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解决使用球温度计测量平均辐射温度时自由和混合对流的系统误差修正问题。

Addressing a systematic error correcting for free and mixed convection when measuring mean radiant temperature with globe thermometers.

机构信息

CHAOS Laboratory, Princeton University, Princeton, NJ, 08544, USA.

AIL Research, Inc., Hopewell, NJ, 08525, USA.

出版信息

Sci Rep. 2022 Apr 19;12(1):6473. doi: 10.1038/s41598-022-10172-5.

DOI:10.1038/s41598-022-10172-5
PMID:35440747
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9019106/
Abstract

It is widely accepted that most people spend the majority of their lives indoors. Most individuals do not realize that while indoors, roughly half of heat exchange affecting their thermal comfort is in the form of thermal infrared radiation. We show that while researchers have been aware of its thermal comfort significance over the past century, systemic error has crept into the most common evaluation techniques, preventing adequate characterization of the radiant environment. Measuring and characterizing radiant heat transfer is a critical component of both building energy efficiency and occupant thermal comfort and productivity. Globe thermometers are typically used to measure mean radiant temperature (MRT), a commonly used metric for accounting for the radiant effects of an environment at a point in space. In this paper we extend previous field work to a controlled laboratory setting to (1) rigorously demonstrate that existing correction factors used in the American Society of Heating Ventilation and Air-conditioning Engineers (ASHRAE) Standard 55 or ISO7726 for using globe thermometers to quantify MRT are not sufficient; (2) develop a correction to improve the use of globe thermometers to address problems in the current standards; and (3) show that mean radiant temperature measured with ping-pong ball-sized globe thermometers is not reliable due to a stochastic convective bias. We also provide an analysis of the maximum precision of globe sensors themselves, a piece missing from the domain in contemporary literature.

摘要

人们普遍认为,大多数人一生中的大部分时间都在室内度过。大多数人没有意识到,当他们在室内时,大约一半影响他们热舒适感的热交换是以热红外辐射的形式进行的。我们表明,尽管在过去的一个世纪里,研究人员已经意识到它对热舒适感的重要性,但系统误差已经潜入到最常见的评估技术中,从而无法充分描述辐射环境。测量和描述热辐射传递是建筑能效和居住者热舒适度和生产力的关键组成部分。球形温度计通常用于测量平均辐射温度(MRT),这是一种常用的度量标准,用于衡量空间中某个点的环境的辐射效应。在本文中,我们将之前的现场工作扩展到一个受控的实验室环境中,(1)严格证明美国采暖、制冷与空调工程师学会(ASHRAE)标准 55 或 ISO7726 中用于使用球形温度计来量化 MRT 的现有校正因子不充分;(2)开发一种校正方法,以改善球形温度计的使用,解决当前标准中的问题;(3)表明由于随机对流偏差,用乒乓球大小的球形温度计测量的平均辐射温度不可靠。我们还分析了球形传感器本身的最大精度,这是当代文献中缺失的一部分。

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本文引用的文献

1
Globe thermometer free convection error potentials.球式温度计的自然对流误差电位。
Sci Rep. 2020 Feb 14;10(1):2652. doi: 10.1038/s41598-020-59441-1.
2
The Globe Thermometer in Studies of Heating and Ventilation.用于供暖与通风研究的球形温度计。
J Hyg (Lond). 1934 Dec;34(4):458-73. doi: 10.1017/s0022172400043242.
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The Influence of the Humidity of the Air on Capacity for Work at High Temperatures.空气湿度对高温下工作能力的影响
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The assessment of the thermal environment. A review.热环境评估。综述。
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Relationship between air temperature and mean radiant temperature in thermal comfort.热舒适中气温与平均辐射温度的关系。
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Small globe thermometers.小型球形温度计。
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The effects of added clothing on warmth and comfort in cool conditions.添加衣物对凉爽环境下保暖性和舒适度的影响。
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