Parametric analysis of axial wall conduction in a microtube subjected to two classical thermal boundary conditions

Tiwari, Nishant; Moharana, Manoj Kumar

doi:10.1007/s12046-019-1151-8

Cited by 3 publications

(1 citation statement)

References 30 publications

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“…Microchannel heat sink facilitates liquid cooling with higher surface area to volume ratio but simultaneously accompanied with excessive pressure drop limiting the application to low flow rate laminar flows. The substrate material significantly affects the conjugate heat transfer process and was demonstrated that phase change phenomenon in microchannel significantly improves thermal performance (Tiwari and Moharana, 2019a, 2019c). Thus, to enhance cooling, it becomes necessary to either improve fluid and heat sink material properties or somehow change the flow behaviour to enhance convective heat transfer.…”

Section: Introductionmentioning

confidence: 99%

Optimisation of porous slab parameters for jet-impingement microchannel heat sink performance enhancement

Pandey

Ansari

Husain

2021

HFF

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Purpose Porous media can provide excellent performance in thermal energy transport applications. This study aims to optimise the square porous slabs (placed in the middle of the channel) parameters to enhance the cooling performance of the jet-impingement microchannel heat sink. Design/methodology/approach Three levels of each design parameters, i.e. porous slab side, porous slab height, type of material, permeability and quadratic drag factor, are studied; and an L27 orthogonal array is adopted to generate the design points in the specified design space. Optimum designs of the porous media slabs are achieved to minimise the maximum-wall temperature, thermal resistance and pressure drop and maximise the average heat transfer coefficient and figure of merit (FOM). Findings Results exhibited that the porous media material and permeability are the most, whereas drag factor is the least significant factors with respect to the overall performance of the heat sink. The optimum value of FOM for the proposed hybrid heat sink model belongs to the set of design variables, i.e. 0.4 mm slab side, 0.6 mm slab height, 5 × 10−11 m2 permeability, 0.21 drag factor and copper as substrate material. Originality/value This study proposes a novel design and a hybrid approach to investigate and optimise the hydrothermal performance of jet impingements on porous slabs inserted in the microchannels.

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Section: Introductionmentioning

confidence: 99%