CHEMICAL ENGINEERING TRANSACTIONS  
 

VOL. 76, 2019 

A publication of 

 

The Italian Association 
of Chemical Engineering 
Online at www.aidic.it/cet 

Guest Editors: Petar S. Varbanov, Timothy G. Walmsley, Jiří J. Klemeš, Panos Seferlis 
Copyright © 2019, AIDIC Servizi S.r.l. 

ISBN 978-88-95608-73-0; ISSN 2283-9216 

Experimental Comparison of the Evaporation and 

Condensation Heat Transfer Coefficients on the Outside of 

Enhanced Surface Tubes with Different Outer Diameters  

David John Kukulkaa,*, Rick Smithb, Wei Lic 

aState University of New York College at Buffalo, 1300 Elmwood Avenue, Buffalo, New York, 14222 USA,  
bVipertex,  658 Ohio Street, Buffalo New York. USA 
cZhejiang University, 866 Yuhangtang Road, Hangzhou 310027, PR China 

 kukulkdj@buffalostate.edu 

An experimental investigation was performed, and results are presented here for an evaporation and 

condensation heat transfer study that took place using enhanced heat transfer (1EHT) tubes of different outside 

diameters. Results were compared to the performance of a smooth surface copper tube. The equivalent outer 

diameter of the horizontal copper tubes considered were 12.7 mm (0.5 in) and 19.05 mm (0.75 in). The test 

apparatus included a straight horizontal test section with an active length heated by water. Constant heat flux 

was maintained and refrigerant quality varied. 

Experimental runs were performed using R410A and R134a as the working fluids. Experimental condensation 

results are presented for a fixed inlet/outlet vapor quality and fixed saturation temperature, while mass flux 

varied; producing a heat transfer coefficient increase (compared to smooth tube) in the range 54 to 64 %, with 

a frictional pressure drop increase for the 1EHT tubes in the range of 8 to 31 %. Unexpected evaporation results 

were found at higher mass flows; producing a decrease (compared to smooth tubes) of the heat transfer 

coefficient for 1EHT tubes in the range of 100 – 220 %; with an increase of frictional pressure drop values for 

the 1EHT tubes in the range 5 to 17 %. 

Enhanced heat transfer tubes are important options to be considered in the design of high efficiency systems. 

A wide variety of industrial processes involve the transfer of heat energy during phase change and many of 

those processes employ old technology. These processes are ideal candidates for a redesign that could achieve 

improved process performance. Vipertex 1EHT enhanced tubes recover more energy and provide an 

opportunity to advance the design of many heat transfer products. 

1. Introduction 

Heat transfer surface enhancement is widely utilized in industrial applications and is one of the most effective 

passive techniques used in order to enhance heat transfer. Heat transfer enhancement techniques improve heat 

exchanger effectiveness. Enhancement is achieved by increasing turbulence, increasing surface area, 

producing more efficient fluid mixing and creating more efficient condensate drainage. Typical ways to 

accomplish this is through minor surface modifications that roughen the surface; use surface enhancements 

that modify the flow and generate secondary flows; and produce an increase to the surface area. Two-phase 

flow heat exchangers are commonly used in a variety of industries (HVAC, refrigeration, process, etc.); it is often 

desired to improve the heat transfer in those heat exchangers by utilizing enhanced tubes that can increase the 

heat transfer coefficient (HTC) and increase performance. Reay (2008) states that “between 1900 and 1955 the 

average rate of global energy use rose from about 1 TW to 2 TW. Between 1955 and 1999 energy use rose 

from 2 TW to about 12 TW, and to 2006 a further 16% growth in primary energy use was recorded world-wide.” 

Over the past ten years’ energy use continued its increase and the increasing trend in energy usage over the 

next decade is expected to continue. Reay (2008) notes “that there is a need to reduce CO2 emissions by over 

50 % in order to stabilise their impact on global warming. One way in which we can address this is by judicious 

use of process intensification technology.” He goes on to define process intensification as: ‘‘Any engineering 

 
 
 
 
 
 
 
 
 
 
                                                                                                                                                                 DOI: 10.3303/CET1976006 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
Paper Received: 16/03/2019; Revised: 30/04/2019; Accepted: 07/05/2019 
Please cite this article as: Kukulka D.J., Smith R., Li W., 2019, Experimental Comparison of the Evaporation and Condensation Heat Transfer 
Coefficients on the Outside of Enhanced Surface Tubes with Different Outer Diameters, Chemical Engineering Transactions, 76, 31-36  
DOI:10.3303/CET1976006 
  

31



development that leads to a substantially smaller, cleaner, safer and more energy-efficient technology.” He 

continues that it is most often characterised by a huge reduction in plant volume (orders of magnitude); in 

addition, process intensification is also an important technique in the reduction of greenhouse gas emissions. 

