Comparison between the thermal properties of cement composites using infrared thermal images.

Q2 Agricultural and Biological Sciences

Agronomy research Pub Date : 2020-01-01 DOI:10.15159/AR.20.110

P. Ferraz, R. F. Mendes, G. Ferraz, F. A. Damasceno, I. Silva, L. Vaz, L. Mendes, D. Cecchin, J. O. Castro

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引用次数: 1

Abstract

The use of agribusiness residual lignocellulosic fibres can be a good alternative in the development of lignocellulosic composites. The current work aimed to investigate the thermal performance of cement-based composites with lignocellulosic materials: Eucalyptus, sugarcane bagasse, coconut fibre in comparison with commercial gypsum board to be used as internal partitions of the building using infrared thermal images. Three repetitions for each kind of lignocellulosic material were made, and three commercial gypsum boards were used. In the production of the panels, the following parameters were applied: material and cement ratio, 1:2.75; water and cement ratio, 1:2.5; hydration water rate of 0.25; additive, 4% (based on cement mass). The calculations were performed for a nominal panel density of 1,200 kg m3. The thermal analysis was performed in a chamber composed of MDP (Medium-Density Particleboard) and with an internal layer of rock wool and the heat source (thermal resistance). For the superficial temperature measurement, a FLIR E75 camera was used to capture the infrared images. When the internal temperature of the chamber stabilized at 50 °C, an infrared thermal image was collected from each side of the composite. Thermal properties were analysed: thermal conductivity, resistivity, resistance, and transmittance. Based on the results, sugar cane cement composites were characterized by higher values of thermal conductivity. Related to thermal resistivity, thermal resistance, and thermal transmittance, only the coconut panel presented similar behaviour to the commercial gypsum board. Thus, cement composite using coconut can be a potential alternative that might solve energy and environmental concerns simultaneously.

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水泥复合材料红外热成像热性能比较。

利用农业企业剩余木质纤维素纤维是开发木质纤维素复合材料的一个很好的选择。目前的工作旨在研究水泥基复合材料与木质纤维素材料的热性能:桉树、甘蔗渣、椰子纤维，与商业石膏板进行比较，使用红外热图像作为建筑物的内部分区。每种木质纤维素材料重复三次，使用三块商业石膏板。在板材的生产中，采用以下参数:材料与水泥的比例为1:2.75;水灰比1:25 .5;水化率0.25;添加剂，4%(基于水泥质量)。计算是在标称面板密度为1200 kg m3时进行的。热分析是在一个由MDP(中密度刨花板)组成的室中进行的，内层是岩棉和热源(热阻)。表面温度测量采用FLIR E75相机进行红外图像采集。当腔室内部温度稳定在50℃时，从复合材料的每侧采集红外热像。热性能分析:导热系数，电阻率，电阻率和透光率。结果表明，甘蔗水泥复合材料具有较高的导热系数。在热电阻率、热阻和热透射率方面，只有椰子板表现出与商业石膏板相似的行为。因此，使用椰子的水泥复合材料可能是一种潜在的替代品，可以同时解决能源和环境问题。

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

Agronomy research Agricultural and Biological Sciences-Agronomy and Crop Science

CiteScore

2.10

自引率

0.00%

发文量

审稿时长

7 weeks

期刊介绍： Agronomy Research is a peer-reviewed international Journal intended for publication of broad-spectrum original articles, reviews and short communications on actual problems of modern biosystems engineering including crop and animal science, genetics, economics, farm- and production engineering, environmental aspects, agro-ecology, renewable energy and bioenergy etc. in the temperate regions of the world.