Statistical analysis of the variation of floor vibrations in nuclear power plants subject to seismic loads

•Floor flexibility plays a non-negligible role in amplifying horizontal vibrations.•COV of in-floor horizontal and vertical acceleration are 0.15–0.25 and 0.25–0.55.•In-floor variation of vibrations is higher in lower floors.•Floor spectra from limited nodes underestimates vibrations by a factor of...

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Published in	Nuclear engineering and design Vol. 309; pp. 84 - 96
Main Authors	Jussila, Vilho, Li, Yue, Fülöp, Ludovic
Format	Journal Article
Language	English
Published	Amsterdam Elsevier B.V 01.12.2016 Elsevier BV
Subjects	3-D technology Acceleration Aseismic buildings Bedrock Computer simulation Confidence Damping Data processing Earthquake accelerograms Earthquake construction Earthquake dampers Energy modeling Engineering Flooring Ground motion Integration Nuclear electric power generation Nuclear energy Nuclear power plants Response spectra Seismic engineering Seismic response Statistical analysis Statistics Studies Three dimensional models Time integration Vibration Vibrations SSC CDF ABBSUM A. Engineering Mechanics SSI MDOF ZPA COV PGA SDOF CQC SRSS EMPF PSA
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Abstract	•Floor flexibility plays a non-negligible role in amplifying horizontal vibrations.•COV of in-floor horizontal and vertical acceleration are 0.15–0.25 and 0.25–0.55.•In-floor variation of vibrations is higher in lower floors.•Floor spectra from limited nodes underestimates vibrations by a factor of 1.5–1.75. Floor vibration of a reactor building subjected to seismic loads was investigated, with the aim of quantifying the variability of vibrations on each floor. A detailed 3D building model founded on the bedrock was excited simultaneously in three directions by artificial accelerograms compatible with Finnish ground response spectra. Dynamic simulation for 21s was carried out using explicit time integration. The extracted results of the simulation were acceleration in several floor locations, transformed to pseudo-acceleration (PSA) spectra in the next stage. At first, the monitored locations on the floors were estimated by engineering judgement in order to arrive at a feasible number of floor nodes for post processing of the data. It became apparent that engineering judgment was insufficient to depict the key locations with high floor vibrations, which resulted in un-conservative vibration estimates. For this reason, a more systematic approach was later considered, in which nodes of the floors were selected with a more refined grid of 2m. With this method, in addition to the highest PSA peaks in all directions, the full vibration distribution in each floor can be determined. A statistical evaluation of the floor responses was also carried out in order to define floor accelerations and PSAs with high confidence of non-exceedance. The conclusion was that in-floor variability can be as high as 50–60% and models with sufficiently dense node grids should be used in order to achieve a realistic estimate of floor vibration under seismic action. The effects of the shape of the input spectra, damping, and flexibility of the floors on floor vibration of nuclear power plant buildings were also investigated.
AbstractList	Floor vibration of a reactor building subjected to seismic loads was investigated, with the aim of quantifying the variability of vibrations on each floor. A detailed 3D building model founded on the bedrock was excited simultaneously in three directions by artificial accelerograms compatible with Finnish ground response spectra. Dynamic simulation for 21 s was carried out using explicit time integration. The extracted results of the simulation were acceleration in several floor locations, transformed to pseudo-acceleration (PSA) spectra in the next stage. At first, the monitored locations on the floors were estimated by engineering judgement in order to arrive at a feasible number of floor nodes for post processing of the data. It became apparent that engineering judgment was insufficient to depict the key locations with high floor vibrations, which resulted in un-conservative vibration estimates. For this reason, a more systematic approach was later considered, in which nodes of the floors were selected with a more refined grid of 2 m. With this method, in addition to the highest PSA peaks in all directions, the full vibration distribution in each floor can be determined. A statistical evaluation of the floor responses was also carried out in order to define floor accelerations and PSAs with high confidence of non-exceedance. The conclusion was that in-floor variability can be as high as 50-60% and models with sufficiently dense node grids should be used in order to achieve a realistic estimate of floor vibration under seismic action. The effects of the shape of the input spectra, damping, and flexibility of the floors on floor vibration of nuclear power plant buildings were also investigated. •Floor flexibility plays a non-negligible role in amplifying horizontal vibrations.•COV of in-floor horizontal and vertical acceleration are 0.15–0.25 and 0.25–0.55.•In-floor variation of vibrations is higher in lower floors.•Floor spectra from limited nodes underestimates vibrations by a factor of 1.5–1.75. Floor vibration of a reactor building subjected to seismic loads was investigated, with the aim of quantifying the variability of vibrations on each floor. A detailed 3D building model founded on the bedrock was excited simultaneously in three directions by artificial accelerograms compatible with Finnish ground response spectra. Dynamic simulation for 21s was carried out using explicit time integration. The extracted results of the simulation were acceleration in several floor locations, transformed to pseudo-acceleration (PSA) spectra in the next stage. At first, the monitored locations on the floors were estimated by engineering judgement in order to arrive at a feasible number of floor nodes for post processing of the data. It became apparent that engineering judgment was insufficient to depict the key locations with high floor vibrations, which resulted in un-conservative vibration estimates. For this reason, a more systematic approach was later considered, in which nodes of the floors were selected with a more refined grid of 2m. With this method, in addition to the highest PSA peaks in all directions, the full vibration distribution in each floor can be determined. A statistical evaluation of the floor responses was also carried out in order to define floor accelerations and PSAs with high confidence of non-exceedance. The conclusion was that in-floor variability can be as high as 50–60% and models with sufficiently dense node grids should be used in order to achieve a realistic estimate of floor vibration under seismic action. The effects of the shape of the input spectra, damping, and flexibility of the floors on floor vibration of nuclear power plant buildings were also investigated.
Author	Fülöp, Ludovic Li, Yue Jussila, Vilho
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Snippet	•Floor flexibility plays a non-negligible role in amplifying horizontal vibrations.•COV of in-floor horizontal and vertical acceleration are 0.15–0.25 and... Floor vibration of a reactor building subjected to seismic loads was investigated, with the aim of quantifying the variability of vibrations on each floor. A...
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SubjectTerms	3-D technology Acceleration Aseismic buildings Bedrock Computer simulation Confidence Damping Data processing Earthquake accelerograms Earthquake construction Earthquake dampers Energy modeling Engineering Flooring Ground motion Integration Nuclear electric power generation Nuclear energy Nuclear power plants Response spectra Seismic engineering Seismic response Statistical analysis Statistics Studies Three dimensional models Time integration Vibration Vibrations
Title	Statistical analysis of the variation of floor vibrations in nuclear power plants subject to seismic loads
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