Thermal Science and Engineering Progress

Published by: Elsevier

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Highlights

  • Heat transfer characteristics of metal foam integrated surface using air-jet impingement for different Re and z/d
  • Experimental analysis to assess the impact of a circular orifice on the thermal characteristics of a metal foamed surface
  • Enhanced cooling is observed throughout the metal-foamed plate in all local regions at increased impinging distances
  • Optimizing the impinging distance for a given Reynolds number leads to better cooling
  • Study contributes to identifying the foam section appropriate for improving heat transmission

Abstract

The use of metal foam in conjunction with air-jet impingement enhances heat transfer in electronic cooling systems by expanding convection surface area, improving heat dissipation, and enhancing coolant mixing. It may reduce concentrated heat flow and improve cooling efficiency in sectors like electronics, aerospace, and automotive. The present study examines the heat transfer attributes of a heated surface combined with metal foam and exposed to an air jet, revealing its potential for improving cooling systems. This study conducts an experimental analysis to assess the impact of a circular orifice on the thermal transfer characteristics of a metal foamed surface. Present research examines many characteristics, including nozzle-to-plate distance (z/d) and local and average heat transfer (Nusselt number), both along the longitudinal and transverse axes at varying Reynolds numbers (Re = 10000–50000) and plate-to-nozzle distances (z/d = 2–10) using infrared images obtained by the thin foil thermal imaging technique. The emphasis of the study is on the local distribution of these heat transfer characteristics. A copper metal foam with a porosity of 90 % and 20 pores per inch is combined with the flat plate. When compared to foil without foam, the thermal properties of heated thin foil integrated with metal foam using a circular orifice are found to be better in the stagnation region. Moreover, this study also investigates the influence of plate segments integrated with metal foam on the distribution of localized and average heat transfer. The thermal performance of the thin foil, when paired with the metal foam in the stagnation zone, is superior to that of the foil without foam. The local Nusselt number for y/d = 0, 2, 4 and 6 with foam at the stagnation point (x/d = 0) increases by 112 %, 107 %, 129 %, and 124 %, accordingly, as the Re increases from 10000 to 50000. The use of an integrated metal foam heated plate enhances localized thermal propagation. The foam effect is more evident in the impingement zone than in the wall jet region at a lower z/d. At lower impinging distances, foam at the impingement zone contributes more to heat transmission and results in non-uniform cooling. Higher impinging distances approaching z/d = 6–8 may result in consistent cooling and optimal foam use.

Keywords

Jet impingement
;
Metal foam
;
Circular orifice
;
Reynolds number
;
Nusselt number
;
Foam enhancement factor
;
Heat transfer coefficient

