The structural integrity of the containment vessel (CV) for a pressurized water reactor (PWR) plant under a loss-of-coolant accident is evaluated by a safety analysis code that uses the average temperature of gas phase in the CV during reactor operation as an initial condition. Since the estimation of the average temperature by measurement is difficult, this paper addressed the numerical simulation for the temperature distribution in the CV of an operating PWR plant. The simulation considered heat generation of the equipment, the ventilation and air conditioning systems (VAC), heat transfer to the structure, and heat release to the CV exterior based on the design values of the PWR plant. The temperature increased with a rise in height within the CV and the flow field transformed from forced convection to natural convection. Compared with the measured temperature data in the actual PWR plant, predicted temperatures in the lower regions agreed well with the measured values. The temperature differences became larger above the fourth floor, and the temperature inside the steam generator (SG) loop chamber on the fourth floor was most strongly underestimated, 16.2K due to the large temperature gradient around the heat release equipment. Nevertheless, the predicted temperature distribution represented a qualitative tendency, low at the bottom of the CV and increases with a rise in height within the CV. The total volume-averaged temperature was nearly equal to the average gas phase temperature. To improve the predictive performance, parameter studies regarding heat from the equipment and the reconsideration of the numerical model that can be applicable to large temperature gradient around the equipment are needed.

References

1.
Mitsubishi Heavy Industries, Ltd.
,
2000
, “
Mitsubishi PWR Primary Containment Vessel Internal Pressure Evaluation Analysis Method
,” , Mitsubishi Heavy Industries, Ltd., Tokyo (in Japanese).
2.
Japan Nuclear Energy Safety Organization
,
2008
, “
Knowledge Base Development of Accident Management: Investigation of Multi-Dimensional Flow Analysis in the Containment Vessel and Application to an Accident Management by Natural Convection Cooling
,” , Japan Nuclear Energy Safety Organization, Tokyo (in Japanese).
3.
Kim
,
J.
,
Hong
,
S. W.
,
Kim
,
S. B.
, and
Kim
,
H. D.
,
2004
, “
3-Dimensional Analysis of the Steam-Hydrogen Behavior From a Small Break Loss of Coolant Accident in the APR1400 Containment
,”
J. Korean Nucl. Soc.
,
36
(
1
), pp.
24
35
.
4.
Houkema
,
M.
,
Siccama
,
N. B.
,
Lycklama á Nijeholt
,
J. A.
, and
Komen
,
E. M. J.
,
2008
, “
Validation of the CFX4 CFD Code for Containment Thermal-Hydraulics
,”
Nucl. Eng. Des.
,
238
(
3
), pp.
590
599
.10.1016/j.nucengdes.2007.02.033
5.
Paladino
,
D.
,
Zboray
,
R.
,
Benz
,
P.
, and
Andreani
,
M.
,
2010
, “
Three-Gas Mixture Plume Inducing Mixing and Stratification in a Multi-Compartment Containment
,”
Nucl. Eng. Des.
,
240
(
2
), pp.
210
220
.10.1016/j.nucengdes.2008.07.014
6.
Heitsch
,
M.
,
Smith
,
B.
,
Karppinen
,
I.
,
Kimber
,
G.
,
Komen
,
Ed
,
Paillere
,
H.
, and
Willemsen
,
S.
,
2003
, “
Review of CFD Applications to Containment Related Phenomena
,” ECORA Project , European Commission.
7.
Scheuerer
,
M.
,
Heitsch
,
M.
,
Menter
,
F.
,
Egorov
,
Y.
,
Toth
,
I.
,
Bestion
,
D.
,
Pigny
,
S.
,
Paillere
,
H.
,
Martin
,
A.
,
Boucker
,
M.
,
Krepper
,
E.
,
Willemsen
,
S.
,
Muhlbauer
,
P.
,
Andreani
,
M.
,
Smith
,
B.
,
Karlsson
,
R.
,
Henriksson
,
M.
,
Hemstrom
,
B.
,
Karppinen
,
I.
, and
Kimber
,
G.
,
2005
, “
Evaluation of Computational Fluid Dynamic Methods for Reactor Safety Analysis (ECORA)
,”
Nucl. Eng. Des.
,
235
(
2
4
), pp.
359
368
.10.1016/j.nucengdes.2004.08.049
8.
ANSYS Inc.
,
2009
, “
Standard Wall Function
,”
ANSYS FLUENT 12.0 Theory Guide
,
ANSYS Inc.
, pp.
4
76
.
9.
MacGregor
,
R. K.
, and
Emery
,
A. F.
,
1969
, “
Free Convection Through Vertical Plane Layers: Moderate and High Prandtl Number Fluids
,”
ASME J. Heat Transf.
,
91
(
3
), pp.
391
401
.10.1115/1.3580194
10.
The Society of Heating, Air-Conditioning and Sanitary Engineers of Japan
,
1989
,
Maximum Heat Load Calculation Method for Designing
,
The Society of Heating, Air-Conditioning and Sanitary Engineers of Japan
,
Tokyo
, Chap. 3.2.(3), Heat transfer coefficient on outer surface (in Japanese).
11.
The American Society of Mechanical Engineers
,
2009
,
Standard for Verification and Validation in Computational Fluid Dynamics and Heat Transfer
, .
12.
Celik
,
I. B.
,
Ghia
,
U.
,
Roache
,
P. J.
,
Freitas
,
C. J.
, and
Raad
,
P. E.
,
2008
, “
Procedure for Estimation and Reporting of Uncertainty Due to Discretization in CFD Applications
,”
ASME J. Fluid. Eng.
,
130
(
7
), Announcements.10.1115/1.2960953
You do not currently have access to this content.