Deformation limit for the ultimate strength of hollow section joints

The current paper focuses on numerical simulation peculiarities of offset welded rectangular hollow section joints. Understanding the modelling techniques can result in easier and faster and above all correct outcomes from FEA for future use. The steel joints under discussion are composed from cold-formed regular rectangular hollow sections where RHS brace members are laterally shifted from chord axis. Joints work under monotonically increasing compression load applied to a brace top. Numerical models were developed in FE programme Abaqus. FE-models is composed of C3D8R 8-noded solid linear brick elements with an emphasis on mesh size effect and modelling of a weld seam. FE advanced model were compiled considering both material and geometric nonlinearities. For validation purposes, the full-scale laboratory tests were conducted. Proposed FE models reliably predict the structural behaviour of welded offset T-joints thanks to good agreement achieved on deformation limit 3 % b0 with the maximum deviation 10.3 %.

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Static Strenght of Doubler Plate Reinforced Tubular K-Joints under Bending Load

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.166-169.645 ◽

2012 ◽

Vol 166-169 ◽

pp. 645-648

Author(s):

Wei Ning Sui ◽

Xin Long Zhang ◽

Guo Chang Li ◽

Xue Bai

Keyword(s):

Ultimate Strength ◽

Static Strength ◽

Geometric Parameters ◽

Hollow Section ◽

Numerical Studies ◽

Bending Load ◽

Circular Hollow Section

Abstract: In order to study static strength of doubler plate reinforced circular hollow section (CHS) K-joints, experimental and numerical studies conducted by the authors. The effects of parameters Δ (the ratio between the length of doubler plate and the diameter of the brace) and α (the width of the doubler plate) on CHS K-joints subjected to bending load have been investigated and reported by the authors. It is found that the ultimate strength of a CHS K-joints reinforced with appropriately proportioned doubler plates can be up to 2 ratio to its un-reinforced counterpart. Reasonable geometric parameters of the doubler plate can make the chord, brace and doubler plate work together to bear the external bending load. The width and length parameter of the doubler plate, however, have no effect on the stiffness of the reinforced K-joints.

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Numerical Study on the Deformation Behavior of Longitudinal Plate-to-High-Strength Circular Hollow-Section X-Joints under Axial Load

Applied Sciences ◽

10.3390/app9193999 ◽

2019 ◽

Vol 9 (19) ◽

pp. 3999

Author(s):

Swoo-Heon Lee ◽

Kyung-Jae Shin ◽

So-Yeong Kim ◽

Hee-Du Lee

Keyword(s):

Yield Strength ◽

High Strength Steel ◽

Axial Load ◽

Joint Strength ◽

High Strength ◽

Hollow Section ◽

Strength Limit ◽

Ultimate Deformation ◽

Deformation Limit ◽

Circular Hollow Section

This study aims to investigate the joint strength of longitudinal plate-to-high-strength steel circular hollow-section X-type joints under plate axial load. The material properties of high-strength steel with nominal yield strengths of 460, 650, 900, and 1100 MPa were used for parametric analysis. The variables for analysis were ratios of chord diameter to thickness, plate width to chord diameter, and utilization. To determine the capacity of connections, the joint strengths using a deformation limit and a strength limit were considered and compared with American Institute of Steel Construction (AISC), Eurocode 3, and ISO 14346. The joint strength determined by the ultimate deformation limit is approximately equal to the joint strength determined by the strength limit state at the yield strength of 460 MPa. The difference between both the joint strengths, however, becomes higher with increasing yield strength. The design equations estimate the joint strength based on the ultimate deformation limit approximately until the limitation of the nominal yield strength in each design code. As the nominal yield strength increases, the joint strengths are overestimated. In using high-strength steel in circular hollow-section X-type joints, the reduction factors of 0.75 and 0.62 for AISC and ISO 14346 are suggested for the nominal yield strengths of 900 and 1100 MPa, respectively. In Eurocode 3, the reduction factor of 0.67 is also suggested for a yield strength of 1100 MPa.

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Ultimate strength capacity of a square hollow section filled with fibrous foamed concrete

IOP Conference Series Materials Science and Engineering ◽

10.1088/1757-899x/271/1/012103 ◽

2017 ◽

Vol 271 ◽

pp. 012103 ◽

Cited By ~ 1

Author(s):

Siti Amirah Azra Khairuddin ◽

Norashidah Abd Rahman ◽

Norwati Jamaluddin ◽

Zainorizuan Mohd Jaini ◽

Noorwirdawati Ali

Keyword(s):

Ultimate Strength ◽

Hollow Section ◽

Strength Capacity ◽

Foamed Concrete

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Mechanical Testing of Recycled HDPE Extruded Hollow Section

ANNUAL JOURNAL OF TECHNICAL UNIVERSITY OF VARNA BULGARIA ◽

10.29114/ajtuv.vol4.iss2.180 ◽

2020 ◽

Vol 4 (2) ◽

pp. 112-121

Author(s):

Greg Wheatley ◽

Rendage Sachini Sandeepa Chandrasiri

Keyword(s):

Thermal Expansion ◽

Yield Strength ◽

Ultimate Strength ◽

Modulus Of Elasticity ◽

Coefficient Of Thermal Expansion ◽

Linear Thermal Expansion ◽

Environmental Benefits ◽

Hollow Section ◽

Significant Difference ◽

Recycled Hdpe

High density polyethylene (HDPE) is a thermoplastic polymer which is classified as one of the highly consumed types of plastics. One major advantage of thermoplastic materials is their ability of recycling and reprocessing which will bring considerable economicand environmental benefits. The present paper, therefore, endeavours to explore the practical possibility of using recycled HDPE hollow section as a replacement of virgin HDPE made by the extrusion process. The main focus of the study was to evaluate the mechanical performance of the recycled HDPE and compare the results with virgin or non-recycled HDPE. The modulus of elasticity, tensile yield and ultimate strength, compressive yield and ultimate strength, flexural yield and ultimate strength and the coefficient of thermal expansion were the main parameters to be checked against the respective mechanical properties. Thus, pursuant to the rsults, it was found out that the modulus of elasticity and the tensile yield strength are lower in recycled HDPE compared to the non-recycled HDPE. However, there is no significant difference between the recycled and non-recycled HDPE for the tensile ultimate strength, compressive yield strength and compressive ultimate strength. The flexural yield strength and flexural ultimate strength properties of the recycled HDPE proved to be superior to those of the non-recycled HDPE. The coefficient of linear thermal expansion of the recycled HDPE sample was 130 μm/(m.°C) and that for the non-recycled HDPE was 142 μm/(m.°C).

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