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Paper Title Author Objective Findings Future scope
1The prediction of ductile fracture in the metalblanking process
A.M. Goijaerts, L.E. Govaert and F.P.T. Baaijens
Develop a ductile fracture model valid for the metal blanking process.
Ductile fracture can be predicted in the blanking processif the ductile fracture model is characterised (C
is determined) in a blanking experiment.
Researchhas to be performed whether the ductile fracture criteriaare applicable in other deformation processes.
2Characterization of ductile fracture in metal blanking
A.M. Goijaerts, L.E. Govaert and F.P.T. Baaijens
3Finite Element Assisted Prediction of Ductile Fracture in Sheet Bulging of Magnesium Alloys
David Hunt B.Eng
Finite Element Model of a sheet bulgingprocess was built and validated with results obtained from physical testing.
There were twokey factors which influenced the results of the experimental sheet bulging; heattransfer and sticking.
4Prediction of Ductile Fracture in Metal Blanking
A. M. GoijaertsL. E. GovaertF. P. T. Baaijens
This study is focused on the description of ductile fracture initiation, which is needed to predict product shapes in the blanking process.
In this approach atensile test is used to characterize the fracture model, instead of a complex and elaborateblanking experiment. Finite element simulations and blanking experiments are performedfor five different clearances to validate both approaches.
In conclusion it can be statedthat for the investigated material, the first approach gives very good results within theexperimental error. The second approach, the more favorable one for industry, yieldsresults within 6 percent of the experiments over a wide, industrial range of clearances,when a newly proposed criterion is used.
5
An Application of Finite Element Method and Design of Experiments in the Optimization of Sheet Metal Blanking Process
Emad Al-Momani, Ibrahim Rawabdeh
The model investigates the effect ofpotential parameters influencing the blanking process and their interactions. This helped in choosing the process leadingparameters for two identical products manufactured from two different materials blanked with a reasonable quality on thesame mold.
Finite Element Method (FEM) and Design of Experiments (DOE) approach are used in order to achieve theintended model objectives. The combination of both techniques is proposed to result in a reduction of the necessaryexperimental cost and effort in addition to getting a higher level of verification.
It can be stated that the Finite ElementMethod coupled with Design of Experiments approach provide a good contribution towards the optimization of sheet metalblanking process.
6
7Evaluation of ductile fracture models fordifferent metals in blanking
A.M. Goijaerts*, L.E. Govaert, F.P.T. Baaijens
In this approach, instead of a complex and elaborate blanking experiment, atensile test is used to characterise a newly proposed criterion, which was shown to predict accurately the ductile fracture for differentloading conditions.
In this paper, ®nite element simulations and experiments are performed on both tensile testing and blanking to evaluatethe validity of both approaches with corresponding criteria for ®ve different metals. In the blanking process, different clearances as well asdifferent cutting radii of the tools are considered.
Material characterisation is a signi®cant issue in modellingof the blanking process. Because very large strainsoccur in the localised shear zone it is important to determineaccurately the stress±strain relation for large strains, whichis not straightforward. Tensile tests are performed on prerolledspecimens to evolve this relation up to large strains forall metals.
8 Investigation of the viscous and thermal effects on ductile fracture in sheet metal
Ahmad Rafsanjani &
methodology is proposed to
To verifythe validity of the
This study shows that the
blanking process
Saeed Abbasion &Anoushiravan Farshidianfar & Nilgoon Irani
predict the ductile damage in the sheet metal blankingprocess using a coupled thermomechanical finite-elementmethod.
proposed model, several blankingsimulations are performed and the results compared withthose obtained from an experimental study.
fracture initiates at the maximum temperature during theprocess and after the fracture takes place the temperaturedecreases sharply.
