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Reversed Cyclic Load Tests of Reinforced Concrete Frame SubassemblagesRattray, Suzanne 05 1900 (has links)
No description available.
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The influence of cementation on liquefaction resistance of sandsIwabuchi, Jotaro January 1986 (has links)
Cohesionless sands are known to be susceptible to failure by liquefaction when they are saturated and subjected to earthquake shaking. Considerable study has been directed towards this subject over the past 20 years in recognition of the possibility of large-scale property damage or loss of life due to this type of failure. Recent evidence has shown that small degrees of cementation in a sand significantly reduce the likelihood of liquefication. However, the work to date has been limited to studies with conventional testing devices and simple loading paths. These devices are suspected of inducing premature failure in cemented soils, and are not capable of modeling the effects of multiaxial loading.
In this investigation, there were two major objectives. The first involved the development and fabrication of a new three~dimensional shear device with the capability of applying load to cemented sands with a minimum of stress concentration effects, and of using load paths which are more representative of the true effects of an earthquake than is possible in conventional equipment. The second concerned performance of a series of production tests to investigate the behavior of cemented sands under a range of earthquake loading paths. The production tests were largely performed using the new three—dimensional shear device.
The test results showed that cemented soils have more resistance to earthquake loading than previously thought since stress concentration effects in conventional testing do induce premature failure through the effects of stress concentrations. On the other hand, it was found that either cemented or uncemented sands show less resistance to earthquake loadings if multiaxial stress conditions are applied to the sample as opposed to uniaxial loadings. This is important in explaining the fact that sites with seemingly similar conditions often show different behavior, since slightly different earthquake loading pattems can cause different responses. One factor explaining differences in response is found to be the mean normal stress, which is not the same for all loadings, and plays an important role in the pore pressures developed in the soil. / Ph. D. / incomplete_metadata
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Computational assessment of seismic resistance of RC framed buildings with masonry infillLoots, Jurie 12 1900 (has links)
Thesis (MScIng)--Stellenbosch University, 2005. / Some digitised pages may appear illegible due to the condition of the original hard copy. / ENGLISH ABSTRACT: Reinforced concrete (RC) frames with unreinforced masonry infill form the structural system
of many buildings and this is also true for South Africa. It is common practice to consider the
masonry infill as a non-structural component and therefore it does not contribute to the
performance of the Re frame buildings under lateral loading such as earthquake loading.
This is done by leaving a sufficient gap between the Re frame and the infill. This ensures
that there is no contact between the frame and the infill during an earthquake event.
However, it has been suggested that masonry infill can play a significant role in the
performance of a Re frame building under lateral loading.
The first part of the study focuses on the South African situation. The relevance of shear
walls in these Re frame buildings as well as the size of the gap (between frame and infill) left
in practice, are investigated. This is done by finite element analysis.
The second part of the study focuses on the effects that the infill can have on the global
performance of the structure when there is full contact between the Re frames and infill. The
effect of openings in the infill to the response of the frame is also investigated. Finite element
models of single span Re frames with infill is built and analyzed in order to investigate
possible damage to the infill, frame infill interaction and to obtain the non linear stiffness of
the frame with infill as a whole. This obtained non linear stiffness can be modelled in Diana
as a non linear spring that will be used in the development of a simplified analysis method.
The simplified method developed consists of a frame and two such non linear springs, placed
diagonally, and which have the same force versus displacement behaviour as the original
frame with infill. These single span frames can be added together to model a whole frame. In
a first step to generalise the simplified method, various geometries of infills are considered,
varying span and height, as well as opening percentage, representing windows and doors of
varying total area and positioning. However, in this study a single masonry type, namely solid
baked clay bricks set in a general mortar, is considered. To generalise the approach further,
other masonry types can be considered in the same way. The use of these springs in a
simplified model saves computational time and this means that larger structures can be
modelled in Diana to investigate response of'Rf' frame buildings with infill. The work reported in this thesis considers only in-plane action. Out-of-plane-action of the
masonry infill has been reported in the literature to be considerable, under the condition that it
is sufficiently tied to the frame to prevent mere toppling over, causing life risking hazards in
earthquake events. This matter should be studied in continuation of the current research to
generalise the simple approach to three dimensions. / AFRIKAANSE OPSOMMING: Gewapende betonrame (GBR-e) met ongewapende messelwerk invulpanele (invul) vorm die
strukturele ruggraat van vele geboue en dit geld ook vir geboue in Suid-Afrika. Dit is
algemene praktyk om die invulpaneel in sulke geboue as 'n nie-strukturele komponent te
beskou. Daarvolgens dra dit nie by tot die gedrag van 'n GBR gebou onderhewig aan 'n
aarbewing nie. Dit word bereik deur 'n groot genoeg gaping tussen die betonraam en die
invul te los. Die gevolg is dat daar geen kontak tussen die betonraam en die invul plaasvind
indien daar 'n aardbewing sou voorkom nie. Dit is egter voorgestel dat invul 'n
noemenswaardige rol kan speel in die gedrag van 'n GBR gebou onderwerp aan 'n horisontale
las.
