An analytical model is proposed to study the two-phase flow instabilities of in-phase and out-of-phase modes in parallel boiling channels. This model takes into consideration the interaction between channels with different void fraction variations by modeling the diffusion of neutrons. Linear stability analysis in the frequency domain is performed to obtain stability boundaries and flow oscillation modes. In the case of parallel two channels, two types of stability boundaries are found to exist on the stability map; one for the instability of the in-phase mode and the other for that of the out-of-phase mode respectively. For a certain range of the void-reactivity coefficient, the void-reactivity feedback loop is found to be unstable in a certain region on the stability map, which has an effect on the stability of the in-phase mode. The interaction between channels affects the instability of the out-of-phase mode. The results are also obtained for the case of three and four channels. It is found that the channels having stronger interaction between them are more likely to oscillate in-phase with each other, while those having weaker interaction are more likely to oscillate out-of-phase with each other.

Issue Section:
Phase Change and Multiphase Heat Transfer
Keywords:
Computer Codes, Flow Instability, Multiphase Flows
Topics:
Boiling, Two-phase flow, Stability, Computers, Diffusion (Physics), Feedback, Flow (Dynamics), Flow instability, Modeling, Multiphase flow, Neutrons, Oscillations, Porosity
1.
Araya
F.
,
Hirano
M.
,
Yoshida
K.
,
Matsumoto
K.
,
Yokobayashi
M.
, and
Kohsaka
A.
,
1992
, “
Development of Method to Determine Instability Threshold with RETRAN Code
,”
J. At. Energy Soc. Jpn.
, Vol.
34
, No.
9
, pp.
83
92
.
2.
Blakeman, E. D., and March-Leuba, J., 1989, “A Parametric Analysis of Decay Ratio Calculations in a Boiling Water Reactor,” CONF-890555-4, Proceedings of the 7th Power Plant Dynamics, Control, and Testing Symposium, American Nuclear Society, LaGrange Park, IL.
3.
Boure
J. A.
,
Bergles
A. E.
, and
Tong
L. S.
,
1973
, “
Review of Two-Phase Flow Instability
,”
Nucl. Eng. Des.
, Vol.
25
, pp.
165
192
.
4.
Commonwealth Edition Co., 1977, “LaSalle Country Station Unit 1 and 2 License Application,” Docket-50373-175.
5.
Enomoto, T., Muto, S., Yoshimoto, S., Yokomizo, O., Chuman, K., 1986, “Three Dimensional Stability Analysis of BWR Core,” 2nd International Topical Meeting on Nucl. Power Plant Thermal Hydraulics and Operations, Vol. 2, pp. 15–22.
6.
Fukuda, K., and Kobori, T., 1978, “Two-Phase Flow Instability in Parallel Channels,” Proc. 6th Int. Heat Transfer Conf, Vol. B17, Hemisphere, New York, pp. 369–374.
7.
Fukuda
K.
,
Kage
K.
, and
Hasegawa
S.
,
1982
, “
Analysis on Two-Phase Flow Oscillation Mode in Parallel Multi-Channels
,”
Memoirs of the Faculty of Eng. Kyushu Univ.
, Vol.
42
, No.
3
, pp.
163
175
.
8.
Fukuda, K., Rao, Y. F., and Uehiro, M., 1998, “A Multi-Point Kinetic Model and Its Application to Analyses and Experiments of the Regional Instabilities in BWR’s,” Proc. 6th Int. Conf. on Nuclear Engineering, San Diego, CA, ASME, New York, Paper No. 6113.
9.
Gialdi
E.
,
Grifoni
S.
,
Parmeggiani
C.
, and
Tricoli
C.
,
1985
, “
Core Stability in Operating BWR: Operational Experience
,”
Progress in Nucl. Energy
, Vol.
15
, pp.
447
459
.
10.
Hetrick, D. L., 1971, Dynamics of Nuclear Reactors, University of Chicago Press, Chicago, pp. 260–275.
11.
Ishii, M., and Zuber, N., 1970, “Thermally Induced Flow Instabilities in Two-Phase Mixture,” Proc. 4th Int. Heat Transfer Conf., Vol. B5, Hemisphere, New York, pp. 11–7.
12.
Lahey
R. T.
,
1986
, “
Advances in the Analytical Modeling of Linear and Nonlinear Density-Wave Instability Modes
,”
Nucl. Eng. Des.
, Vol.
95
, pp.
5
34
.
13.
Lahey, R. T., Jr., and Moody, F. J., 1993, The Thermo-Hydraulics of a Boiling Water Nuclear Reactor, 2nd Ed., American Nuclear Society, LaGrange Park, IL.
14.
March-Leuba
J.
, and
Blakeman
E. D.
,
1991
, “
A Mechanism for Out-of-phase Power Instabilities in Boiling Water Reactor
,”
Nucl. Sci. Eng.
, Vol.
107
, pp.
173
179
.
15.
Muto
S.
,
Yokomizo
O.
,
Yoshimoto
Y.
,
Fukahori
T.
, and
Ebata
S.
,
1990
, “
Space-Dependent Analysis of BWR Core Nuclear Thermal Hydraulic Instability and Thermal Margin
,”
Nucl. Eng. Des.
, Vol.
120
, pp.
227
239
.
16.
Rao
Y. F.
,
Fukuda
K.
, and
Kaneshima
R.
,
1995
, “
Analytical Study of Coupled Neutronic and Thermodynamic Instabilities in a Boiling Channel
,”
Nucl. Eng. Des.
, Vol.
154
, pp.
133
144
.
17.
Takeuchi
Y.
, and
Takigawa
Y.
,
1994
, “
TRACG Transient Analysis Code—Three-Dimensional Kinetics Model Implementation and Application for Space-Dependent Analysis
,”
Nucl. Tech.
, Vol.
105
, pp.
162
183
.
18.
Takigawa
Y.
,
Ebata
S.
,
Chan
K. C.
, and
Tricoli
C.
,
1987
, “
CAORSO Limit Cycle Oscillation Analysis with Three-Dimensional Transient Code TOSDIN-2
,”
Nucl. Tech.
, Vol.
79
, pp.
210
227
.
19.
U.S. NRC, 1988, “Augmented Inspection Team Report,” NRC Report No. 50-373/ 88008.
20.
Valtonen, K., 1990, “BWR Stability Analysis,” STUK-A88.
21.
Uehiro, M., Rao, Y. F., and Fukuda, K., 1997, “Multi-Channel Modeling Based on a Multi-Point Reactor Model for the Regional Instability in BWRs,” Proc. 8th Int. Topical Meeting on Nuclear Reactor Thermal-Hydraulics, (Nureth-8), Vol. 1, Kyoto, Japan, American Nuclear Society, LaGrange, IL, pp. 375–384.
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