Compression of a plastic porous material between rotating plates

Alexandrov, Sergei; Pirumov, Alexander; Chesnikova, O. V.

doi:10.1007/s10808-009-0087-x

Cited by 6 publications

(8 citation statements)

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“…Compression between rotating hinged plates has also been widely studied for a plastic material, under a range of different constitutive laws (Alexandrov & Lyamina 2003; Alexandrov & Jeng 2009; Alexandrov, Pirumov & Chesnikova 2009; Alexandrov & Miszuris 2015). A distinguished feature of the rigid plastic problem is the existence of unyielded regions in rigid body rotation adjacent to the rotating plates, for sufficiently large wedge angles.…”

Section: Introductionmentioning

confidence: 99%

Viscoplastic flow between hinged plates

Taylor-West

Hogg

2023

J. Fluid Mech.

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The incompressible motion of viscoplastic fluid between two semi-infinite rigid plates, hinged at their ends and rotating towards one another at constant angular velocity, generates self-similar flow fields because there is no externally imposed length scale in the absence of inertia. The magnitude of the strain rate scales with the angular velocity of the plates and the dimensionless deviatoric stresses are functions only of the polar angle and a dimensionless measure of the yield stress; they are independent of the radial distance from the corner. These flows feature unyielded regions adjacent to the boundaries for sufficiently large angles between the plates. Moreover, when the dimensionless yield stress is large, there are viscoplastic boundary layers that are attached to the boundary or the plug, the asymptotic structures of which are constructed.

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Section: Introductionmentioning

confidence: 99%

Viscoplastic flow between hinged plates

Taylor-West

Hogg

2023

J. Fluid Mech.

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“…For some processes, the strain-rate intensity factor was determined in [7][8][9][10], where the solutions were obtained on the basis of the double shear model [11], which is the generalization of the model of a rigid perfectly/plastic material. Note that the qualitative behavior of the solutions obtained on the basis of the double shear model coincides with the behavior of the solutions obtained on the basis of the model of a rigid perfectly/plastic material [12,13].…”

mentioning

confidence: 99%

“…With allowance for inequality (7) and the last relation in Eqs. (6), the boundary conditions (1) acquire the form…”

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confidence: 99%

Strain-rate intensity factor in compression of a layer of a plastic material between cylindrical surfaces

Alexandrov

Lyamina

2009

J Appl Mech Tech Phy

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A model problem for a rigid perfectly/plastic material is obtained. Based on this solution, it is possible to estimate the influence of the friction surface curvature and one of the types of additional rotational motion of the friction surface on the strain-rate intensity factor.The strain-rate intensity factor introduced in [1] as a coefficient at the principal singular term in the expansion of the equivalent strain rate into a series in the vicinity of the maximum friction surface is used to predict the evolution of material properties in a thin layer near surfaces with large friction stresses in metal-forming processes [2,3]. Quantitative dependences between the strain-rate intensity factor and parameters characterizing material properties, however, have not been established. It seems of interest, therefore, to find the dependence of the strainrate intensity factor on parameters of metal-forming processes, which can be used, in particular, to determine the above-mentioned quantitative dependences. One parameter that can be readily changed in an experiment is the curvature of the friction surface. In the present paper, we study the compression of a layer of a plastic material between two concentric cylinders with the maximum friction law being satisfied on the cylinder surfaces. This simple model problem allows the effect of the friction surface curvature on the strain-rate intensity factor to be estimated.It was found that the strain-rate intensity factor is affected by additional rotation of the instrument, which is used in industrial processes for changing the energy and force parameters of the process [4-6]. The effect of one type of additional rotation of the friction surface on the strain-rate intensity factor is considered in the present paper within the framework of the model problem being solved.For some processes, the strain-rate intensity factor was determined in [7][8][9][10], where the solutions were obtained on the basis of the double shear model [11], which is the generalization of the model of a rigid perfectly/plastic material. Note that the qualitative behavior of the solutions obtained on the basis of the double shear model coincides with the behavior of the solutions obtained on the basis of the model of a rigid perfectly/plastic material [12,13].Let us consider a plane flow of a layer of a plastic material compressed between two surfaces, which have the form of concentric circular cylinders and which obey the maximum friction law. We introduce a polar coordinate system (r, θ) whose origin coincides with the cylinder centers. The radius of the outer cylinder determined by the equation r = R 2 is assumed to be constant. The radius of the inner cylinder increases with a velocity U 0 , and its current radius is described by the equation r = R 1 (Fig. 1). As the flow is symmetric about the axis θ = 0, it is sufficient to construct the solution for θ 0. Let σ rr , σ θθ , and σ rθ be the components of the stress tensor in the polar coordinate system, and let u r and u θ be the components of the ve...

