Thermal Simulation Approach to the Cooling of a Power IGBT by Heat Pipe Systems

Q1 Mathematics International Review on Modelling and Simulations Pub Date : 2013-04-30 DOI:10.15866/IREMOS.V6I2.2442

Driss Améni, Maalej Samah, Z. Chaker

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Abstract

In this work, we have developed a model in order to simulate the cooling of a power IGBT by heat pipe systems. The IGBT is modeled by RC thermal circuit approach on the basis on its thermal characteristics that are delivered by the manufacturer. The heat pipe is also modeled by RC thermal circuit. The thermal resistances and capacitances of the heat pipe model are determined both by experiments and theoretical calculations. The model aims to determine the junction temperature of the IGBT as well as the heat pipe temperatures in response to a periodic heat input power as a function of different parameters such as the cyclic ratio and the witching frequency. The simulations results indicate that for, a given switching frequency, the cyclic ratio affects the junction temperature which oscillates between a minimum value and a maximum one. Indeed, the maximum as well as the minimum junction temperatures increase with increasing cyclic ratio. For a given cyclic ratio, the junction temperature is also affected by the switching frequency. The maximum junction temperature decreases as the switching frequency increases, however, the minimum junction temperature increases with increasing switching frequency. In all cases, the junction temperature values remain less than the maximum temperature allowed for the safety operation of the IGBT.

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热管冷却大功率IGBT的热模拟方法

在这项工作中，我们建立了一个模型来模拟热管系统对功率IGBT的冷却。根据制造商提供的IGBT的热特性，采用RC热电路方法对其进行建模。用RC热电路对热管进行了建模。通过实验和理论计算确定了热管模型的热阻和热容。该模型旨在确定IGBT的结温以及热管温度对周期性热输入功率的响应，并将其作为不同参数(如循环比和开关频率)的函数。仿真结果表明，对于给定的开关频率，循环比影响结温，结温在最小值和最大值之间振荡。实际上，结温的最大值和最小值都随循环比的增加而增加。对于给定的循环比，结温也受开关频率的影响。最高结温随开关频率的增加而降低，最低结温随开关频率的增加而升高。在所有情况下，结温值保持小于IGBT安全运行所允许的最高温度。

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来源期刊

International Review on Modelling and Simulations Engineering-Mechanical Engineering

CiteScore

2.80

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0.00%

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期刊介绍： The International Review on Modelling and Simulations (IREMOS) is a peer-reviewed journal that publishes original theoretical and applied papers concerning Modelling, Numerical studies, Algorithms and Simulations in all the engineering fields. The topics to be covered include, but are not limited to: theoretical aspects of modelling and simulation, methods and algorithms for design control and validation of systems, tools for high performance computing simulation. The applied papers can deal with Modelling, Numerical studies, Algorithms and Simulations regarding all the engineering fields; particularly about the electrical engineering (power system, power electronics, automotive applications, power devices, energy conversion, electrical machines, lighting systems and so on), the mechanical engineering (kinematics and dynamics of rigid bodies, vehicle system dynamics, theory of machines and mechanisms, vibration and balancing of machine parts, stability of mechanical systems, computational mechanics, mechanics of materials and structures, plasticity, hydromechanics, aerodynamics, aeroelasticity, biomechanics, geomechanics, thermodynamics, heat transfer, refrigeration, fluid mechanics, micromechanics, nanomechanics, robotics, mechatronics, combustion theory, turbomachinery, manufacturing processes and so on), the chemical engineering (chemical reaction engineering, environmental chemical engineering, materials synthesis and processing and so on). IREMOS also publishes letters to the Editor and research notes which discuss new research, or research in progress in any of the above thematic areas.