The increase of requirements concerning the accuracy of numerical analysis of technological processes with nonlinear contact such as drawing, cutting, embossing, burnishing rolling, thread rolling and machine cutting involves the extension of accuracy in determining workability parameters: initial yield stress σY0, plastic hardening modulus ET and true failure strain φf. Currently, those parameters are often determined in uniaxial tensile testing. Determination of the strain and stress states after the exceedance of ultimate tensile strength of the material, in the moment of stability loss (creation of the neck) constitutes the basic issue. Appearance of characteristic necking disturbs uniform, uniaxial state of stress. In the smallest intersection of the specimen there additionally appear radial stress and circumferential stress - three-dimensional state of stress is obtained. Currently used methods: Birdgman, Davidenkov-Spiridonova or Siebel do not allow calculating the values of those stress precisely enough. The paper concerns the new hybrid method of evaluating stress and strain states in the cylindrical specimen during of tension with the use of Finite Element Method (FEM).
This work describes the thread rolling as a real object and its physical and mathematical modelling. An incremental modelling and numerical solution of the contact problem between movable elastic or rigid tool and elastic/visco-plastic bodies developed in [ is adopted to the numerical simulation of thread rolling process for the case of rigid tool (threading head) and elastic/visco-plastic body (pipe or bar). An update Lagrangian formulation was used to describe nonlinear phenomena on a typical incremental step. For solution of discrete equations of motions and deformations of the object the explicit integration method was applied. The algorithm and application of 3D numerical analysis in ANSYS program were elaborated. This algorithm let for determination of influence of friction coefficient, initial yield stress and plastic hardening modulus. This factors influence will be carried out with 5 levels rotary experiment plan, which let for elaboration of regression equation to describe this relationship. Exemplary results of 3D numerical analysis of displacement and strain in thread for different conditions of rolling process are presented.
In this study the process of burnishing rolling is considered as a geometrical and physical boundary and initial value problem, with unknown boundary conditions in the contact area. 3D dynamic explicit method for burnishing rolling process with taking into account surface after turning (as previous treatment) under ANSYS/LS-DYNA environment was established. The analysis covered surfaces characterized by vertical angles of the asperities in range: 60°÷150°. The simulation results (i.e. surface deformation, states of strain and stresses, depth of stress deposition) were evaluated. The influence of vertical angle of the asperities after turning process on the states of stress and strain and the depth of its deposition are presented.
The shearing process such as the blanking of sheet metals has been used often to prepare workpieces for subsequent forming operations. The use of FEM simulation is increasing for investigation and optimizing the blanking process. In the current literature a blanking FEM simulations for the limited capability and large computational cost of the three dimensional (3D) analysis has been largely limited to two dimensional (2D) plane axis-symmetry problems. However, a significant progress in modelling which takes into account the influence of real material (e.g. microstructure of the material), physical and technological conditions can be obtained by using 3D numerical analysis methods in this area. The objective of this paper is to present 3D finite element analysis of the ductile fracture, strain distribution and stress in blanking process with the assumption geometrical and physical nonlinearities. The physical, mathematical and computer model of the process are elaborated. Dynamic effects, mechanical coupling, constitutive damage law and contact friction are taken into account. The application in ANSYS/LS-DYNA program is elaborated. The effect of the main process parameter a blanking clearance on the deformation of 1018 steel and quality of the blanks sheared edge is analyzed. The results of computer simulations can be used to forecasting quality of the final parts optimization.
Generally advantages of superficial plastic processes are well-known (smooth, strain hardening of surface, the low unite price and large repeatability of product quality), but industrial application it procures many difficulties. The lack of suitable methods of preparation surface, unequivocally guidelines concerning on preparations of surface under processing and data about choice of technological parameters are the basic problems. In aim of enlargement the product's quality not only enlargement of burnished product accuracy, but also enlargement of surface preparation accuracy about regular geometrical structure after previous treatment are needed. The paper concerns on the suitable semi-finished product surface preparation under finishing burnishing rolling. New method of surface preparations under burnishing rolling consisted in embossing of surface regular asperities. The physical, mathematical and computer model of the process was elaborated with the assumption geometrical and physical nonlinearities. The application in ANSYS/LS-DYNA program enabling the investigation of influence: friction conditions in tool-workpiece contact zone, the value and type of material hardening on the displacement, strain and stress state in object was elaborated. The results of computer simulations can be used to forecasting quality of the parts optimization.
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