Introduction

Jet impingement heat transfer is an effective localized cooling technique used in various engineering applications, including hot steel plates, gas turbine cascades, paper mills, metals, glass manufacturing, and electronic component cooling. Its simple design, low pressure loss, homogeneous distribution, short routes, and high efficacy make it widely used in industrial operations, including aircraft cooling, electronic component cooling, and textile manufacturing [[1], [2], [3]]. Researchers found that the thermal efficiency of impinging jets is influenced by factors such as Reynolds number, impinging distance, nozzle shape, jet confinement, turbulence intensity, and test specimen orientation [[2], [3], [4], [5], [6], [7], [8]]. Research on jet impingement tests on flat surfaces has mainly focused on circular orifices and nozzles, but limited studies have explored the use of metal foam as an additional method to enhance heat transfer.
Jet impingement cooling is a popular technique for achieving higher localized heat fluxes in thermal systems due to its flexible design, lower pressure drop, and shorter flow path. A fast-moving fluid, like air or liquid, impinges on a heated surface to effectively remove heat, creating a thinner boundary layer and faster heat dissipation from the surface. Different cooling fluids like air, water, air–water mixture, aqueous surfactant solutions, and nanofluids are used for industrial purposes. Heat transfer rate in impinging jets is influenced by parameters like jet Reynolds number, nozzle geometry, impinging distance, confinement, turbulence intensity, and test specimen orientation [4,6,7,9]. Numerous studies have examined the heat transfer and fluid flow characteristics of jet impingement, including tests conducted by Martin [1], Viskanta [3], Jambunathan et al. [7], and Livingood and Hrycak [10], as well as the fluid flow and heat transfer characteristics of unconfined axially symmetrical air jets.
Lytle and Webb [4] used an infrared camera to study heat transfer from a smooth plate to a round nozzle at a shorter influencing range. Lee et al. [11] found that heat transfer in stagnation regions improved with increased nozzle diameter. Other researchers studied the effect of nozzle geometry on jet impingement performance using experimental and numerical techniques. Kim and Park [12] found that non-circular turbulent jets had more dominant secondary flow than axisymmetric jets. Katti and Prabhu [6] examined factors like Reynolds number and non-dimensional impinging distance on circular jet impingement efficiency. Previous research mainly focused on experimental experiments, but most studies considered axisymmetric geometry and impingement on a smooth plate.
Researchers have utilized various techniques to improve heat transmission from flat surfaces during jet impingement, including swirl generators, longitudinal swirling strips, turbulence boosters, jet intermittency, mechanical tabs, and surface roughness [[13], [14], [15], [16]]. Air convective cooling is widely used for electronic components due to its simple design, with open-cell metal foams (OCMFs) being considered as a potential candidate for improved cooling performance. Metal foams, with desirable attributes like high surface area density, lightweight, rigidity, high porosity, customized thermal conductivity, and lower manufacturing costs, are being explored for thermal management applications [[17], [18], [19], [20], [21]]. Metal foam, characterized by porosity, PPI, size, and design, is preferred due to its higher surface area and enhanced mixing and turbulence, resulting in higher heat transfer [[22], [23], [24]]. Researchers have studied the integration of open-cell metal foams (OCMF) with plates during jet impingement cooling to improve heat transfer, analyzing parameters like foam thickness, porosity, pore density, and thermal conductivity. Calmidi and Mahajan [25] proposed an analytical model for estimating effective thermal conductivity of high-porosity fibrous metal. Bhattacharya et al. [26] studied the thermal performance of finned porous metal substrates for electronic device thermal management. They found that heat transfer performance in metal foam heat sinks is 1.5–2 times higher than conventional heat sinks. Jeng et al. [27] analyzed convective heat transfer and pressure drop characteristics of aluminium porous blocks, finding that the average Nusselt number increases with foam thickness and pore size. Paek et al. [28] study on porous material conductivity found that effective thermal conductivity increases with foam density and decreases with pore size. Shih et al. [29] suggested using an airflow-limiting mask and metal foam to direct cooling air towards a heated surface, improving cooling efficiency. They studied the effects of porosity, pore density, and restricted fluid flow on heat sink thermal performance. Wang et al. [30] found finned copper foam better than conventional sinks, and Yogi et al. [31] found lower heat transfer performance in aluminum OCMF with 40 PPI porous media.
Research suggests that open-cell metal foam can enhance heat dissipation by increasing contact space, improving interaction, and reducing pressure drop [[32], [33], [34]]. This is primarily due to its numerous advantages, including interconnected cavities providing ample contact area, enhanced amalgamation, and increased dispersion. Earlier studies involving air-jet impingement cooling using metal foam primarily analysed average thermal characteristics using circular, elliptical and other non axi-symmetric jets. The present study analysed both average and local heat transfer characteristics to effectively quantify the enhancement in the cooling rate in comparison to the heated surface without foam. Foam is an effective passive flow control method, offering substantial performance enhancements at an affordable cost in various applications [35,36]. Depending on the porosity and pore density, foam can either retard or accelerate the flow [37]. However, in the present study, foam distributes the incoming air jet into several micro-jets when they pass through porous material. These microjets then collide with the hot plate, hence increasing the coefficient of heat transfer.
Attached to the heating surface, the OCMF acts as a fin and increases the surface area per unit volume. Conduction transports heat from the plate to the foam's upper surface. The turbulence created due to the micro air-jets developed by the metal foam increases fluid mixing, distrupts, and breaks the thermal boundary layer. Circular jet impingement cooling effectively reduces the thermal boundary layer through increased turbulence and enhanced mixing, resulting in improved cooling efficiency. Similar mechanisms of heat transfer through metal foam have been reported by the earlier researchers [32,33,38,39].
Research on air-jet impingement using open-cell metal foam is limited to low Reynolds numbers and lacks information on foam area optimization's impact on heat transfer characteristics. Studies on the optimization of cooling properties of foam-embedded surfaces with circular orifices are limited. The literature has not explored the local and average thermal behaviour of circular orifices at higher Reynolds numbers for different foam sections under air-jet impingement. The present study examines the thermal behaviour of different foam sections on a heated plate with an axisymmetric orifice under air jet impingement.
The present analysis aims to estimate the thermal characteristics of a foamed surface and compare its performance with a plain surface without foam during jet impingement. The parameters under consideration include the foam thickness, coolant flow rate (Reynolds number Re), nozzle-to-plate distance (z/d), and spatial location away from the stagnation point. The experiments also examine the localized Nusselt number variation in the longitudinal (x/d) and transverse (y/d) directions. The infrared thermography technique is employed to monitor temperature, which is then used to evaluate thermal performance parameters. The experimental investigation aims to achieve the following objectives:
  • Examine the influence of a circular orifice on the thermal attributes of a copper foam embedded flat surface using air-jet impingement.
  • Study the local, average and stagnation heat transfer characteristics of metal foamed surface across the longitudinal and transverse directions.
  • Investigate the effects of varying impinging distance and Reynolds number on the thermal characteristics of a metal foamed surface.
  • Optimization of the foam area involved in the cooling of foam-embedded heated surface.

