Based on the well-known quarter car representation of the automobile suspension design problem, pdomnce parameters relating to passenger discomfort, working space and tyre load variability are generated for passive, active and semi-active suspension systems. Active systems of two types having different hardware implications are considered, and linear optimal control theory is used in each case to derive a good set o control law parameters. The semi-active systems studied have control laws based on the fully active systems, but are capable only of dissipating energy, so that where the corresponding active system would be acting as an energy supply, the semi-active system switches off Practically realizable switching dynamics are assumed in the calculations. Results for all the systems, for one road surface roughness and vehicle speed, are generated in a form which allows comparison between systems of diffient types which have equal suspension working space requirements. The wider implications of the results are discussed, and far-reaching conclusions about the relative capabilities and design features of passive, active and semi-active systems are drawn.
Using methods established in earlier work, calculations are carried out to reveal the influence of actuator bandwidth on the performance capabilities of a class of active suspension system for automobiles. The suspension consists of an actuator in series with a spring, the combination being in parallel with a passive damper, and the system is modelled as a single wheel station traversing a random road. The results indicate that a system with a 3 Hz bandwidth actuator and variable damping will have excellent ride performance qualities over a wide range of road roughness conditions. Since such a system can be expected to be easily adaptable to the running conditions, to provide good static and dynamic attitude control, to be capable of contributing to good steering control responses and to be inexpensive in terms of capital and energy consumption costs compared with most of the active systems which have previously been discussed, it issuggested that it is aprime -. candidate for further st;dy and practical developmint.
In this paper, the ball screw feed drive system is
simulated and it?s frequency response is studied. Various
parameters effect on the dynamic behavior of the ball
screw system have been investigated. Ball screw feed drive
system is used in high speed machine tools due to their
high efficiency. Estimation of the dynamic behavior of ball
screw feed drive mechanism is very important in the
industrial processes in order to get high demand for
precision and accuracy in machine tools. Optimizing the
drive operation can provide significant cost savings. A four
degree of freedom system, lumped parameter model is
used for modeling a single axis ball screw feed drive
system and use it to study and analyze vibrations in this
model. The mathematical modeling provides an important
information about frequency response when applying
different levels of table mass, stiffness of the nut, axial
stiffness of the ball screw shaft and torsional stiffness of
the ball screw on the system, to describe the effects of these
parameters on the system dynamic behavior. The study of
dynamic response of ball screw feed drive system provides
a better performance control and better understanding of
ball screw dynamics.
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