Design of nanofluid-cooled heat sink using topology optimization

The paper presented topology optimization of 2D and 3D Nanofluid-Cooled Heat Sink (NCHS). The flow and heat transfer problem in the NCHS was treated as a single-phase nanofluid based convective heat transfer model. The temperature-dependent fluid properties were taken into account in the model due to the strong temperature-dependent features of nanofluids. An average temperature minimum problem was studied subject to the fluid area and energy dissipation constraints by using the density method. In the method, the design variable is updated according to the gradient information obtained by an adjoint based sensitivity analysis process. The effects of the energy dissipation constraint, temperature-dependent fluid properties and nanofluid characteristics on optimal configurations of NCHS were numerically investigated with following conclusions. Firstly, branched flow channels in the optimal configuration increased with the rise of the allowed energy dissipation. Secondly, temperature-dependent fluid properties were significant for obtaining the appropriate optimal results with best cooling performance. Thirdly, heat transfer performances of optimal configurations were enhanced by reducing the nanoparticle diameter or increasing the nanoparticle volume fraction. Fourthly, the optimal configuration for nanofluid had better cooling performance than that for its base fluid.     

高能合成煤油GN-1性能研究 --“液体火箭推进”专刊

结合火箭发动机工程应用环境，研究了GN-1煤油高温高压热物性、安全特性、传热结焦性能以及点火延迟性能，并和现役火箭煤油作了对比分析。采用商业仪器对GN-1煤油在最高200℃、最高压力25MPa范围内的密度、黏度、定压比热容、导热系数、表面张力进行了实验测量。在实验数据的基础上，依据基团贡献法、基于比容平移法则的P-R方程、摩擦理论、广义对应态原理分别对GN-1煤油在最高350℃、最高压力60MPa范围内的密度、黏度、定压比热容、导热系数、表面张力进行了理论计算，建立了GN-1煤油的密度方程、黏度方程、导热系数方程，并将方程的计算值与实验值进行了对比，计算偏差较小。对GN-1煤油和火箭煤油的安全性能进行对比研究，GN-1煤油的闪点为40℃，自燃温度为305℃，高于火箭煤油(225℃)；燃点为47℃，低于火箭煤油(82℃)，GN-1煤油的爆炸极限范围为0.44%-2.9%（40℃）。GN-1煤油和火箭煤油的急性经口毒性LD50＞5000mg/kg，均属于第五级化合物（实际无毒）。在入口压力10 MPa，流速10 m·s-1，内壁温480℃条件下，GN-1煤油的传热系数比火箭煤油提高14.4%，建立了传热准则方程。GN-1煤油出口油温220℃时试验段平均结焦速率是出口油温150℃时的4.43倍，GN-1煤油不锈钢材质管路中试验段平均结焦为高合管材质管路中的22.3%。在970K-1105K温度范围内，GN-1煤油的点火延迟时间为320μs-471μs，是火箭煤油的55.6%-69.3%。相关研究可对发动机可靠设计及应用提供重要参考。     

高热流密度燃烧室壁面阵列空气射流-燃油组合冷却结构研究（爆震专刊）

针对高热流密度燃烧室壁面热防护需求提出了一种空气阵列射流冲击和燃油冷却肋板的集成冷却方式,在射流平均雷诺数(Re_j)为10000至30000、燃油进口流速(v_f)为2.33m/s至5.23m/s的范围内,采用数值模拟方法对其传热特性进行了研究,并基于壁面加热侧当量对流换热系数的概念,分析了基准肋板以及燃油冷却肋板的传热增强作用。与无肋板靶面的阵列射流冲击相比,带肋板阵列射流冲击的面积平均当量对流换热系数是前者的1.6倍,压力损失系数相对提高了约25%；采用燃油冷却肋板,加热壁面综合传热能力进一步增强,在Re_j=10000时,采用燃油冷却肋板的面积平均当量对流换热系数是基准肋板的1.5倍以上,即使在Re_j=30000时,燃油冷却肋板的传热增强比也可以达到1.2；燃油冷却肋板的出口温度相对进口温度的提升在20K~50K范围内,其提升幅度随着射流雷诺数或燃油进口流速的增大而减小。     

A swept fin-induced flow field with different height mounting gaps

In order to apply the air fin successfully and ensure the maneuverability of hypersonic vehicle, a key problem to be studied urgently is the heat flux brought by the fin mounting gap. The appearance of mounting gap and fin shaft can induce many complex flow structures which need more attentions to be investigated. Under Ma 6, Nano-tracer-based Planar Laser Scattering (NPLS) and Temperature Sensitive Paints (TSP) were applied to visualize and measure transient flow structures and heat flux distribution of a swept fin-induced flow field with different height mounting gaps. Complementarily, Reynolds-averaged N-S equations were solved with k-ω SST turbulent model. The heat flux distribution results of numerical simulation and TSP observed the change of high heat flux region with different mounting gap, both in position and magnitude. The streamlines based on Computational Fluid Dynamics (CFD) and flow visualization results obtained by NPLS revealed the cause of high heat flux region. The high heat flux region in this flow field is mainly related to the reattachment of vortex and flow stagnation. The increase of gap height can lead to stronger gap overflow and shaft-induced horseshoe vortex, which are source of the high heat flux around the fin. The case with the highest mounting gap (4 mm) en-counters the most severe aerodynamic heating, both on the surface of fin and plate. Thus, under the premise of ensuring the flexibility of the fin, the gap should be set as small as possible.     

