Natural convection heat transfer performance of additively manufactured tube bundle heat exchangers with novel fin design

Sebastian Unger,Heiko Pietruske,Matthias Beyer,Uwe Hampel,Lutz Szalinski

doi:10.1007/s00231-020-03014-5

Sebastian Unger, Heiko Pietruske + Show 3 more

Open Access

https://doi.org/10.1007/s00231-020-03014-5

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Abstract

We studied the heat transfer of finned heat exchanger configurations with a novel design. These novel fin designs use integrated pins to enhance the heat conduction from the fin base to the fin tip as well as the air-side heat transfer on the fin surface. Oval tubes with conventional circular plain fins (CPF) as well as novel circular integrated pin fins (CIPF) and serrated integrated pin fins (SIPF) were additively generated by a Selective Laser Melting (SLM) process and installed at the bottom of a 6.5 m long chimney. All heat exchanger designs were tested in a 2-row and 3-row configuration with Rayleigh numbers between 25,000 and 120,000. We found the average Nusselt number of SIPF to be higher and the Nusselt number of the CIPF to be lower than for the CPF. Moreover, the 2-row configuration achieved a higher Nusselt number compared to the 3-row configuration for all heat exchanger designs. The analysis of the individual tube rows showed the highest Nusselt numbers at the first tube row and the lowest one at the last tube row for both configurations. However, for the SIPF the difference between the first and second tube row is smaller compared to the CPF and CIPF. In order to evaluate the compactness of the heat exchanger, the volumetric heat flux density was considered. Similar to Nusselt number the volumetric heat flux density enhanced for the SIPF and reduced for the CIPF compared to the conventional design. Also the 2-row configuration reached greater thermal performance compared to the 3-row configuration. Additionally, the volume and the surface area of the heat exchanger are 6.9% and 30.7% lower for the SIPF compared to the CPF. The experimental data were used to develop an empirical heat transfer correlation between Nusselt number, Rayleigh number, fin design and tube row number.

Highlights

The heat transfer by natural convection is an attractive alternative to the forced convection, since there are neither fans nor blowers required
The average air-side heat transfer coefficient for the natural convection was calculated from the measured data and the fluid properties as following: Fig. 2 Investigated fin designs a) circular plain fin (CPF), b) circular integrated pin fin (CIPF) and c) serrated integrated pin fin (SIPF)
Both configurations were equipped with plain circular fins (CPF), integrated pinned fins (CIPF) and serrated integrated pinned fins (SIPF)

Summary

Introduction

The heat transfer by natural convection is an attractive alternative to the forced convection, since there are neither fans nor blowers required. The area for installation is higher or the heat transfer surface must be extended by fins or both. Common applications of such finned tube bundle heat exchangers are air conditioning and refrigerating systems, electronic cooling devices and thermal power plants. We devised two novel heat exchanger designs for improving the air-side convective heat transfer and enhancing the heat conduction in the solid part of the fin. These designs were additively manufactured by an SLM process and experimentally investigated in a chimney. In order to put the results into the context of the state of the art in this field, we will briefly discuss the latter in the following paragraphs

Methods

Results

Conclusion