TY - JOUR
T1 - On the flow induced vibration of an externally excited nuclear reactor experiment
AU - Latimer, Griffen
AU - Marcum, Wade R.
AU - Howard, Trevor K.
AU - Jones, Warren
AU - Phillips, Ann Marie
AU - Woolstenhulme, Nicolas
AU - Liu, Suyang
AU - Weiss, Aaron
AU - Campbell, Jed
AU - Moussaoui, Musa
AU - Jensen, Colby
N1 - Publisher Copyright:
© 2018
PY - 2018/8/15
Y1 - 2018/8/15
N2 - An in-pile, drop-in experiment design is presently being designed and studied for the near-term deployment within the Advanced Test Reactor (ATR) located at the Idaho National Laboratory (INL); this experiment is termed the Miniplate-1 Large-B (MP-1 LB) Experiment. A number of explicit studies are performed during the design- and safety-related stage. Traditionally, a clear and logical methodology has been developed and utilized for analyses such as hydraulics, thermal-loads, mechanical loads, and others for these experiments. Recently a small component from a different experiment assembly mechanically separated while in the reactor's core. While this experiment didn't compromise the safety of the reactor, it led to a higher-level question which centered on whether the appropriate level of consideration was being made toward the fluid–structure-interactions of these experiments. The outcome yielded separate flow test experiments of like-for-like geometry in an experimental loop located at Oregon State University which produces experimental data compliant with applicable parts and requirements to ASME's NQA-1 2008, 2009a standard – suitable for benchmark evaluation. The objectives of this study are to (1) develop a process for handling and interpreting the mechanical response of the test elements during hydraulic testing, to (2) characterize the motion of a specific test element during a flow test which imposes a wide range of hydraulic conditions, and (3) provide objective observations toward the potential safety related implications that are tied to the synthesized data. The outcome of this study has led to a confident process in inspecting the experimental data, synthesized it for interpretation, identified several unique hydraulic characteristics of the experiment design which were previously unknown, and demonstrated that the likelihood for mechanical failure resulting from fluid-structure-interactions in the reactor is far below any criterion for concern of the element's safety.
AB - An in-pile, drop-in experiment design is presently being designed and studied for the near-term deployment within the Advanced Test Reactor (ATR) located at the Idaho National Laboratory (INL); this experiment is termed the Miniplate-1 Large-B (MP-1 LB) Experiment. A number of explicit studies are performed during the design- and safety-related stage. Traditionally, a clear and logical methodology has been developed and utilized for analyses such as hydraulics, thermal-loads, mechanical loads, and others for these experiments. Recently a small component from a different experiment assembly mechanically separated while in the reactor's core. While this experiment didn't compromise the safety of the reactor, it led to a higher-level question which centered on whether the appropriate level of consideration was being made toward the fluid–structure-interactions of these experiments. The outcome yielded separate flow test experiments of like-for-like geometry in an experimental loop located at Oregon State University which produces experimental data compliant with applicable parts and requirements to ASME's NQA-1 2008, 2009a standard – suitable for benchmark evaluation. The objectives of this study are to (1) develop a process for handling and interpreting the mechanical response of the test elements during hydraulic testing, to (2) characterize the motion of a specific test element during a flow test which imposes a wide range of hydraulic conditions, and (3) provide objective observations toward the potential safety related implications that are tied to the synthesized data. The outcome of this study has led to a confident process in inspecting the experimental data, synthesized it for interpretation, identified several unique hydraulic characteristics of the experiment design which were previously unknown, and demonstrated that the likelihood for mechanical failure resulting from fluid-structure-interactions in the reactor is far below any criterion for concern of the element's safety.
UR - http://www.scopus.com/inward/record.url?scp=85046776649&partnerID=8YFLogxK
U2 - 10.1016/j.nucengdes.2018.05.007
DO - 10.1016/j.nucengdes.2018.05.007
M3 - Article
AN - SCOPUS:85046776649
SN - 0029-5493
VL - 335
SP - 1
EP - 17
JO - Nuclear Engineering and Design
JF - Nuclear Engineering and Design
ER -