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Section snippets

Test facility

Fig. 1 shows a simplified layout for assessing heat transfer rate of a surface with metallic foam under an impinging jet. The apparatus includes a heat-generating device, jet unit, target surface unit, and IR camera. The study uses a thin SS foil measuring 150 mm x 80 mm x 0.05 mm for the smooth surface investigation. The investigation involves integrating a 90 % porosity copper metal foam with 20 PPI into flat SS foil. The process involves the use of a thermal glue (SE 4485) with a

Data reduction and procedure

The local heat transfer characteristic is measured in terms of the local Nusselt number (Nu) and is calculated for ith control volume (CV) as [6,40,41]:Nu=hidkwhere d and k are the internal diameter of the nozzle and thermal conductivity of the fluid, respectively. Here, hi denotes the local heat transfer coefficient for ith CV (Fig. 5) and is calculated as [6,40]:hi=qconv,iAiTs,i-Tj,iwhere, Ai, Ts,i, Tj,i represents the convective area of ith CV, the surface temperature of the ith CV, and the

Results and discussion

This study examined the heat transfer characteristics of a flat hot surface and a surface integrated with metal foam using circular orifice air-jet impingement. In the current research a series of experiments were performed to investigate the local, average and stagnation heat transfer coefficients, as well as the foam enhancement factor of a heated stainless-steel foil. Table 2 provides a detailed summary of the operational variables included in this study. The research examined the various

Conclusions

This research investigates the thermal properties of a heated surface integrated with metal foam by employing a circular orifice air-jet impingement directed stream of air and assessing the influence of porous foam on the heat transfer characteristics of the heated surface. The heat transfer properties of an axisymmetric orifice are assessed at both lower and higher Reynolds numbers (Re = 10000–50000) and impinging distances (z/d = 2–10) using open-cell metal foam with a porosity of 90 %. Tests

CRediT authorship contribution statement

Pradeep Kumar Singh: Writing – original draft, Methodology, Investigation, Conceptualization. Santosh K. Sahu: Writing – review & editing, Supervision, Conceptualization.

Declaration of competing interest

The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

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  • This article is part of a special issue entitled: ‘ICFTES'24’ published in Thermal Science and Engineering Progress.
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