Varbanov et al. (2018) discuss concepts and methods for improvement of the efficiency at all stages of energy 

sourcing, conversion and use. Xie et al. (2019) discusses methods to improve condensation on the condenser 

wall. Aroonrat and Wongwises (2019) investigated the effect of dimpled depth on the condensation heat transfer 

coefficient and pressure drop of R-134a flowing inside dimpled tubes. Pan et al. (2013) discuss the significant 

effect that heat transfer intensification of individual heat exchangers has on capital, maintenance, installation 

and operating costs. Li et al. (2017) experimentally studied the condensation heat transfer coefficient of R134a 

inside smooth and micro-fin tubes. Tube diameter was determined to have a small influence on the heat transfer 

coefficient for the smooth tubes; while the heat transfer coefficient increases with decreasing tube diameter for 

the micro-fin tubes. Sarmadian et al. (2017) measured and analysed the condensation heat transfer and 

frictional pressure drops of refrigerant R-600a (isobutane) inside a helically dimpled tube and a plain tube of 

internal diameter 8.3 mm. Fernardez et al. (2010) carried out an experimental investigation on R417A, R422 

and R422D condensation on CuNi Turbo tubes. Fitzgrerald et al. (2012) presented condensation inundation on 

a low-finned tube and discuss the effects of vapour velocity on inundation angle. There have been numerous 

studies performed on shell side condensation, however there is no general model that can be used for the 

prediction of annular side condensation with enhanced tube surfaces since a different heat transfer mechanism 

takes place. There have been some specialized investigations that investigated the heat transfer performance 

of tubes with a specialized enhanced surface; however, it is necessary to carry out experimental research to 

determine the heat transfer characteristics for the newly developed enhanced dimpled tubes.  

The types of tubes investigated in the present study include 1EHT, three-dimensional tubes that have been 

produced using multiple enhancement characters that are made of dimple arrays; details are shown in Figure 1 

(a - d). The inner surface of the helically dimpled tube has been designed and reshaped through three-

dimensional material surface modifications that consists of both shallow and deep protrusions which are placed 

evenly in helical directions on the tube wall.  These enhanced surfaces are an enhanced hybrid surface that 

achieves its enhancement by using various dimples with different heights. Previous tube side enhancement 

studies of enhanced tubes demonstrate that the performance of enhanced tubes exceeds normal smooth tubes 

in heat transfer performance. However, few condensation heat transfer studies have been conducted on the 

outside of an enhanced tube and limited investigations have been performed in the changeable spaces for 

annular side flow condensation. There are no correlations that accurately predicts the performance of different 

size outer diameter (OD) three dimensional enhanced heat transfer tubes and experimental research is a more 

accurate representation of heat transfer performance.  

The enhanced dimple tubes used in this study have been designed to maximize the heat transfer and to 

minimize the pressure drop that they produce. Previous research on the 1EHT tube reveals its extraordinary 

enhancement for heat transfer applications, providing the motivation for additional research on its heat transfer 

performance in other working conditions.  

2. Experimental procedure 

Condensation tests were conducted at 318 K saturation temperature; for a range of mass flux from 50 to 100 

kg/ (m2s); with heat flux in the range from 10 to 20 kW/ m2; 0.8 inlet vapour quality and 0.2 outlet vapour quality. 

Evaporation tests were conducted at 279K saturation temperature; for a range of mass flux from 40 – 70 kg/ 

(m2s); with heat flux in the range from 8 – 15 kW/ m2; 0.1 inlet vapour quality and 0.6 / 0.8 outlet vapour quality.  

The schematic diagram of the test apparatus utilized to evaluate the flow boiling heat transfer characteristics of 

R134A and R410A inside circular tubes is shown in Figure 2 (a-c). A detailed description of the test apparatus 

and uncertainty is given by Li et al. (2012) and later by Wu et al. (2014). 

 

 
 

 

(a) (b) (c) 

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(d) 

Figure 1: Surface enhancement of the 1EHT tube: (a) inner surface and (b) outer surface enhancement 

structure, (c) Non-Contact Profilometer three dimensional representation of the surface enhancement structure 

(d) details of the enhancement structure. 

 
 

(a) 

 

 
(b) (c)  

Figure 2: Schematic diagram of the (a) experimental system, (b) test section, (c) cross section of the test section. 

3. Results 

Experimental condensation results as shown in Figure 3 for a fixed inlet/outlet vapour quality and fixed saturation 

temperature, while mass flux and heat flux varied; producing a heat transfer coefficient increase (when 

compared to smooth tubes) in the range of 54 to 64 %, with a frictional pressure drop value increase for the 

1EHT tubes in the range of 8 to 31 %. Unexpected evaporation results were found in Figure 4; producing a 

decrease of the heat transfer coefficient for 1EHT tubes in the range of 100 – 220 %; with frictional pressure 

drop values increase for the 1EHT tubes in the range 5 to 17 %. 

