直流接地极及杆塔接地网附近电磁场的有限元分析

高压直流输电系统处于单极大地回线运行方式时,有很大的直流电流通过直流接地极流入大地,这将造成接地极本身及附近输电杆塔接地网的腐蚀。在理论分析接地极和杆塔接地网电磁场的基础上,应用有限元分析软件COMSOL Multiphysics,以德宝直流输电工程千阳接地极为例,建立了多层大地土壤结构下的直流接地极和杆塔接地网数值模型,添加相关边界条件,进行网格划分处理,计算分析了接地极地表电位分布规律,并对杆塔接地网附近电位及泄漏电流密度进行了研究,结果发现:接地极地表电位沿径向距离逐渐降低;杆塔接地网本体上的电位最高,接地网的射线末端泄漏电流密度最大, 射线首端的泄漏电流密度最小,接地网矩形与射线的连接处电流密度有突变。该研究对掌握直流接地极及杆塔接地网周围电场分布情况和腐蚀规律,具有重要的意义。     

软脆铌酸锂晶体磨削的实验仿真研究

针对铌酸锂晶片在磨削加工时经常发生断裂的问题,对晶片断裂的原因进行了理论分析,并从晶体学的角度分析发现断裂与实验采用的晶片晶体结构有关。提出了基于多物理场耦合软件COMSOL Multiphysics对铌酸锂晶片磨削加工仿真的方法,为模拟铌酸锂晶片磨削减薄过程,对比分析了7种不同厚度的铌酸锂晶片在磨削加工时的应力分布和变形情况,对有外加电载荷磨削加工情况也进行了耦合仿真。研究结果表明,未施加电场时铌酸锂晶片的变形量随着晶片减薄过程逐渐减小,当铌酸锂晶片减薄至80μm时,晶片的外围出现均匀分布的4个应力集中位置,容易导致晶片产生裂纹甚至破裂;铌酸锂晶片变形量因外加电载荷而减小,因此合理施加外电场能够有效减弱晶片的应力集中趋势。     

A critical analysis of the performance of plate- and point-electrodes for determination of electrical properties of the soil mass

In the recent past, researchers have started utilizing electrical properties of the soil mass for its characterization by employing either plate- or point electrodes. Though, plate-electrodes are easy to use for laboratory experiments, and quantification of geometrical characteristics of the electric field generated within them is easy to quantify, their application for in-situ experiments and for samples of cylindrical shape becomes difficult. On the other hand, usage of point-electrodes which are cylindrical in shape, are used for moisture content determination of the soil or migration of contaminants in it, for coarse-grained soils and fine-grained soils might yield erroneous results, due to the presence of inter particle voids and presence of cavities & anomalies, respectively. Furthermore, quantification of geometrical parameters of the electric field of point-electrodes is quite difficult which results erroneous measurements in determination of electrical properties of the material, in which they are installed. Hence, establishment of the uniqueness of electrical properties obtained from the plate- and point-electrodes, for identical samples becomes utmost important. With this in view, COMSOL Multiphysics® was employed to simulate the electrical response of various geomaterials in their uncontaminated and contaminated states and results were critically evaluated vis-à-vis those obtained from the impedance analysis (1 Hz to 40 MHz). Efforts have also been made to relate the geometrical dimensions of electrodes and electric field generated across the point electrodes, which would facilitate proper design and installation of sensors in a material to achieve the desired output. This study demonstrates the suitability and versatility of the point-electrodes for various (field and laboratory) applications where in moisture profiling and contaminant transport is to be established.     

Multiphysics phase-field modeling of quasi-static cracking in urania ceramic nuclear fuel

This work presents phase-field modeling of quasi-static cracking in urania (UO₂) ceramic nuclear fuel under neutron radiation at high temperatures. Considering the tightly coupled multi-physics processes within the fuel during reactor power operation, a diffusion model including Fickian and Soret effects is used to describe the oxygen hyper-stoichiometry (x in UO_2+x), and the temperature field is given by a thermal model involving non-uniform fission-generated heat source and heat flow across fuel pellet, pellet-cladding gap and cladding to the outside heat sink. Both temperature and irradiation effects are taken into account for the basic thermo-mechanical properties and irradiation behaviors of the nuclear fuel. Especially, the acceleration of fuel thermal creep by oxygen hyper-stoichiometry is included. The fracture due to the above physical processes is approximated by a scalar phase-field variable based upon a cohesive phase-field fracture method. A granite fracture experiment is simulated to validate the thermo-fracture coupling approach. For the first time, the diffusion-thermo-mechanical-fracture coupling model is applied to UO₂ fuel pellet cracking during reactor startup, power ramp and reactor shutdown. UO₂ creep is found to play an important role on the fuel pellet fragmentation. The developed capability supports interpretation of experimental data and can guide material design of ceramic nuclear fuels.     

