INELASTIC SEISMIC RESPONSE ANALYSIS OF ECCENTRICALLY LOADED STEEL BRIDGE PIERS

KASAI, Akira, 葛西, 昭, LIU, Qingyun, 劉, 青芸, USAMI, Tsutomu, 宇佐美, 勉

07 1900

No description available.

eccentrically loaded

steel bridge piers

seismic analysis

inelastic behavior

A Numerical Study On Beam Stabilty In Eccentrically Braced Frames

Yigitsoy, Gul

01 September 2010

A two-phase research program was undertaken numerically to assess the behavior of the beam outside of the link that is designed for overstrength of the link in eccentrically braced frames (EBFs). In the first phase, software was developed to conduct a statistical analysis of the typical cases designed according to the AISC Seismic Provisions for Structural Steel Buildings. In this analysis, it was noticed that most of the statistically analyzed cases do not satisfy the code requirement provided for overstrength factor. Furthermore, the analyses results revealed that troublesome designs are highly influenced by normalized link length and slenderness of the beam. In this phase, redistribution of forces between beam and brace after the yielding of beam was also studied and it was observed that the forces not carried by the yielded beam are taken by the brace. In second phase, a total of 91 problematic designs were analyzed on finite element program to investigate the effective parameters on the overstrength issue, and overall and local stability of the beam outside of the links. According to analysis results, it was observed that unbraced beam length and flange slenderness are responsible for the stability of the system. Based on these results, the boundary values were suggested to prevent lateral torsional buckling of the beam and local buckling of the brace connection panel separately. Moreover, the overstrength factor specified by code was found conservative for the intermediate and long links although it is fit for the short links.

TA Engineering Design 174

Capacity of Eccentrically Loaded Slender Concrete Block Walls

Suwalski, Piotr Daniel

09 1900

<p> The behavior of concrete block walls subjected to vertical compressive loads with out-of-plane eccentricities was investigated both experimentally and analytically. Particular attention was devoted to the effect of wall slenderness on capacity.</p> <p> In the experimental study, 14 full scale walls and numerous small specimens were tested to provide complete and reliable data concerning the behavior of concrete block walls and its components. Plain walls and partially grouted reinforced walls were tested in symmetric single curvature under compressive loads with out-of-plane eccentricities. Reinforced walls were tested in pure bending, as well.</p> <p> Prisms were tested to analyze the behavior of concrete masonry in compression with no slenderness or eccentricity effects. Bond tests were carried out to determine the behavior at interfaces of grout and steel reinforcing bars as well as between mortar and concrete blocks. Material tests were conducted to determine the mechanical properties of the blocks, mortar, grout and steel reinforcement used.</p> <p> A two-dimensional finite element model for the vertical cross section of block masonry walls was developed. It is capable of modeling local failure modes such as cracking, crushing and debonding. Material properties of the concrete blocks, mortar, grout, and steel bars were treated individually. The large deformation analysis allowed for consideration of the slenderness effect. The model was verified through comparison with experimental results. Fairly good agreement was obtained.</p> <p> The material properties of specimens tested during the experimental investigation were the basis of a parametric study. Results of this study were used to investigate the effect of the wall slenderness and the eccentricity of applied loads on the capacity of concrete block walls. They were used to evaluate the current provisions in the Canadian Masonry Code, CAN3-S304-M84. An attempt was made to develop original design equations based on the reduction coefficient approach. The proposed equations for plain and reinforced blockwork were shown to provide more consistent predictions of capacity than current design methods.</p> / Thesis / Master of Engineering (MEngr)

Vliv seizmického zatížení na chování železobetonového rámu / Influence of seismic load on behavior of reinforced concrete frame.

Zlámalová, Pavlína

January 2020

The aim of this work is a static analysis of the reinforced concrete frame structure loaded by the effects of seismic loading. The work deals with the solution of multi-storey reinforced concrete structure designed for common loading conditions and further for possibilities of strengthening of the structure on effect of seismic loading. In the first phase of the work, the static analysis and the design of the main load-bearing elements of the frame structure (columns and main girder) were carried out for the ultimate limit state for the standard design load. In the second phase, the static analysis of the structure for the effects of accidental actions from low and high seismicity was performed and it was assessed whether the main load-bearing elements of the structure would continue to comply. Given that the structure did not satisfy the accidental actions of seismic loading, various ways of structure strengthening were designed and analyzed for their impact on the global and local behaviour of the structure. Also the designing of additional steps for structural reliability were performed. Static analyzes were performed in Scia Engineering and RFEM Dlubal software.

