On the regularization for ductile damage models

Gamma titanium aluminides are promising alloys for low-pressure turbine blades. A significant disadvantage of such intermetallic alloys is failure induced during forming processes due to ductile damage and flow instabilities. Previous investigations on a gamma titanium aluminide alloy (TNM), have shown ductile damage due to tensile stress components and instabilities such as shear bands, pores and micro-cracks at low temperatures and high strain rates. The main part of the current work is to delineate damage and unstable regions in the low temperature region. Hot deformation experiments are conducted on a Gleeble®3800 thermomechanical treatment simulator to obtain flow curves to be implemented in a finite element method (FEM) code. Instabilities in the material are described by existing instability criteria as proposed by Semiatin and Jonas and implemented into FEM code DEFORMTM 2D. Predictions of ductile damage models and the instability parameter are validated through detailed microstructural studies of deformed specimens analysed by light optical- and scanning electron microscopy.

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Prediction of fracture limits of Ni–Cr based alloy under warm forming condition using ductile damage models and numerical method

Transactions of Nonferrous Metals Society of China ◽

10.1016/s1003-6326(21)65660-1 ◽

2021 ◽

Vol 31 (8) ◽

pp. 2372-2387

Author(s):

Ayush MORCHHALE ◽

Anand BADRISH ◽

Nitin KOTKUNDE ◽

Swadesh Kumar SINGH ◽

Navneet KHANNA ◽

...

Keyword(s):

Numerical Method ◽

Warm Forming ◽

Ductile Damage ◽

Damage Models ◽

Forming Condition

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Prediction of fracture limits of IN625 alloy by coupling ductile damage models and anisotropic yielding functions with the classical Marciniak and Kuczyński model

Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture ◽

10.1177/09544054211051868 ◽

2021 ◽

pp. 095440542110518

Author(s):

Ayush Morchhale ◽

Nitin Kotkunde ◽

Swadesh Kumar Singh ◽

Navneet Khanna

Keyword(s):

Manufacturing Industry ◽

Forming Limit Diagram ◽

Ductile Damage ◽

Inconel 625 ◽

Forming Limit ◽

Uniaxial Tensile ◽

Forming Limits ◽

Damage Models ◽

Uniaxial Tensile Testing ◽

Anisotropic Yielding

The fracture forming limit diagram (FFLD) is gaining special attention in high strength materials where the necking tendency rarely occurs during sheet metal forming processes. In the present work, the classical Marciniak and Kuczyński (MK) model has been modified by coupling it with different ductile damage models (Cockcroft and Latham, Brozzo, Oyane, Ko, Oh, Rice and Tracey, McClintock and Clift) and anisotropic yielding functions (Hill 1948 and Barlat 1989) to predict the fracture limits of Inconel 625 (IN625) alloy at different temperatures. Firstly, uniaxial tensile testing has been conducted for the determination of important mechanical properties. Consequently, stretch forming experiments have been performed to analyze the forming limits of a material. It has been found that the safe and fracture forming limits of the material increased by approximately 17.26% and 22.22%, respectively, on increasing the temperature from 300 to 673 K. From the comparative analysis of different combinations of ductile damage models and yielding functions, the Cockcroft and Latham (C-L) damage model in combination with the Barlat 1989 yielding function helped in best predicting the theoretical FFLD as it displayed the least average root mean square error (RMSE) of 0.033. The other ductile damage models used for predicting the theoretical fracture limits displayed large error; hence, they should not be considered while designing a critical component in the manufacturing industry using IN625 alloy.

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Implementation of Ductile Damage Models to Determine Constraint Parameters for Ductile Materials-Phase 1 (Generic Constraint Conditions)

10.1115/1.0000209v ◽

2021 ◽

Author(s):

Jack Beswick ◽

Peter James ◽

John Sharples

Keyword(s):

Phase 1 ◽

Ductile Damage ◽

Ductile Materials ◽

Damage Models

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A comparison of ductile damage models with application to LCF

PAMM ◽

10.1002/pamm.200910077 ◽

2009 ◽

Vol 9 (1) ◽

pp. 205-206

Author(s):

Olaf Kintzel

Keyword(s):

Ductile Damage ◽

Damage Models

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A hybrid approach for modelling of plasticity and failure behaviour of advanced high-strength steel sheets

International Journal of Damage Mechanics ◽

10.1177/1056789512439319 ◽

2012 ◽

Vol 22 (2) ◽

pp. 188-218 ◽

Cited By ~ 100

Author(s):

J Lian ◽

M Sharaf ◽

F Archie ◽

S Münstermann

Keyword(s):

Damage Evolution ◽

Damage Mechanics ◽

Hybrid Approach ◽

High Strength Steels ◽

High Strength ◽

Numerical Approach ◽

Ductile Damage ◽

Dissipation Energy ◽

Damage Models ◽

Steel Sheets

The ductile damage mechanisms dominating in modern high-strength steels have emphasised the significance of the onset of damage and the subsequent damage evolution in sheet metal forming processes. This paper contributes to the modelling of the plasticity and ductile damage behaviour of a dual-phase steel sheet by proposing a new damage mechanics approach derived from the combination of different types of damage models. It addresses the influence of stress state on the plasticity behaviour and onset of damage of materials, and quantifies the microstructure degradation using a dissipation-energy-based damage evolution law. The model is implemented into ABAQUS/Explicit by means of a user material subroutine (VUMAT) and applied to the subsequent numerical simulations. A hybrid experimental and numerical approach is employed to calibrate the material parameters, and the detailed program is demonstrated. The calibrated parameters and the model are then verified by experiments at different levels, and a good agreement between the experimental and numerical results is achieved.

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Ductile Damage Evolution Under Different Strain Rate Conditions

10.1115/imece2000-2475 ◽

2000 ◽

Author(s):

Nicola Bonora ◽

Domenico Gentile ◽

Pietro Paolo Milella ◽

Golam Newaz ◽

Francesco Iacoviello

Keyword(s):

Strain Rate ◽

Deformation Rate ◽

Damage Evolution ◽

Damage Mechanics ◽

Dynamic Effect ◽

Material Behavior ◽

Ductile Damage ◽

Type Model ◽

Material Loss ◽

Damage Models

Abstract Failure of ductile metals is always controlled at microstructural level by the formation and growth of microcavities that nucleate from inclusions embedded in the ductile matrix, also at high deformation rate. Many damage models have been proposed to describe both evolutions of these cavities under the action of increasing plastic deformation, and the associated effects on the material behavior. Basically, two classes of damage models are currently available: the Gurson’s type model and continuum damage mechanics (CDM). In the framework of CDM, Bonora (1997) proposed a non-linear damage model for ductile failure that overcome the main limitations presented by others formulations: the model is material independent and its validity under multiaxial state of stress conditions has been verified for a number of class of metals, (Bonora, 1998, Bonora and Newaz, 1997). In addition, this model has the main feature to require a limited number of physically based parameters that can be easily identified with ad hoc tensile tests. In this paper, for the first time, the effect of the strain rate on ductile damage evolution has been studied in a quantitative manner evaluating the material loss of stiffness under dynamic loading. Damage measurements on SA537 Cl 1 steel have been performed according to the multiple strain gauge technique on hourglass shaped rectangular tensile specimen. Dynamic effect was introduced performing the test at different imposed displacement rates. An extensive scanning electron microscopy analysis has been performed in order to correlate damage effects with the microstructure morphological modification as a function of the applied deformation rate.

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