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“…Solutions of this problem for different material models make it possible to find some specific features of these solutions, including their singular character [7,8,14]. Other solutions of model problems within the framework of the anisotropic plasticity theory were obtained in [15,16], where the asymptotic analysis of solutions in the vicinity of the maximum friction surfaces was not performed.…”

mentioning

confidence: 99%

“…Figure 2 shows the dependence A(θ 0 ) calculated by Eq. (14) for different values of the parameter c characterizing plastic anisotropy. Figure 3 shows the dimensionless strain rate intensity factor d = D/(ωr 1/2 ) as a function of θ 0 , which was calculated by Eq.…”

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Specific features of solving the problem of compression of an orthotropic plastic material between rotating plates

Alexandrov

2009

J Appl Mech Tech Phy

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An instantaneous flow with compression of a wedge-shaped layer of a rigid-plastic orthotropic material between rotating plates is considered under the assumption that the principal axes of anisotropy are rays emanating from the wedge angle and lines orthogonal to them and that the maximum friction law is valid on the plate surfaces. The solution is reduced to quadratures, and its asymptotic analysis is performed. It is found that the solution is singular near the friction surface in the general case, and conditions at which the singularity disappears are given. It is demonstrated that a rigid area can arise near the friction surface. The behavior of the resultant solution near the friction surfaces is compared with the behavior of known solutions for other models of rigid-plastic materials.In some models of rigid-plastic materials, the solutions are singular near the maximum friction surfaces (in particular, some derivatives of the projections of the velocity vector and the stress tensor components tend to infinity near such surfaces). The general asymptotic analysis of the behavior of solutions was performed in [1] for an arbitrary flow of an ideal rigid-plastic material satisfying an arbitrary smooth yield condition independent of the mean stress, in [2] for an axisymmetric flow of a material satisfying the Tresca yield condition, in [3] for a plane flow, and in [4] for an axisymmetric flow of a material satisfying the double shear model (the model itself is described in [5]). In all cases, the equivalent strain rate (second invariant of the strain rate tensor) near the maximum friction surface during slipping was found to tend to infinity in an inverse proportion to the square root from the distance to this surface. Solutions of problems for various material models show that this property of the velocity field depends on the material model [6-10]. The singular behavior of the velocity field allows new theories to be proposed to describe the changes in the material properties in a thin layer near the friction surfaces [11,12].A solution of a model problem of an instantaneous flow of a wedge-shaped layer of a rigid-plastic orthotropic material satisfying the model [13] between rotating plates with the maximum friction law on the plate surfaces is obtained in the present work. Solutions of this problem for different material models make it possible to find some specific features of these solutions, including their singular character [7,8,14]. Other solutions of model problems within the framework of the anisotropic plasticity theory were obtained in [15,16], where the asymptotic analysis of solutions in the vicinity of the maximum friction surfaces was not performed.Let us consider an instantaneous plane flow of a plastic orthotropic material compressed between two plates rotating with an angular velocity ω with respect to the point O (Fig. 1). Assuming that there is no drain at the point O, we introduce a polar coordinate system (r, θ) with the origin at the point O. As θ = 0 is considered as the axis of symmetr...

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Compression of a plastic porous material between rotating plates

Cited by 6 publications

References 6 publications

Viscoplastic flow between hinged plates

Viscoplastic flow between hinged plates

Strain-rate intensity factor in compression of a layer of a plastic material between cylindrical surfaces

Specific features of solving the problem of compression of an orthotropic plastic material between rotating plates

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