散射对高温气体-碳黑颗粒混合物辐射传输的影响

基于全光谱k分布(Full spectrum k distribution,FSK)模型、MIE理论和有限体积法(Finite volume method,FVM),构建了均温、均质辐射参与性气体-碳黑颗粒混合物介质热辐射传输模型,并分析了碳黑不同尺寸、不同体积浓度以及介质不同路径长度和不同温度条件下,因忽略碳黑颗粒散射所导致的介质热辐射传输特性(如辐射热流、辐射源项)的计算误差。研究结果表明:体积分数不变,增大粒径,计算误差呈现出先增大后减小的趋势;数密度不变,增大粒径,或者粒径不变,增大体积分数,均将使得计算误差相应增大;粒径、体积分数不变,增大路径长度,或者升高介质温度,均将增大计算误差。通常对于含有大颗粒、高碳黑浓度的辐射参与性气体-碳黑颗粒混合物介质,碳黑颗粒散射不能忽略。     

一种运载火箭用大功率电动伺服驱动器的散热设计

散热对电子设备的性能有着直接的影响，散热器广泛应用于电子产品的热设计用于改善其散热能力，因此散热器应作为关键部件进行设计。针对航天领域使用的大功率电动伺服驱动器的散热问题，提出了通过热力学理论计算指导散热器结构设计的方法。首先通过理论计算结果确定散热器的结构尺寸，然后通过PRO/E三维建模软件对散热器进行建模并利用ANYSY ICEPAK热仿真软件对所设计的散热器进行热仿真，最后搭建了伺服驱动器的热试验环境。仿真结果和试验数据均验证了该设计方法的正确性。     

基于视频的行人再识别

行人再识别是指在无交叉区域的多摄像机视频监控系统中,匹配不同摄像机中的相同行人目标。本文提出了一种基于视频的行人再识别方法,用HOG3D来描述一组视频的时空特征,在训练集上用预训练的DenseNet来微调模型参数,利用迁移学习得到的模型来提取视频中行人的表观特征,融合两种特征来描述视频序列中的行人。最后将融合的高维特征降维,并用度量学习方法计算行人对之间的距离。本文在PRID 2011和iLIDS-VID这两个视频数据集上进行了使用,实验结果表明本文的方法取得了较高的累积匹配得分。     

基于有限Fourier级数的航天器转移轨迹设计

针对航天器小推力转移轨迹的初始设计问题，利用基于三阶Fourier级数的设计方法实现了航天器小推力的多圈转移。同时，基于有限Fourier级数的形状法，对具有多个约束条件的小推力多圈转移轨迹进行了优化设计。选取了共面同轴同偏心率的初始和末端轨道位置，对所提出的方法进行了仿真验证。结果表明：与改进逆五阶多项式形状法相比，所提出的方法虽然增加了转移时间，但当转移圈数为5圈、有限Fourier级数的项数为10时，可减少将近75%的转移速度增量，同时大大减小了所需的最大推力加速度的值。     

R141b在圆形微通道内的沸腾换热实验研究

为提高换热强度、解决设备内部高热流密度散热问题,采用实验方法研究R141b在不同直径(D=0.5mm和1.0mm)水平圆形微通道内的沸腾换热特性,分析了热流密度(q=2.0kW/m~2～47.6kW/m~2)、质量干度(x=0～0.6)、质量流速(G=111.11kg/(m~2·s)～333.33kg/(m~2·s))的变化对平均传热系数h的影响,探究不同情况下影响沸腾换热的主导因素。实验研究表明:平均传热系数h随热流密度q的增加而减小,在不同范围内减小速率有明显差异;热流密度q=2kW/m~2～5kW/m~2时质量流速G对平均传热系数h影响较明显,热流密度较高时质量流速G对换热影响很小;在质量流速G=111.11kg/(m~2·s)～333.33kg/(m~2·s),质量干度x0.3时,平均传热系数h随质量干度x增加而明显下降,在设计微通道换热器时应尽量使R141b处于初始沸腾阶段以获得更好换热效果,并采取一定措施预防干度过高引起的换热恶化。     

Recent active thermal management technologies for the development of energy-optimized aerospace vehicles in China

Recently, the development of modern vehicles has brought about aggressive integration and miniaturization of on-board electrical and electronic devices. It will lead to exponential growth in both the overall waste heat and heat flux to be dissipated to maintain the devices within a safe temperature range. However, both the total heat sinks aboard and the cooling capacity of currently utilized thermal control strategy are severely limited, which threatens the lifetime of the on-board equipment and even the entire flight system and shrink the vehicle’s flight time and range. Facing these thermal challenges, the USA proposed the program of “INVENT” to maximize utilities of the available heat sinks and enhance the cooling ability of thermal control strategies. Following the efforts done by the USA researchers, scientists in China fought their ways to develop thermal management technologies for Chinese advanced energy-optimized airplanes and spacecraft. This paper elaborates the available on-board heat sinks and aerospace thermal management systems using both active and passive technologies not confined to the technology in China. Subsequently, active thermal management technologies in China including fuel thermal management system, environment control system, non-fuel liquid cooling strategy are reviewed. At last, space thermal control technologies used in Chinese Space Station and Chang’e-3 and to be used in Chang’e-5 are introduced. Key issues to be solved are also identified, which could facilitate the development of aerospace thermal control techniques across the world.