Estimation and Validation of Junction Temperature of IGBT for Grid-Connected PV Applications

Mohan P. Thakre, M. Patil, Y. Mahadik
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Abstract

Recent advances in power electronics have led to increased use of electricity from renewable energy systems, such as photovoltaic (PV) as well as wind energy systems. Developments in power semiconductor technology, i.e. a wide band gap, have increased the conversion efficiency of power electronics to more than 98%, however the dependability with power electronics is becoming a major concern. Junction Temperature is the primary parameter that affects this same reliability of the IGBT. Mission profile (Solar Irradiance & Ambient Temperature) variation throughout junction temperature tends to lead to mechanical failure (Bond wire lift off, solder fatigue etc.). Therefore, in order to assess reliability, the junction temperature needs to be estimated. But the junction temperature cannot be calculated directly, it requires an indirect method of estimation and validation. The 3 kW grid connected to the PV Inverter is however discussed in this paper. PV Inverter consists of four IGW30N60H3 IGBTs from the Infmeon manufacturer. Annual mission profile data is logged in Hyderabad, India. Foster electro thermal modeling (ETM) is held out for junction temperature evaluation. Validation for the estimated junction temperature is required as estimated by indirect method. Finally, the estimated junction temperature is validated by correlation with annual solar irradiance, ambient temperature and case temperature.
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并网光伏应用中IGBT结温的估算与验证
电力电子技术的最新进展导致可再生能源系统的电力使用增加,例如光伏(PV)和风能系统。功率半导体技术的发展,即宽带隙,使电力电子设备的转换效率提高到98%以上,但是电力电子设备的可靠性正在成为一个主要问题。结温是影响IGBT可靠性的主要参数。任务剖面(太阳辐照度和环境温度)在整个结温中的变化往往会导致机械故障(键合线脱落,焊料疲劳等)。因此,为了评估可靠性,需要对结温进行估计。但结温不能直接计算,需要间接的估计和验证方法。然而,本文讨论了与光伏逆变器连接的3kw电网。光伏逆变器由4台IGW30N60H3型igbt组成。年度任务概况数据记录在印度海得拉巴。福斯特电热模型(ETM)提出了结温评估。需要对间接方法估计的结温进行验证。最后,通过与年太阳辐照度、环境温度和壳体温度的相关性验证了估算结温。
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