Investigation of thermal residual stresses during laser ablation of tantalum carbide coated graphite substrates using micro-Raman spectroscopy and COMSOL multiphysics

Laser ablation of high-temperature ceramic coatings results in thermal residual stresses due to which the coatings fail by cracking and debonding. Hence, the measurement of such residual stresses during laser ablation process holds utmost importance from the view of performance of coatings in extreme conditions. The present research aims at investigating the effect of laser parameters such as laser pulse energy, scanning speed and line spacing on thermal residual stresses induced in tantalum carbide-coated graphite substrates. Residual stresses were measured using micro-Raman spectroscopy and correlated with Raman peak shifts. Transient thermal analysis was performed using COMSOL Multiphysics to model the single ablated track and residual stresses were reported at low, moderate and high pulse energy regimes. The results showed that the initial laser conditions caused higher tensile residual stresses. Moderate pulse energy regime comprised higher compressive residual stresses due to off centre overlapping of the laser pulses. Higher pulse energy (250 μJ), higher scanning speed (1000 mm/s) and moderate line spacing (20 μm) caused accumulation of tensile residual stresses during the final stage of laser ablation. The deviation of experimental residual stresses from COMSOL numerical model was attributed to unaccounted additional stresses induced during thermal spraying process and deformation potentials in the numerical model.     

基于ADμC812的芯片温度控制系统的研究

介绍了一种以PID增量算法为核心,以812为硬件基础的温度控制系统,并给出了硬件电路和软件设计的总体结构。采用模拟软件COMSOL Multiphysics3.2分析控制对象的温度分布能够使控制结果与实际要求更为符合,满足芯片培养细胞的需要。     

Multiphysics modeling and optimization of mechatronic multibody systems

Modeling mechatronic multibody systems requires the same type of methodology as for designing and prototyping mechatronic devices: a unified and integrated engineering approach. Various formulations are currently proposed to deal with multiphysics modeling, e.g., graph theories, equational approaches, co-simulation techniques. Recent works have pointed out their relative advantages and drawbacks, depending on the application to deal with: model size, model complexity, degree of coupling, frequency range, etc. This paper is the result of a close collaboration between three laboratories, and aims at showing that for “non-academic” mechatronic applications (i.e., issuing from real industrial issues), multibody dynamics formulations can be generalized to mechatronic systems, for the model generation as well as for the numerical analysis phases. Model portability being also an important aspect of the work, they must be easily interfaced with control design and optimization programs. A global “demonstrator”, based on an industrial case, is discussed: multiphysics modeling and mathematical optimization are carried out to illustrate the consistency and the efficiency of the proposed approaches.     

Unsteady two-dimensional multiphysical simulation of a pressure tube model expanded to contact with the outer concentric tube

For the blind calculation of the International Collaborative Standard Problem (ICSP) experiment on heavy water reactor moderator subcooling requirements, the COMSOL Multiphysics code is used to simulate plastic deformation of a pressure tube (PT) as a result of the interaction of stress and temperature. It is shown that the thermal stress model of COMSOL is compatible to simulate the multiple heat transfers (including the radiation heat transfer and heat conduction) and stress strain in the simplified two-dimensional problem. The benchmark test result for radiation heat transfer is in good agreement with the analytical solution for the concentric configuration of PT and calandria tube (CT). Since the original strain model of COMSOL only considers an elastic deformation with thermal expansion coefficient, the PT/CT contact cannot be predicted in the ICSP. Therefore, the plastic deformation model by the Shewfelt and Godin, widely used in the fuel channel analysis of CANadian Deuterium Uranium (CANDU) reactor, is implemented to the strain equation of COMSOL. The heat-up of PT, the strain rate, and the contact time of the PT/CT are calculated with the boundary conditions (BCs) given for blind calculation of the ICSP experiment.

The result shows a sudden expansion of the inner concentric PT within a few milliseconds. This unsteady simulation should be helpful for the conceptual design of experiment as well as for the understanding of multiphysics inside the fuel channels of the CANDU reactor.     

弓网电弧接触线温度分布仿真研究

为了分析弓网电弧对接触网导线温升的影响,以接触线为研究对象,建立了电弧作用下弓网系统滑动摩擦副的三维有限元模型,利用COMSOL Multiphysics仿真分析,得到不同类型的接触网导线在不同环境下的温度分布特征.结果表明:相同条件下,铜镁合金、纯铜、铜锡合金接触线的温升依次升高.接触线的截面积越大温升越高.同种接触导线分别处于正常、覆冰和潮湿状态时,接触线的温升依次升高.仿真结果对选择接触线以及降低弓网电弧对接触线的热损伤具有一定参考价值.     

Simulation of microwave's heating effect on coal seam permeability enhancement

As hydraulic fracturing was forbidden in some countries due to possible negative environmental impacts and enhanced coalbed methane(ECBM) was restricted by in-situ conditions, microwave heating was proposed to enhance coalbed permeability. One of the mechanisms of improving coal permeability with microwave irradiation is that thermal expansion caused by microwave heating. To study the influence of microwave's heating effect of coal samples, the simulations were conducted using a coupled electromagnetic, thermal and mechanical model in this paper. The temperature, Von-Mises stress and strain distribution of coal sample are recorded every 10 s. The permeability distribution is also obtained based on the relationship between strain and permeability from articles. It was found that volume average temperature, stress, strain and permeability increase almost linearly with time. The average permeability increased from 1.65×10~(-16) m~2 to 3.63×10~(-16)m~2 under 2.45 GHz and 500W microwave radiation after 300s. The significant increase proved microwave to be effective in coal seam permeability enhancement.