Effect of column removal time on progressive collapse of high rise structures

Stephen, O.D., Lam, Dennis, Toropov, V.V.

January 2013

No / Accepted for conference.

Column Removal

Progressive Collapse

High Rise Structures

Experimental Evaluation Of A Precast Concrete Beam-To-Column Prototype Design Under A Column Removal Scenario

Torres Alamo, Jorge Omar

06 May 2017

Precast concrete multistory buildings are used in an attempt to optimize the available construction space and reduce costs. However, little is known about predicting their capacity in a brittle response mode due to the sudden loss of a critical element that could induce a Progressive Collapse Scenario. Therefore, the National Institute for Standards and Technology (NIST) developed an explicit approach in the design of precast concrete systems that is intended to mitigate a progressive collapse by enhancing the rotational capacity of joints and the robustness of the structural system. A full-scale experiment was conducted to investigate the structural performance of a prototype design under a column-removal scenario. The test assembly frame, consisting of three columns and two beams, was subjected to a displacement controlled vertical force acting at the center to characterize the failure modes and collapse mechanisms. Brittleailures of critical structural elements were observed and significantly impacted the performance.

precast concrete connections

progressive collapse

disproportionate collapse

alternative load path method

rotational capacity

column removal scenario

Testing of a Full-Scale Composite Floor Plate

Lam, Dennis, Dai, Xianghe, Sheehan, Therese

29 January 2019

Yes / A full-scale composite floor plate was tested to investigate the flexural behavior and in-plane effects of the floor slab in a grillage of composite beams that reduces the tendency for longitudinal splitting of the concrete slab along the line of the primary beams. This is important in cases where the steel decking is discontinuous when it is orientated parallel to the beams. In this case, it is important to demonstrate that the amount of transverse reinforcement required to transfer local forces from the shear connectors can be reduced relative to the requirements of Eurocode 4. The mechanism under study involved in-plane compression forces being developed in the slab due to the restraining action of the floor plate, which was held in position by the peripheral composite beams; while the secondary beams acted as transverse ties to resist the forces in the floor plate that would otherwise lead to splitting of the slab along the line of the primary beams. The tendency for cracking along the center line of the primary beam and at the peripheral beams was closely monitored. This is the first large floor plate test that has been carried out under laboratory conditions since the Cardington tests in the early 1990s, although those tests were not carried out to failure. This floor plate test was designed so that the longitudinal force transferred by the primary beams was relatively high (i.e., it was designed for full shear connection), but the transverse reinforcement was taken as the minimum of 0.2% of the concrete area. The test confirmed that the primary beams reached their plastic bending resistance despite the discontinuous decking and transverse reinforcement at the minimum percentage given in Eurocode 4. Based on this test, a reduction factor due to shear connectors at edge beams without U-bars is proposed.

Floor plate test

Composite beams

Edge beams

Eurocode 4

In-plane effect

Column removal

Robustness

Experimental and Analytical Collapse Evaluation of an Existing Building

Akah, Ebiji Anthony

15 October 2015

No description available.

Civil Engineering

progressive collapse

full-scale testing

steel building

column removal

strain gauges

displacement sensors

linear static

nonlinear dynamic

SAP2000 analysis

three-dimensional model

two-dimensional model

GSA design guidelines