Difference between revisions of "Liquid Wall Contact Law"
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== Description == | == Description == | ||
This [[Contact Laws#Frictional Contact Laws|frictional contact law]] implements a friction-style contact between liquid and | This [[Contact Laws#Frictional Contact Laws|frictional contact law]] implements a friction-style contact between liquid and a wall where contact shear is related to shear rate, viscosity, and a scaling factor to vary from stick to slip contact. When the surfaces are in contact, the frictional sliding traction is | ||
| | ||
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where ''k'' is a scaling factor (with units 1/length), <math>\eta(\dot\gamma)</math> is viscosity of a fluid (which may depend on shear rate), and <math>\Delta v_t</math> is the final difference in tangential velocities between fluid and the other material (usually a wall). | where ''k'' is a scaling factor (with units 1/length), <math>\eta(\dot\gamma)</math> is viscosity of a fluid (which may depend on shear rate), and <math>\Delta v_t</math> is the final difference in tangential velocities between fluid and the other material (usually a wall). | ||
Note that ''k'' = 0 leads to zero sliding traction, which is the same as frictionless contact (and could be done using a [[Coulomb Friction Law]] with it's <tt>coeff</tt> = 0). As ''k'' get large, the law approaches stick contact having <math>\Delta v_t\to 0</math> (and could be done using a [[Coulomb Friction Law]] with it's <tt>coeff</tt> = -1). All other values of ''k'' give partial-slip boundary conditions that depend on the liquid's viscosity and could be tailored to match experimental results. | |||
After running some simulations for a range of ''k'' and at different resolutions, those results indicate that ''k'' is a material property. In other words, ''k'' is independent of grid cell size, or only weakly dependent of grid cell size. A possible physical interpretation is that 1/''k'' is a "zone of influence" for the boundary region near a wall. If other problems show mesh dependence for ''k'', it could (and then should) be varied with cell size. | |||
== Properties == | == Properties == | ||
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! Property !! Description !! Units !! Default | ! Property !! Description !! Units !! Default | ||
|- | |- | ||
| coeff || The scaling factor k in the contact law || 1/[[ConsistentUnits Command#Legacy and Consistent Units|length units]] || 2 | | coeff || The scaling factor ''k'' in the contact law || 1/[[ConsistentUnits Command#Legacy and Consistent Units|length units]] || 2 | ||
|- | |||
| LiquidPhase || Enter the liquid phase material by ID (scripted files only) or by number || none || none | |||
|- | |||
| displacementOnly || Set to: 0 to detect contact when COD<0 <i>and</i> stress<0; 1 to detect contact whenever COD<0 regardless of stress; <0 to detect contact when COD<0 <i>and</i> stress<<tt>-displacementOnly</tt> (in [[ConsistentUnits Command#Legacy and Consistent Units|pressure units]])|| none || 0 | |||
|- | |- | ||
| | | Dc || <0 to find separation assuming perfect interfaciall contact, ≥0 to use [[Linear Imperfect Interface|imperfect interface methods]] to find separation. || [[ConsistentUnits Command#Legacy and Consistent Units|pressure/length units]] || none | ||
|} | |} | ||
Note that this contact law uses the viscosity provided by the | Note that this contact law uses the viscosity provided by the entered <tt>LiquidPhase</tt> material for all contact situations assigned to the law. Simulations that use this contact law must therefore insure that it only applies to contact involving that liquid material by setting [[Friction#Friction in Multimaterial MPM|default or custom contact laws]] as needed. | ||
See [[Coulomb Friction Law#Comments on Parameters|some comments]] about the <tt>displacementOnly</tt> and </tt>Dc</tt> parameters. | |||
== Examples == | |||
These commands create a liquid contact law for "MyLiquid" (using scripted commands) or material number 1 (using XML commands): | |||
Material "LiquidContact","Liquid Contact Law","LiquidContact" | |||
LiquidPhase "MyLiquid" | |||
coeff 100 | |||
Done | |||
<Material Type='64' Name='Liquid Contact Law'> | |||
<LiquidPhase>1</LiquidPhase> | |||
<coeff>100</coeff> | |||
</Material> |
Latest revision as of 12:00, 18 September 2020
Description
This frictional contact law implements a friction-style contact between liquid and a wall where contact shear is related to shear rate, viscosity, and a scaling factor to vary from stick to slip contact. When the surfaces are in contact, the frictional sliding traction is
[math]\displaystyle{ S_{slide} = k\ \eta(k\Delta v_t) \Delta v_t }[/math]
where k is a scaling factor (with units 1/length), [math]\displaystyle{ \eta(\dot\gamma) }[/math] is viscosity of a fluid (which may depend on shear rate), and [math]\displaystyle{ \Delta v_t }[/math] is the final difference in tangential velocities between fluid and the other material (usually a wall).
Note that k = 0 leads to zero sliding traction, which is the same as frictionless contact (and could be done using a Coulomb Friction Law with it's coeff = 0). As k get large, the law approaches stick contact having [math]\displaystyle{ \Delta v_t\to 0 }[/math] (and could be done using a Coulomb Friction Law with it's coeff = -1). All other values of k give partial-slip boundary conditions that depend on the liquid's viscosity and could be tailored to match experimental results.
After running some simulations for a range of k and at different resolutions, those results indicate that k is a material property. In other words, k is independent of grid cell size, or only weakly dependent of grid cell size. A possible physical interpretation is that 1/k is a "zone of influence" for the boundary region near a wall. If other problems show mesh dependence for k, it could (and then should) be varied with cell size.
Properties
The properties for this law are:
Property | Description | Units | Default |
---|---|---|---|
coeff | The scaling factor k in the contact law | 1/length units | 2 |
LiquidPhase | Enter the liquid phase material by ID (scripted files only) or by number | none | none |
displacementOnly | Set to: 0 to detect contact when COD<0 and stress<0; 1 to detect contact whenever COD<0 regardless of stress; <0 to detect contact when COD<0 and stress<-displacementOnly (in pressure units) | none | 0 |
Dc | <0 to find separation assuming perfect interfaciall contact, ≥0 to use imperfect interface methods to find separation. | pressure/length units | none |
Note that this contact law uses the viscosity provided by the entered LiquidPhase material for all contact situations assigned to the law. Simulations that use this contact law must therefore insure that it only applies to contact involving that liquid material by setting default or custom contact laws as needed.
See some comments about the displacementOnly and Dc parameters.
Examples
These commands create a liquid contact law for "MyLiquid" (using scripted commands) or material number 1 (using XML commands):
Material "LiquidContact","Liquid Contact Law","LiquidContact" LiquidPhase "MyLiquid" coeff 100 Done <Material Type='64' Name='Liquid Contact Law'> <LiquidPhase>1</LiquidPhase> <coeff>100</coeff> </Material>