MICROWAVE RAPID HEATING SYSTEM USING CARBON HEATING TUBE

Proceedings 17th International Conference on Microwave and High Frequency Heating Pub Date : 2019-10-15 DOI:10.4995/ampere2019.2019.9756

T. Sameshima, T. Kikuchi, T. Uehara, T. Arima, M. Hasumi, Tomoyoshi Miyazaki, Go Kobayashi, I. Serizawa

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Abstract

We report a microwave heating system with a carbon heating tube (CHT) made by a 4-mm diameter quartz tube filled carbon particles and Ar gas at 1400 Pa. 2.45-GHz microwave at 200 W was introduced to a 300-dimameter metal cavity, in which 60-mm-long CHT was set at the central position. The numerical simulation with a finite element moment method resulted in the standing wave of the electric field caused by three dimensional Fresnel interference effect with low high electric field intensity ranging from from 1 to 6 kV/m because of effective absorption of microwave power by the CHT. The lowest average electrical field intensity of 5 kV/m in the cavity space was given by the electrical conductivity of carbon ranging from 10 to 55 S/m. The CHT with 55 S/m heated to 1200oC by microwave irradiation at 200 W. This heating method was applied to activate 1.0x1015-cm-2 boron and phosphorus implanted regions in n-type crystalline silicon substrate to fabricate pn junction and solar cells. The CHT heating at 1200oC realized decrease in the sheet resistivity to 146 Ω/sq, decrease in the density of defect states to 1.3x1011 and 9.2x1010 cm-2 for boron (p+) and phosphorus (n+) implanted surfaces, and solar cell characteristic with a conversion efficiency of 15% under illumination of air mass 1.5 at 0.1 W/cm2.

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微波快速加热系统采用碳素加热管

本文报道了一种由直径4 mm的石英管填充碳颗粒和1400 Pa氩气制成的碳加热管(CHT)的微波加热系统。在300直径的金属腔中引入200 W的2.45 ghz微波，其中60 mm长的CHT设置在中心位置。采用有限元矩法进行数值模拟，得到三维菲涅耳干涉效应引起的电场驻波，由于CHT对微波功率的有效吸收，在1 ~ 6 kV/m范围内具有较低的高电场强度。碳的电导率在10 ~ 55 S/m之间，给出了空腔空间中最低的平均电场强度为5 kV/m。55s /m的CHT通过200w微波辐射加热至1200oC。利用该加热方法激活了n型晶体硅衬底中1.0 × 1015 cm-2的硼磷注入区，制备了pn结和太阳能电池。在1200oC的CHT加热下，硼(p+)和磷(n+)注入表面的电阻率降至146 Ω/sq，缺陷态密度降至1.3x1011和9.2x1010 cm-2，在0.1 W/cm2的空气质量1.5照射下，太阳能电池的转换效率达到15%。

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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Proceedings 17th International Conference on Microwave and High Frequency Heating

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