Access the full text.
Sign up today, get DeepDyve free for 14 days.
川口 光年 (1964)
O. A. Ladyzhenskaya: The Mathematical Theory of Viscous Incompressible Flow, Gordon and Breach Sci. Pub. New York-London, 1963, 184頁, 15×23cm, 3,400円., 19
D. Einzel, P. Panzer, Mario Liu (1990)
Boundary condition for fluid flow: Curved or rough surfaces.Physical review letters, 64 19
G. Carey, R. Krishnan (1982)
Penalty approximation of stokes flowComputer Methods in Applied Mechanics and Engineering, 35
V.E. Dussan
On the spreading of liquids on solid surfaces: static and dynamic contact lines
G. Stokes
On the theories of the internal friction of fluids in motion, and of the equilibrium and motion of elastic solids
G. Celata, M. Cumo, S. McPhail, G. Zummo (2006)
Characterization of fluid dynamic behaviour and channel wall effects in microtubeInternational Journal of Heat and Fluid Flow, 27
G. Carey, R. Krishnan (1985)
Continuation techniques for a penalty approximation of the Navier-Stokes equationsComputer Methods in Applied Mechanics and Engineering, 48
O. Pinazza, M. Spiga (2003)
Friction factor at low Knudsen number for the duct with sine-shaped cross-sectionInternational Journal of Heat and Fluid Flow, 24
G. Carey, R. Krishnan (1984)
Penalty finite element method for the Navier-Stokes equationsComputer Methods in Applied Mechanics and Engineering, 42
M. Utku, G. Carey (1983)
Penalty resolution of the babuska circle paradoxComputer Methods in Applied Mechanics and Engineering, 41
M. Sbragaglia, A. Prosperetti (2007)
Effective velocity boundary condition at a mixed slip surfaceJournal of Fluid Mechanics, 578
Microfluidics: The No-Slip Boundary Condition
COMSOL
COMSOL Multiphysics, Version 3.4.
H. Huppert, J. Shepherd, R. Sigurdsson, S. Sparks (1982)
On lava dome growth, with application to the 1979 lava extrusion of the soufrière of St. VincentJournal of Volcanology and Geothermal Research, 14
M. Matthews, J. Hill (2006)
Micro/nano sliding plate problem with Navier boundary conditionZeitschrift für angewandte Mathematik und Physik ZAMP, 57
E. Barragy, G. Carey (1993)
Stream function vorticity solution using high‐p element‐by‐element techniquesCommunications in Numerical Methods in Engineering, 9
B. Armaly, F. Durst, J. Pereira, B. Schoenung (1983)
Experimental and theoretical investigation of backward-facing step flowJournal of Fluid Mechanics, 127
V. John (2002)
Slip With Friction and Penetration With Resistance Boundary Conditions for the Navier-Stokes Equatio
G. Stokes (2009)
Mathematical and Physical Papers vol.1: On the Theories of the Internal Friction of Fluids in Motion, and of the Equilibrium and Motion of Elastic Solids
F. Hoog, R. Anderssen (2005)
Approximate solutions for the Couette viscometry equationBulletin of the Australian Mathematical Society, 72
C. Navier
Mémoire sur les lois du mouvement des fluids
CSIRO
Fastflo Version 3 Tutorial Guide
S. Yang, L. Fang (2005)
Effect of surface roughness on slip flows in hydrophobic and hydrophilic microchannels by molecular dynamics simulationMolecular Simulation, 31
Thomas Podgorski, J. Flesselles, L. Limat (2001)
Corners, cusps, and pearls in running drops.Physical review letters, 87 3
M. Cieplak, J. Koplik, J. Banavar (2000)
Boundary conditions at a fluid-solid interface.Physical review letters, 86 5
P. Thompson, M. Robbins, M. Robbins (1990)
Shear flow near solids: Epitaxial order and flow boundary conditions.Physical review. A, Atomic, molecular, and optical physics, 41 12
J. Leray (1933)
Étude de diverses équations intégrales non linéaires et de quelques problèmes que pose l'Hydrodynamique.Journal de Mathématiques Pures et Appliquées, 12
K. Seetharamu, R. Lewis, P. Nithiarasu (2004)
