Absorption of water vapor into aqueous lithium bromide is a fundamental step in absorption refrigeration. When the liquid film is laminar, the coupled heat and mass transfer process is controlled by mass transfer, resulting in low transfer coefficients. Significant augmentation of mass transfer, and hence of the coupled process, is achieved by introducing a trace amount (on the order of 100 ppm) of 2-ethyl-hexanol. The alcohol acts as a surfactant and drives Marangoni convection that effectively mixes the liquid providing a much higher effective mass diffusivity. The film flow in the presence of the alcohol is noticeably different with a complex, apparently unstructured appearance. The flow activity, which can be easily observed, has never been satisfactorily explained until the recent introduction of the Vapor Surfactant theory. This paper presents a series of experimental results of absorption in an actual chiller facility. The novel features of the work include measurement of the effect of inlet subcooling, discussion of the effect of droplets ejected from the tube bundle and an explanation of the importance of flux in the alcohol augmentation physics.

1.
Nagaoka, Y., Nishiyama, N., Ajisaka, K., and Nakamura, M., 1987, “Absorber of Absorption refrigerating Machine: Enhancement of Heat and Mass Transfer in Falling Film Absorbers by Surface Configuration,” 17th Int. Congress of Refrigeration, Vienna, Austria, International Institute of Refrigeration, pp. 990–995.
2.
Consenza
,
F.
, and
Vliet
,
G.
,
1990
, “
Absorption in Falling Water/LiBr Films on Horizontal Tubes
,”
ASHRAE Trans.
,
96
, Pt. 1, pp.
693
701
.
3.
Greiter, I., Wagner, A., Weiss, V., and Alefeld, G., 1993, “Experimental Investigation of Heat and Mass Transfer in a Horizontal-Tube Falling-Film Absorber with Aqueous Solutions,” Proc. Int. Absorption Heat Pump Conf., Vol. 31, New Orleans, ASME, AES Vol. 31, pp. 225–232.
4.
Remec
,
J.
,
Gjerkes
,
H.
, and
Gaspersic
,
B.
,
1996
, “
Absorption of Vapor into Liquid Film on Horizontal Tubes
,”
ASHRAE Trans.
,
102
, Pt. 1, pp.
973
979
.
5.
Beutler, A., Hoffmann, L., Ziegler, F., Alefeld, G., Gommed, K., Grossman, G., and Shavit, A., 1996, “Experimental Investigation of Heat and Mass Transfer in Film Absorption on Horizontal and Vertical Tubes,” Proc. of Ab-Sorption 96, Vol. I, Montreal, Canada, CANMET-EDRL, Natural Resources Canada, pp. 409–419.
6.
Hoffmann
,
L.
,
Greiter
,
I.
,
Wagner
,
A.
,
Weiss
,
V.
, and
Alefeld
,
G.
,
1996
, “
Experimental Investigation of Heat Transfer in a Horizontal Tube Falling Film Absorber with Aqueous Solutions of LiBr with and without Surfactants
,”
Int. J. Refrig.
,
19
, No.
5
, pp.
331
341
.
7.
Atchley, J. A., Perez-Blanco, H., Kirby, M. J., and Miller, W. A., 1998, “An Experimental and Analytical Study of Advanced Surfaces for Absorption Chiller Absorbers,” final report to the Gas Research Institute (GRI-95/0498).
8.
Bennett, C. O. O., and Myers, J. E., 1962, Momentum, Heat, and Mass Transfer, McGraw-Hill Book Co., Inc., pp. 409–411.
9.
Miller, W., 1998, personal communication (draft of chapter from report).
10.
Kulankara, S., 1999, “Effect of Enhancement Additives on the Absorption of Water Vapor by Aqueous Lithium Bromide,” Ph.D. dissertation, Univ. of Maryland at Baltimore, Baltimore, MD.
11.
Kulankara
,
S.
, and
Herold
,
K. E.
,
2000
, “
Theory of Heat/Mass Transfer Additives in Absorption Chillers
,”
International J. Heating, Ventilating, Air-Conditioning and Refrigeration
,
6
, No.
4
, pp.
369
380
.
12.
Yuan
,
Z.
, and
Herold
,
K. E.
,
2001
, “
Surface Tension of Aqueous Lithium Bromide with Controlled Vapor Concentration of 2-ethyl-hexanol
,”
ASHRAE Trans.
,
107
, Pt. 1, pp.
463
468
.
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