Die eerste deel van die studie fokus op die Suid-Afrikaanse situasie. Die relavansie van
skuifmure in GBR geboue asook die grootte van die gaping (tussen die raam en invul) wat in
die praktyk gebruik word, word ondersoek. Dit word gedoen met behulp van eindige element
analises.
Die tweede deel van die studie fokus op die effek wat invul kan hê op die globale gedrag van
'n struktuur wanneer daar volle kontak tussen die GBR en die invul is. Die effek wat die
teenwoordigheid van openinge in die invul kan hê op die gedrag van 'n GBR is ook
ondersoek. Eindige element modelle van enkelspan GBR met invul is gemodelleer en
geanaliseer om die moontlike skade aan die invul, die interaksie tussen die GBR en die invul
asook die nie-lineêre styfheid van die raam en invul as 'n geheel, te ondersoek. Hierdie nielineêre
styfheid kan in Diana as 'n nie-lineêre veer gemodelleer word en word gebruik in die
ontwikkeling van 'n vereenvoudigde metode.
Hierdie vereenvoudigde metode wat ontwikkel is, bestaan uit 'n raam en twee sulke nielineêre
vere (diagonaal geplaas). Die raam met vere het dieselfde krag teenoor
verplasingsgedrag as die van die oorspronklike raam met invul wat dit voorstel. Hierdie rame
kan saamgevoeg word om 'n raam uit 'n gebou as 'n geheel te modelleer. Verskeie invul
geometrieë word gebruik in die analises in 'n eerste stap om die vereenvoudigde metode te
veralgemeen. Die span en hoogte asook opening persentasie van die invul word gevariëer om
vensters en deure van veskeie grootte en posisie voor te stel. In die studie, 'n enkel
messelwerk tipe, naamlik solied klei bakstene geset in algemene mortar, word gebruik. Ander messelwerk tipes kan gebruik word om die metode verder te veralgemeen. Die gebruik van
die vere in die vereenvoudigde metode spaar berekenings tyd en dit beteken dat groter
strukture in Diana gemodelleer kan word om die gedrag van GBR geboue met invul te
ondersoek.
Die werk gedoen in die tesis neem slegs in-vlak aksie in ag. Literatuurstudie dui daarop dat
goeie uit-vlak-aksie van messelwerk invul bestaan, mits dit goed geanker is aan die raam om
te verseker dat dit nie kan omval en 'n gevaar vir lewens in 'n aardbewing inhou nie. Dit
behoort verder bestudeer te vord in die vervolging van die huidige ondersoek om die
vereenvoudige metode na drie dimensies te veralgemeen.
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Experimental evaluation of the seismic performance of hospital piping subassembliesGoodwin, Elliott Richard. January 2004 (has links)
Thesis (M.S.)--University of Nevada, Reno, 2004. / "December 2004." Includes bibliographical references (leaves 57-61). Online version available on the World Wide Web.
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Deformation-based seismic design models for waterfront structuresYang, Dong-Shan 10 March 1999 (has links)
Recent experience demonstrates that waterfront structures are vulnerable to
earthquake damage. The poor seismic performance of these facilities has been
primarily due to liquefaction of backfill and/or foundation soils and the lack of
seismic design standards for waterfront structures. The seismic performance of
waterfront structures is a key issue in the evaluation of the unimpeded operations of
the port system and affiliated facilities following earthquakes. The widespread
economic consequences of earthquake-induced damage to waterfront structures and
required serviceability of port components after earthquakes highlight the need for
improved performance-based design methods.