Fundamentals of the Finite Element Method for Heat and Fluid Flow
G. Stokes (2009)
On the Effect of the Internal Friction of Fluids on the Motion of Pendulums, 9
B. Kirk, J. Peterson, Roy Stogner, G. Carey (2006)
libMesh: a C++ library for parallel adaptive mesh refinement/coarsening simulationsEngineering with Computers, 22
M. Holt, G. Carey, J. Oden (1989)
Finite Elements: Fluid Mechanics.Mathematics of Computation, 52
E. Dussan (1979)
LIQUIDS ON SOLID SURFACES: STATIC AND DYNAMIC CONTACT LINES
E. Hopf
Über die Anfangswertaufgabe für die hydrodynamischen Grundgleichungen
M. Engelman, R. Sani, P. Gresho (1982)
The implementation of normal and/or tangential boundary conditions in finite element codes for incompressible fluid flowInternational Journal for Numerical Methods in Fluids, 2
Yingxi Zhu, S. Granick (2002)
No-slip boundary condition switches to partial slip when fluid contains surfactantLangmuir, 18
Y. Stokes (2000)
Numerical design tools for thermal replication of optical-quality surfacesComputers & Fluids, 29
T. Galea, P. Attard (2004)
Molecular dynamics study of the effect of atomic roughness on the slip length at the fluid-solid boundary during shear flow.Langmuir : the ACS journal of surfaces and colloids, 20 8
G. Beavers, D. Joseph (1967)
Boundary conditions at a naturally permeable wallJournal of Fluid Mechanics, 30
C. Neto, Drew Evans, E. Bonaccurso, H. Butt, V. Craig (2005)
Boundary slip in Newtonian liquids: a review of experimental studiesReports on Progress in Physics, 68
E. Hopf (1950)
Über die Anfangswertaufgabe für die hydrodynamischen Grundgleichungen. Erhard Schmidt zu seinem 75. Geburtstag gewidmetMathematische Nachrichten, 4
V. John
Slip with friction and penetration with resistance boundary conditions for the Navier‐Stokes equations – numerical tests and aspects of the implementation
Z. Alloui, M. Fekri, H. Beji, P. Vasseur (2008)
Natural convection in a horizontal binary fluid layer bounded by thin porous layersInternational Journal of Heat and Fluid Flow, 29
O. Ladyzhenskaya, R. Silverman, J. Schwartz, J. Romain (1972)
The Mathematical Theory of Viscous Incompressible Flow
R. Krishnan, G. Carey (1985)
ON THE COMPUTED PRESSURES FOR NAVIER-STOKES PROBLEMS AT INCREASING REYNOLDS NUMBERS USING THE PENALTY FINITE ELEMENT METHODInternational Journal for Numerical Methods in Fluids, 5
R. Temam (1977)
Navier-Stokes Equations
J. Lions (1960)
Sur la régularité et l'unicité des solutions turbulentes des équations de Navier StokesRendiconti del Seminario Matematico della Università di Padova, 30
G. Carey, W. Richardson, C. Reed, B. Mulvaney
Circuit, Device and Process Simulation
Y. Stokes, E. Tuck (2004)
The role of inertia in extensional fall of a viscous dropJournal of Fluid Mechanics, 498
CSIRO
Fastflo. CSIRO Mathematical and Information Sciences
M. Utku, G. Carey (1982)
Boundary penalty techniquesComputer Methods in Applied Mechanics and Engineering, 30
Y. Stokes, E. Tuck, L. Schwartz
Extensional fall of a very viscous fluid
G. Carey, R. Krishnan
Penalty approximation of Stokes flow, Parts I & II
A. Münch, B. Wagner, Thomas Witelski (2005)
Lubrication Models with Small to Large Slip LengthsJournal of Engineering Mathematics, 53
S. Kaniel, M. Shinbrot (1967)
Smoothness of weak solutions of the Navier-Stokes equationsArchive for Rational Mechanics and Analysis, 24
R. Courant
Calculus of Variations and Supplementary Notes and Exercises
T. Qian, Xiaoping Wang, P. Sheng (2006)
A variational approach to moving contact line hydrodynamicsJournal of Fluid Mechanics, 564
J. Ellis, M. Thompson (2004)
Slip and coupling phenomena at the liquid–solid interfacePhysical Chemistry Chemical Physics, 6
J. Banavar, M. Cieplak, J. Koplik (2001)
Christodoulides, Demetrios N.
