Modeling of Two-Phase Heat Exchangers With Zeotropic Fluid Mixtures

Gomse, David; Kochenburger, Thomas; Grohmann, Steffen

doi:10.1115/1.4038852

Cited by 5 publications

(1 citation statement)

References 25 publications

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“…A study performed a computed tomography (CT) scan to examine a prototype polymer-based EMHX such as this, and it indicates significant flow maldistribution due to channel height variations [19]. There have been significant improvements in the modeling of micro-channel HX, which can be used to drive the development of EMHX [4,[20][21][22][23][24][25][26][27][28][29][30][31]. Recently, a paper [32] developed a finite difference model that can be applied to this EMHX that was scanned, allowing for a comparison between modeled and experimental heat transfer characteristics when maldistribution is present.…”

Section: Introductionmentioning

confidence: 99%

Expanded Microchannel Heat Exchanger: Finite Difference Modeling

Denkenberger

Pearce

Brandemuehl

et al. 2021

Designs

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A finite difference model of a heat exchanger (HX) considered maldistribution, axial conduction, heat leak, and the edge effect, all of which are needed to model a high effectiveness HX. An HX prototype was developed, and channel height data were obtained using a computerized tomography (CT) scan from previous work along with experimental results. This study used the core geometry data to model results with the finite difference model, and compared the modeled and experimental results to help improve the expanded microchannel HX (EMHX) prototype design. The root mean square (RMS) error was 3.8%. Manifold geometries were not put into the model because the data were not available, so impacts of the manifold were investigated by varying the temperature conditions at the inlet and exit of the core. Previous studies have not considered the influence of heat transfer in the manifold on the HX effectiveness when maldistribution is present. With no flow maldistribution, manifold heat transfer increases overall effectiveness roughly as would be expected by the greater heat transfer area in the manifolds. Manifold heat transfer coupled with flow maldistribution for the prototype, however, causes a decrease in the effectiveness at high flow rate, and an increase in effectiveness at low flow rate.

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