Case study on thermal management of planar elements with various polymeric heat exchangers: experiment and simulation
Research output: Contribution to journal › Article › Research › peer-review
Authors
Organisational units
External Organisational units
- Brno University of Technology
- Christian-Doppler Lab for Metallurgical Applications of Magnetohydrodynamics
Abstract
A reliable battery thermal management system (BTMS) is essential to ensure proper performance, a long life span and
high electric vehicle safety. The primary objective of BTMS is to maintain the cells’ temperature in the range of 15–35 °C
while limiting the temperature spread between cells to below 5 °C. Active thermal management with polymeric hollow fib-
ers (PHFs) has been reported in a few articles, but its tremendous flexibility is mainly advantageous for cylindrical cells.
Extruded polymeric cold plate heat exchangers with rounded rectangle channels (RRCs) are proposed as a more elegant
solution for planar batteries. Heat exchangers using PHFs and RRCs were experimentally compared, with a strong focus on
minimizing the maximum temperature and temperature spread of the experimental setup while simultaneously achieving
minimal pressure drops. The system behavior with different parameters, including materials, geometry and thermophysical
properties, was further studied using properly validated CFD models.
high electric vehicle safety. The primary objective of BTMS is to maintain the cells’ temperature in the range of 15–35 °C
while limiting the temperature spread between cells to below 5 °C. Active thermal management with polymeric hollow fib-
ers (PHFs) has been reported in a few articles, but its tremendous flexibility is mainly advantageous for cylindrical cells.
Extruded polymeric cold plate heat exchangers with rounded rectangle channels (RRCs) are proposed as a more elegant
solution for planar batteries. Heat exchangers using PHFs and RRCs were experimentally compared, with a strong focus on
minimizing the maximum temperature and temperature spread of the experimental setup while simultaneously achieving
minimal pressure drops. The system behavior with different parameters, including materials, geometry and thermophysical
properties, was further studied using properly validated CFD models.
Details
| Original language | English |
|---|---|
| Pages (from-to) | 5229-5238 |
| Number of pages | 10 |
| Journal | Journal of Thermal Analysis and Calorimetry |
| Volume | 149.2024 |
| Issue number | June |
| DOIs | |
| Publication status | Published - 2 May 2024 |
