Evaluate your design in real-time using SimSolid dynamics
analysis.
Setup
Specify the modal results to which the analysis is linked. The modal
solution must exist in the current design study. In SimSolid, the time integration of the equations of
motion is extremely fast and all modes are always included in the
analysis.
For Frequency and Random Response, specify the frequency span upper and
lower limits. For Transient response, specify Time span.
Specify damping using Rayleigh damping coefficients or Modal damping.
Select the Evaluate peak responses during solving
check box to evaluate peak responses during solving phase.
Assumes the damping matrix is proportional to the mass and stiffness
matrices. You need to specify values for Mass (F1) and Stiffness (F2) in
the Dynamics creation dialog to use this method.
Modal Damping
Creates critical damping ratio for each mode. You can specify this value
in the Dynamics analysis creation dialog.
Notes for Dynamics Analysis
When the base excitation type is displacement, the initial condition for
displacement and velocity is always assumed to be zero.
In SimSolid, the boundary compatibility is
approximately met. The response at the constrained end is not going to be an
absolute zero but is relatively small compared to the peak responses.
Equivalent radiated power density is calculated as:(1)
Where:
Normal velocity of the picked point
ERPC (Speed of sound in air)
343 m/s
ERPRHO (Density of air)
1.225 Kg/m3
ERPRLF (Radiation loss factor)
1
Equivalent radiated power is calculated as an integral of
ERP density over picked faces as:
(2)
Phase for Absolute displacement can be queried using Pick Info for frequency
dynamics.
Relationship between relative and absolute displacement in frequency
dynamics is as follows.
Relative motion is calculated as:(3)
Where base excitation is:(4)
Solving this differential equation, the
relative displacement can be calculated as:(5)
Absolute motion is calculated
as:(6)
Where, (7)
Solving this equation, the absolute
displacement can be calculated as:(8)
In Frequency and Random dynamics, the Complex Function Method is used to
solve differential equations. Displacement, velocity, and acceleration
results have complex components.
Given complex values of displacement
as:(9)
Displacement magnitude is calculated
as:(10)
When a transient dynamics analysis is linked to a prestressed modal
analysis, a new result type is offered called Total Displacement. Total
Displacement is the combination of the prestressed and dynamic
displacements. Therefore, displacement magnitude is the displacement caused
by the dynamic analysis.
For a random response analysis, the Power Spectral Density (PSD) of the
response , is related to the power spectral density of
the source, , by:(11)
Where, is the frequency response function.
For
better understanding, let us take an example of base excitation with
acceleration as the excitation type as an input to a random response
analysis.
The base excitation with amplitude is used to define the
input for frequency response analysis, so the units of the acceleration
excitation type would be either of below highlighted units,
m/sec2; mm/sec2; cm/sec2; G;
in/sec2
Units for the PSD function depend on the boundary condition. In this
example, as base excitation is given as acceleration, the unit for PSD
will be (mm/s2)2/Hz.
Create Time Function
Define amplitude versus time response curves for transient dynamics analysis or thermal transient analysis.
Create Frequency Function
Define amplitude versus frequency response curves in frequency response dynamics analysis.