An explosive type of vapor bubble growth was observed during pool boiling experiments in microgravity using R-113. Photographs reveal that the liquid-vapor interface of the explosive bubbles are wrinkled and corrugated, leading to the conclusion that some type of instability mechanism is acting. The classical hydrodynamic instability theories of Landau and Rayleigh-Taylor do not consider the effect of heat transfer, at the interface, which is believed to be responsible for the observed instability of the evaporating surface. This was confirmed by the mechanisms proposed by Prosperetti and Plesset, combined with a model of the early growth of spherical vapor bubbles.
Issue Section:
Boiling and Condensation
1.
Avedisian
C. T.
1985
, “The Homogeneous Nucleation Limits of Liquids
,” J. Phys. Chem. Ref. Data
, Vol. 14
, No. 3
, pp. 695
–729
.2.
Birkhoff
G.
1956
, “Stability of Spherical Bubble
,” Q. Appl. Math.
, Vol. 13
, pp. 451
451
.3.
Ervin, J. S., 1991, “Incipient Boiling in Microgravity,” Ph.D. thesis, University of Michigan, Ann Arbor, MI.
4.
Ervin
J. S.
Merte
H.
Keller
R. B.
Kirk
K.
1992
, “Transient Pool Boiling in Microgravity
,” Int. J. Heat Mass Transfer
, Vol. 35
, pp. 659
–674
.5.
Frost
D. L.
1988
, “Dynamics of Explosive Boiling of a Droplet
,” Phys. Fluids
, Vol. 31
, pp. 2554
–2561
.6.
Frost
D.
Sturtevant
B.
1986
, “Effects of Ambient Pressure on the Instability of a Liquid Boiling Explosively at the Superheat Limit
,” ASME JOURNAL OF HEAT TRANSFER
, Vol. 108
, pp. 418
–424
.7.
Grolmes, M. A., and Fauske, H. K., 1974, “Axial Propagation of Free Surface Boiling into Superheated Liquids in Vertical Tubes,” Proceeding of the Fifth International Heat Transfer Conference, Vol. 4, JSME, Tokyo, pp. 30–34.
8.
Higuera
F. J.
1987
, “The Hydrodynamic Stability of an Evaporating Liquid
,” Phys. Fluids
, Vol. 30
, pp. 679
–686
.9.
Istratov
A. G.
Librovich
V. B.
1969
, “On the Stability of Gasdynamic Discontinuities Associated with Chemical Reactions: The Case of a Spherical Flame
,” Astronautica Acta
, Vol. 14
, pp. 453
–467
.10.
Landau
L.
1944
, “On the Theory of Slow Combustion
,” Acta Physicochemica U.S.S.R.
, Vol. 19
, pp. 76
–85
.11.
Landau, L., and Lifshitz, E. M., 1959, Fluid Mechanics, Pergamon, New York, pp. 479.
12.
Lee, H. S., 1993, “Vapor Bubble Dynamics in Microgravity,” Ph.D. thesis, The University of Michigan, Ann Arbor, MI.
13.
Lee
H. S.
Merte
H.
1996
a, “Spherical Bubble Growth in Liquids in Uniformly Superheated Liquids
,” Int. J. Heat Mass Transfer
, Vol. 39
, No. 12
, pp. 2427
–2447
.14.
Lee
H. S.
Merte
H.
1996
b, “Hemispherical Vapor Bubble Growth in Microgravity: Experiments and Model
,” Int. J. Heat Mass Transfer
, Vol. 39
, No. 12
, pp. 2449
–2461
.15.
McCann
H.
Clarke
L. J.
Masters
A. P.
1989
, “An Experimental Study of Vapour Growth at the Superheat Limit Temperature
,” Int. J. Heat Mass Transfer
, Vol. 32
, pp. 1077
–1093
.16.
Merte
H.
Lee
H. S.
1997
, “Quasi-Homogeneous Nucleation in Micro-gravity at Low Heat Flex: Experiments and Theory
,” ASME JOURNAL OF HEAT TRANSFER
, Vol. 119
, pp. 305
–312
.17.
Mikic
B. B.
Rohsenow
W. M.
Griffith
P.
1970
, “On Bubble Growth Rates
,” Int. J. Heat Transfer
, Vol. 13
, pp. 657
657
.18.
Miller
C. A.
1973
, “Stability of Moving Surface in Fluid Systems With Heat and Mass Transport
,” AIChE Journal
, Vol. 19
, No. 5
, pp. 909
–915
.19.
Palmer
H. J.
1976
, “The Hydrodynamic Stability of Rapidly Evaporating Liquids at Reduced Pressure
,” J. Fluid Mech.
, Vol. 75
, pp. 487
–511
.20.
Palmer
H. J.
Maheshri
J. C.
1981
, “Enhanced Interfacial Heat Transfer by Differential Vapor Recoil Instabilities
,” Int. J. Heat Transfer
, Vol. 4
, pp. 117
–123
.21.
Plesset
M. S.
1954
, “On the Stability of Fluid Flows With Spherical Symmetry
,” J. Appl. Phys.
, Vol. 25
, pp. 96
–98
.22.
Plesset
M. S.
Prosperetti
A.
1977
, “Bubble Dynamics and Cavitation
,” Ann. Rev. Fluid Mech.
, Vol. 9
, pp. 145
–185
.23.
Plesset
M. S.
Zwick
S. A.
1954
, “The Growth of Vapor Bubble in Superheated Liquid
,” J. Appl. Phys.
, Vol. 25
, pp. 493
493
.24.
Prosperetti
A.
Plesset
M. S.
1978
, “Vapor Bubble Growth in a Superheated Liquid
,” J. Fluid Mech.
, Vol. 85
, Part 2, pp. 349
–368
.25.
Prosperetti
A.
Plesset
M. S.
1984
, “The Stability of an Evaporating Liquid Surface
,” Phys. Fluids
, Vol. 27
, pp. 1590
–1602
.26.
Rayleigh, 1917, Phil. Mag., No. 34, p. 94.
27.
Reid
R. C.
1983
, “Rapid Phase Transitions from Liquid to Vapor
,” Advances in Chemical Engineering
, Vol. 12
, pp. 105
–208
.28.
Shepherd
J. E.
Sturtevant
B.
1982
, “Rapid Evaporation at the Superheat Limit
,” J. Fluid Mech.
, Vol. 121
, pp. 379
–402
.29.
Sturtevant
B.
Shepherd
J. E.
1982
, “Evaporative Instability at the Superheat Limit
,” Appl. Sci. Res.
, Vol. 38
, pp. 85
–97
.30.
Taylor
G. I.
1950
, “The Stability of Liquid Surfaces When Accelerated in a Direction Perpendicular to Their Planes: I
,” Proc. R. Soc. Land.
, Vol. A201
, pp. 192
192
.
This content is only available via PDF.
Copyright © 1998
by The American Society of Mechanical Engineers
You do not currently have access to this content.