Thermal Model of a Traction Inverter for an Automotive Application, Including DC-Link Capacitor, Power Modules and Electrical Connections Porsche AG

Format:

Book

Conference/Event

Author/Creator:

Blaschke, Wolfgang Maximilian, author.

Contributor:

Kulzer, André Casal

Mengoni, Leonard

Pflüger, Robin

Conference Name:

2025 Sustainable Energy & Powertrains (2025-11-25 : Stuttgart, Germany)

Language:

English

Physical Description:

1 online resource cm

Place of Publication:

Warrendale, PA SAE International 2025

Summary:

In automotive applications a power electronic converter is used for energy conversion between battery and electrical machine. For high performance drives a lightweight design is demanded. Additionally, a higher efficiency of the inverter results in lower cooling requirements but is often achieved by increasing component weight. Hence, thermal modeling of the components and their interactions is essential to determine the best compromise between weight, efficiency and cooling requirements. In traction inverters the DC-link capacitors, power modules, high voltage electrical connections and low voltage devices dissipate power. In this paper the focus is on the thermal modeling of the DC-link capacitor, power modules and high voltage electrical connections and their system, as the performance of the inverter is defined by these components. The thermal models are derived based on physical properties and geometries. First, the DC-link capacitor thermal model is presented and considers the anisotropic heat conductivity of the capacitor coil and the inhomogeneous loss feeding in the busbars. Next, the thermal model of a power module and heatsink is explained taking temperature dependent material properties into account. Based on the input temperature of the coolant and heat dissipation of the power modules the temperature rise of the fluid is calculated. Furthermore, the electrical connections, consisting of a combination of cables, busbars and shunts are thermally modeled. With the individual component models combined an overall inverter thermal model is developed. A comparison between the thermal system model and measurements is carried out finally. For this several temperature sensors were integrated into an inverter. By taking the measured temperatures into account, the thermal system model is validated for stationary and dynamic load points. As all models are based on geometric and material properties it is possible to observe the impact of sizing in the future

Notes:

Vendor supplied data

Publisher Number:

2025-01-0519

Access Restriction:

Restricted for use by site license