soil-structure interaction effectsradiation of energy back into the ground from the structure...
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Soil-Structure Interaction Effects
" Various aspects of soil-structure interaction (SSI) result in reducedmotion of the foundation basernat of a structure from that recordedby an instrument on a small pad
" These reductions are due to wave scattering effects includingvertical and horizontal spatial variation of the ground motion, andradiation of energy back into the ground from the structure (radiationdamping).- These effects always result in a reduction of the foundation
motion.
* Soil-structure interaction also results in a frequency shift, primarily ofthe fundamental frequency of the structure.
- Such a frequency shift can either reduce or increase theresponse of the structure foundation. As a result, any frequencyshifting due to SSI, when significant, must always be considered.
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I Demonstration of SSI Effects
* A 3-stick model of a typical NPP structure on a rock sitesubjected to high frequency input motion has beenconsidered
" In-structure response spectra are generated from SASSIanalyses
" Both coherent and incoherent ground motion has beenconsidered
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Representative NPPStructure StickModel with Outriggersand Offset MassCenters
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I Structural Model Characteristics
" Advanced reactor structure stick model witheccentricities- 160 fixed-base modes model the dynamic characteristics of the
structure
- Frequencies 3.0 Hz - 141 Hz
- Total mass (x = 92.7%, y = 92.5%, z = 93.1%)
" Three sticks are coupled at various locations - modesare coupled- ASB-3.2 Hz; SCV-5.5 Hz;CIS-13.3 Hz fixed base
" Relative mass distribution- ASB - 86%
- CIS-11%
- SCV-3%I___I ll 'iI
I Rock Site ProfileShear Wave Velocities vs. Depth
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I Site-Specific Response Spectra forRock Site at Ground Surface (Depth O-ft)
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I Importance of SSI- Foundation Response
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I mportance of SSI - Shield BuildingResponse
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I Importance of SSI - Steel ContainmentVessel Response
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I mportance of SSI -Containment InternalStructure Response
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I SSI Effects: Soil Stiffness
* Seismic input motion
- RG 1.60
* Soil stiffness as characterized by shear wave velocity
- Stiff rock Vs = 6,000 fps
- Stiff soil Vs = 2,500 fps
- Medium soil Vs = 1,000 fps
- Soft soil Vs = 500 fps* In-structure response spectra (Node 18x)
* Combined Effects of Frequency Shift and RadiationDamping
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I Observation of SSI Effects: Soil Stiffness
Response Spectra, Node 18. x-D1rdion
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I SSI Effects: Structure Damping
" Seismic input motion
- RG 1.60
" Soil stiffness as characterized by shear wave velocity
- Stiff rock Vs = 6,000 fps
- Soft soil Vs = 500 fps• Structure Damping (4% and 10%)" In-structure response spectra (Node 18x)" Importance of Structure Damping dependent on SSI
Effects
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Observation of SSI Effects: StructureDamping
Response Spectra, Node 18, x-Diredion
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I Observation of SSI Effects
" It is shown that SSI analysis is very important forstructures on rock sites subjected to high frequencyground motion
" There are significant reductions in response at highfrequencies due to frequency shifting below the power ofthe input and radiation damping
* There are significant increases in response at lowfrequencies due to induced rotations from SSI and fromincoherence
• There is as much reduction in high frequency responsefrom SSI on a rock site with high frequency input motionas there is from incoherence
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Damping
• Structure and soil damping is typically very low- Structure - 4% of critical Response Level 1- Soil - less than 10% of critical depending on
earthquake strain" Radiation damping due to SSI
- Can be very large approaching critical damping foruniform sites
- Can be low for shallow soil over rock site- Impedance mismatch of soil layers prevents radiation
of energy out from the structure
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! Demonstration of Effects of Embedment andIncoherence
" Simple NPP structure has been investigated todemonstrate the effects of embedment and incoherence
• Four cases were evaluated- Surface founded, coherent ground motion- Surface founded, incoherent ground motion- Embedded, coherent ground motion- Embedded, incoherent ground motion
" Embedment ratio of 0.5 was considered" The high frequency ground motion input and soil profile
used for other evaluation was employed
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I Embedment - Structural Model
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I Embedment - Structural Model
" Reactor building shell radius = 84.63 feet" Height of springline above basemat = 151.3 feet
" Wall thickness = 3.5 feet" Basemat radius = 84.63 feet
" Basemat thickness = 10 feet" 93 foot high internal structure" Frequencies
- Reactor Building shell horizontal: 3.9 Hz, 11.3 Hz- Reactor Building shell vertical: 10.5 Hz, 17.4 Hz- Internal Structure horizontal: 12.0 Hz, 17.5 Hz, 46.5 Hz- Internal Structure vertical: 39.4 Hz
" Embedment depth = 42 feet
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I Ground Motion and Soil Profile
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I Foundation Horizontal Response
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IoTop of Containment Shell HorizontalResponse
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I Internal Structure Mid-Height HorizontalResponse
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ITop of Internal Structure HorizontalResponse
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IObservations on Embedment andIncoherence
"In general, embedment produces reduced ISRS and formany cases this reduction is very significant- An exception is at the top of the containment shell. At this
location, the 2nd fixed base mode is 11 Hz and the SSI modesare 11 Hz for the surface case and 13 Hz for the embeddedcase. The 13 Hz mode and high frequency input resulted inincreased response for the embedded case
" Incoherency effects are independent of structureembedment- There is no systematic bias in the relatively small differences in
incoherency effects for both surface founded and embeddedstructures
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