Ventilation Performance of Air Duct in Double Loaded Corridor Building: A Case Study

Muhammad S. Ulum, Wenny Arminda, M. Kamaruddin, Widi Dwi Satria
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Abstract

Buildings with double-loaded corridor types are often found in Indonesia and generally function as offices or lecture rooms. This type of building is popular because of its efficient circulation path to accommodate the movement of occupants. However, a wall separating the room from the corridor makes it impossible to put windows to implement a cross-ventilation system due to acoustic problems. Hence, to achieve indoor thermal comfort, this type of building relies on using an air conditioning (AC) system. However, with the WHO's call to reduce the use of AC during the COVID-19 pandemic, it is necessary to evaluate cross-ventilation in double-loaded corridor buildings to meet comfort standards while still preventing acoustic problems due to noise from corridors and other spaces. The study proposes a new natural ventilation system using air ducts placed above the corridor ceiling to create cross-ventilation in lecture buildings. The E-ITERA building was chosen as a case study in this research. The building has a glass facade with several small windows that can be opened outside. The corridor of this building is designed with openings at both ends, allowing for direct connection to the outside air. The walls facing the passage have a single door and four small ventilations on the aisle's upper side. Simulations were carried out in two classrooms on the 3rd floor using CFD (Computational Fluid Dynamics) software. Experiments were carried out to change the size of the air duct and the size of the ventilation on the wall that leads to the corridor. The results showed that the air duct was able to create cross-ventilation. Ventilation performance is improved when the WWR air duct is the same as the WWR window. The highest air velocity in the centre of the room is 0.6 m/s. Doi: 10.28991/CEJ-2023-09-10-06 Full Text: PDF
双层走廊建筑中风管的通风性能:案例研究
双层走廊式建筑通常出现在印度尼西亚,一般用作办公室或阶梯教室。这种类型的建筑很受欢迎,因为它具有高效的流通路径,可以满足用户的移动需求。然而,由于房间与走廊之间有一堵墙隔开,因此无法安装窗户来实施交叉通风系统。因此,要实现室内热舒适度,这类建筑只能依靠空调系统。然而,世界卫生组织呼吁在 COVID-19 大流行期间减少空调的使用,因此有必要对双层走廊建筑的交叉通风进行评估,以满足舒适度标准,同时还能防止因走廊和其他空间的噪音而产生的声学问题。这项研究提出了一种新的自然通风系统,利用放置在走廊天花板上方的通风管道,在演讲楼中实现交叉通风。本研究选择了 E-ITERA 大楼作为案例。该建筑的外墙为玻璃幕墙,有几扇可向外打开的小窗户。大楼走廊的两端都设计有开口,可以直接与室外空气相通。面向通道的墙壁有一扇门,过道上侧有四个小型通风口。使用 CFD(计算流体动力学)软件在三楼的两个教室进行了模拟。实验改变了通向走廊的墙壁上的通风管道和通风口的大小。结果表明,风道能够形成交叉通风。当 WWR 风道与 WWR 窗相同时,通风性能会得到改善。房间中心的最高风速为 0.6 米/秒。Doi: 10.28991/CEJ-2023-09-10-06 全文:PDF
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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