Virtual design of a machine tools ball-screw feed drive.
Parpala, Radu ; Predincea, Nicolae
Abstract: Today machine tools manufacturers can no longer afford to
consume time and money building and testing real prototypes of the
machine tools model, instead they use virtual prototypes. This paper is
focused on the virtual prototyping of a machine tools feed drive system.
In the virtual prototype approach engineers are able to simulate the
static, dynamic and kinematic behavior of the model before they build
the real machine. The design model can be further improved in order to
satisfy the required conditions before being produced.
Key words: Virtual machine tools, feed drive, simulation.
1. INTRODUCTION
In the virtual prototype approach it is possible to simulate the
kinematic, static and dynamic behavior of the machine tools including
all aspects of real life exploitation. Using different software packets
one is able to simulate even the cutting process. This complex design
concept was enabled by the use of high performance computer technology.
This paper presents the design and dynamic analyses of a ball-screw
feed drive, this mechanism are used to realize translational movement of
machine axes and play an essential role in machine tools performance.
Because of the impact that feed drives imply over the finite piece
quality the design demands are very high so accurate analyses must be
performed in order to assure a very good behavior of the whole machine
tools. (Altintas et al., 2005)
2. VIRTUAL PROTOTYPING
Because the fact that now days machine tools are very complex
mecatronical system is essential to ensure that all design steeps are
evaluated and simulated in order to obtain a physical prototype of the
machine tools that will meets the requirements (Weck, 2001).
2.1 Computer aided design
One of the first steps in virtual prototyping is building the CAD
model. The 3D model of the feed drive must be designed in order to be
accepted as input by various software suits that will be used for
further analyses. Because it's hard to find an integrated
environment in which to perform all analyses engineers must take into
consideration software's compatibilities.
The 3D model of the feed drive was designed by using the CATIA V5
CAD software mainly because of it's good integration with the ANSYS software which was used for statically and dynamical FEM analyses. All
3D part where fully parameterized in order to optimize needed parameters
in FEM analyzes
A simulation of a manufacturing process was also perform using the
CATIA V5 manufacturing module this was performed prior to the kinematics
simulation in order to correctly consider input parameters as
acceleration and velocities.
[FIGURE 1 OMITTED]
[FIGURE 2 OMITTED]
2.2 Multi body motion simulation
During the initial design phase simplified models are used in order
to analyze the cinematic behavior of the mechanism.
Using motion simulation engineers are not only able to determine
speed and acceleration but also to get forces and moments for all the
part involve in mechanism this way further individual static analyses
can be performed.
For the multi body simulation, the feed drive mechanism consists of
rigid bodies that have mass and inertia moment properties but cannot
deform. The interactions between parts are modeled by using joints
(revolute and translational), flexible connectors (spring-dampers),
contact forces and motion generators.
The kinematic simulation analyzes the position of all the bodies of
the mechanism depending on the time parameter. The movements of one or
more parts are described by a low of motion. By using as input
velocities and forces from the CAM simulation we can determinate inertia
forces and moments. (Gross & Hamann, 2001)
2.3 FEM dynamic analysis
In the dynamic analysis the position of all bodies are determinate
as a result of time dependent forces applied to the mechanism.
The finite element method is used to determinate dynamic
characteristics of the feed drive system, e.g. natural-frequencies and
mode shapes. (Zaeh & Oertli, 2004)
The meshed structural components are connected using spring
elements with corresponding stiffness and damping values.
Load and boundary condition are also needed for FEM analysis, for
machine tools elements loads can be obtained from cutting process
simulation or from multi body motion simulation. (Golz, 1990).
By using ANSYS Workbench one is able to optimize the design process
by changing one or more of the initial parameters; those parameters are
automatically updated into the CATIA 3D CAD model.
By analyzing the calculation result in the post-processing program
the designers can evaluate the machine properties during the design
stage.
3. CONCLUSION
Using a set of dedicated softwares engineers are able to analyze
and optimized all aspects of real life usage of machine tools elements
without spending money on real prototypes this could bring important
time and money savings.
Initiated mainly by the automotive and aircraft industry, the
development of modern software tools for integrated simulation of
products has been enchanted lately. Unfortunate at the moment there are
no integrated software platform for the virtual design and analyze of
the machines tools.
4. REFERENCES
Altintas, Y.; Brecher C.; Weck M. & Witt S. (2005). Virtual
machine tool, Annals of the CIRP, 54/2: 651-669.
Zaeh, M. & Oertli, Th. (2004) Finite Element Modeling of Ball
Screw Feed Drive Systems, Annals of the CIRP, 53/1: 289-292.
Gross, H. & Hamann, J. (2001) Electrical Feed Drives in
Automation. Basics, Computation, Dimensioning. Siemens, Publicis MCD Corporate Publishing, Erlangen and Munich
Weck, M., (2001) Werkzeugmaschinen. Mechatronishce Systeme,
Vorschube, Prozessdiagnose., Springer-Verlag, Berlin, Heidelberg, ISBN 3-540-67614-7
Golz, H.U.,(1990), Analyse, Modellbildung und Optimierung des
Betriebsverhaltens von Kugelgewindetrieben, Universitat Karlsruhe, ISBN
0724-4967
