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2023-12-15

Strains

In the navigator, define the strains to be displayed on the surfaces. The table lists the strains of each surface according to the specifications set in the Result Table Manager .

The surface strains are subdivided into the following categories:

  • Basic Total Strains: strains in the direction of the surface axes
  • Principal Total Strains: strains in the direction of the principal axes
  • Maximum Total Strains: extreme values of strains
  • Equivalent Total Strains: strains analyzed according to different equivalent stress hypotheses

Basic total strains

The basic strains are related to the directions of the local surface axes. When analyzing curved surfaces, they refer to the local axes of finite elements (see image Displaying FE Axis Systems ).

The basic strains have the following meanings:

Principal total strains

While the basic strains refer to the xyz coordinate system of a surface, the principal strains represent the extreme values of the strains in a surface element. The principal axes 1 (maximum value) and 2 (minimum value) are arranged orthogonally.

The principal strains are determined from the basic strains. They have the following meanings:

It is possible to graphically display the principal axis directions α as 'Trajectories' (compare image Displaying Trajectories of Principal Axes ).

Maximum total strains

This category shows the strain's positive and negative extreme values resulting from the principal total strains.

εmax,+ Maximum value of strain on positive side of surface
εmin,+ Minimum value of strain on positive side of surface
max|+ Greatest extreme value on positive side of surface
εmax,- Maximum value of strain on negative side of surface
εmin,- Minimum value of strain on negative side of surface
max|- Greatest extreme value on negative side of surface
εmax Maximum value of strain on positive or negative side of surface
εmin Minimum value of strain on positive or negative side of surface
max| Greatest extreme value on positive or negative side of surface

Equivalent total strains

The Basic Strains are combined according to four equivalent stress hypotheses for the plane stress condition.

von Mises

The approach by von Mises is also called "shape modification hypothesis". This energy is the type of energy that causes a distortion or deformation of the object.

The equivalent total strains according to von Mises have the following meanings:

Tresca

The Tresca hypothesis assumes that the failure is caused by the maximum shear stress.

The equivalent total strains according to Tresca have the following meanings:

Rankine

The hypothesis according to Rankine assumes that the greatest principal stress leads to failure.

The equivalent total strains according to Rankine have the following meanings:

Bach

In the case of the Bach hypothesis, it is assumed that the failure occurs in the direction of the greatest strain.

The equivalent total strains according to Bach have the following meanings:

εv,Bach,+ Greatest absolute value of principal strain ε1,+ or ε2,+ on positive side of surface
εv,Bach,- Greatest absolute value of principal strain ε1,- or ε2,- on negative side of surface
max| Maximum equivalent strain εv,Bach on positive or negative side of surface

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