Please use this identifier to cite or link to this item: https://scholarhub.balamand.edu.lb/handle/uob/2318
Title: Numerical modelling of lean duplex stainless steel and assessment of existing design methods
Authors: Saliba, Najib G. 
Issa, Johnny
Affiliations: Department of Civil and Environmental Engineering 
Department of Mechanical Engineering 
Keywords: Continuous strength method
Cross-section classification
Finite element
Lean duplex
Numerical modelling
Shear
Welded I-sections
Subjects: Bending
Stainless steel
Issue Date: 2017
Part of: Athens journal of technology and engineering
Volume: 5
Issue: 1
Start page: 33
End page: 52
Abstract: 
The longevity and unique mechanical properties of stainless steel are sufficient reasons for adopting it as a main material in the construction industry. However, its high initial cost, which is largely influenced by the level of nickel content (8% - 10% in the common austenitic grade), relatively restricts its application in structures. The development of lean duplex stainless steel, a low nickel grade offering twice the strength of the austenitic grade at nearly half the initial cost, and refining the codified design equations, may increase the usage rate of stainless steel in construction. The aim of this paper is to continue the previous research conducted on lean duplex stainless steel by providing more data on its structural performance using numerical modelling and evaluating existing and proposed design equations which were not available earlier. A detailed description of the modelling using the general-purpose finite element analysis package ABAQUS is presented. Forty-eight lean duplex stainless steel welded I-sections loaded in bending and shear were simulated. The obtained numerical results are reported and used in conjunction with existing experimental and numerical data on stainless steel welded I-sections to assess the Eurocode 3: Part 1.4 codified slenderness limits and shear resistance design equations, the continuous strength method (CSM) for bending and newly proposed shear design equations. Analysis of the results reveals that the current codified design provisions are generally conservative and improved predictions can be achieved using the CSM and the proposed slenderness limits and shear resistance equations.
Description: 
This paper was presented in " Proceedings of the 6th Annual International Conference on Civil Engineering, Athens, Greece, 20-23 June, 2016 ".
URI: https://scholarhub.balamand.edu.lb/handle/uob/2318
Open URL: Link to full text
Type: Journal Article
Appears in Collections:Department of Civil and Environmental Engineering

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