The primary objective of this research is to develop an extensive experimental database for the airingress phenomenon for the validation of computational fluid dynamics (CFD) analyses. This research is intended to be a separate-effects experimental study. However, the project team will perform a careful scaling analysis prior to designing a scaled-down test facility in order to closely tie this research with the real application. As a reference design in this study, the team will use the 600 MWth gas turbine modular helium reactor (GT-MHR) developed by General Atomic. In the test matrix of the experiments, researchers will vary the temperature and pressure of the helium— along with break size, location, shape, and orientation—to simulate deferent scenarios and to identify potential mitigation strategies. Under support of the Department of Energy, a high-temperature helium test facility has been designed and is currently being constructed at Ohio State University, primarily for hightemperature compact heat exchanger testing for the VHTR program. Once the facility is in operation (expected April 2009), this study will utilize high-temperature helium up to 900°C and 3 MPa for loss-of-coolant accident (LOCA) depressurization and air-ingress experiments. The project team will first conduct a scaling study and then design an air-ingress test facility. The major parameter to be measured in the experiments is oxygen (or nitrogen) concentration history at various locations following a LOCA scenario. The team will use two measurement techniques: 1) oxygen (or similar type) sensors employed in the flow field, which will introduce some undesirable intrusiveness, disturbing the flow, and 2) a planar laser-induced fluorescence (PLIF) imaging technique, which has no physical intrusiveness to the flow but requires a transparent window or test section that the laser beam can penetrate. The team will construct two test facilities, one for high-temperature helium tests with local sensors and the other for lowtemperature helium tests with the PLIF technique. The results from the two instruments will provide a means to cross-calibrate the measurement techniques.
[1]
Ronald K. Hanson,et al.
Pressure and composition dependences of acetone laser-induced fluorescence with excitation at 248, 266, and 308 nm
,
1999
.
[2]
H. No,et al.
Experimental study on the oxidation of nuclear graphite and development of an oxidation model
,
2006
.
[3]
Eung Soo Kim,et al.
Air-ingress analysis: Part 1. Theoretical approach
,
2011
.
[4]
Eung Soo Kim,et al.
Air-ingress analysis: Part 2—Computational fluid dynamic models
,
2011
.
[5]
R. Moormann,et al.
Phenomenology of Graphite Burning in Air Ingress Accidents of HTRs
,
2011
.
[6]
R. Hanson,et al.
Simultaneous imaging of temperature and mole fraction using acetone planar laser-induced fluorescence
,
2001
.
[7]
Stuart B. Dalziel,et al.
Gravity currents produced by lock exchange
,
2004,
Journal of Fluid Mechanics.
[8]
Brian Jackson,et al.
Scaling analysis for the high temperature Gas Reactor Test Section (GRTS)
,
2010
.
[9]
T. Benjamin.
Gravity currents and related phenomena
,
1968,
Journal of Fluid Mechanics.
[10]
R. Hanson,et al.
Temperature imaging with single- and dual-wavelength acetone planar laser-induced fluorescence.
,
1997,
Optics letters.
[11]
Eung Soo Kim,et al.
Conceptual Study on Air Ingress Mitigation for VHTRs
,
2012
.
[12]
T. Maruyama,et al.
Change in physical properties of high density isotropic graphites irradiated in the 'JOYO' fast reactor
,
1995
.
[13]
A. Banerjee,et al.
A Convection Heat Transfer Correlation for a Binary Air-Helium Mixture at Low Reynolds Number
,
2007
.
[14]
E. Kim,et al.
Analysis on the Density Driven Air-Ingress Accident in VHTRs
,
2008
.
[15]
Luo Xiaowei,et al.
Effect of temperature on graphite oxidation behavior
,
2004
.
[16]
Eung Soo Kim,et al.
Validations of CFD Code for Density-Gradient Driven Air Ingress Stratified Flow
,
2010
.