, an Early Design Phase (EDP) experimental research platform was used to investigate the amount of sunlight on building facades with different orientations. This method enables the calculation of shading angles where there is a balance between the hot periods (requiring cooling) and cool periods (requiring heating) from the urban and building perspective. This has been achieved by means of the development of analytical software that uses weather files as one of the inputs to calculate critical solar angles. Over and above the calculation of current building solar protection angles, this method also facilitates the calculation of the increase in solar protection that will be required with climate change such as with the expected A2 climate change scenario (business-as-usual scenario) for South Africa. To support the EDP analysis, detailed simulations were also undertaken by means of Ecotect v5.60. Keywords : Cities, climate change, natural daylight, shade, sun, South Africa
南非城镇规划中的阳光、阴影和自然日光,重点是比勒陀利亚
对南非不同城镇的生物气候分析表明,如果使用正确的被动设计原则组合,它们都具有显著的被动设计潜力。在所有这些措施中,太阳能保护和遮阳是南非所有气候地区减少能源使用和提高建筑内部舒适度的最重要的被动设计措施。公共开放空间和街道的正确设计在很大程度上促进了节能建筑,同时提供了功能性和舒适的城市开放空间和道路。被动式太阳能建筑旨在在太阳的昼夜和年周期中保持室内热舒适性,同时减少对主动供暖和制冷系统的需求。本文的目的是以比勒陀利亚为例,研究气候区对被动式设计潜力的影响,其中遮阳设计是其中不可或缺的一部分。这包括街道宽度、建筑高度、街道布局、方向以及城市环境中树木和植物可获得的阳光量的影响。《空间规划和土地管理法》(2013年)、《茨瓦内市土地使用管理细则》(2016年)和《2008年茨瓦内城镇规划方案》(2014年修订)被用作监管框架。为了支持这项研究,使用了早期设计阶段(EDP)实验研究平台来研究不同方向的建筑立面上的阳光量。从城市和建筑的角度来看,这种方法可以计算在炎热时期(需要冷却)和凉爽时期(需要供暖)之间存在平衡的遮阳角度。这是通过开发分析软件实现的,该软件使用天气文件作为计算临界太阳角的输入之一。除了计算当前建筑的太阳能保护角度外,该方法还便于计算气候变化所需的太阳能保护的增加,例如南非的预期A2气候变化情景(照常营业情景)。为了支持EDP分析,还通过Ecotect v5.60进行了详细的模拟。关键词:城市,气候变化,自然光,树荫,阳光,南非
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
Town and Regional Planning
Town and Regional Planning REGIONAL & URBAN PLANNING-
CiteScore
0.80
自引率
20.00%
发文量
0
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