An explicit is solved by calculating results in small time increments or time steps. The size of the time step depends
on many factors but is automatically calculated by Radioss.
Composite materials consist of two or more materials combined each other. Most composites consist
of two materials, binder (matrix) and reinforcement. Reinforcements come in three forms, particulate,
discontinuous fiber, and continuous fiber.
A non-uniform pressure is assumed inside the volume. The gas flow in FVMBAG1 is solved using a finite volume integration scheme which allows the gas flow through the airbag to be correctly modeled.
An "AIRBAG1" time step is estimated into the Engine, but this time step will never control the time
step during the run. If that is the case, it means there is a non-physical airbag definition in the
input deck.
By using data from a tank test output, it is possible to obtain the temperature and the mass flow of the gas supplied,
which can be used as input to Radioss.
The objective here is to provide some guidelines on how to troubleshoot a simulation where the airbag does not deploy
properly or crashes because of the airbag.
Optimization in Radioss was introduced in version 13.0. It is implemented by invoking the optimization capabilities of
OptiStruct and simultaneously using the Radioss solver for analysis.
This option is used to simulate chambered airbags and may be used to unfold an
airbag.
Each COMMU1 type monitored volume works like an AIRBAG1
type monitored volume with possible vent communication with some other
COMMU1 type monitored volume. A chambered airbag is therefore
designed with two or more COMMU1 type monitored volumes.
Each monitored volume can have an inflator and vent holes.
Case 1: Folded Airbag
To model a folded airbag, one COMMU1 type monitored volume is used for each
folded part. The boundary between two folded parts is closed with a void (dummy)
property set. The area of communication is defined with this void property set. The
pressure in each folded part will be different and the area of communication will
increase during inflation. With this modelization the volume with inflator will
inflate first and before the folded parts.
Volume 1: Prop. 1 + 4 + 5
Communication area: vol. 1 to 2: prop. 4
vol. 1 to 3: prop. 5
Volume 2: Prop. 2 + 4
Communication area: vol. 2 to 1: prop. 4
Volume 3: Prop. 3 + 5
Communication area: vol. 3 to 1: prop. 5
Case 2: General Use
Monitored volume 1 can communicate with monitored volume 2 with or without communication from 2 to 1. Communication area, deflation pressure or time from 1 to 2 can be different than corresponding values from 2 to 1. That way it is possible to model a valve communication.
Two communication monitored volumes can have common nodes or common shell property set, but this is optional.
Volume 1 communicates with volume 2, and volume 2 with volume 1 and 3, but there is no
communication from 3 to 2.
General Equations
Same equations for AIRBAG1 type monitored volume are used, but
incoming and outgoing enthalpy and kinetic energies will take into account the
communicating bags. For each communicating volume for which pressure is lower than
in current volume, a mass and energy flow is computed with same equations for vent
holes, the external pressure is just replaced by the pressure of communicating
volume:(1)
with,(2)
(3)
(4)
(5)
These mass and energy fluxes are removed from current volume and added to
communicating volume at the next cycle.
Inflator, Vent Hole, Initial Conditions
Inflator, atmospheric vent holes and initial conditions are identical to
/MONVOL/AIRBAG1 type monitored volume.
Specific Input
The specific input for this type is:
is viscosity factor
is external pressure
is relative vent deflation
pressure
Avent is vent area () or discharge factor
()
Tstart is time to deflate vent hole
Initial gas and injected gas defined with /MAT/GAS.
Inject properties defined with /PROP/INJECT1 or
/PROP/INJECT2.
fct_IDM is injected mass
curve (or mass rate)
FscaleM is scale factor
for injected mass curve (or mass rate)
fct_IDT is injected
temperature curve
FscaleT is scale factor
for injected temperature curve
sens_ID is sensor number to start injection
Nvent is number of vent hole
Nbag is the number of communicating volume
For each communicating volume (1 to Nbag):
bag_ID is the identification of communicating
volume
defines the communication area
is the relative communication
deflation pressure
Acom is the communication
area () or discharge factor ()
Tcom is the time to
deflate communication area
In volume j input, the data for communication with volume k
concerns only the flow from j to k. The data
concerning the flow from k to j is defined in
volume k input.