Performance analysis of variable thickness longitudinal fin with functionally graded material in dry and fully wet conditions

Bajpai, Upendra; Soni, Palash; Gaba, Vivek Kumar; Bhowmick, Shubhankar

doi:10.1108/wje-03-2022-0102

Cited by 1 publication

(2 citation statements)

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“…Yontar et al (2020) have reported the numerical solution of constant thickness annular fin using a joint approach. Bajpai et al (2022) investigated the performance of varying geometry FGM longitudinal fins for fully wet conditions. Ranjan and Mallick (2018) reported the performance analysis of FGM annular fin based upon multiple variable thermal parameters.…”

Section: Introductionmentioning

confidence: 99%

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Continuous composite longitudinal fins under oscillating boundary conditions: a lattice Boltzmann solution

Sahu,

Bhowmick

2024

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PurposeTransient response of continuous composite material (CCM) fin made of high thermally conductive composite material is presented. The continuously varying effective properties of composite material such as thermal conductivity, heat capacity and density have been modelled using the Mori-Tanaka homogenization theory and rule of mixture. Additionally, temperature dependency of thermal conductivity, heat generation (composite materials) and convection coefficient (fluid properties) have also been incorporated. Different base boundary conditions are addressed such as oscillating heat flow, oscillating temperature, step-changing heat flow and step-changing temperature. At the other boundary, the fin is assumed to have a convective tip.Design/methodology/approachLattice Boltzmann method is implemented using an in-house source code for obtaining the numerical solution of typical non-linear heat balance equation of the aforementioned problem under various transient base boundary conditions.FindingsThe effects of various thermal parameters such as material diffusivity ratio and conductivity ratio, area ratio and Biot number on transient response of fin and temperature distribution of fins are studied and interpreted. The heat transfer rate and time for attainment of steady state temperature of metal matrix composite (MMC) fin are found to be proportionally dependent on their diffusivity ratio. Additionally for higher values of area ratio and biot number, MMC fins are reported to dissipate the heat more efficiently in comparision to homogeneous fins in terms of time required to attain the steady state and surface temperature.Practical implicationsResponse of transient fin associated with advanced class of material can facilitates the practicing engineers for designing high-performance and/or miniaturized thermal management devices as used in electronic packaging industries.Originality/valueStudies of composite fin consisting of laminating second layer of material over the first layer have been reported previously, however transient response of CCM fin fabricated by continuously varying the volume fraction of two materials along the fin length has not been reported till date. Such material finds its application in thermal management and electronic packaging industries. Results are plotted in form of a graph for different application-wise material combinations that have not been reported earlier, and it can be treated as design data.

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Section: Introductionmentioning

confidence: 99%

“…(2020) have reported the numerical solution of constant thickness annular fin using a joint approach. Bajpai et al. (2022) investigated the performance of varying geometry FGM longitudinal fins for fully wet conditions.…”

Section: Introductionmentioning

confidence: 99%

Continuous composite longitudinal fins under oscillating boundary conditions: a lattice Boltzmann solution

Sahu,

Bhowmick

2024

Self Cite

View full text Add to dashboard Cite

show abstract

Performance analysis of variable thickness longitudinal fin with functionally graded material in dry and fully wet conditions

Cited by 1 publication

References 18 publications

Continuous composite longitudinal fins under oscillating boundary conditions: a lattice Boltzmann solution

Continuous composite longitudinal fins under oscillating boundary conditions: a lattice Boltzmann solution

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