Modern developments in microelectronics manufacturing and architecture continue to lead to reductions in feature sizes on microprocessor chips. The demand for faster and more powerful systems has approached the limits of conventional passive and active electronics cooling schemes. Future high-powered electronics require new and innovative heat removal methods. The research study presented in this paper is conducted in order to better understand two-phase heat transfer in a microchannel heat sink using FC-72 as the test fluid. The test section consists of an (1cm × 1cm) array of nineteen parallel microchannels etched into silicon with the following dimensions: hydraulic diameter (D{sub}h = 253 microns) with a ratio of (L/D{sub}h = 39.52). The base of each channel contains six re-entrant type cavities spaced evenly along the length. Each cavity, measuring 20 microns in mouth size, is used to promote controlled nucleation activity. The experimental results presented include the bulk fluid temperature and pressure at the inlet and outlet. To simulate the heat generated by a typical microprocessor, a uniform heat flux was applied to the base of the channel array using a series of thin film serpentine aluminum heaters. System parameters that were varied in this study include the applied heat flux and mass flow rate.
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机译:微电子制造和建筑的现代发展继续导致微处理器芯片上的特色尺寸减少。对更快和更强大的系统的需求已经接近了传统被动和主动电子冷却方案的限制。未来的高功率电子设备需要新的和创新的散热方法。本文提出的研究研究是为了更好地了解使用Fc-72作为测试流体的微通道散热器中的两相热传递。测试部分由蚀刻成硅的(1cm×1cm)阵列,其具有以下尺寸:液压直径(d {sub} h = 253微米),其比率(l / d {sub} h = 39.52 )。每个通道的底座包含沿着长度均匀间隔开的六个再参赛者腔。每个腔体,尺寸为20微米,用于促进受控成核活性。呈现的实验结果包括入口和出口的体积流体温度和压力。为了模拟由典型的微处理器产生的热量,使用一系列薄膜锯齿铝加热器将均匀的热通量施加到通道阵列的底部。本研究中变化的系统参数包括施加的热通量和质量流量。
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