Block tearing of S700 high strength steel bolted connections: Testing, numerical modelling and design

Abstract The block tearing behaviour and resistance of S700 high strength steel (HSS) bolted connections in tension have been investigated through tests and numerical simulations and reported in this paper. The experiments were performed on sixteen S700 high strength steel bolted connections, including seven 2-bolt connections (with each comprising two bolts arranged perpendicular to the loading direction) and nine 4-bolt connections (with each comprising four bolts arranged in two rows). All specimens were carefully designed, with a series of geometric parameters, including the end and edge distances as well as the longitudinal and transverse pitches, varied and studied. The experimental setup and procedures, together with the key observed results, including the failure loads, the load–elongation curves and the block tearing failure modes, are fully reported and discussed. The experiments were supplemented by numerical simulations; finite element models were firstly developed to replicate the experimental behaviour and then employed to perform parametric studies to generate further numerical data on S700 high strength steel bolted connections susceptible to block tearing over a wide range of geometric dimensions. On the basis of the test and numerical data, the existing design methods for high strength steel bolted connections susceptible to block tearing, as given in the European code, American Specification and Australian Standard, were evaluated. The evaluation results revealed that all three considered design codes lead to consistent and safe-sided but conservative predictions of the failure loads, due principally to the lack of appropriate consideration of the location and area of the shear failure plane. The proposals of Teh and Uz [1], developed for normal strength steel bolted connections, were then investigated and shown to result in substantial improvements of block tearing resistance predictions, although some of the resistances are unsafe. Finally, the reliability of the proposal of Teh and Uz [1] when used for S700 high strength steel bolted connections was demonstrated by means of statistical analyses.

[1]  Yating Liang,et al.  Minor-axis flexural buckling behaviour and resistances of pin-ended S690 high strength steel welded I-section columns , 2020 .

[2]  B. Young,et al.  Flexural behaviour and strengths of press-braked S960 ultra-high strength steel channel section beams , 2019 .

[3]  David A. Nethercot,et al.  Numerical study of stainless steel gusset plate connections , 2013 .

[4]  L. Gardner,et al.  Behavior and Design of Normal- and High-Strength Steel SHS and RHS Columns , 2020 .

[5]  Primož Može,et al.  Net cross-section design resistance and local ductility of elements made of high strength steel , 2007 .

[7]  Aziz Ahmed,et al.  Behaviour and strength of bolted connections failing in shear , 2019, Journal of Constructional Steel Research.

[8]  Primož Može,et al.  High strength steel tension splices with one or two bolts , 2010 .

[9]  Hitoshi Kuwamura,et al.  Ductile Fracture Simulation of Structural Steels under Monotonic Tension , 2014 .

[10]  K. Tan,et al.  Experimental and numerical study of S700 high strength steel double shear bolted connections in tension , 2020 .

[11]  Leroy Gardner,et al.  Flexural Buckling of Hot-Finished High-Strength Steel SHS and RHS Columns , 2017 .

[12]  Guoqiang Li,et al.  Bearing-strength of high strength steel plates in two-bolt connections , 2019, Journal of Constructional Steel Research.

[13]  Lip H. Teh,et al.  Block shear failure planes of bolted connections - direct experimental verifications , 2015 .

[14]  David A. Nethercot,et al.  Numerical investigation of net section failure in stainless steel bolted connections , 2010 .

[15]  Guo-Qiang Li,et al.  Behavior of single bolt bearing on high strength steel plate , 2017 .

[16]  Ben Young,et al.  Bearing factors of cold-formed stainless steel double shear bolted connections at elevated temperatures , 2016 .

[17]  Theodore V. Galambos,et al.  Updating Standard Shape Material Properties Database for Design and Reliability , 2003 .

[18]  F. A. McClintock,et al.  A Criterion for Ductile Fracture by the Growth of Holes , 1968 .

[19]  Binhui Jiang,et al.  Net section resistance of bolted S690 steel angles subjected to tension , 2020 .

[20]  D. M. Tracey,et al.  On the ductile enlargement of voids in triaxial stress fields , 1969 .

[21]  Binhui Jiang,et al.  Block shear failure of S275 and S690 steel angles with single-line bolted connections , 2020 .

[22]  Ben Young,et al.  Tests on high-strength steel hollow sections: a review , 2017 .

[23]  K. Rasmussen High Strength Steel Structures , 2005 .

[24]  L. Teh,et al.  Predicting Steel Tensile Responses and Fracture Using the Phenomenological Ductile Shear Fracture Model , 2017 .

[25]  Lip H. Teh,et al.  Active Shear Planes of Bolted Connections Failing in Block Shear , 2013 .

[26]  Lip H. Teh,et al.  Unconventional block shear failures of bolted connections in cold-reduced steel sheets , 2013 .

[27]  M. Yam,et al.  Shear lag effect on ultimate tensile capacity of high strength steel angles , 2018, Journal of Constructional Steel Research.

[28]  Ou Zhao,et al.  Net section fracture of S700 high strength steel staggered bolted connections , 2021, Thin-Walled Structures.

[29]  Primož Može,et al.  Investigation of high strength steel connections with several bolts in double shear , 2011 .