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http://dx.doi.org/10.1016/j.net.2016.12.018

Visualization of Crust in Metallic Piping Through Real-Time Neutron Radiography Obtained with Low Intensity Thermal Neutron Flux  

Luiz, Leandro C. (Nuclear Engineering Program, Federal University of Rio de Janeiro)
Ferreira, Francisco J.O. (National Nuclear Energy Commission, CNEN/IEN, Division Reactors)
Crispim, Verginia R. (Nuclear Engineering Program, Federal University of Rio de Janeiro)
Publication Information
Nuclear Engineering and Technology / v.49, no.4, 2017 , pp. 781-786 More about this Journal
Abstract
The presence of crust on the inner walls of metallic ducts impairs transportation because crust completely or partially hinders the passage of fluid to the processing unit and causes damage to equipment connected to the production line. Its localization is crucial. With the development of the electronic imaging system installed at the Argonauta/Nuclear Engineering Institute (IEN)/National Nuclear Energy Commission (CNEN) reactor, it became possible to visualize crust in the interior of metallic piping of small diameter using real-time neutron radiography images obtained with a low neutron flux. The obtained images showed the resistance offered by crust on the passage of water inside the pipe. No discrepancy of the flow profile at the bottom of the pipe, before the crust region, was registered. However, after the passage of liquid through the pipe, images of the disturbances of the flow were clear and discrepancies in the flow profile were steep. This shows that this technique added the assembled apparatus was efficient for the visualization of the crust and of the two-phase flows.
Keywords
Nondestructive Assays; Real-Time Neutron Radiography; Two-Phase Flow;
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  • Reference
1 J.G. Collier, Convective Boiling and Condensation, second ed., McGraw Hill, New York, 1981.
2 K. Sonada, A. Ono, N. Takenaka, T. Fujii, S. Tazawa, T. Nakani, Visualization and volumetric fraction measurement of multiphase flow by neutron radiography, in: Proceedings of the Fourth World Conference, Gordon and Breach Science Publishers, John P. Barton, San Francisco, California, USA, 1993, pp. 347-354.
3 W.J. Richards, M.J. Tuttle, K. Ulowetz, R. Mcgee, Real-Time Neutron Radiography - Applications for the Automotive Industry, UCD McClellan Nuclear Radiation Center, UC Davis, 2003. Available from: http://escholarship.org/uc/item/35t9b89n.
4 H. Berger, Advances in neutron radiographic techniques and applications: a method for nondestructive testing, Appl Radiat Isot 61 (2004) 437-442.   DOI
5 R.C. Lanza, E.W. McFarland, S. Shi, Cooled-CCD and amorphous silicon-based neutron imaging systems for low-fluence neutron sources, in: Proc. SPIE 2867, International Conference Neutrons in Research and Industry 1996, Crete, Greece, 1997, pp. 332-338.
6 F.J.O. Ferreira, V.R. Crispim, A.X. Silva, Detection of drugs and explosives using neutron computerized tomography and artificial intelligence technique, Appl Radiat Isot 68 (2010) 1012-1017.   DOI
7 International Atomic Energy Agency (IAEA), IAEA-TECDOC-1604 Neutron Imaging: A Nondestructive Tool for Materials Testing Report of a coordinated research project 2003-2006, IAEA, Vienna, Austria, 2008.
8 F.J.O. Ferreira, V.R. Crispim, A.X. Silva, Electronic imaging system for neutron radiography at a low power research reactor, Radiat. Meas. 45 (2010) 806-809.   DOI
9 F. Casali, P. Chirco, M. Zanarini, Advanced imaging techniques: the new deal for neutron physics, La Revista del Nuovo Cimento 18 (1995) 1-69.
10 M. Ishii, N. Zuber, Drag coefficient and relative velocity in bubbly, droplet, or particulate flows, AlChE 25 (1979) 843-855.   DOI
11 G.B. Wallis, One-Dimensional Two-phase Flow, second ed., McGraw Hill, New York, 1979.
12 M. Ishii, ONE-dimensional Drift-flux Model and Constitutive Equation for Relative Motion between Phases in Various Two-phase Flow Regimes, Report No. ANL 77-47, Argonne National Lab, Lemont (IL), 1977.