STAR CCM+ CFD Simulations of Enhanced Heat Transfer in High-Power Density Electronics Using Forced Air Heat Exchanger and Pumped Fluid Loop Cold Plate Fabricated from High Thermal Conductivity Materials

Anderson, Kevin R.; Devost, Matthew; Pakdee, Watit; Krishnamoorthy, Niveditha

doi:10.4236/jectc.2013.34016

Cited by 4 publications

(2 citation statements)

References 24 publications

(34 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The increasing number of channels results in a decrease of the maximum temperature (Tmax) and maximum temperature difference (ΔT) of battery packs. Anderson, Devost, Pakdee, and Krishnamoorthy [35] also studied heat transfer and fluid flow simulation of a novel heat exchanger/cold plate fabricated from k-core high thermal conductivity material in order to realize the thermal control system hardware design for applications to very large power density (∼1kW/m 2 ) electronics packaging scenarios. In another study, Ye et al [5] proposed an optimized heat pipe thermal management system (HPTMS) for fast-charging lithium-ion battery cell/pack.…”

Section: Introductionmentioning

confidence: 99%

Numerical modeling and experimental investigation of a prismatic battery subjected to water cooling

Panchal

Khasow

Dinçer

et al. 2017

Numerical Heat Transfer, Part A: Applications

View full text Add to dashboard Cite

In this paper, a numerical model using ANSYS Fluent for a minichannel cold plate is developed for water-cooled LiFePO 4 battery. The temperature and velocity distributions are investigated using experimental and computational approach at different C-rates and boundary conditions (BCs). In this regard, a battery thermal management system (BTMS) with water cooling is designed and developed for a pouch-type LiFePO 4 battery using dual cold plates placed one on top and the other at the bottom of a battery. For these tasks, the battery is discharged at high discharge rates of 3C (60 A) and 4C (80 A) and with various BCs of 5°C, 15°C, and 25°C with water cooling in order to provide quantitative data regarding the thermal behavior of lithium-ion batteries. Computationally, a high-fidelity computational fluid dynamics (CFD) model was also developed for a minichannel cold plate, and the simulated data are then validated with the experimental data for temperature profiles. The present results show that increased discharge rates (between 3C and 4C) and increased operating temperature or bath temperature (between 5°C, 15°C, and 25°C) result in increased temperature at cold plates as experimentally measured. Furthermore, the sensors nearest the electrodes (anode and cathode) measured the higher temperatures than the sensors located at the center of the battery surface.

show abstract

Section: Introductionmentioning

confidence: 99%

Numerical modeling and experimental investigation of a prismatic battery subjected to water cooling

Panchal

Khasow

Dinçer

et al. 2017

Numerical Heat Transfer, Part A: Applications

View full text Add to dashboard Cite

show abstract

“…These problems play a key role in the design and optimization process of products, whose operation needs to consider thermal limitations (e.g., supersonic aerodynamics problems [1]), the stability of thermal processes, the thermal stress level, thermal effectiveness, etc. The importance of such numerical solution problems is primarily determined by the necessity of the spatial and time distribution of temperatures, as well as in spotting problem areas when simulating emergency situations in the designed structures for which a natural experiment is often impossible or entails considerable financial expenses [2][3][4].…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulation of the Conjugate Heat Transfer of a “Fluid–Solid Body” System on an Unmatched Grid Interface

Korotkov,

Kozelkov,

Kurkin

et al. 2023

Fluids

View full text Add to dashboard Cite

Recently, when modeling transient problems of conjugate heat transfer, the independent construction of grid models for fluid and solid subdomains is increasingly being used. Such grid models, as a rule, are unmatched and require the development of special grid interfaces that match the heat fluxes at the interface. Currently, the most common sequential approach to modeling problems of conjugate heat transfer requires the iterative matching of boundary conditions, which can significantly slow down the process of the convergence of the solution in the case of modeling transient problems with fast processes. The present study is devoted to the development of a direct method for solving conjugate heat transfer problems on grid models consisting of inconsistent grid fragments on adjacent boundaries in which, in the general case, the number and location of nodes do not coincide. A conservative method for the discretization of the heat transfer equation by the direct method in the region of inconsistent interface boundaries between liquid and solid bodies is proposed. The proposed method for matching heat fluxes at mismatched boundaries is based on the principle of forming matched virtual boundaries, proposed in the GGI (General Grid Interface) method. A description of a numerical scheme is presented, which takes into account the different scales of cells and the sharply different thermophysical properties at the interface between liquid and solid media. An algorithm for constructing a conjugate matrix, the form of matrix coefficients responsible for conjugate heat transfer, and methods for calculating them are described. The operability of the presented method is demonstrated by the example of calculating conjugate heat transfer problems, the grid models of which consist of inconsistent grid fragments. The use of the direct conjugation method makes it possible to effectively solve both stationary and non-stationary problems using inconsistent meshes, without the need to modify them in the conjugation region within a single CFD solver.

show abstract

Novel CFD approach for the thermal analysis of a continuous variable transmission (CVT)

Wurm

Fitl²,

Gumpesberger³

et al. 2016

Applied Thermal Engineering

View full text Add to dashboard Cite

STAR CCM+ CFD Simulations of Enhanced Heat Transfer in High-Power Density Electronics Using Forced Air Heat Exchanger and Pumped Fluid Loop Cold Plate Fabricated from High Thermal Conductivity Materials

Cited by 4 publications

References 24 publications

Numerical modeling and experimental investigation of a prismatic battery subjected to water cooling

Numerical modeling and experimental investigation of a prismatic battery subjected to water cooling

Numerical Simulation of the Conjugate Heat Transfer of a “Fluid–Solid Body” System on an Unmatched Grid Interface

Novel CFD approach for the thermal analysis of a continuous variable transmission (CVT)

Contact Info

Product

Resources

About