Eccentrically Braced Frames in Combination with Moment Frames to Re-Center Buildings After a Seismic Event

Liebau, Corey

04 November 2020

No description available.

Civil Engineering

eccentrically braced frame

seismic

re-centering

moment resisting frame

aftershock

removable

Eccentrically loaded concrete encased steel composite columns

El-Lobody, E., Young, B., Lam, Dennis

January 2011

This paper presents a nonlinear 3-D finite element model for eccentrically loaded concrete encased steel composite columns. The columns were pin-ended subjected to an eccentric load acting along the major axis, with eccentricity varied from 0.125 to 0.375 of the overall depth (D) of the column sections. The model accounted for the inelastic behaviour of steel, concrete, longitudinal and transverse reinforcement bars as well as the effect of concrete confinement of the concrete encased steel composite columns. The interface between the steel section and concrete, the longitudinal and transverse reinforcement bars, and the reinforcement bars and concrete were also considered allowing the bond behaviour to be modelled and the different components to retain its profile during the deformation of the column. The initial overall geometric imperfection was carefully incorporated in the model. The finite element model has been validated against existing test results. The concrete strengths varied from normal to high strength (30¿110 MPa). The steel section yield stresses also varied from normal to high strength (275¿690 MPa). Furthermore, the variables that influence the eccentrically loaded composite column behaviour and strength comprising different eccentricities, different column dimensions, different structural steel sizes, different concrete strengths, and different structural steel yield stresses were investigated in a parametric study. Generally, it is shown that the effect on the composite column strength owing to the increase in structural steel yield stress is significant for eccentrically loaded columns with small eccentricity of 0.125D. On the other hand, for columns with higher eccentricity 0.375D, the effect on the composite column strength due to the increase in structural steel yield stress is significant for columns with concrete strengths lower than 70 MPa. The strength of composite columns obtained from the finite element analysis were compared with the design strengths calculated using the Eurocode 4 for composite columns. Generally, it is shown that the EC4 accurately predicted the eccentrically loaded composite columns, while overestimated the moment.

Activation of Satellite Cells Following Eccentrically-Biased Exercise in Humans

O'Reilly, Ciara E.

12 1900

<p> We aimed to examine the satellite cell response and the potential of HGF signaling in mediating satellite cell activation and proliferation. To achieve this, we determined the time course of satellite cell activation and expression of HGF, HGFA, HAI-l, HAI-2 and the MRFs in skeletal muscle, as well as HGF protein in the blood, before and over five days following an acute bout of eccentrically-biased exercise. Eight recreationally active participants (20.6 ± 2.1 y; 180.5 ± 5.2 cm; 81.4 ± 9.8 kg) were recruited for the study. Subjects were required to perform 300 eccentric contractions involving the quadriceps femoris muscles at 180 °/s, over a 60° range of motion with a randomly selected leg. A baseline biopsy (PRE) was taken from the opposite leg. Muscle and blood samples were taken before the exercise (PRE) and at 4 h (T4), 24 h (T24), 72 h (T72) and 120 h (T120) following the exercise. The exercise protocol resulted in an increase in the number of satellite cells (N-CAM labeled cells), expressed both relative to myofiber number and relative to total myonuclei, between PRE and T4 which was sustained over the time course (p<0.001). Further increases in N-CAM labeled cells, expressed relative to myofibre cross-section, were observed between T4 and T24 (p=0.01) and between T4 and T72 (p=0.002). Myf5 mRNA expression increased significantly from both PRE and T4 by T24 (p=0.04). MyoD mRNA increased significantly from PRE by T4 (p=0.02). Myogenin mRNA increased significantly at T24 versus PRE (p=0.02). No significant change was observed over time for MRF4. HGF protein increased significantly in serum from baseline (PRE) to T4 (p=0.04). Active HGF protein was detected in skeletal muscle at rest (14.4±1.3 avg IDV/actin avg IDV) and tended to increase from PRE to T24 (p=0.12). HGFA protein increased significantly from PRE to T24 (p=0.04). HAI-2 increased significantly from PRE at T72 (p=0.03) and T120 (p=0.04). HAI-1 protein increased significantly from PRE to T24 (p=0.02). HAI-2 (32 kDa) increased significantly from baseline (PRE) by T24 (p=0.03), and also by T72 and T120 (p=0.02). HAI-2 (28 kDa) protein showed no significant change over time HGF, HGFA, HAI-1, and HAI-2 transcripts were undetected over the time course. We conclude that a single bout of high-intensity exercise is sufficient to activate satellite cells, which may involve both a local and systemic response to exercise-induced injury. Furthermore, we propose that HGF signaling plays an important role in the regulation of satellite cells in the post exercise period.</p> / Thesis / Master of Science (MSc)

