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Evaluation of Temperature Gradient in Advanced Automated Directional Solidification Furnace (AADSF) by Numerical Simulation

机译：高级自动定向凝固炉（aaDsF）温度梯度的数值模拟评价

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A numerical model of heat transfer using combined conduction, radiation and convection in AADSF was used to evaluate temperature gradients in the vicinity of the crystal/melt interface for variety of hot and cold zone set point temperatures specifically for the growth of mercury cadmium telluride (MCT). Reverse usage of hot and cold zones was simulated to aid the choice of proper orientation of crystal/melt interface regarding residual acceleration vector without actual change of furnace location on board the orbiter. It appears that an additional booster heater will be extremely helpful to ensure desired temperature gradient when hot and cold zones are reversed. Further efforts are required to investigate advantages/disadvantages of symmetrical furnace design (i.e. with similar length of hot and cold zones).

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作者
Bune, A. V. ; Gillies, D. C. ; Lehoczky, S. L.;
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年度 1996
页码 1-10
总页数 10
原文格式 PDF
正文语种 eng
中图分类工业技术;
关键词
Heat transfer; Furnaces; Mercury cadmium tellurides; Melts(Crystal growth); Temperature gradients; Mathematical models; Low temperature; Directional solidification(Crystals);

机译：传热;熔炉;汞碲化镉;熔体（晶体生长）;温度梯度;数学模型;低温;定向凝固（晶体）;

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专利

1. Crystallization process control during directional solidification in a high-temperature-gradient furnace by guided ultrasonic waves and real-time signal evaluation [J] . M. Schmachtl, A. Schievenbusch, G. Zimmermann, Ultrasonics . 1998,第1a5期

机译：超声引导和实时信号评估在高温梯度炉定向凝固过程中的结晶过程控制
2. Numerical Simulation on the Suppression of Crucible Wall Constraint in Directional Solidification Furnace [J] . Sanmugavel S., Srinivasan M., Aravinth K., Silicon . 2019,第2期

机译：方向凝固炉中坩埚壁约束抑制的数值模拟
3. Simulation of the temperature distribution on the mold surface and inside casting during high-gradient directional solidification [J] . Bondarenko Yu. A., Echin A. B., Bazhenov V. E., Russian Journal of Non-Ferrous Metals . 2017,第5期

机译：高梯度方向凝固过程中模具表面和内部铸造温度分布的仿真
4. Evaluation of temperature gradient in advanced automated directional solidification furnace (AADSF) by numerical simulation [C] . Andris V. Bune, NASA Marshall Space Flight Ctr., Huntsville, Space Processing of Materials . 1996

机译：通过数值模拟评估高级自动定向凝固炉（AADSF）中的温度梯度
5. Numerical simulation of directional solidification of binary alloys with high thermal gradients. [D] . Huang, Huang-Wen. 1996

机译：高热梯度二元合金定向凝固的数值模拟。
6. Numerical Simulation and Optimization of Directional Solidification Process of Single Crystal Superalloy Casting [O] . Hang Zhang, Qingyan Xu, Baicheng Liu 2014

机译：单晶高温合金铸件定向凝固过程的数值模拟与优化
7. The Advanced Automated Directional Solidification Furnace [O] . Jeter L. B., Cole J. M., Reeves F. A., 1996

机译：先进的自动定向凝固炉

Evaluation of Temperature Gradient in Advanced Automated Directional Solidification Furnace (AADSF) by Numerical Simulation

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