9Ductility and fracture toughness of molybdenum with MgAl2O4 additions
I.M. Gunter a,1, J.H. Schneibel b, J.J. Kruzic
10 1111111111 222222
12Numerical modelling of the metal blanking process
D. Brokken, W.A.M. Brekelmans and F.P.T. Baaijens
13An experimental and numerical study of a planar blanking process
Y.W. Stegeman, A.M. Goijaerts *, D. Brokken, W.A.M. Brekelmans, L.E. Govaert,F.P.T. Baaijens
14Predicting the shape of blanked products:a Finite element approach
D. Brokken*, W.A.M. Brekelmans, F.P.T. Baaijens
15 Can a new experimental and numerical studyimprove metal blanking?
A.M. Goijaerts*, Y.W. Stegeman, L.E. Govaert, D. Brokken,W.A.M.
Brekelmans, F.P.T. Baaijens
16A Study of Brittle to Ductile Fracture Transition Temperatures inBulk Pb-Free Solders
Peter Ratchev1, Tony Loccufier1, Bart Vandevelde1, Bert Verlinden2, Steven Teliszewski3,Daniel Werkhoven3, Bart Allaert4
17 Slitting process ductile
18A New Ductile Fracture Criterion for Various DeformationConditions Based on Microvoid Model
HUANG .Iian-ke , DONG Xiang-huai
19New ductile fracture criterion for prediction of fracture forming limit diagrams of sheet metals
Yanshan Lou, Hoon Huh⇑, Sungjun Lim, Keunhwan Pack
20
A ductile failure model applied to the determination of the fracture toughness of welded joints. Numerical simulation and experimental validation
I. Pen˜uelas *, C. Betego´ n, C. Rodrı´guez
21On the numerical prediction of the ductile fracture in metal forming
K. Saanouni
22Modeling the ductile fracture behavior of an aluminum alloy 5083-H116 including the residual stress effect
Jun Zhou a, Xiaosheng Gao a,⇑, Matthew Hayden b, James A. Joyce c
23 Mechanics of fatigue crack growth in a bonding interface
Hans-Jakob Schindler a,
Christian Leinenbach b,⇑
24Description of shear failure in ductile metals via back stress concept linked to damage-micro porosity softening
Patrice Longère a,⇑, André Dragon b
25Simulation of stable tearing crack growth events using the cohesive zone model approach
Xin Chen, Xiaomin Deng ⇑, Michael A. Sutton
26Improvement of the extended finite element method for ductile crack growth
R. Pourmodheji, M. Mashayekhi∗
27Crack retardation mechanism due to overload in base material and laser welds of Al alloys
S. Daneshpour a,⇑, J. Dyck b, V. Ventzke a, N. Huber a
28
3-Dimensional observation of the interior fracture mechanism and establishment of cumulative fatigue damage evaluation on spot welded joints using 590 MPa-classsteel
Ryota Tanegashima, Hiroyuki Akebono, Masahiko Kato, Atsushi Sugeta ⇑
29An ellipsoidal void model for simulating ductile fracture behavior
Kazutake Komori ⇑
30Ductile fracture criteria for simulating shearby node separation method
K. Komori
31
Investigation on the microstructure and mechanical properties of Ti–6Al–4Valloy joints with electron beam welding
Shaogang Wang⇑, Xinqiang Wu
32
Effect of sintering time on the microstructure and mechanical properties of (Ti,Ta)(C,N)-based cermets
E. Chicardi a,⁎, Y. Torres b, J.M. Córdoba a, M.J. Sayagués a, J.A. Rodríguez b, F.J. Gotor a
33Microstructure,mechanicalpropertiesandfracturebehaviorofpeak-aged Mg–4Y–2Nd–1Gdalloysunder differentaging conditions
Zhijie Liu a, GuohuaWua,b,n, WencaiLiu a, SongPang a, WenjiangDing a,b
34
Prediction of ductile fracture for advanced high strength steel with a new criterion: Experiments and simulation
Yanshan Lou, Hoon Huh∗
35
Fatigue crack growth behavior in powder-metallurgy 6061 aluminum alloyreinforced with submicron Al2O3 particulates