Guidelines for preliminary design of beams in eccentrically braced frames

Dara, Sepehr

09 November 2010

Seismic-resistant steel eccentrically braced frames (EBFs) are designed so that that yielding during earthquake loading is restricted primarily to the ductile links. To achieve this behavior, all members other than the link are designed to be stronger than the link, i.e. to develop the capacity of the link. However, satisfying these capacity design requirements for the beam segment outside of the link can be difficult in the overall design process of an EBF. In some cases, it may be necessary to make significant changes to the configuration of the EBF in order to satisfy beam design requirements. If this discovery is made late in the design process, such changes can be costly. The overall goal of this research was to develop guidelines for preliminary design of EBFs that will result in configurations where the beam is likely to satisfy capacity design requirements. Simplified approximate equations were developed to predict the axial force and moment in the beam segment outside of the link when link ultimate strength is developed. These equations, although approximate, provided significant insight into variables that affect capacity design of the beam. These equations were then used to conduct an extensive series of parametric studies on a wide variety of EBF configurations. The results of these studies show that the most important variables affecting beam design are 1) the nondimensional link length, 2) the ratio of web area to total area for the wide flange section used for the beam and link, 3) the angle between the brace and the beam, and 4) the flexural stiffness of the brace relative to the beam. Recommendations are provided for selection of values for these variables in preliminary design. / text

Eccentrically braced frames

EBF

Shear link

Moment link

Beam segment outside the link

Axial compressive strength

Flexural strength

Eccentrically braced steel frames as a seismic force resisting system

Hague, Samuel Dalton

January 1900

Master of Science / Department of Architectural Engineering / Kimberly Waggle Kramer / Braced frames are a common seismic lateral force resisting system used in steel structure. Eccentrically braced frames (EBFs) are a relatively new lateral force resisting system developed to resist seismic events in a predictable manner. Properly designed and detailed EBFs behave in a ductile manner through shear or flexural yielding of a link element. The link is created through brace eccentricity with either the column centerlines or the beam midpoint. The ductile yielding produces wide, balanced hysteresis loops, indicating excellent energy dissipation, which is required for high seismic events. This report explains the underlying research of the behavior of EBFs and details the seismic specification used in design. The design process of an EBF is described in detail with design calculations for a 2- and 5-story structure. The design process is from the AISC 341-10 Seismic Provisions for Structural Steel Buildings with the gravity and lateral loads calculated according to ASCE 7-10 Minimum Design Loads for Buildings and Other Structures. Seismic loads are calculated using the Equivalent Lateral Force Procedure. The final member sizes of the 2-story EBF are compared to the results of a study by Eric Grusenmeyer (2012). The results of the parametric study are discussed in detail.

Steel

Seismic

Eccentrically braced frame

Lateral force resisting system

Architectural engineering (0462)

Civil Engineering (0543)

Engineering (0537)

Development of the Design of Eccentrically Braced Frames with Replaceable Shear Links

Mansour, Nabil

23 February 2011

In current design of steel eccentrically braced frames (EBFs), the yielding link is coupled with the floor beam. This often results in oversized link elements, which leads to over-designed structures and foundations. In addition, the beams are expected to sustain significant damage through repeated inelastic deformations under design level earthquakes, and thus the structure may require extensive repair or need to be replaced. These drawbacks can be mitigated by designing EBFs with replaceable shear links. Two different replaceable link types with alternate section profiles, connection configurations, welding details and intermediate stiffener spacing were tested. A total of 13 cyclic quasi-static full-scale cyclic tests were performed, which included tests on eccentrically braced frames with the replaceable shear links, to study their inelastic seismic performance. The links exhibited a very good ductile behaviour, developing stable and repeatable yielding. Additional inelastic rotation capacity can be achieved with bolted replaceable links when allowing bolt bearing deformations to occur. The on-site replaceability of the link sections is confirmed even in the presence of residual deformations of 0.5% drift.

eccentrically braced steel frames

shear link

replaceable link

seismic fuse

bolted connection

inelastic rotations

residual drifts

aftershock

bolt bearing

seismic design

cyclic full scale testing

0543