Song, Gwi-Eun Lee, Joohyun Lee, Dae-Young 2024-01-20T15:01:38Z 2024-01-20T15:01:38Z 2021-09-05 2012-05 0017-9310 https://pubs.kist.re.kr/handle/201004/129311 With the aim of improving heat exchanger compactness, this study investigates how the optimum configuration of an air-liquid plate heat exchanger changes as the heat exchanger depth decreases. In this respect, optimization of an air-liquid plate heat exchanger with a given frontal area and a given depth is achieved. The optimum fin pitch and plate pitch are obtained to maximize the heat transfer rate based on heat transfer and pressure loss correlations in finned channels. Then, the focus of this study is placed on how the optimum channel configuration changes when the heat exchanger depth decreases for compactness. The results illustrate that the heat transfer performance can remain unchanged if the geometric parameters, such as the plate thickness, the plate pitch, the fin thickness, and the fin pitch, are reduced proportionally to the square root of the flow depth reduction given that the flow remains laminar. This finding is arranged into a simple scaling rule to obtain the configuration of a more compact heat exchanger from an existing configuration. In addition, the scaling arguments are extended to practical situations where the fin thickness and the plate thickness are not properly reduced following the scaling rule due to limitations on available material thicknesses. (C) 2012 Elsevier Ltd. All rights reserved. English PERGAMON-ELSEVIER SCIENCE LTD FORCED-CONVECTION TURBULENT FLOW OPTIMIZATION REGION SINKS DUCTS TEMPERATURE SHAPE A method to reduce the flow depth of a plate heat exchanger without a loss of heat transfer performance Article 10.1016/j.ijheatmasstransfer.2012.02.027 1 INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER, v.55, no.11-12, pp.2992 - 2998 INTERNATIONAL JOURNAL OF HEAT AND MASS TRANSFER 55 11-12 2992 2998 scie scopus 000303550800026 2-s2.0-84858725991 Thermodynamics Engineering, Mechanical Mechanics Thermodynamics Engineering Mechanics Article FORCED-CONVECTION TURBULENT FLOW OPTIMIZATION REGION SINKS DUCTS TEMPERATURE SHAPE Plate heat exchanger Compactness Finned channel Optimum configuration Flow depth Scaling rule