Viscoplastic flow in an extrusion damper

Syrakos, Alexandros; Dimakopoulos, Yannis; Georgiou, Georgios C.; Tsamopoulos, John

doi:10.1016/j.jnnfm.2016.02.011

Cited by 17 publications

(38 citation statements)

References 66 publications

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“…2). It can be seen that both D τ + f,i and D τ − f,i equal a characteristic viscosity, given by (25) or (26), times the velocity gradient in the direction d f , albeit calculated differently: the gradient as computed in D τ + f,i is sensitive to velocity oscillations whereas that computed in D τ − f,i is not. The mechanism of oscillation suppression is similar to that for momentum interpolation: in the presence of spurious velocity oscillations, the smooth part of D τ + f,i is cancelled out by D τ − f,i , but the oscillatory part produces oscillations in the operator image (in F h (φ h ), in the terminology of Eq.…”

Section: Discretisation Of the Momentum Equationmentioning

confidence: 97%

“…The "velocities" u p+ f and u p− f are functions of local pressure variations, and attempt to quantify the contributions of these pressure variations to the velocity field. Pressure and velocity are connected through the momentum equation, so consider this equation in the following non-conservative form, where we assume that the stress tensor can be approximated through the use of a characteristic viscosity such as (25) or (26) as τ ≈ η(∇u + (∇u) T ):…”

Section: Discretisation Of the Continuity Equationmentioning

confidence: 99%

“…In the latter case, the solid and dash-dot lines correspond to the use of Eqs. (25) and (26), respectively. Dashed lines with short or long dashes correspond, respectively, to replacing S by S/2 or 2S in (25).…”

Section: Solution Of the Algebraic Systemmentioning

confidence: 99%

“…An alternative, very popular discretisation / solution method in Computational Fluid Dynamics is the Finite Volume Method (FVM); it has been successfully applied to viscoplastic (e.g. [24,25]) and viscoelastic (e.g. [26][27][28][29]) flows individually, but not to EVP flows, to the best of our knowledge (a hybrid FE/FV method was used in [30]).…”

Section: Introductionmentioning

confidence: 99%

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A finite volume method for the simulation of elastoviscoplastic flows and its application to the lid-driven cavity case

Syrakos

Dimakopoulos

Tsamopoulos

2020

Journal of Non-Newtonian Fluid Mechanics

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We propose a Finite Volume Method for the simulation of elastoviscoplastic flows, modelled after the extension to the Herschel-Bulkley model by Saramito [J. Non-Newton. Fluid Mech. 158 (2009) 154-161]. The method is akin to methods for viscoelastic flows. It is applicable to cell-centred grids, both structured and unstructured, and includes a novel pressure stabilisation technique of the "momentum interpolation" type. Stabilisation of the velocity and stresses is achieved through a "both sides diffusion" technique and the CUBISTA convection scheme, respectively. A second-order accurate temporal discretisation scheme with adaptive time step is employed. The method is used to obtain benchmark results of lid-driven cavity flow, with the model parameters chosen so as to represent Carbopol. The results are compared against those obtained with the classic Herschel-Bulkley model. Simulations are performed for various lid velocities, with slip and no-slip boundary conditions, and with different initial conditions for stress. Furthermore, we investigate the cessation of the flow, once the lid is suddenly halted.

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Section: Discretisation Of the Momentum Equationmentioning

confidence: 97%

Section: Discretisation Of the Continuity Equationmentioning

confidence: 99%

Section: Solution Of the Algebraic Systemmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A finite volume method for the simulation of elastoviscoplastic flows and its application to the lid-driven cavity case

Syrakos

Dimakopoulos

Tsamopoulos

2020

Journal of Non-Newtonian Fluid Mechanics

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“…A possible reason for the lack of such prior studies is that viscoelastic simulations are much more expensive than those involving generalised Newtonian fluids such as the CY, as additional differential equations have to be solved (one per stress component), which are unwieldy at high elasticity (the notorious high-Weissenberg number problem -see e.g. [21]), while also much smaller time steps are needed in order to capture the elastic phenomena (whereas if the flow is assumed generalised Newtonian, it is also quasi-steady due to the high viscosity of typical damper fluids and one can employ large time steps without loss of accuracy -see [22]).…”

Section: Introductionmentioning

confidence: 99%

Theoretical study of the flow in a fluid damper containing high viscosity silicone oil: Effects of shear-thinning and viscoelasticity

2018

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The flow inside a fluid damper where a piston reciprocates sinusoidally inside an outer casing containing high-viscosity silicone oil is simulated using a Finite Volume method, at various excitation frequencies. The oil is modelled by the Carreau-Yasuda (CY) and Phan-Thien & Tanner (PTT) constitutive equations. Both models account for shear-thinning but only the PTT model accounts for elasticity. The CY and other generalised Newtonian models have been previously used in theoretical studies of fluid dampers, but the present study is the first to perform full two-dimensional (axisymmetric) simulations employing a viscoelastic constitutive equation. It is found that the CY and PTT predictions are similar when the excitation frequency is low, but at medium and higher frequencies the CY model fails to describe important phenomena that are predicted by the PTT model and observed in experimental studies found in the literature, such as the hysteresis of the force-displacement and force-velocity loops. Elastic effects are quantified by applying a decomposition of the damper force into elastic and viscous components, inspired from LAOS (Large Amplitude Oscillatory Shear) theory. The CY model also overestimates the damper force relative to the PTT, because it underpredicts the flow development length inside the piston-cylinder gap. It is thus concluded that (a) fluid elasticity must be accounted for and (b) theoretical approaches that rely on the assumption of one-dimensional flow in the piston-cylinder gap are of limited accuracy, even if they account for fluid viscoelasticity. The consequences of using lower-viscosity silicone oil are also briefly examined. This is the accepted version of the article published in:

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