Boundary Condition Styles

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Setting Styles

The possible boundary condition styles are defined below. In scripted files, the style can be set by name or number; in XML files, the style must be set by number. Unless otherwise specified, the units for (value) are the standard units for the current type of boundary condition (i.e., velocity units for velocity, degrees K for temperature, etc.) and the units for (time) are alt time units.

  • constant (or 1) - the applied boundary condition is set to the constant (value) and it is applied for times after (time).
  • linear (or 2) - the applied boundary condition is

                         [math]\displaystyle{ BC = ({\rm value})*(t-({\rm time})) }[/math]

    where t is the current time (in alt time units). This condition is applied only for times after (time). The units for (value) should change to the standard units for the boundary condition per alt time units.
  • sine (or 3) - the applied boundary condition is

                         [math]\displaystyle{ BC = ({\rm value})\sin\bigl[({\rm time})*t\bigr] }[/math]

    This condition is applied for all times. The units for (time) should change to 1/alt time units (i.e., it becomes a frequency in radians/alt time units).
  • cosine (or 4) - the applied boundary condition is

                         [math]\displaystyle{ BC = ({\rm value})\cos\bigl[({\rm time})*t\bigr] }[/math]

    This condition is applied for all times. The units for (time) should change to 1/alt time units (i.e., it becomes a frequency in radians/alt time units).
  • silent (or 5) - to apply an "absorbing" boundary condition as explained below. These are only allowed for load, heat flux, and concentration flux conditions.
  • function (or 6) - the applied boundary condition is determined by a user-defined function of time (t in alt time units), nodal point position, and/or of current clockwise particle rotation angle (2D only). The function should evaluate to the desired value in the standard units for the type of boundary condition. If (time) is supplied, the condition starts at time (time) (in alt time units) and the function is evaluated at [t-(time)] (instead of at t).

To get any time-dependence for a boundary condition, you can combine more than one conditions in the same direction and the resulting condition will be a superposition of the applied conditions. See below for some special considerations when applying multiple boundary condition on the same node.

Silent Boundary Conditions

The object of silent boundary conditions is to apply an absorbing edge. The goal is to simulate a small portion of a large object by having stress waves, heat fluxes, and concentration fluxes absorbed by the edges rather the reflect back into the object. Their development in MPM is in a paper by Shen and Chen (2005).[1] These conditions can be shown to work well in small, idealized simulations. They have been less useful in other simulations.

Some considerations about using silent boundary conditions in NairnMPM are.

  • Silent boundary conditions can only be applied to edges that are along the x, y, or z direction and the direction for the conditions should specify the normal to that edge.
  • When an edge uses silent boundary conditions, that condition must be the only condition that is used (i.e., you can not superpose multiple boundary conditions along silent edges).
  • For load conditions, silent boundary conditions only work for isotropic materials, because they rely on calculations of isotropic bulk and shear wave speeds.
  • For heat flux conditions, silent boundary conditions set natural flux determined by (k grad T).n extrapolated from particles along the edge with the boundary condition. It should enable simulation of heat flow through materials, but its use is relatively unexplored. Here k is thermal conductivity tensor, T is temperature, and n is normal vector; this condition works for isotropic and anisotropic materials.
  • For concentration flux conditions, silent boundary conditions set natural flux determined by (D grad c).n extrapolated from particles along the edge with the boundary condition. It should enable simulation of solvent flow through materials, but its use is relatively unexplored. Here D is diffusion tensor, c is concenration, and n is normal vector; this condition works for isotropic and anisotropic materials.

Notes

  1. When applying multiple velocity conditions on the same node, the combinations must either be in the same direction or in orthogonal directions. For example, you can apply any combination of velocities along analysis axes (x, y, or z).
  2. When using skewed velocity conditions, the typical problem will use only a single skewed direction on a node. You can use any number of conditions in that single direction. You should not mix skewed velocity conditions with velocity conditions along one of the skew axes. For example, you should not apply some conditions in the x direction and others in the skewed x-y or x-z direction, because these two directions are not orthogonal. In principle orthogonal skewed directions could be used, but such problems can normally be recast to get the same fixed velocity by fixing the two axes in the skew plane instead.
  3. When applying multiple concentration conditions on the same node, the net result must add up to a valid concentration potential between 0 and 1.

References

  1. L. Shen and Z. Chen, "A Silent Boundary Scheme with the Material Point Method for Dynamic Analyses," Computer Modeling in Engineering & Sciences, 7, 305-320 (2005).