Input Files
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Introduction
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Introduction
A common application of explicit analysis is the simulation of drop tests for consumer electronics.
This example is of a simplified representation of a Cell Phone dropped from 1.5m onto a rigid plane.
Options and Keywords Used
Keyword documentation may be found in the reference guide available from
Radioss OpenRadioss User Documentation
4-node shell (Q4) and 3-node shell (T3), Fabric Law for Elastic Orthotropic Shells
One-chambered airbag with hybrid input of injected gas (/MONVOL/AIRBAG1)
Sensor (/SENSOR2nd Order Tetrahedral Elements (/TETRA10)
Rigid wall (/RWALL) (Rigid cylinder and Rigid parallelogram)Rigid body (/RBODYPlane)
Initial velocity (/INIVEL)
Rotational and translational velocity on a group of nodes in a given coordinate system (/INIVEL/AXIS)
Translational material velocity (/INIVEL/TRA)
Gravity load on a node group (/GRAV)
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Figure 3. Trajectory of the Soccer Ball of Santini's Header
Model Description
During the European football (Soccer) Cup final in 1976 (Bayern of Munich versus Saint Etienne), a shot from Bathenay and a header from Santini rebounded off the square cross-section frame of the German team's goal. The purpose of this demonstration is to determine the influence of a square or a round cross-section bar for both cases.
The main differences between both shots are the incidence, the velocity and the impact point of the ball on the bar (its vertical value).
The material used for the ball follows a linear elastic orthotropic law (/MAT/LAW19) with the following characteristics:
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Units: mm, ms, g, N, MPa
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Model Method
The ball is modeled using 60 3-node shells and 1420 4-node shells. The shell element formulations are set by default. For display purposes, the goal post and the ground are also modeled with 4-node shell elements, but their mesh will not be used for the computation. Instead, rigid walls are defined for the goal post and the ground.
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OpenRadioss Options Used
A rigid body is created, containing all the nodes of the ball. It is deactivated just before impact on the bar.
Rotational and translational initial velocities are applied to the rigid body’s main node using /INIVEL/AXIS. The velocities are defined in a local coordinate system using /FRAME/FIX.
The goal posts are modeled with a cylindrical rigid wall for the round post and two rigid parallelograms for the square post.
Gravity is taken into account using a gravity load.
The ball is considered as an airbag, which is activated when the rigid body is deactivated.
Multiple Engine files are used. The second Engine file deactivates the ball rigid body using /RBODY/OFF. The time animation output is also increased to every 1 ms, so more details about the ball impacting the goal can be viewed. The third Engine file changes the animation output back to every 12.5 ms.
Results
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Conclusion
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for drop velocity
Gravity load (/GRAV)
Tied Interfaces for components (/INTER/TYPE2)
Model Description
The simplified Cell Phone model is constructed from 130000 solid (Hex and Tetra elements)
The ground plane is represented by a rigid wall
Initial velocity is defined to represent a drop height of 1.5m
The phone case is modeled using /MAT/PLAS_TAB (LAW36) with a plastic stress/strain curve, all other parts are modeled as Elastic (/MAT/LAW1)
Conclusion
OpenRadiossis capable of modelling drop test events on electronic devices, aiding the design process and optimisation of phone and case design.