A numerical analysis on multi-stage Tesla valve based cold plate for cooling of pouch type Li-ion batteries

•Liquid cooling of pouch type li-ion batteries with multi-stage Tesla valve proposed•Channel geometry, coolant properties optimized numerically from COMSOL simulation•Forward and reverse flow configuration across the multi-stage Tesla valve explored•An enhanced heat transfer in the reverse flow obse...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2021-10, Vol.177, p.121560, Article 121560
Main Authors: Monika, K., Chakraborty, Chanchal, Roy, Sounak, Sujith, R., Datta, Santanu Prasad
Format: Article
Language:English
Subjects:
Battery thermal management
Computational fluid dynamics
Configurations
Cooling
Diodicity
Electric vehicles
Heat flux
Liquid cooling
Lithium
Lithium-ion batteries
Maximum temperature
Microfluidics
Mini-channel cold plate
Multi-stage Tesla valve
Numerical analysis
Operating temperature
Pressure drop
Rechargeable batteries
Reversed flow
Temperature distribution
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Summary:•Liquid cooling of pouch type li-ion batteries with multi-stage Tesla valve proposed•Channel geometry, coolant properties optimized numerically from COMSOL simulation•Forward and reverse flow configuration across the multi-stage Tesla valve explored•An enhanced heat transfer in the reverse flow observed at the cost of pressure drop•Maximum cold plate temperature noted within 40°C for Re varying from 2500 to 4750 The operating temperature can significantly influence the performance, cycle life, and safety of Li-ion batteries used in electric vehicles. One of the critical factors is to assess the temperature distribution within the battery pack when operated under extreme conditions and choosing an appropriate cooling method. Concerning this, a liquid cooling plate comprising Tesla valve configuration with high recognition in microfluidic applications is proposed to provide a safer temperature range for pouch type Li-ion batteries. A multi-stage Tesla valve with forward and reverse flow configuration is designed and analysed to improve a conventional rectangular channel's intrinsic temperature gradient issues for turbulent flow conditions. Moreover, the influence of various parameters such as channel number, the distance between two consecutive valves, coolant temperature, and heat flux applied on the cold plate's top and bottom surfaces are numerically investigated for varying Reynold's number using COMSOL Multiphysics software. An enhancement in heat transfer with the reverse flow in multi-stage Tesla valve is seen, mainly caused by flow bifurcation and mixing mechanisms, at the cost of pressure drop. A cold plate with 4 channels and valve to valve distance of 8.82 mm exhibits the most effective cooling performance.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2021.121560