A Novel Approach to Multi-Apertures and Multi-Aspects Ratio Light Pipe

Q2 Energy

Journal of Daylighting Pub Date : 2020-09-16 DOI:10.15627/JD.2020.17

A. Goharian, M. Mahdavinejad

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引用次数: 8

Abstract

Daylightophil architecture concept is one of the most significant ways to reduce the electrical load consumption in building sector. In deep-plan buildings, or windowless buildings, advanced light transmission systems are used to compensate lighting demands in highperformance architecture theory. The manuscript is to challenge recent innovations in the light transmission systems, the choice of their type should be commensurate with the architectural design, space performance, and design requirements. Light pipes collect sunlight from the outdoor and transmit in the indoor for illumination. This paper presents analysis of daylight simulation of a novel vertical light pipe, which is embedded in an office building to transmit the light in three room, simultaneously. The light pipe (M-type) has two side apertures and one base aperture (multi-apertures) with different diameters (multi-aspect ratio). To analyze this novel vertical light pipe, a comparison was made with a conventional light pipe (S-type) with side-apertures. First, ray-tracing simulations were performed to investigate the penetration of light beams between the two light pipes. In comparison of level of illuminance between two types of light pipes, the efficiencies were evaluated. Daylight simulations were performed continuously throughout the year during daylight hours; in fact, fixed simulation makes it possible to analyze the effect of the sun altitude angle and the azimuth on the level of illuminance and output light beams direction to the spaces. Also, to investigate the effect of altitude and azimuth angles on the efficiency of the pipe (Mtype) and the direction of light output from the side apertures, altitude and azimuths were selected to simulate the design for providing symmetric sunlight on both sides of the building. © 2020 The Author(s). Published by solarlits.com. This is an open access article under the CC BY license (https://creativecommons.org/licenses/by/4.0/).

查看原文本刊更多论文

一种新的多孔径多纵横比光管的设计方法

日光建筑理念是减少建筑用电负荷消耗的重要途径之一。在深平面建筑或无窗建筑中，高性能建筑理论采用先进的透光系统来补偿照明需求。稿件旨在挑战近年来在光传输系统方面的创新，其类型的选择应与建筑设计、空间性能和设计要求相适应。光管收集室外的阳光并将其传送到室内照明。本文对一种新型的垂直光管进行了日光模拟分析，该垂直光管安装在办公楼内，可同时传输三个房间的光线。光管(m型)有两个不同直径(多长宽比)的侧孔和一个基底孔(多孔)。为了分析这种新型垂直光管，将其与传统的s型侧孔光管进行了比较。首先，进行了光线追踪模拟，以研究光束在两个光管之间的穿透性。通过对两种光管的照度进行比较，评价了两种光管的效率。白天模拟在全年白天连续进行;事实上，固定模拟可以分析太阳高度角和方位角对空间照度水平和输出光束方向的影响。此外，为了研究高度和方位角对管道(m型)效率和侧孔光输出方向的影响，我们选择高度和方位角来模拟在建筑两侧提供对称阳光的设计。©2020作者。由solarlits.com出版。这是一篇基于CC BY许可(https://creativecommons.org/licenses/by/4.0/)的开放获取文章。

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

Journal of Daylighting Energy-Renewable Energy, Sustainability and the Environment

CiteScore

4.00

自引率

0.00%

发文量

审稿时长

10 weeks

期刊介绍： Journal of Daylighting is an international journal devoted to investigations of daylighting in buildings. It is the leading journal that publishes original research on all aspects of solar energy and lighting. Areas of special interest for this journal include, but are not limited to, the following: -Daylighting systems -Lighting simulation -Lighting designs -Luminaires -Lighting metrology and light quality -Lighting control -Building physics - lighting -Building energy modeling -Energy efficient buildings -Zero-energy buildings -Indoor environment quality -Sustainable solar energy systems -Application of solar energy sources in buildings -Photovoltaics systems -Building-integrated photovoltaics -Concentrator technology -Concentrator photovoltaic -Solar thermal