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As is shown in Figure 4 the evaporation heat transfer coefficient outside the smooth tube and EHT tube is given; 

the HTC of the EHT tube is lower than that of smooth tube when the outlet vapour quality is up to 0.8. This is 

mainly because a larger dryout appears at the top of the outside tube at a higher vapour quality. The outside 

surface is not in contact with the liquid but directly exchanges heat transfer with the refrigerant vapour. 

Therefore, this results in heat transfer deterioration and a sharp decrease of the HTC. Moreover, the dryout 

vapour quality of the EHT tube decreases due to the rough enhanced surface (dimples and secondary petal 

array), the partial dryout phenomenon will occur earlier than that of the smooth tube, resulting in the HTC of the 

EHT tube being lower than that of a smooth tube for a high vapor quality. It is uncertain what will happen at 

other qualities, this is the subject of additional studies. 

 

 
(a) 

 
(b) 

Figure 3: Shellside results for (a) condensation heat transfer coefficient (HTC). (b) pressure drop; as a function 

of mass flux (G) for the smooth and enhanced tubes of different diameters. 

 

 

34



 
(a) 

 
(b) 

Figure 4: Shellside results for (a) evaporation heat transfer coefficient (HTC). (b) pressure drop as a function of 

mass flux (G) for the smooth and enhanced tubes of different diameters. 

4. Conclusions 

An experimental study was performed for evaporation and condensation on the outside tube surface. The effects 

of saturation temperature, mass flux and vapour quality on the heat transfer coefficient for smooth and enhanced 

tubes were investigated. These experiments were carried out for condensation tests were conducted at 318 K 

saturation temperature, 50 - 100 kg/ (m2s) mass flux, 10 – 20 kW/ m2 heat flux, 0.8 inlet vapour quality and 0.2 

outlet vapour quality. Evaporation tests were performed at a saturation temperature of 279K, 40 – 70 kg/ (m2s) 

mass flux, 8 – 15 kW/ m2 heat flux, 0.1 inlet vapour quality and 0.6 / 0.8 outlet vapour quality. 

 In summary, there is an uncommon trend for the condensation heat transfer on the outside the smooth tube. 

As shown in the experimental results, the heat transfer coefficient decreases at first and then flattens out 

gradually over low mass flux range; then it continues to rise with increasing mass flux. This phenomenon can 

be explained by the relative significance of gravity, surface tension and inertia force. For the tested tubes, the 

impact of shear stress is strengthened as the saturated temperature decreases. Consequently, the heat transfer 

35



coefficient increases with the larger turbulence effect. The average vapour quality and mass flux has a positive 

effect on the condensation heat transfer coefficient. Experimental condensation results for a fixed inlet/outlet 

vapour quality and fixed saturation temperature, while mass flux and heat flux varied; producing an increase to 

the heat transfer coefficient in the range of 54 to 64 %, with a frictional pressure drop value increase for the 

1EHT tubes in the range of 8 to 31 %. Finally, evaporation heat transfer coefficient for smooth tubes is larger 

than the 1EHT tubes by approximately 100 – 220 %; However, the frictional pressure drop values of 1EHT tubes 

is larger than the smooth tubes by approximately 5 to 17%. Additional studies at other conditions are currently 

being studied. 

References 

Aroonrat K., Wongwises S., 2019, Experimental investigation of condensation heat transfer and pressure drop 

of R-134a flowing inside dimpled tubes with different dimpled depths, International Journal of Heat and Mass 

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Fernandez-Seara J, Uhía F J, Diz R, 2010, Vapour condensation of R22 retrofit substitutes R417A, R422A and 

R422D on CuNi turbo C tubes. International Journal of Refrigeration, 33(1), 148-157. 

Fitzgerald C L, Briggs A, Rose J W, 2012, Effect of vapour velocity on condensate retention between fins during 

condensation on low-finned tubes, International Journal of Heat and Mass Transfer, 55(4), 1412-1418. 

Li Q., Tao L., Li L., Hu Y. and Wu S., 2017, Experimental Investigation of the Condensation Heat Transfer 

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Pan M., Jamaliniya S., Smith R., Bulatov I., Gough M., Droegemueller P., Higley T., 2013, New insights to 

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Reay D., 2008, The role of process intensification in cutting greenhouse gas emissions, Applied Thermal 

Engineering, 28, 2011–2019. 

Sarmadian A., Shafaee M., Mashouf H., Mohseni S.G., 2017, Condensation heat transfer and pressure drop 

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Varbanov P., Jia XX, Kukulka DJ, Liu X, Klemeš JJ, 2018, Emission minimisation by improving heat transfer, 

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