The weak foundation soils and high water tables that are common at ports
result in a high vulnerability to seismically-induced ground failures and corresponding
damage to adjacent structures. Liquefaction of backfill and foundation soils next to
waterfront structures contributes to an increase in active lateral earth pressures against
walls, loss of stability of rock dike, excessive ground settlements, and lateral soil
movements. Current pseudostatic methods are not well suited to account for the
influence of excess pore pressure generation as well as amplification of acceleration. In order to limit earthquake-induced deformations of waterfront structures, various ground treatment strategies have been used to mitigate liquefaction hazards at numerous ports. However, very few guidelines exist for specifying the extent of remedial soil treatment required to insure the serviceability of the waterfront components after a design-level earthquake.
This research has investigated the seismic response of waterfront structures, specifically concrete caissons and pile-supported wharves, during past earthquakes. A numerical model was validated by comparing the computed response to field performance. A series of parametric studies were conducted for waterfront structures in improved soils. The effectiveness of soil improvement in controlling permanent seismically-induced deformations of the waterfront structures is evaluated as functions of wall geometry, the density of backfill soils, the stiffness of piles, the extent of the improved soil, and the characteristics of the strong ground motions. The results were synthesized into simplified, practice-oriented design charts for deformation-based analysis, and preliminary guidelines for estimating the extent of ground treatment that is required given allowable deformation limits for the caissons and pile-supported systems. / Graduation date: 1999
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Panel zone behavior of moment connections between rectangular concrete-filled steel tubes and wide flange beams /Koester, Bradley Donald, January 2000 (has links)
Thesis (Ph. D.)--University of Texas at Austin, 2000. / Vita. Includes bibliographical references (leaves 191-194). Available also in a digital version from Dissertation Abstracts.
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Seismic analysis, design, and evaluation of post-tensioned friction damped connections for steel moment resisting frames /Rojas Cruz, Pedro Pablo, January 2003 (has links)
Thesis (Ph. D.)--Lehigh University, 2003. / Includes vita. In two parts. Includes bibliographical references (leaves 598-603).
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Influence of strengthening and repair schemes on dowel type timber joints and moment resisting framesYang, Jiaqi, 楊家琦 January 2013 (has links)
Timber has been a widely used construction material throughout the history of human development and it is still popular to this day. Timber frames are a common structural form used in historical and modern day structures. An effective means to connect timber members together is via bolts or dowels due to their high strength, ductile behaviour and flexibility in application. Such joints are, however, vulnerable and prone to damage especially during seismic attacks. In order to improve the performance and longevity of timber framed structures, it is necessary to develop simple but effective strengthening schemes for dowel-type timber joints. Additionally, strategies to repair and reinstate damaged joints are also required.
The main objectives of this program of doctoral research are to (1) develop strengthening and repair schemes for bolted timber joints using advanced composite materials (i.e. carbon fibre reinforced polymer, CFRP) as well as traditional materials (i.e. steel plates, epoxies and mortars), and (2) investigate the effectiveness of the schemes in improving the seismic performance of timber frames. The strengthening and repair schemes are applied to single-bolt joints and tested under monotonic load. Optimal strengthening and repair schemes are then applied to moment resisting joints and the joints are subjected to monotonic and cyclic loading. Finite element models are then assembled for the latter joint tests. The calibrated joint models are then used in finite element models of timber frames with varying number of storeys and support conditions. The seismic performances of the timber frames are investigated by conducting both nonlinear static and nonlinear time history analyses. The results of the experimental investigations and the finite element analyses show that the strengthening schemes can enhance the strength and stiffness of joints. Optimum strengthening schemes can also improve the seismic performance of timber frames. Based on the work arising from the program of research, future research needs are finally identified. / published_or_final_version / Civil Engineering / Doctoral / Doctor of Philosophy
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Seismic strengthening by providing structural diaphragmWang, Renjun 28 August 2008 (has links)
Not available / text
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Seismic retrofit of bridges using shape memory alloysDelemont, Michael A. 12 1900 (has links)
No description available.
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