Nonlinear Dynamic Analysis of Modular Steel Buildings in Two and Three Dimensions

Fathieh, Amirahmad

22 November 2013

Modular construction is a relatively new technique where prefabricated units are assembled on-site to produce a complete building. Due to detailing requirements for the assembly of the modules, these systems are prone to undesirable failure mechanisms during large earthquakes. Specifically, for multi-story Modular Steel Buildings (MSBs), inelasticity concentration in vertical connections can be an area of concern. Diaphragm interaction, relative displacements between modules and the forces in the horizontal connections need to be investigated. In this study, two 4-story MSBs with two different structural configurations were chosen to be analyzed. In the first model which was introduced in a study by Annan et al. (2009 a), some of the unrealistic detailing assumptions were challenged. To have a more accurate assessment of the structural capacity, in the second model, a more realistic MSB model was proposed. Using OpenSees, Incremental Dynamic Analyses (IDA) have been performed and conclusions were made.

Modular steel building

Seismic performance

Earthquake retrofitting

Nonlinear dynamic analysis

3D

IDA

Braced frame

Diaphragm action

0543

Nonlinear Dynamic Analysis of Modular Steel Buildings in Two and Three Dimensions

Fathieh, Amirahmad

22 November 2013

Modular construction is a relatively new technique where prefabricated units are assembled on-site to produce a complete building. Due to detailing requirements for the assembly of the modules, these systems are prone to undesirable failure mechanisms during large earthquakes. Specifically, for multi-story Modular Steel Buildings (MSBs), inelasticity concentration in vertical connections can be an area of concern. Diaphragm interaction, relative displacements between modules and the forces in the horizontal connections need to be investigated. In this study, two 4-story MSBs with two different structural configurations were chosen to be analyzed. In the first model which was introduced in a study by Annan et al. (2009 a), some of the unrealistic detailing assumptions were challenged. To have a more accurate assessment of the structural capacity, in the second model, a more realistic MSB model was proposed. Using OpenSees, Incremental Dynamic Analyses (IDA) have been performed and conclusions were made.

Modular steel building

Seismic performance

Earthquake retrofitting

Nonlinear dynamic analysis

3D

IDA

Braced frame

Diaphragm action

0543

Parametric Study of Seismic-Resistant Friction-Damped Braced Frame System

Blebo, Felix C.

19 September 2013

No description available.

Civil Engineering

Design

Extern vindstabilisering för flervåningshus i trä

Sörnmo, Daniel, Nilsson, Karl

January 2018

Sammanfattning Intresset för höghuskonstruktioner i trä ökar allt mer runt om i världen. I Sverige ligger fokus på höghuskonstruktioner som utnyttjar intern vindstabilisering med skivor i KL-trä. I de högsta byggnaderna som använder trä som konstruktionsmaterial idag är det fackverk av limträ på byggnadernas ytterkant som når högst byggnadshöjder. Av den anledningen inleddes examensarbetet med målet att undersöka de dynamiska egenskaperna hos olika fackverkskonstruktioner med hänsyn till komforten för brukarna, något som vanligtvis är den mest kritiska analysen. För att bedöma komforten användes ISO 10137. Eftersom egenskaperna hos trä är sämre lämpade för höghuskonstruktioner jämfört med stål och betong valdes att förstärka byggnadens styvhet med en kärna i KL-trä runt hiss och trapphus. Den dynamiska analysen på fackverken har två delar, en av dem berör byggnadens dynamiska egenskaper och utförs i huvudsak i FEM-programmet Robot Structural Analysis och den andra delen handlar om byggnadens acceleration under inverkan av vind och består av handberäkningar. Båda områden inleddes med en litteraturstudie för att försäkra att resultatet i Robot Structural Analysis motsvarar beteendet hos en riktig byggnad och att sätta sig in i beräkningsgången av byggnadens acceleration, samt förstå bakgrunden till beräkningarna. Olika varianter av fyra sorters fackverk analyserades, X-fackverk, K-fackverk, diagridsystem och singulärt diagonala fackverk. Efter genomförda analyser framgick att diagridsystemet uppnådde den högsta byggnadshöjden på 87 m. X-fackverket klarar komfortkraven upp till 81 m och har mindre materialåtgång till fackverket jämfört med diagridsystemet. Jämfört med tidigare arbeten och konstruktioner klarar de undersökta konstruktionerna komfortfortkraven på högre höjder. Förklaringen till de höga konstruktionshöjderna kopplas till robustheten hos fackverken och kombinationen med KL-träkärnan. / Abstract There has been an awakening in high-rise buildings in timber around the world. In Sweden, the focus has been placed on high-rise building that utilize internal stabilisation against wind loading using panels made of cross laminated timber. However, the tallest timber buildings today utilize external stabilisation of glulam trusses. Therefore, the thesis work began with the purpose of examining the dynamical properties of different braced frame structures with regard to not cause discomfort to occupants, which is usually the most critical part of the building design. ISO 10137 was used to assess the comfort. Since the properties of timber are less well-suited for high-rise building constructions in comparison to steel and concrete, a decision was made to strengthen the rigidity of the building using a core made of cross laminated timber around the elevator and stairwell. The dynamic analysis of the braced frame structures has two parts. The first part concerns the building’s dynamic properties and is carried out mainly by using the FEM-software Robot Structural Analysis. The second part focuses on the acceleration of the building under the influence of wind and consists of hand calculations. Furthermore, the work in both areas began with a literature study in order to ensure that the result from Robot Structural Analysis corresponds with the behaviour of a real building and to familiarise oneself with the calculations regarding the acceleration of the building, as well as to understand the background of the calculations. Different variations of four types of braced frames structures were analysed: X-braced, K-braced, diagrid system and single-diagonal types. The analyses showed that the diagrid system reached highest with a building height of 87 m, while the X-braced type meets the comfort requirements up to 81 m and require less material compared to the diagrid system. As a result of the robustness of the trusses and the combination with the core made of cross laminated limber the examined constructions manage to meet the comfort requirements at higher heights than previous works and constructions.

Braced frame

External wind stabilization

Glulam

High rise timber building

modal analysis

Extern vindstabilisering

Fackverk

Höghus i trä

Limträ

Modalanalys

Building Technologies

Husbyggnad

Damage-Free Seismic-Resistant Self-Centering Friction-Damped Braced Frames with Buckling-Restrained Columns

Blebo, Felix C.

26 June 2015

No description available.

Civil Engineering

Engineering

friction damping

seismic-resistant

buckling-restrained column

buckling-restrained braces

soft story failure

residual drift

damage free seismic reistant systems