Nonlinear Structural Analysis - PowerPoint PPT Presentation

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Nonlinear Structural Analysis

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Chapter 1 Introduction – PowerPoint PPT presentation

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Title: Nonlinear Structural Analysis


1
Introduction
  • Chapter 1

2
A. Feature Overview
Field from a periodic arrangement of coils from
the winding editor
Enclosure
  • Workbench EMAG features at release 9.0
  • 3D modeling ONLY, using the SOLID117 edge
    formulated element available in ANSYS.
  • An enclosure tool is available to conveniently
    model the domain surrounding the electromagnetic
    device/system.
  • Automatic gap detection refines mesh locally in
    air gaps.
  • Can model nonlinear permeable materials with BH
    curves, permanent magnets, and coils.
  • A winding tool facilitates the modeling of
    multiple windings in rotating machinery.
  • Can calculate field quantities (flux density,
    field intensity), force and torque, inductance,
    and flux linkage.
  • At release 9.0, only magnetostatic analyses are
    possible.
  • Parameters used to define dimensions, material
    properties, etc. may be varied automatically in a
    series of solutions using the parameter manager.

Gap detection
BH data
Parameter Manager
Armature forces
3
B. Underlying Technology
  • The 3D SOLID117 used in Workbench correctly
    calculates the discontinuity in the tangential
    component of B at iron-air interface
  • Edge formulated element has 12 edge-flux DOFs
    (AZ) at each midside node
  • In SOLID117, AZ IS NOT the z component of the
    magnetic vector potential. Rather, it is the
    integral of the tangential component of A along
    an element edge. A useful physical
    interpretation the sum of AZ around a closed
    loop formed by edges equals the flux passing
    through the loop (right hand rule).
  • AZ units Webers (volt-seconds)
  • You may not remove midside nodes they are used
    to support the edge-flux DOF AZ
  • The presence of midside nodes does not imply a
    quadratic shape function. SOLID117 shape
    functions are linear.

4
C. Enclosures
  • Use the Enclosure Tool to define surrounding
    electromagnetic domain (air). Predefined shapes
    include Box, Sphere, and Cylinder. The Cushion
    is how far the enclosure extends beyond the
    surfaces of the modeled geometry. Merge Parts?
    should be set to Yes when solid model geometry
    is present.

5
D. Boundary Conditions
  • Surfaces may either be flux normal (naturally
    occurring) or flux parallel.
  • Specify flux parallel on even symmetry boundaries
    and to approximate far field by applying to
    external surfaces of enclosures under Environment
    in the Simulation Tree.

6
E. Modeling Permanent Magnets
  • PM polarity may be in ?X direction in a user
    defined coordinate system (named PM_CSYS in
    this example). The coordinate system orientation
    may be modified.

7
F. Modeling Permanent Magnets
  • PM properties may be defined as linear hard
    (shown here) with coercive force Hc and residual
    induction Br

8
G. Modeling Conductors
  • Option 1 Create a solid conductor from a solid
    body
  • Procedure
  • Insert a conductor on the environment branch of
    the tree using imported or created solid
    geometry.
  • Define the number of turns.
  • Insert a voltage condition on one face
  • Insert an impressed current on the opposite
    face.

Current injected into this face
Voltage 0 on this face
In general, the current density in a solid
conductor is NOT uniform over its cross section.
With this conductor option, if symmetry is used
in the model, only the portion of the conductor
present in the modeled portion of the system
should be included. The current distribution is
that of a solid with DC excitation (no skin
effects, no induced voltage or current in the
conductor). The distribution of current may be
visualized using this option.
Resulting current distribution
9
Modeling Conductors
  • Option 2 Create a stranded conductor from a
    line body
  • Procedure
  • Create a sketch
  • Promote the sketch to a line body
  • Promote the line body to a winding body

3 winding body
2 line body
1 sketch
4 field created by winding body in spherical
enclosure
The current density in a stranded conductor is
always uniform over its cross section. All
conductors present in the physical system must be
included in the model, even if symmetry is used.
10
Modeling Conductors
  • Option 3 Create a series of stranded conductors
    (for rotating machines) using the winding editor
  • Procedure
  • Bring up the winding editor tool.
  • Define the number of slots.
  • Edit the values of the table to define coils in
    each phase, connectivity, number of turns, and
    geometry.

6
Slot 3
Slot 2
1
Slot 4
Slot 1
Slot 6
Slot 5
The current density in a stranded conductor is
always uniform over its cross section. All
conductors present in the physical system must be
included in the model, even if symmetry is used.
2
3
4
5
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