Modified moment connection between I‐beam and double‐I built‐up column

Several steel structure standards around the world contain an equation to encourage any column flexural yielding during earthquake shaking to occur at the column ends, rather than along the column length. The accuracy of these equations and their applicability to columns of both moment frames and braced frames are examined in this paper. It is shown, using an analytical procedure developed from first principles considering the reduction in member stiffness from axial force due to geometric and material nonlinearity, that the existing code equations are conservative. Less conservative empirical equations are developed based on the analysis results. It is found that these equations are applicable to frames with a braced connection, rather than a moment connection into the column. Time-history analysis of eccentrically-braced frames with inverted V-bracing, where the active link occurs at the centre of the beam, is carried out. The likely column end moment ratio needed for the new equations is determined. The analysis also shows that yielding often did not occur in the bottom story columns during earthquake excitations. A simple check is proposed to relate the axial force limit and the design drift to flexural yielding of columns which can be used in conjunction with the proposed equations.

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Stiffness prediction for bolted moment-connections in cold-formed steel trusses

Engineering review ◽

10.30765/er.1428 ◽

2020 ◽

Vol 41 (1) ◽

Author(s):

Apai Benchaphong ◽

Rattanasak Hongthong ◽

Sutera Benchanukrom ◽

Nirut Konkong

Keyword(s):

Finite Element Analysis ◽

Finite Element ◽

Analytical Method ◽

Truss Structures ◽

Rotational Stiffness ◽

Element Analysis ◽

Moment Connection ◽

Rigid Connection ◽

Cold Formed Steel ◽

Steel Trusses

The purpose of this research was to study the behavior of cold-formed steel cantilever truss structures. A cantilever truss structure and bolt-moment connection were tested and verified by the 3D-finite element model. The verification results showed a good correlation between an experimental test and finite element analysis. An analytical method for elastic rotational stiffness of bolt-moment connection was proposed. The equation proposed in the analytical method was used to approximate the elastic rotational stiffness of the bolt group connection, and was also applied to the Richard-Abbott model for generating the nonlinear moment-rotation curve which modeled the semi-rigid connection stiffness. The 2D-finite element analysis was applied to study the behavior of the truss connection, caused by semi-rigid connection stiffness which caused a change of force to the truss elements. The results showed that the force in the structural members increased by between 13.62%-74.32% of the axial forces, and the bending moment decreased by between 33.05%-100%. These results strongly suggest that the semi-rigid connection between cold-formed steel cantilever truss structures should be considered in structural analysis to achieve optimum design, acknowledging this as the real behavior of the structure.

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Application of Fracture Mechanics to Steel Connections in Moment Frames under Seismic Loading

Advances in Structural Engineering ◽

10.1177/136943329700100104 ◽

1997 ◽

Vol 1 (1) ◽

pp. 23-37 ◽

Cited By ~ 3

Author(s):

C. Joh ◽

W.F. Chen

Keyword(s):

Fracture Mechanics ◽

Steel Structures ◽

Northridge Earthquake ◽

Moment Frames ◽

Moment Connections ◽

Related Factors ◽

Steel Connections ◽

Moment Connection ◽

San Fernando ◽

The Moment

The 6.8 magnitude Northridge earthquake that shook California's San Fernando Valley on January 17 in 1994, did not cause the collapse of any steel structures but connections, confidently designed and constructed in the past with traditional code simplification and common site welding techniques, were discovered not to meet our expectations. This paper reviews connection failures during the 1994 Northridge earthquake and the design philosophy and examines the post-Northridge earthquake experimental and analytical researches. Possible causes of the moment connections damage are categorized into three classes; welding-related factors, design-related factors, and material-related factors. For the analyses, the idealizations of the moment connection considering each factor are studied. From the idealization of the moment connection, the five-plate model is analyzed to investigate the stress concentration and stress state of the connection. The equivalent design crack models are investigated using the fracture mechanics approach.

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Stability and low-cycle fatigue limits of moment connection rotation capacity

Engineering Structures ◽

10.1016/s0141-0296(02)00178-5 ◽

2003 ◽

Vol 25 (5) ◽

pp. 691-700 ◽

Cited By ~ 10

Author(s):

B. Stojadinovic

Keyword(s):

Low Cycle Fatigue ◽

Cycle Fatigue ◽

Moment Connection ◽

Rotation Capacity

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Connections between Simply Supported Concrete Beams Made Continuous

Transportation Research Record Journal of the Transportation Research Board ◽

10.1177/0361198105192800114 ◽

2005 ◽

Vol 1928 (1) ◽

pp. 126-133

Author(s):

Amy Dimmerling ◽

Richard A. Miller ◽

Reid Castrodale ◽

Amir Mirmiran ◽

Makarand Hastak ◽

...

Keyword(s):

Concrete Beams ◽

Heat Of Hydration ◽

Moment Connections ◽

Moment Capacity ◽

Moment Connection ◽

Differential Shrinkage ◽

Negative Moment ◽

Live Loads ◽

Creep And Shrinkage ◽

Sufficient Strength

Precast bridge girders can be made continuous for live loads with the provision of a moment connection over the supports. NCHRP Project 12–53 examined methods for making this type of moment connection. This is usually done by placing negative moment reinforcement in a cast-in-place deck over the support and by placing a diaphragm between the girder ends. To counteract positive moments caused by creep and shrinkage, positive moment connections are often provided at the girder ends. An experimental study of the strength of six different positive moment details, involving either extended strand or extended bar, was conducted. The results showed that all details had sufficient strength. Details using additional stirrups in the diaphragm were found to have increased ductility, and the use of horizontal web bars increased capacity. Two full-size specimens were tested to determine the level of continuity after cracking occurs at the joints. One of these specimens was also monitored for several months to determine the effects of creep, shrinkage, and temperature on the connections. It was found that expansion and contraction of the deck caused by heat of hydration and changes in ambient temperature greatly affected the system. However, an anticipated formation of negative moment caused by differential shrinkage did not occur. Even when the positive moment connection was near failure, the system maintained 70% continuity even when cracked. The system was also found to have adequate negative moment capacity.

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