000015796 001__ 15796
000015796 005__ 20161115135330.0
000015796 04107 $$aeng
000015796 046__ $$k2013-06-12
000015796 100__ $$aSalonikios, T.
000015796 24500 $$aSeismic Load Assessment for Masonry Monumental Buildings

000015796 24630 $$n34.$$pComputational Methods in Structural Dynamics and Earhquake Engineering
000015796 260__ $$bNational Technical University of Athens, 2013
000015796 506__ $$arestricted
000015796 520__ $$2eng$$aIn present work, selected experimental data of the last 25 years are used together with the inelastic analysis of masonry frames and the postprocessing of the records of strong earthquakes in Northern Greece, for the estimation of rational seismic loads that are appropriate for the seismic evaluation and/or upgrade of existing masonry buildings. The estimated rational seismic loads have significantly lower values than the seismic loads that are suggested by modern seismic codes. It is commonly accepted that modern codes usually suggest very high seismic loads. This happens even in the case that in these codes are foreseen provisions appropriate for masonry structures. These provisions usually refer to modern masonry buildings where is possible to provide high strength. Through the literature review was found that in existing unreinforced masonry buildings is possible to be developed an “equivalent” damping around 20%. Also was found that the eigenfrequency of masonry buildings is reduced at 2/3 - 1/2 of the elastic one and the corresponding reduction of the stiffness is at least 50% of the elastic one. These reductions happen close after the “yielding” point of the “equivalent” bilinear elastoplastic diagram of the structure. The performance points of such structures are located after that “yielding” point. Through the nonlinear analyses of masonry frames, resulted the base shear that these frames is possible to resist and its value is 25% of the total vertical loads of the frames. This value was found for the models with nonlinear frame elements and for the models with discrete brick – mortar joint elements. The models, where bricks and mortar joints were simulated by continuous elements, had higher strength than two aforementioned models. Through the postprocessing of recorded accelerograms of strong earthquakes, resulted spectral accelerations with values around 70%g. The corresponding normalized accelerations resulted 50%g and correspond to damping 5%. By considering “equivalent” damping 20% (as was found above) the normalized spectral accelerations resulted around to 25%g that are close to the value noticed above as the resisted accelerations of the examined frames. These spectral accelerations were found for the records of Achaia – Ilia earthquake. For this earthquake were not observed any collapses of monumental masonry structures at the stricken area with the exception of some local damages and local failures. This way, many of the conclusions - suggestions of the present work are confirmed. It is also concluded that additional experimental and analytical research effort is necessary in the aforementioned fields for the legislation of the conclusion of the present work.

000015796 540__ $$aText je chráněný podle autorského zákona č. 121/2000 Sb.
000015796 653__ $$aMasonry, Monument, Seismic Loads, Equivalent Damping, Earthquake Records, Exact Response, Inelastic Analysis, Masonry Frames, National Strong Motion Network.

000015796 7112_ $$aCOMPDYN 2013 - 4th International Thematic Conference$$cIsland of Kos (GR)$$d2013-06-12 / 2013-06-14$$gCOMPDYN2013
000015796 720__ $$aSalonikios, T.$$iMorfidis, K.$$iLekidis, V.
000015796 8560_ $$ffischerc@itam.cas.cz
000015796 8564_ $$s3132350$$uhttps://invenio.itam.cas.cz/record/15796/files/1467.pdf$$yOriginal version of the author's contribution as presented on CD, section: CD-MS 18  SEISMIC ASSESSMENT OF HERRITAGE STRUCTURES AND MONUMENTS THROUGH SIMULATION
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000015796 962__ $$r15525
000015796 980__ $$aPAPER