Traditional methods for structural damage evolution and failure mode analysis usually depend on specific failure path analysis, which is inefficient and time-consuming to implement for complex structures. In this paper, an efficient failure path-independent methodology for structural damage evolution and failure mode analysis of framed structures is proposed based on the elastic modulus reduction method. The element bearing ratio, uniformity of element bearing ratio and reference element bearing ratio are defined in terms of the homogeneous generalized yield function of spatial beam element, while a dynamic criterion is presented to identify the highly stressed elements. Subsequently, a self-adaptive strategy of elastic modulus adjustment is developed to reduce the elastic moduli of the highly stressed elements for simulation of structural damage evolution. Finally, the reduction rate of elastic moduli of the highly stressed elements is presented to determine the failed sections among the failure elements in the last iteration, based on which the potential failure mode is identified. The applicability, computational accuracy and efficiency of the proposed methodology are validated by comparing with the elasto-plastic methods through two numerical examples.
BarreraOCocksACFPonterARS (2009) Evaluation of the convergent properties of the linear matching method for computing the collapse of structural components. European Journal of Mechanics-A/Solids28: 655–667.
3.
BilottaALeonettiLGarceaG (2012) An algorithm for incremental elastoplastic analysis using equality constrained sequential quadratic programming. Computers & Structures102–103: 97–107.
4.
ChenHFPonterARS (2001) Shakedown and limit analyses for 3-D structures using the linear matching method. International Journal of Pressure Vessels and Piping78: 443–451.
5.
CreustGJTorresPLGroehsAG (1984) Elastoplastic frame analysis with generalized yield function and finite displacements. Computers & Structures18: 925–929.
6.
DuanLChenWF (1990) A yield surface equation for doubly symmetrical sections. Engineer Structures12: 114–119.
7.
GendyASSaleebAF (1993) Generalized surface representations in the elasto-plastic three-dimensional analysis of frames. Engineer Structures49: 351–362.
8.
HamiltonRMackenzieDShiJ (1996) Simplified lower bound limit analysis of pressurized cylinder/cylinder intersections using generalised yield criteria. International Journal of Pressure Vessels and Piping67: 219–226.
9.
HarrisonHB (1980) Structural Analysis and Design: Some Minicomputer Applications (Parts I and II), Sydney: Pergamon Press.
10.
HongSYuanKYJuJW. New strain energy based thermo-elastoviscoplastic isotropic damage-self healing model for bituminous composites – Part I: Formulations. International Journal of Damage Mechanics.2015a. DOI: 10.1177/1056789515610706 first published on13 October 2015.
11.
HongSYuanKYJuJW. New strain energy based thermo-elastoviscoplastic isotropic damage-self healing model for bituminous composites – Part II: Computational aspects. International Journal of Damage Mechanics.2015b. DOI: 10.1177/1056789515610707 first published on 13 October 2015.
12.
Jones GL and Dhalla AK (1981) Classification of clamp induced stresses in thin-walled pipe. In: ASME paper 81-PVP-17. Madison, Pennsylvania: American Society of Mechanical Engineers.
13.
KimDSOkSYSongJ (2013) System reliability analysis using dominant failure modes identified by selective searching technique. Reliability Engineering and System Safety119: 316–331.
14.
KingWS (1994) The limit loads of steel semi-rigid frames analyzed with different methods. Computers & Structures51: 475–487.
15.
MackenzieDBoyleJTHamiltonR (2000) The elastic compensation method for limit and shakedown analysis: A review. The Journal of Strain Analysis for Engineering Design35: 171–188.
16.
MackenzieDNadarajahCShiJ (1993) Simple bounds on limit loads by elastic finite element analysis. Journal of Pressure Vessel Technology115: 27–31.
17.
Marin-ArtiedaCCDargushGF (2007) Approximate limit load evaluation of structural frames using linear elastic analysis. Engineering Structures29: 296–304.
18.
PisanoAAFuschiPDe DomenicoD (2013) Peak loads and failure modes of steel-reinforced concrete beams: Predictions by limit analysis. Engineering Structures56: 477–488.
19.
RahmanMK (1998) Ultimate strength estimation of ships’ transverse frames by incremental elastic-plastic finite element analysis. Marine Structures11: 291–317.
20.
RodriguesRSBirckGIturriozI. Damage index proposals applied to quasi-brittle materials simulated using the lattice discrete element method. International Journal of Damage Mechanics.2016. First published on 20 January 2016. DOI: 10.1177/1056789516628182.
21.
RustWSchweizerhofK (2003) Finite element limit load analysis of thin-walled structures by ANSYS (implicit), LS-DYNA (explicit) and in combination. Thin-Walled Structures41: 227–244.
22.
SekulovićMNefovska-DanilovićM (2004) Static inelastic analysis of steel frames with flexible connections. Journal of Theoretical and Applied Mechanics31: 101–134.
23.
SeshadriR (1991) The generalized local stress strain (GLOSS) analysis—Theory and applications. ASME Journal of Pressure Vessel Technology113: 219–227.
24.
ShiJBoyleJTMackenzieD (1996) Approximate limit design of frames using elastic analysis. Computers & Structures61: 495–501.
25.
WangCK (1963) General computer program for limit analysis. Journal of the Structural Division89: 101–117.
26.
VoyiadjisGZKattanPI. Mechanics of damage, healing, damageability, and integrity of materials: A conceptual framework. International Journal of Damage Mechanics.2016. First published on 2 March 2016. DOI: 10.1177/1056789516635730.
27.
YangLFLiQZhangW (2014) Homogeneous generalized yield criterion based elastic modulus reduction method for limit analysis of thin-walled structures with angle steel. Thin-Walled Structures80: 153–158.
28.
YangLFYuBJuJW (2015) Incorporated strength capacity technique for limit load evaluation of trusses and framed structures under constant loading. Journal of Structural Engineering-ASCE141: 04015023(1–11).
29.
YangLFYuBQiaoYP (2009) Elastic modulus reduction method for limit load evaluation of frame structures. Acta Mechanica Solida Sinica22: 109–115.
30.
YangPLiuYOhtakeY (2005) Limit analysis based on a modified elastic compensation method for nozzle-to-cylinder junctions. International Journal of Pressure Vessels and Piping82: 770–776.
31.
YuBYangLF (2010) Elastic modulus reduction method for limit analysis of thin plate and shell structures. Thin-Walled Structures48: 291–298.
