Anchor plate effect on the breakout capacity in tension for thin-walled concrete panels

Abstract Although provisions available in current design codes that take account of the presence of anchor plates, the existing provisions take no account of the effects of anchor plate size. In this study, the effect of anchor plate size on the concrete breakout strength in tension was evaluated for a single anchor system used in a thin-walled concrete wall panel. Twenty-seven specimens were tested to investigate the effects of anchor plate width and thickness. The test results show that concrete breakout strength is considerably improved with increased anchor plate size, with the rate of improvement diminishing in very large anchor plates. A simplified analytical model was proposed to determine the optimal width and thickness of anchor plates. The predicted optimal values were validated with the test results; the proposed analytical model is capable of determining the proper size of anchor plates in thin-walled concrete panels.

[1]  Miguel Azenha,et al.  Development of sandwich panels combining fibre reinforced concrete layers and fibre reinforced polymer connectors. Part I: Conception and pull-out tests , 2013 .

[2]  Jiuk Shin,et al.  A Study on Effect of Anchor Plate on Concrete Breakout Capacity and Elasticity-Based Analysis Model of Anchor Plate , 2013 .

[3]  Ho-Ryong Kim,et al.  Composite Behavior of Insulated Concrete Sandwich Wall Panels Subjected to Wind Pressure and Suction , 2015, Materials.

[4]  H. L. Graves,et al.  Breakout Capacity of Anchors in ConcretePart 1: Tension , 2004 .

[5]  Young-Chan You,et al.  Composite Behavior of a Novel Insulated Concrete Sandwich Wall Panel Reinforced with GFRP Shear Grids: Effects of Insulation Types , 2015, Materials.

[6]  Pruettha Nanakorn,et al.  Analysis of anchor bolt pullout in concrete by the element-free Galerkin method , 2008 .

[7]  Ashraf K. Nazir,et al.  The effect of soil reinforcement on pullout resistance of an existing vertical anchor plate in sand , 2006 .

[8]  Rolf Eligehausen,et al.  CONCRETE CAPACITY DESIGN (CCD) APPROACH FOR FASTENING TO CONCRETE , 1995 .

[9]  Basile G. Rabbat,et al.  Notes on ACI 318-08, building code requirements for structural concrete : with design applications , 2008 .

[10]  Saad Ali AlTaan,et al.  Breakout Capacity of Headed Anchors in Steel Fibre Normal and High Strength Concrete , 2012 .

[11]  Roberto Ballarini,et al.  Pullout Capacity of Headed Anchors in Prestressed Concrete , 2012 .

[12]  Jerome F. Hajjar,et al.  Headed steel stud anchors in composite structures, Part II: Tension and interaction , 2010 .

[13]  John E. Breen,et al.  ANCHORAGE BEHAVIOR OF HEADED REINFORCEMENT: LITERATURE REVIEW , 2002 .

[14]  Alejandro Pérez Caldentey,et al.  Plate-anchored reinforcement bars: A new simple and physical model for practical applications , 2013 .

[15]  Keun-Hyeok Yang,et al.  Mechanism Analysis for Concrete Breakout Capacity of Single Anchors in Tension , 2008 .

[16]  Lian-heng Zhao,et al.  Joined Influences of Nonlinearity and Dilation on the Ultimate Pullout Capacity of Horizontal Shallow Plate Anchors by Energy Dissipation Method , 2011 .

[17]  Amr S. Elnashai,et al.  Mechanical and informational modeling of steel beam-to-column connections , 2010 .

[18]  Vincenzo Piluso,et al.  Rotational behaviour of column base plate connections: Experimental analysis and modelling , 2014 .