The objective of this investigation was to develop micro/nano-scale temperature sensors for measuring surface temperature transients in multi-phase flows and heat transfer. Surface temperature fluctuations were measured on substrates exposed to phase change processes. Prior reports in the literature indicate that these miniature scale surface temperature fluctuations can result in 60-90 percent of the total heat flux during phase change heat transfer. In this study, DTS (Diode Temperature Sensors) were fabricated with a doping depth of ~100 nm on n-type silicon to measure the surface temperature transients on a substrate exposed to droplet impingement cooling. DTS are expected to have better sensor characteristics compared to TFTs (Thin Film Thermocouples), due to their small size and faster response (which comes at the expense of the smaller operating temperature range). Additional advantages of DTS include the availability of robust commercial micro fabrication processes (with diode and transistor node sizes currently in the size range of ~ 30 nm), and that only 2N wire leads can be used to interrogate a set of N x N array of sensors (in contrast thermocouples require 2 N x N wire leads for N x N sensor array). The DTS array was fabricated using conventional semi-conductor processes. The temperature response of the TFT and DTS was also calibrated using NIST standards. Transient temperature response of the DTS was recorded using droplet impingement cooling experiments. The droplet impingement cooling experiments were performed for two different test fluids (acetone and ethanol). An infrared camera was used to verify the surface temperature of the substrate and compare these measurements with the temperature values recorded by individual DTS. PVD (Physical Vapor Deposition) was used for obtaining the catalyst coatings for subsequent CNT synthesis using CVD (Chemical Vapor Deposition) as well as for fabricating the thin film thermocouple (TFT) arrays using the "lift-off" process. Flow boiling experiments were conducted for three different substrates. Flow boiling experiments on bare silicon wafer surface were treated as the control experiment, and the results were compared with that of CNT (Carbon Nano-Tube) coated silicon wafer surfaces. Similar experiments were also performed on a pure copper surface. In addition, experiments were performed using compact condensers. Micro-scale patterns fabricated on the refrigerant side of the compact heat exchanger were observed to cause significant enhancement of the condensation heat transfer coefficient.
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机译:这项研究的目的是开发微型/纳米级温度传感器,用于测量多相流和热传递中的表面温度瞬变。在暴露于相变过程的基板上测量表面温度波动。文献中的先前报道表明,这些微小尺度的表面温度波动可导致相变传热期间总热通量的60-90%。在这项研究中,DTS(二极管温度传感器)在n型硅上的掺杂深度约为100 nm,以测量暴露于液滴撞击冷却的基板上的表面温度瞬变。与DTS(薄膜热电偶)相比,由于DTS尺寸小,响应速度快(以较小的工作温度范围为代价),因此DTS有望具有更好的传感器特性。 DTS的其他优点包括可使用强大的商用微制造工艺(目前二极管和晶体管的节点尺寸约为30 nm),并且仅2N导线可用于查询一组N x N阵列。传感器(相反,热电偶需要2 N x N条导线才能安装N x N传感器阵列)。 DTS阵列是使用常规半导体工艺制造的。 TFT和DTS的温度响应也使用NIST标准进行了校准。使用液滴撞击冷却实验记录DTS的瞬态温度响应。针对两种不同的测试液(丙酮和乙醇)进行了液滴撞击冷却实验。使用红外热像仪来验证基材的表面温度,并将这些测量值与各个DTS记录的温度值进行比较。 PVD(物理气相沉积)用于获得催化剂涂层,以用于随后使用CVD(化学气相沉积)进行CNT合成以及使用“剥离”工艺制造薄膜热电偶(TFT)阵列。针对三种不同的基材进行了沸腾实验。将在裸硅晶片表面上的流动沸腾实验作为对照实验,并将结果与CNT(碳纳米管)涂覆的硅晶片表面的沸腾实验进行比较。在纯铜表面上也进行了类似的实验。另外,使用紧凑型冷凝器进行了实验。观察到在紧凑型热交换器的制冷剂侧制造的微细图案使凝结传热系数显着提高。
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