Analysis, evaluation and integration of modular natural illumination system using a rectangular Fresnel lens for high performance

IF 2.1 3区工程技术 Q2 CONSTRUCTION & BUILDING TECHNOLOGY

Lighting Research & Technology Pub Date : 2022-04-17 DOI:10.1177/14771535211063624

H. Garg, DS Bisht, K. Sharma, V. Kumar, K. Kaur, N. Garg

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引用次数: 2

Abstract

Daylighting using natural illumination system (NILS) is gaining popularity due to transition to the renewable and non-conventional energy resources. In the proposed work, optomechanical design, numerical analysis, experimentation and integration of a modular Fresnel lens for NILS to effectively harness the sunlight is discussed. The modular and integrated design delivers uniform light at the receiving area of the daylight transportation system. This modular Fresnel lens is a combination of linear Fresnel lenses designed to offer a moderate concentration ratio to avoid hot spots. The distribution of solar radiation on the focal plane/entry section of the plastic optical fibre bundle (daylight transportation system) is simulated using the ray-trace technique for a lens system with a concentration ratio of 81. The irradiance distributions at the focal plane were found uniform with a radiometric and photometric transmission efficiency of 72.45% and 85.96%, respectively, for the lens element. The overall photometric transmission efficiency of the system with 10 m long plastic/acrylic optical fibre cable was found as 40.97%.

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采用矩形菲涅耳透镜的高性能模块化自然照明系统的分析、评估和集成

由于向可再生能源和非常规能源的过渡，使用自然照明系统(NILS)的采光越来越受欢迎。本文讨论了一种模块化菲涅耳透镜的光力学设计、数值分析、实验和集成，以有效地利用NILS的太阳光。模块化和集成设计在日光运输系统的接收区域提供均匀的光线。这种模块化菲涅耳透镜是线性菲涅耳透镜的组合，旨在提供适度的集中比，以避免热点。在聚光比为81的透镜系统中，利用光线追踪技术模拟了太阳辐射在塑料光纤束(日光传输系统)的焦平面/入射截面上的分布。焦平面上的辐照度分布均匀，透镜元件的辐射透射效率为72.45%，光度透射效率为85.96%。10 m长的塑料/腈纶光缆系统的整体光度传输效率为40.97%。

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

Lighting Research & Technology 工程技术-光学

CiteScore

5.40

自引率

16.00%

发文量

审稿时长

>12 weeks

期刊介绍： Lighting Research & Technology (LR&T) publishes original peer-reviewed research on all aspects of light and lighting and is published in association with The Society of Light and Lighting. LR&T covers the human response to light, the science of light generation, light control and measurement plus lighting design for both interior and exterior environments, as well as daylighting, energy efficiency and sustainability