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DNV-OS-C502 Offshore Concrete Structures

App.D: Seismic Analysis (Guidelines)

A: General

A100: Seismic analysis

App.D
A 100   Seismic analysis

LNG containment structures shall be designed in accordance with DNV-OS-C503. The LNG storage tank shall be designed for both the SLE and DLE earthquakes. Systems which are vital for the plant system shall remain operational for both SLE and DLE.

App.D A
102   If ductile response of specific components of the structure under the SLE event is predicted or considered in the analysis, such components shall be designed for ductile behaviour, in accordance with Sec.6. Expected best estimate of stress/strain parameters associated with ductile behaviour may be adopted in the analyses. Due consideration shall be given to the effects of overstrength with respect to the transfer of forces into adjoining members, and for the design of those failure modes of such members that are not ductile, such as shear failure. For those cases where the structure can be designed to the DLE event applying normal ULS criteria, no special detailing for ductility is required.

App.D A
103   Seismic events may be represented by input response spectra or by time histories of significant ground motion, in accordance with DNV-OS-C101 Sec.3 E800. Where the global response of the structure is essentially linear, a dynamic spectral analysis shall normally be appropriate. Where non-linear response of the structure is significant, transient dynamic analysis shall be performed.

App.D A
104   Seismic response of a structure is highly dependent on the natural periods of the structure over a range of modes. This relies upon accurate assessments of the platform mass and stiffness, and a best estimate of soil stiffness.

Such parameters shall be carefully assessed and, if necessary, the sensitivity of the structure to changes in these parameters shall be evaluated.

App.D A
105   Interaction of the structure with its foundation is particularly significant for seismic analysis. The foundation shall be simulated with sufficient accuracy in global structural analysis to ensure accurate assessment of natural periods of vibration and a suitable distribution of soil loads into the structure.

App.D A
106   Two principal types of seismic analyses are suggested for fixed concrete structures:

—	direct soil-structure analysis
—	impedance function/substructure analysis.

App.D A
107   For direct soil-structure analysis, the caisson may be modelled as a rigid structure connected to a flexible simulation of the foundation. In substructure analysis, the caisson may be considered as a rigid circular disk for the computation of impedance functions.

App.D A
108   Consideration shall be given to the range of likely values of soil stiffness in the analysis. In particular, the possible degradation of soil properties during high-level seismic events, such as the ductility level earthquake, shall be considered. Appropriate non-linear or reduced soil stiffness properties shall be used.

App.D A
109   Soil properties, particularly shear wave velocity, dynamic shear modulus and internal damping are dependent on the shear strains used. These values should be adjusted for the expected strains appropriate to the seismic excitation and the variation in vertical effective stress and voids ratio due to the presence of the structure.

App.D A
110   The simulation shall include a representation of the mass of the structure, in accordance with Appendix B A300. Enclosed fluids can be included as a lumped mass where the height of water column is short.

App.D A
111   Unless a detailed evaluation is made, critical internal damping of not more than 5% shall be used to simulate structural and hydrodynamic damping for seismic analysis. Any increased value shall be subject to justification based on expected response. Values of soil damping shall be determined based on the soil type present.

App.D A
112   For the strength level earthquake, linear dynamic global structural analysis may be performed using the response spectrum approach. Spectra used shall be in accordance with DNV-OS-C101 Sec.3 E800, but the analysis shall incorporate the effect of the platform mass on near soil motions, if appropriate. If degradation of soil properties and non-linear soil-structural interaction are significant, a non-linear dynamic time history analysis procedure should be adopted to address these effects, although the platform structure may be modelled as linear elastic. Where seismic isolation or passive energy dissipation devices are employed to mitigate the seismic risk, a non-linear time history procedure will be required. If degradation of soil properties, non-linear soil-structural interaction or base sliding is significant, a non-linear dynamic time history analysis procedure should be adopted to address these effects.

App.D A
113   Sufficient modes shall be included in the analysis to provide an accurate estimate of total global response. At least two modes shall be considered in each of the two principal horizontal directions and a torsional mode about a vertical axis. This requirement may be considered satisfied if it is demonstrated that for the modes considered in the analysis, at least 90% of the participating mass of the structure is included in the calculation of response for each principal horizontal direction.

App.D A
114   One design spectrum may be used equally in each principal horizontal direction, combined with 2/3 of this spectrum in the vertical direction unless a lesser value can be justified based on site-specific data. These spectra may be combined together modally using the complete quadratic combination method (CQCM) and directionally using a square root sum square (SRSS) approach. Alternative methods are permitted with suitable justification that all seismic action effects are included.

App.D A
115   Secondary spectra may be developed for the analysis of components such as deck or conductor frames to evaluate the response of substructures, appurtenances and equipment not modelled for the global analysis. Alternatively, the design of local components may be based on equivalent pseudo-static analysis of such components, based on maximum vertical and horizontal accelerations obtained from the global seismic analysis.

App.D A
116   Action effects from seismic analysis shall be combined with similar results from gravity loading to produce action effects for structural design. Appropriate directions of seismically induced forces shall be considered to maximize these action effects.

App.D A
117   For the ductility level earthquake, non-linear seismic analysis may be performed using a time history or transient approach. Unless time histories are available by scaling or by other means, they may be developed numerically from the design spectra. Multiple time histories are required to represent the random nature of seismic ground motions. At least three sets of tri-axial statistically independent time histories shall be developed and used, and the maximum response parameters shall be adopted in the design. The requirement for statistically independent time histories may be considered satisfied if the correlation coefficient between any pair of time histories is less than 0.3. The time step for integration shall be selected to ensure accuracy and stability of the non-linear dynamic solution, normally it should not be more than 1/(12f).

App.D A
118   The computer model for ductility level earthquake analysis shall include discrete models of all primary components of the structure using either linear elastic or material non-linear simulations. Deflection effects shall be evaluated and gravitational loads included in the analysis to ensure that second order effects are simulated with sufficient accuracy.

App.D A
119   The action effects on components that are simulated as linear elastic in either the SLE or the DLE analyses shall be evaluated and used to confirm that these components satisfy ULS criteria. Components that demonstrate ductile response shall be so designed, and assessed against acceptance criteria relevant for the actual limit state with respect to all relevant response parameters.