Wide-Beam X-Ray Source Target Thermal Management Simulation Using Inner Jet Cooling

Scholarly Research Exchange Pub Date : 2009-02-08 DOI:10.3814/2009/797068

C. Kim, J. Doster, M. Bourham

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引用次数: 2

Abstract

A wide-beam area X-ray source has been proposed as a practical replacement for synchrotron sources in clinical DEI applications. Due to a wide X-ray illumination area, a decrease in X-ray flux is expected and thus high electron beam currents up to 3A are considered. To ensure the target performance without deterioration, melting, cracking, or even evaporation, an active cooling system is required for the target block in order to remove the heat and allow for sufficient scanning time. In this study, jet cooling of the target back is investigated for a prototype proof-of-principle target. The prototype target was simulated with the transient k- ɛ turbulence multiphysics model in ANSYS CFX. The simulations were conducted at a heat flux of 1.8 × 10 7 W/ m 2 , consistent with values anticipated for a full scale target. The simulation results show that the target temperature exceeds the copper melting point in 2 seconds at inlet velocities below 2 m/s. Also, critical heat flux calculations show that a 1.5 m/s inlet velocity at atmospheric pressure is a lower limit for prevention of target burnout using water as a coolant. Inlet velocities in excess of 2 m/s allows for steady-state operation while satisfying all thermal design constraints.

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采用内喷流冷却的宽束x射线源目标热管理模拟

宽光束区域x射线源已被提出作为临床DEI应用中同步加速器源的实际替代品。由于x射线照射范围广，预计x射线通量会减少，因此考虑到高达3A的高电子束电流。为了确保目标性能不变质，不熔化，不开裂，甚至不蒸发，目标块需要一个主动冷却系统，以去除热量并允许足够的扫描时间。在本研究中，研究了一个原理验证的原型靶背部的射流冷却。在ANSYS CFX中采用瞬态k- ε湍流多物理场模型对原型目标进行了仿真。模拟的热流密度为1.8 × 10.7 W/ m2，与全尺度目标的预期值一致。仿真结果表明，在进口速度低于2 m/s时，目标温度在2秒内超过铜熔点。此外，临界热流密度计算表明，在常压下1.5 m/s的入口速度是防止使用水作为冷却剂的目标烧毁的下限。超过2米/秒的进口速度允许稳态运行，同时满足所有热设计约束。

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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