The effect of window design factors on the cooling load in hospitals wards

IF 3.5 Q3 GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY

Smart and Sustainable Built Environment Pub Date : 2023-12-04 DOI:10.1108/sasbe-07-2023-0195

Abdulbasit Almhafdy, A. Alsehail

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Abstract

PurposeThis paper investigates the optimization of window design factors (WDFs) in hospital buildings, particularly in government hospitals within the arid climate of the Qassim region, with the aim of achieving a better cooling load reduction. Continuous monitoring of the hospital ward section is crucial due to patients' needs, requiring optimal indoor air quality and cooling load.Design/methodology/approachThe study identifies the optimal conditions for WDF design to mitigate cooling load, including window-to-wall ratio (WWR), window orientation (WO), room size and U-value (thermal properties), effectively reduce energy consumption in terms of sensible cooling load (MWh/m2) and comply with local codes. Data collection involved a smart weather station, while the Integrated Environmental Solution Virtual Environment (IESVE) software facilitated the simulation process.FindingsKey findings reveal that larger patient rooms were about 40% more energy-efficient than smaller rooms. The northern orientation showed lower energy consumption, and specific WWRs and glazing U-values significantly affected energy loads. In an analysis of U-value changes in energy performance based on the Saudi Building Code (SBC), the presented values did not meet the minimum energy consumption standards. For a valid 40% WWR with a thermal permeability of 2.89, 0.181 MWh/m2 was consumed, while for an invalid 100% WWR with the same permeability but facing the north, 0.156 MWh/m2 was consumed, which is considered an invalid practice. It is vital to follow prescribed standards to ensure energy efficiency and avoid unnecessary costs.Originality/valueFocus lies in emphasizing the significance of adhering to prescribed standards, such as SBC, to guarantee energy efficiency and prevent unwarranted expenses. Additionally, the authors highlight the crucial role of optimizing glazing properties and allocating the WWR appropriately to achieve energy-efficient building design, accounting for diverse orientations and climatic conditions.

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窗户设计因素对医院病房冷负荷的影响

本文研究了医院建筑的窗户设计因子(WDFs)的优化，特别是在卡西姆地区干旱气候下的政府医院，目的是实现更好的冷负荷降低。由于患者的需求，对医院病房的持续监测至关重要，需要最佳的室内空气质量和冷却负荷。设计/方法/方法本研究确定了WDF设计的最佳条件，以减轻冷负荷，包括窗墙比(WWR)、窗户朝向(WO)、房间大小和u值(热性能)，有效地降低了显冷负荷(MWh/m2)的能源消耗，并符合当地法规。数据收集涉及一个智能气象站，而综合环境解决方案虚拟环境(IESVE)软件促进了模拟过程。主要研究结果显示，较大的病房比较小的病房节能约40%。北朝向能耗较低，比WWRs和玻璃u值显著影响能耗负荷。在基于沙特建筑规范(SBC)的能源性能u值变化分析中，呈现的值不符合最低能耗标准。对于渗透率为2.89的有效40% WWR，消耗0.181 MWh/m2，而对于渗透率相同但朝北的无效100% WWR，消耗0.156 MWh/m2，这被认为是无效的做法。遵守规定的标准以确保能源效率和避免不必要的成本是至关重要的。重点在于强调遵守规定标准的重要性，如SBC，以保证能源效率和防止不必要的费用。此外，作者还强调了优化玻璃性能和适当分配WWR的关键作用，以实现节能建筑设计，考虑到不同的朝向和气候条件。

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

Smart and Sustainable Built Environment GREEN & SUSTAINABLE SCIENCE & TECHNOLOGY-

CiteScore

9.20

自引率

8.30%

发文量