Numerical and experimental study on the influence of top bypass flow on the performance of plate fin heat exchanger

•Top bypass flow has great influence on thermal performance of PFHE.•Experiments agree with simulations well with an average difference of 13.5%.•A relationship between top bypass duct and its optimized air velocity is gained.•A ratio of 0.5 for frontal fin to heat exchanger area is suggested. Bypas...

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Bibliographic Details
Published in:Applied thermal engineering 2019-01, Vol.146, p.356-363
Main Authors: Cai, Huikun, Su, Lijun, Liao, Yidai, Weng, Zeju
Format: Article
Language:English
Subjects:
Bypasses
Computer simulation
Design optimization
Heat conductivity
Heat exchangers
Heat transfer coefficients
Height ratio of top bypass flow duct to fin
Mathematical models
Optimized frontal area ratio
Plate-fin heat exchanger
Plate-fin heat exchangers
Simulation
Thermal cycling
Thermal performance analysis
Top bypass flow
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Summary:•Top bypass flow has great influence on thermal performance of PFHE.•Experiments agree with simulations well with an average difference of 13.5%.•A relationship between top bypass duct and its optimized air velocity is gained.•A ratio of 0.5 for frontal fin to heat exchanger area is suggested. Bypass flow deserves a deep research as it is the important phenomenon in plate-fin heat exchanger and is of great influence on the thermal performance. Present studies had consulted this problem, but did not conduct a throughout study and restricted in a limited geometry. Therefore, in this paper an experimental bench is built for the research. Numerical simulations are also carried out on the models with and without bypass flow. The discrepancy of average heat transfer coefficient in simulation with bypass flow increases with air velocity and the maximum difference reaches 82.76% at the velocity of 10 m/s when compared to the model without that, but reduces to be 19.1% when compared to experimental results. After experimental validation, top bypass flow is analyzed with different ratios of top duct height to fin height and varied air velocities. A relationship between air velocity and its minimum height ratio is gained for the estimation in initial design of plate-fin heat exchanger. The optimization with varied fin numbers and interval distances is also carried out, and it is found that the optimized ratio of frontal fin area to frontal plate-fin heat exchanger area is almost keeping at an approximate value of 0.5 for all cases, but thinner fin and narrower air flowing channel can make better heat transfer effect. This paper reveals the influence of top bypass flow on thermal performance and design principle of plate-fin heat exchanger, which is hopeful to be an instruction for its future application in many fields.
ISSN:1359-4311
1873-5606
DOI:10.1016/j.applthermaleng.2018.10.007