Zuhair M. Gasem ⇑
36Ductile Damage Models Applied To Anisotropic Fracture Of Al2024 T351
D. Steglich, W. Brocks and T. Pardoen1
37Deformation and Fracture of Ductile Materials
description
38Ductile Fracture M. Zikry
39Chapter 2Brittle and Ductile Fracture
Description
40Modelling Brittle-Ductile Transitions S.G. ROBERTS
41 A finite element analysis of dynamic fracture M. JHA 1 and R.
initiation by ductile failure mechanisms in a 4340 steel
NARASIMHAN 2
42 Ductile And Brittle Fracture Of SteelA. P. Gulyaev UDC 620.17:669.14
43Scaling Effect in Dynamic Fracture (Spallation) of Brittle and Ductile Material
V. A. Ogorodnikov, 1 A. G. Ivanov, 1
44Investigation of the viscous and thermal effects on ductile fracture in sheet metal blanking process
Ahmad Rafsanjani & Saeed Abbasion &Anoushiravan Farshidianfar & Nilgoon Irani
45A variational void coalescence model for ductile metals
Amir Siddiq · Roman Arciniega · Tamer El Sayed
46Simulation of fatigue crack propagation in ductile metals by blunting and re-sharpening
Vladislav Levkovitch1,∗, Rainer Sievert2 and Bob Svendsen1
47Modeling of hydrogen-assisted ductile crack propagation in metals and alloys
D. C. Ahn · P. Sofronis · R. Dodds Jr.
48
A micromechanical constitutive model for dynamic damage and fracture of ductile materials
N. Jacques · C. Czarnota · S. Mercier ·A. Molinari
49 On using a dual bound approach to Joel Griffin,
characterize the yield Behaviour of porous ductile materials containing void clusters
Cliff Butcher, Zengtao Chen
50An Improved Ductile Fracture Criterion for Fine-blanking Process
ZHAO Zhen
51
Development and application of micromechanical material models for ductile fracture and creep damage
DONG-ZHI SUN, MATTHIAS SESTER and WINFRIED SCHMITT
52Prediction of ductile fracture in axisymmetric tension by void coalescence
A. R. RAGAB
53
A Comparison of the Prediction of Fatigue Damage and Crack Growth in Adhesively Bonded Joints Using Fracture Mechanics and Damage Mechanics Progressive DamageMethods
I. A. Ashcroft a , V. Shenoy a , G. W. Critchlow b & A.D. Crocombe c
54
Influence of Silver Incorporation on Toughness Improvement of Diamond- Like Carbon Film Prepared by Ion BeamAssisted Deposition
X. Yu a , Z. W. Ning a , M. Hua b & C. B. Wang a
55
Effects of strain rate on tensile strength of steel specimens of HAZs with stress concentrations
Yoshihiro Sakino a , Shinya Takahashi b & You-Chol Kim a
56 Fractal analysis of the fatigue fracture surface of metal of welded joints
E. A. Krivonosova a &
A. I. Gorchakov a
57
A TEM Investigation of Crack Formation Mechanism on Chrome-Molybdenum Steel Tested under Real Driving Conditions
Kenji Matsumoto a , Hideo Watanabe b & Naoaki Yoshida b
58Research and Progress in Incremental Sheet FormingProcesses
S. B. M. Echrif a & M. Hrairi a
59
Effect of Spot Welding Parameters on Tensile Properties of DP 600 Steel Sheet Joints
S. Aktas a , U. Ozsarac b & S. Aslanlar b
60Study on Forming Limit Diagrams of AZ31B Alloy Sheet at Different Temperatures
Wenjuan Li a , Guoqun Zhao a , Xinwu Ma a & Jun Gao b
61
Characterization of the fracture toughness of micro-sized tungsten single crystal notched specimens
Stefan Wurster a , Christian Motz a & Reinhard Pippan a
62Point defect generation, nano-void formation and growth. II. Criterion for ductile failure
S. Saimoto a , B.J. Diak a & D.J. Lloyd b
63
Rubber Adhesion to Different Substrates and Its importance in Industrial Applications: A Review
Iraj Rezaeian a , Payam Zahedi a & Ali Rezaeian a
64 An experimental investigation of the effect of interface adhesion on the fracture characteristics of a brittle ductilelayered material
Raman P. Singh & Alains Gratien
