Enhancing Engine Cylinder Heat Dissipation Capacity Through Direct Optimization (DO) Techniques

Abhishek Agarwal, Megersa Olumana Dinka, Masengo Ilunga

Research output: Contribution to journalArticlepeer-review

Abstract

Internal combustion (IC) engines are used widely as the primary power source for automobiles of all types, cars, motorcycles, and trucks. Because of the high combustion temperatures involved in the operation, the excess heat is removed by means of extended fins that increase the surface area for adequate cooling. Significant improvement in the heat dissipation characteristics of the engine cylinder can be achieved by optimizing the design of these fins. The aim of this study is to evaluate the thermal performance of engine cylinder fins using an analytical system of finite element analysis (ANSYS FEA) software, using a direct optimization (DO) approach to identify optimal fin design. Analysis shows that fin length and width play critical roles in improving cooling efficiency, lowering the maximum temperature within the cylinder to 549.46 K and enhancing total heat flux to 7225.31 W/m2, which is a 25.87% increase from the generic design, capable of heating removal of 5740.22 W/m2. The current fin design is effective but could be improved in heat dissipation, mainly at fin tips. To optimize thermal performance while minimizing material costs, a balanced fin dimension is recommended. Alternative materials, transient heating analysis, and experimental verification may be examined in the future to achieve a total understanding of fin geometry and behavior under real operating conditions. These insights lay a foundation to accelerate cooling systems development in the automotive, aerospace, and heavy equipment industries, where efficient heat transfer is key for performance and long-term durability.

Original languageEnglish
Article number2659
JournalProcesses
Volume12
Issue number12
DOIs
Publication statusPublished - Dec 2024

Keywords

  • ANSYS
  • automotive engineering
  • cooling efficiency
  • direct optimization technique
  • engine cylinder fins
  • fin geometry
  • finite element analysis
  • heat dissipation
  • internal combustion engine
  • thermal performance
  • transient heat analysis

ASJC Scopus subject areas

  • Bioengineering
  • Chemical Engineering (miscellaneous)
  • Process Chemistry and Technology

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