微波探测和量化建筑材料内部和表面的水分：对健康建筑和微生物组研究的影响。

Microwave detection and quantification of water hidden in and on building materials: implications for healthy buildings and microbiome studies.

机构信息

Department of Physics, University of Basel, Klingelbergstrasse 82, CH-4056, Basel, Switzerland.

Research School of Physics and Engineering, The Australian National University, Mills Rd., ACT 2601, Canberra, Australia.

出版信息

BMC Infect Dis. 2019 Jan 18;19(1):67. doi: 10.1186/s12879-019-3720-1.

DOI:10.1186/s12879-019-3720-1

PMID:30658591

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6339348/

Abstract

BACKGROUND

Excess water in all its forms (moisture, dampness, hidden water) in buildings negatively impacts occupant health but is hard to reliably detect and quantify. Recent advances in through-wall imaging recommend microwaves as a tool with a high potential to noninvasively detect and quantify water throughout buildings.

METHODS

Microwaves in both transmission and reflection (radar) modes were used to perform a simple demonstration of the detection of water both on and hidden within building materials.

RESULTS

We used both transmission and reflection modes to detect as little as 1 mL of water between two 7 cm thicknesses of concrete. The reflection mode was also used to detect 1 mL of water on a metal surface. We observed oscillations in transmitted and reflected microwave amplitude as a function of microwave wavelength and water layer thickness, which we attribute to thin-film interference effects.

CONCLUSIONS

Improving the detection of water in buildings could help design, maintenance, and remediation become more efficient and effective and perhaps increase the value of microbiome sequence data. Microwave characterization of all forms of water throughout buildings is possible; its practical development would require new collaborations among microwave physicists or engineers, architects, building engineers, remediation practitioners, epidemiologists, and microbiologists.

摘要

背景

建筑物中所有形式的多余水分（潮气、湿气、隐性水）都会对居住者健康产生负面影响，但很难可靠地检测和量化。最近的穿透墙壁成像技术进展推荐使用微波作为一种具有很大潜力的非侵入式工具，可用于检测和量化建筑物内的水分。

方法

使用透射和反射（雷达）模式的微波来简单演示对建筑材料内外的水分进行检测。

结果

我们使用透射和反射两种模式，检测到两块 7 厘米厚的混凝土之间仅有 1 毫升的水。反射模式还用于检测金属表面上的 1 毫升水。我们观察到透射和反射微波幅度随微波波长和水层厚度的变化而产生的振荡，我们将其归因于薄膜干涉效应。

结论

提高建筑物中水分的检测能力可以帮助设计、维护和修复工作更加高效和有效，也许还能增加微生物组序列数据的价值。对建筑物内所有形式的水分进行微波特性描述是可能的；实际开发需要微波物理学家或工程师、建筑师、建筑工程师、修复从业者、流行病学家和微生物学家之间开展新的合作。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/241e/6339348/ae2215a363f2/12879_2019_3720_Fig1_HTML.jpg

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微波探测和量化建筑材料内部和表面的水分：对健康建筑和微生物组研究的影响。

Microwave detection and quantification of water hidden in and on building materials: implications for healthy buildings and microbiome studies.

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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