使用光伏集成垂直遮阳设备优化教室的日光、能源和居住者舒适性能

IF 2.7 4区工程技术 Q2 CONSTRUCTION & BUILDING TECHNOLOGY

Architectural Engineering and Design Management Pub Date : 2022-05-29 DOI:10.1080/17452007.2022.2080173

E. Noorzai, Parnian Bakmohammadi, Maedeh Andaji Garmaroudi

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引用次数: 18

摘要

本研究提出了一种多目标方法来优化固定垂直、参数化建模PV综合遮阳装置的设计，以实现其对室内环境和教室居民的最大效益。由于传统遮阳装置的几何设计，无论是在现实世界的应用还是在文献中，通常仅限于非无定形和矩形形状，我们的目标是深入了解采用具有新颖设计替代方案的面板的可能优势。为此，我们最初利用Grasshopper程序开发了包含平面PV板的遮阳设备的参数化模型。接下来，蜜蜂和瓢虫的环境插件被用来评估日光和能源运行以及居住者的热和视觉舒适度。此外，为了减少所需的照明能量，并通过提供特定任务所需的适当照度来增强用户的视觉便利性，我们将教室划分为可调节的照明区域。最后一步是通过Grasshopper的Octopus插件执行优化过程，并确定最优解。年度模拟的数值结果表明，我们达到了可观的节能高达20%，同时提高了乘员的热和视觉舒适度。

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Optimizing daylight, energy and occupant comfort performance of classrooms with photovoltaic integrated vertical shading devices

ABSTRACT This work proposes a multi-objective approach for optimizing the design of fixed vertical, parametrically modeled PV integrated shading devices to achieve their highest benefits to the indoor environment and residents in a classroom. Since the geometric design of conventional shading devices, whether in real-world applications or the literature, is usually restricted to non-amorphous and rectangular shapes, our goal is to gain insight into the likely advantages of employing panels with novel design alternatives. To this end, we initially developed a parametric model of shading devices containing planar PV panels utilizing the Grasshopper program. Next, the environmental plugins of Honeybee and Ladybug were used to assess daylight and energy operations along with occupants’ thermal and visual comfort. Moreover, to lessen the required lighting energy and enhance users’ visual convenience by providing appropriate illuminance levels required for a specific task, we divided the classroom into adjustable lighting zones. The last step was performing the optimization process via the Octopus plugin for Grasshopper and determining the optimal solutions. The numerical results of the annual simulations show that we reached considerable energy saving up to 20% while enhancing occupants’ thermal and visual comfort.

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来源期刊

Architectural Engineering and Design Management Multiple-

CiteScore

5.80

自引率

3.40%

发文量

期刊介绍： Informative and accessible, this publication analyses and discusses the integration of the main stages within the process of design and construction and multidisciplinary collaborative working between the different professionals involved. Ideal for practitioners and academics alike, Architectural Engineering and Design Management examines specific topics on architectural technology, engineering design, building performance and building design management to highlight the interfaces between them and bridge the gap between architectural abstraction and engineering practice. Coverage includes: -Integration of architectural and engineering design -Integration of building design and construction -Building design management; planning and co-ordination, information and knowledge management, vale engineering and value management -Collaborative working and collaborative visualisation in building design -Architectural technology -Sustainable architecture -Building thermal, aural, visual and structural performance -Education and architectural engineering This journal is a valuable resource for professionals and academics (teachers, researchers and students) involved in building design and construction, including the following disciplines: -Architecture -Building Engineering -Building Service Engineering -Building Physics -Design Management and Design Coordination -Facilities Management Published papers will report on both fundamental research dealing with theoretical work and applied research dealing with practical issues and industrial innovations. In this way, readers explore the interaction between technical considerations and management issues.