Sage Journals: Discover world-class research

Abstract

The heat dissipation structure was developed using a composite bionic design method. An adjoint solver optimized the shape of the heat dissipation structure to achieve a more uniform temperature and velocity distribution, addressing the heat dissipation challenges of high-performance electronic equipment. Additionally, 3D metal printing technology was employed for performance testing. This study primarily examined the effects of flow channel geometry (pressure drop), inlet flow rate, and working fluid type on the heat transfer efficiency and the uniformity of temperature and velocity distribution in microchannel heat exchangers. The pressure drop was reduced by 50.63% (from 0.079 MPa to 0.039 MPa), and the maximum temperature decreased by 7.2 K. As the inlet flow rate increased, the heat dissipation effect continued to improve. Regarding working fluid selection, the heat transfer efficiency of a calcium formate/water mixture surpassed that of ethylene glycol/water and propylene glycol/water mixtures; however, the latter two exhibit better temperature distribution uniformity. The final research findings offer an effective solution to the heat dissipation issues faced by high-performance equipment and present a novel approach to optimizing the design of microchannel heat exchangers, which holds significant reference value.

Keywords

Composite bionic design microchannel shape optimization 3D metal printing coupled analysis

Get full access to this article

View all access options for this article.

References

Walsh

Malouin

Browne

, et al. Embedded microjets for thermal management of high power-density electronic devices. IEEE Trans Components Packag Manuf Technol 2018; 9: 269–278.

Bhattacharyya

Vishwakarma

Srinivasan

, et al. Thermal performance enhancement in heat exchangers using active and passive techniques: a detailed review. J Therm Anal Calorim 2022; 147: 9229–9281.

Zhao

Wang

Negnevitsky

, et al. An up-to-date review on the design improvement and optimization of the liquid-cooling battery thermal management system for electric vehicles. Appl Therm Eng 2023; 219: 119626.

Yang

Zhu

Wang

, et al. Structure bionic design method oriented to integration of biological advantages. Struct Multidiscip Optim 2021; 64: 1017–1039.

Vijetha

Lingaraju

Satish

, et al. Fabrication of microchannel heat sink using additive manufacturing technology: A review. Proc Inst Mech Eng E 2024; 09544089241290631: 1–14.

Jing

. Numerical studies on the hydraulic and thermal performances of microchannels with different cross-sectional shapes. Int J Heat Mass Transf 2019; 143: 118604.

Shi

, et al. Geometry parameters optimization for a microchannel heat sink with secondary flow channel. Int Commun Heat Mass Transf 2019; 104: 89–100.

Salman

Mohammed

Munisamy

, et al. Characteristics of heat transfer and fluid flow in microtube and microchannel using conventional fluids and nanofluids: a review. Renew Sustain Energy Rev 2013; 28: 848–880.

Garcia

JCS

Tanaka

Giannetti

, et al. Multiobjective geometry optimization of microchannel heat exchanger using real-coded genetic algorithm. Appl Therm Eng 2022; 202: 117821.

10.

Gao

Zou

. Numerical investigations of heat transfer and fluid flow characteristics in microchannels with bionic fish-shaped ribs. Processes 2023; 11: 1861.

11.

Sun

Wang

, et al. Thermo-hydraulic performance of nanofluids in a bionic fractal microchannel heat sink with traveling-wave fins. Korean J Chem Eng 2021; 38: 1592–1607.

12.

Yue

Tang

. Cooling characteristics of nanofluids in a snowflake and squid fin composite bionic microchannel heat sink. Colloids Surf A Physicochem Eng Asp 2025; 705: 135614.

13.

Yue

Tang

. A novel composite bionic leaf vein and honeycomb microchannel heat sink applied for thermal management of electronic components. Appl Therm Eng 2024; 252: 123716.

14.

Ilieva

Ursano

Traista

, et al. Biomimicry as a sustainable design methodology—introducing the ‘biomimicry for sustainability’ framework. Biomimetics 2022; 7: 37.

15.

Duan

Mao

, et al. Review about the application of fractal theory in the research of packaging materials. Materials (Basel) 2021; 14: 860.

16.

Zhang

Wang

, et al. Bending characteristics analysis and lightweight design of a bionic beam inspired by bamboo structures. Thin-Walled Struct 2019; 142: 476–498.

17.

Zhu

Peng

, et al. Nature-inspired structures applied in heat transfer enhancement and drag reduction. Micromachines (Basel) 2021; 12: 656.

18.

Kornet

Ziółkowski

Jóźwik

, et al. Thermal-FSI modeling of flow and heat transfer in a heat exchanger based on minichannels. J Power Technol 2017; 97: 373–381.

19.

Zawawi

Saleha

Salwa

, et al. A review: fundamentals of computational fluid dynamics (CFD). In: AIP Conference proceedings. 2030, No 1. Melville, NY: AIP Publishing; 2018. p.020252.

20.

Yang

Kær

. Comparison of reynolds averaged navier-stokes based simulation and large-eddy simulation for one isothermal swirling flow. J Therm Sci 2012; 21: 154–161.

21.

Anderson

. Governing equations of fluid dynamics. In: Computational fluid dynamics: an Introduction. Berlin, Heidelberg: Springer, 1992, pp.15–51.

22.

Wang

Xiong

. Propeller optimization design based on the adjoint method. Chin J Ship Res 2022; 17: 36–41.

23.

Vega-Garcia

Brito-Parada

Cilliers

. Optimising small hydrocyclone design using 3D printing and CFD simulations. Chem Eng J 2018; 350: 653–659.

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.09 MB

0.11 MB

Design and optimization of novel composite bionic pinnate leaf and spider web microchannel heat exchanger

Abstract

Keywords

Get full access to this article

References

Supplementary Material