L. Hocking (1983)
THE SPREADING OF A THIN DROP BY GRAVITY AND CAPILLARITYQuarterly Journal of Mechanics and Applied Mathematics, 36
G. Carey, R. Krishnan
Penalty finite element method for the Navier‐Stokes equations, Parts I & II
F. Hoog, R. Anderssen (2006)
Simple and Accurate Formulas for Flow-Curve Recovery from Couette Rheometer DataApplied Rheology, 16
L. Bocquet, J. Barrat (2006)
Flow boundary conditions from nano- to micro-scales.Soft matter, 3 6
A.B. Basset
Hydrodynamics
L. Tophøj, S. Møller, M. Brøns (2006)
Streamline patterns and their bifurcations near a wall with Navier slip boundary conditionsPhysics of Fluids, 18
J. Nocedal, S. Wright
Numerical Optimisation
M. Behr (2004)
On the application of slip boundary condition on curved boundariesInternational Journal for Numerical Methods in Fluids, 45
J. Reddy, D. Gartling (1994)
The Finite Element Method in Heat Transfer and Fluid Dynamics
B. Armaly, F. Durst, Pereira J.C.F., B. Schoenung (1983)
EXPERIMENTAL AND THEORETICAL INVESTIGATIONS OF BACKWARD-FACING STEP FLOW, 127
Y. Shikhmurzaev (1997)
Moving contact lines in liquid/liquid/solid systemsJournal of Fluid Mechanics, 334
P. Gennes (1985)
Wetting: statics and dynamicsReviews of Modern Physics, 57
Y. Stokes, E. Tuck, L. Schwartz (2000)
Extensional fall of a very viscous fluid dropQuarterly Journal of Mechanics and Applied Mathematics, 53
M. Shinbrot (1973)
Lectures On Fluid Mechanics
C. Huh, L. Scriven (1971)
Hydrodynamic Model of Steady Movement of a Solid / Liquid / Fluid Contact Line, 35
M. Latva-Kokko, D. Rothman (2007)
Scaling of dynamic contact angles in a lattice-Boltzmann model.Physical review letters, 98 25
Purpose – The purpose of this paper is to extend the penalty concept to treat partial slip, free surface, contact and related boundary conditions in viscous flow simulation. Design/methodology/approach – The penalty partial‐slip formulation is analysed and related to the classical Navier slip condition. The same penalty scheme also allows partial penetration through a boundary, hence the implementation of porous wall boundaries. The finite element method is used for investigating and interpreting penalty approaches to boundary conditions. Findings – The generalised penalty approach is verified by means of a novel variant of the circular‐Couette flow problem, having partial slip on one of the cylindrical boundaries, for which an analytic solution is derived. Further verificationis provided by consideration of viscous flow over a sphere with partial slip on the surface, and comparison of numerical and classical solutions. Numerical studies illustrate the versatility of the approach. Research limitations/implications – The penalty approach is applied to some different boundaries: partial slip and partial penetration with no/full slip/penetration as limiting cases; free surface; space‐ and time‐varying boundary conditions which allow progressive contact over time. Application is made to curved and inclined boundaries. Sensitivity of flow to penalty parameters is an avenue for continued research, as is application of the penalty approach for non‐Newtonian flows. Originality/value – This is the first work to show the relation between penalty formulation of boundary conditions and physical boundary conditions. It provides a method that overcomes past difficulties in implementing partial slip on boundaries of general shape, and which handles progressive contact. It also provides useful benchmark problems for future studies.
International Journal of Numerical Methods for Heat and Fluid Flow – Emerald Publishing
Published: Aug 9, 2011
Keywords: Penalty methods; Finite element analysis; Navier slip; Free surface contact; Viscosity; Flow; Simulation
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.