DESIGN OF THERMAL CONDUCTING EQUIPMENT

JURUTERA - Jurnal Umum Teknik Terapan Pub Date : 2022-12-30 DOI:10.55377/jurutera.v9i02.6833

Iskandar, Parlindungan Lumban Batu, Nazaruddin Abdul Rahman, Syamsul Bahri Widodo

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Abstract

This research presents the design and manufacture of thermal conductivity test equipment using heat transfer techniques (steady state) with the ability to test materials at high temperatures. The design of this test equipment is an extension of the ASTM D5470-06 standard, where the same is used to calculate the surface temperature and heat transfer through the sample during the test, where at each reference rod point, 10 K-type thermocouples are embedded. The maximum heater power required by the reference rod with a heating time of 1 hour is 30.4 KW. This test tool uses 3 pieces of 500-Watt power, and Thermoelectric TEC1-12706 12 Volt 6 Ampere 40x40 mm, Heatsink, 12 Volt DC Fan 0.15Ampere 38x38 mm, to keep the test at a steady state. And the use of Thermal Paste to minimize thermal contact resistance. From the calculations, it can be seen that the faster the time needed to heat the reference rod will require greater heater power, and vice versa. For high temperatures, this tool can reach a test temperature of 100 ℃. This research was conducted to measure the thermal conductivity of stainless steel, iron, wood, rubber, and Styrofoam. After the measurement, the thermal conductivity of stainless steel was 15.14037 W / mK Reference 14.00 W / mK, iron 41.07 W / mK Reference 79.5 W / mK, wood 1.54 W / mK Reference 0.21 W / mK, rubber 0.6 Reference 0.2 W / mK, Styrofoam 0.062 W / mK Reference 0.095 W / mK. Thus, further research is needed on the method of measuring the thermal conductivity of metals by transient means.

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导热设备的设计

本研究介绍了利用传热技术(稳态)设计和制造导热测试设备，该设备具有在高温下测试材料的能力。该测试设备的设计是ASTM D5470-06标准的延伸，该标准用于计算测试过程中样品的表面温度和传热，其中在每个参考棒点，嵌入10个k型热电偶。参考杆加热1小时所需的最大加热功率为30.4 KW。本测试工具使用3块500w电源，热电TEC1-12706 12伏6安培40x40mm，散热器，12伏直流风扇0.15安培38x38mm，以保持测试处于稳定状态。并使用导热膏，尽量减少热接触阻力。从计算中可以看出，加热参考棒所需的时间越快，则需要更大的加热器功率，反之亦然。对于高温，该工具可达到100℃的测试温度。本研究的目的是测量不锈钢、铁、木材、橡胶和聚苯乙烯泡沫塑料的导热系数。测量后，不锈钢的导热系数为15.14037 W / mK(参考14.00 W / mK)，铁为41.07 W / mK(参考79.5 W / mK)，木材为1.54 W / mK(参考0.21 W / mK)，橡胶为0.6 W / mK(参考0.2 W / mK)，泡沫塑料为0.062 W / mK(参考0.095 W / mK)。因此，暂态方法测量金属导热系数的方法有待进一步研究。

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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JURUTERA - Jurnal Umum Teknik Terapan

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