The evaporation heat transfer coefficient and pressure drop for refrigerant R-134a flowing in a plate heat exchanger were investigated experimentally in this study. Two vertical counterflow channels were formed in the exchanger by three plates of commercial geometry with a corrugated sine shape of a chevron angle of 60 deg. Upflow boiling of refrigerant R-134a in one channel receives heat from the hot downflow of water in the other channel. The effects of the mean vapor quality, mass flux, heat flux, and pressure of R-134a on the evaporation heat transfer and pressure drop were explored. The quality change of R-134a between the inlet and outlet of the refrigerant channel ranges from 0.09 to 0.18. Even at a very low Reynolds number, the present flow visualization of evaporation in a plate heat exchanger with the transparent outer plate showed that the flow in the plate heat exchanger remains turbulent. It is found that the evaporation heat transfer coefficient of R-134a in the plates is much higher than that in circular pipes and shows a very different variation with the vapor quality from that in circular pipes, particularly in the convective evaporation dominated regime at high vapor quality. Relatively intense evaporation on the corrugated surface was seen from the flow visualization. Moreover, the present data showed that both the evaporation heat transfer coefficient and pressure drop increase with the vapor quality. At a higher mass flux the pressure drop is higher for the entire range of the vapor quality but the evaporation heat transfer is clearly better only at the high quality. Raising the imposed wall heat flux was found to slightly improve the heat transfer, while at a higher refrigerant pressure, both the heat transfer and pressure drop are slightly lower. Based on the present data, empirical correlations for the evaporation heat transfer coefficient and friction factor were proposed.

1.
Akers
W. W.
,
Deans
H. A.
, and
Crosser
O. K.
,
1958
, “
Condensation heat transfer within horizontal tubes
,”
Chemical Engineering Progress
, Vol.
54
, pp.
89
90
.
2.
Collier, J. G., 1981, Convective boiling and condensation, 2nd Ed., McGraw-Hill, New York, pp. 26–69.
3.
D’Yachkov
F. N.
,
1978
, “
Investigation of Heat Transfer and Hydraulics for Boiling of Freon-22 in Internally Finned Tubes
,”
Heat Transfer Sov. Res.
, Vol.
10
, No.
2
, pp.
10
19
.
4.
Eckels
S. J.
, and
Pate
M. B.
,
1991
, “
An Experimental Comparison of Evaporation and Condensation Heat Transfer Coefficients for HFC-134a and CFC-12
,”
Int. J. Refrig.
, Vol.
14
, pp.
70
77
.
5.
Gungor
K. E.
, and
Winterton
R. H. S.
,
1986
, “
A general correlation for flow boiling in tubes and annuli
,”
Int. J. Heat Mass Transfer
, Vol.
29
, No.
3
, pp.
351
358
.
6.
Incropera and Dewitt, 1981, Fundamentals of Heat Transfer, John Wiley and Sons, New York, pp. 399–407.
7.
Kandlikar
S. G.
, and
Shah
R. K.
,
1989
a, “
Multipass Plate Heat Exchangers-Effectiveness-NTU Results and Guidelines for Selecting Pass Arrangements
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
III
, pp.
300
313
.
8.
Kandlikar
S. G.
, and
Shah
R. K.
,
1989
b, “
Asymptotic Effectiveness-NTU Formulas for Multipass Plate Heat Exchangers
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
111
, pp.
314
321
.
9.
Kandlikar
S. G.
,
1990
, “
A General Correlation for Saturated Two-Phase Flow Boiling Heat Transfer Inside Horizontal and Vertical Tubes
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
112
, pp.
219
228
.
10.
Kandlikar
S. G.
,
1991
, “
A Model for Correlating Flow Boiling Heat Transfer in Augmented Tubes and Compact Evaporators
,”
ASME Journal of Heat Transfer
, Vol.
113
, pp.
966
972
.
11.
Kerner
J.
,
Sjogren
S.
, and
Svensson
L.
,
1987
, “
Where Plate Exchangers Offer Advantages Over Shell-and-Tube
,”
Power
, Vol.
131
, pp.
53
58
.
12.
Khanpara
J. C.
,
Bergles
A. E.
, and
Pate
M. B.
,
1986
, “
Augmentation of R113 In-tube Evaporation with Micro-fin Tubes
,”
ASHRAE Trans.
, Vol.
92
, Part 2B, pp.
506
523
.
13.
Khanpara, J. C, Bergles, A. E., and Pate, M. B., 1987, “Local Evaporation Heat Transfer in a Smooth Tube a Micro-Fin Tube Using Refrigerants 22 and 113,” ASME HTD-85, pp. 31–39.
14.
Kline
S. J.
, and
McClintock
F. A.
,
1953
, “
Describing uncertainties in single-sample experiments
,”
Mechanical Engineering
, Vol.
75
, No.
1
, pp.
3
12
.
15.
Reid
R. S.
,
Pate
M. B.
, and
Bergles
A. E.
,
1991
, “
A Comparison of Augmentation Techniques During in Tube Evaporation of R-113
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
113
, pp.
451
458
.
16.
Schlager
L. M.
,
Pate
M. B.
, and
Bergles
A. E.
,
1990
, “
Evaporation and Condensation Heat Transfer and Pressure Drop in Horizontal, 12.7-mm Microfin Tubes With Refrigerant 22
,”
ASME JOURNAL OF HEAT TRANSFER
, Vol.
112
, pp.
1041
1047
.
17.
Shah, R. K., and Focke, W. W., 1988, “Plate Heat Exchangers and Their Design Theory,” Heat Transfer Equipment Design, R. K. Shah, E. C. Subbarao, and R. A. Mashelkar, eds., Hemisphere, Washington, DC, pp. 227–254.
18.
Shah, R. K., and Wanniarachchi, A. S., 1992, “Plate Heat Exchanger Design Theory,” Industrial Heat Exchangers (Lecture Series No. 1991-04), J.-M. Buchlin, ed., Von Karman Institute for Fluid Dynamics, Belgium.
19.
Wattelet, J., Saiz Jabardo, J. M., Chato, J. C, Panek, J. S., and Souza, A. L., 1992, “Experimental Evaluation of Convective Boiling of Refrigerants HFC-134a and CFC-12,” ASME HTD-Vol. 197, pp. 121–127.
20.
Wattelet
J. P.
,
Chato
J. C.
,
Souza
A. L.
, and
Christoffersen
B. R.
,
1994
, “
Evaporation characteristics of R-12, R-134a, and a mixture at low fluxes
,”
ASHRAE Transactions
, Vol.
100
, pp.
603
615
.
21.
Williams, B., 1996, “Heat transfer savings on a plate,” Heating and Air Conditioning Journal, Apr., pp. 29–31.
22.
Wilson
E. E.
,
1915
, “
A Basis for Traditional Design of Heat Transfer Apparatus
,”
Trans. ASME
, Vol.
37
, pp.
47
70
.
This content is only available via PDF.
You do not currently have access to this content.