Adjustment and damping device

Power plants – Pressure fluid source and motor – Utilizing a mixture – suspension – semisolid or...

Reexamination Certificate

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C091S459000

Reexamination Certificate

active

06463736

ABSTRACT:

The invention relates to a controllable actuating and damping device comprising at least a pressure chamber filled with a hydraulic fluid, a reserve of fluid, a pump which connects the pressure chamber and the reserve of fluid, a compensating volume and a return passage with a pass-through valve in which an electrorheological fluid or magnetorheological fluid is used as the hydraulic fluid, exerting a pressure on a piston projecting into the pressure chamber or on a diaphragm, the intensity of which can be controlled by means of the passthrough valve.
The invention furthermore relates to an energy converter for converting mechanical vibration energy into electrical energy.
The invention is directed, in particular, towards an electrorheological actuator for improving the control of couplings and gearboxes, primarily viscous couplings or multi-plate clutches, especially for use in motor-vehicle construction.
The prior art has disclosed various forms of coupling which operate using an electrorheological fluid as hydraulic fluid (see, for example, DE 39 22 930 and GB 2 218 758). In electrorheological couplings, the electrorheological fluid (referred to below as ERF for short) is used directly for torque transmission between the surfaces in motion relative to one another, e.g. the clutch discs. A major disadvantage of such a coupling construction is that very large surfaces are required to transmit high torques since the available electrorheological fluids can transmit only about 10 kPa of shear stress at the maximum. For a simple disc clutch, which is intended to transmit a torque of only about 20 Nm for example, a force-transmitting area of at least 305 cm
2
would therefore be necessary. However, this large area requires a large overall volume of the clutch. Another disadvantage is the pronounced heating of the electrorheological fluid. This results in a further increase in the energy required to control the clutch. For this reason, couplings based on electrorheological fluids have hitherto only been developed as prototypes for the transmission of low torques.
Said type of clutch is described specifically for use in motor-vehicle construction, for decoupling auxiliary units, e.g. for the generator or fan. The very high differential speeds may occur in the region of the clutch discs due to the changes in engine speed, a high torque occurs even in the inactive state of the electrorheological fluid, due to its basic viscosity. This limits the possibilities for controlling the clutch.
One object of the invention is to develop an improved actuator for couplings based on electroviscous fluids as hydraulic fluid which does not have the abovementioned disadvantages. In particular, it should be possible to provide an actuator which allows continuous adjustment, e.g. of multi-plate clutches.
Actuators using hydraulic fluids are known from motor-vehicle construction. The so-called ELDRO devices may be mentioned here by way of example (EMG, AEG). With this type of actuator, a piston with an actuating rod is moved between two end positions by means of the pressure of a hydraulic fluid in a pressure chamber connected to a pump. In this arrangement, the pressure in the pressure chamber is maintained by a hydraulic pump. An actuator of this kind has the disadvantage that the piston can only be moved into two positions and that continuous adjustment of the piston travel is possible only with high outlay on construction.
It is a further object of the invention to develop an active damper which is capable of active anti-phase compensation of shocks or other mechanical vibrations.
Shock absorbers based on the action of electrorheological fluids are described in many places in the patent literature. One example that may be referred to is U.S. Pat. No. 5,259,487. In the case of the shock absorber described there, the electrorheological fluid is forced through an electrode gap by means of a piston. The pressure drop and hence the damper force is infinitely variable from a low to a maximum value using the electrorheological effect in the electrode gap.
In principle, it is possible by means of electrorheological shock absorbers to obtain semi-active suspensions whose damping can be varied within short time periods. In some cases, the switching time is less than 10 msec. Active influencing of the shock-absorber piston is not possible with the shock absorber mentioned.
The prior art has also disclosed passive engine mounts based on electrorheological fluids as the hydraulic fluid. See, for example, publication SAE 931324 of the Proceedings of the 1993 Noise and Vibration Conference, Travers City, Mich., 10th to 13th May 1993.
The mount mentioned is an adaptive mount which can be switched backwards and forwards between various states. These so-called ERF mounts do not have any discernible technical advantage over the conventional hydraulic mounts known from the prior art. On the contrary, the active mounts currently required for use as engine mounts are those which can, for example, completely compensate for engine vibrations, such as the second harmonic of the engine speed in the case of four-cylinder internal combustion engines.
An engine mount that operates in an optimum manner must furthermore fulfil at least two functions. The natural frequencies of the engine/body caused by load changes or excitation by the roadway must be damped in an optimum manner in a frequency range typically of about 12 Hz. Engine vibrations in the higher-frequency range of about 20 to 100 Hz must be isolated in an optimum manner from the chassis and, in particular, the passenger cell. Particularly in the case of diesel engines, there is a requirement that vibrations in the idling range (diesel clatter) at about 30 Hz should be suppressed.
It is another object of the invention to use the damping property of the actuator in such a way that it is possible with a fundamentally identical construction not only to accept and eliminate the mechanical vibrations, e.g. in the case of use as a passive shock absorber, but, where required, to convert them into electrical energy.
The object is achieved according to the invention by a controllable actuating and damping device which is the subject matter of the invention and comprises at least a pressure chamber with a piston, or a diaphragm, a reserve of fluid containing a hydraulic fluid, a pump which connects the pressure chamber and the reserve of fluid, a compensating volume, a return passage with a valve, and an enclosing housing, and is characterized in that the hydraulic fluid is an electrorheological fluid or magnetorheological fluid which is pumped by means of the pump, flows from the reserve of fluid into the pressure chamber and, from there, flows via the valve back into the reserve of fluid or else in the opposite direction, in that the pressure of the hydraulic fluid in the pressure chamber acts on the piston or the diaphragm, and in that the valve is embodied as an ERF or MRF valve by means of which the flow of the hydraulic fluid through the return passage is controlled, thereby allowing the pressure of the hydraulic fluid on the piston or diaphragm to be adjusted.
The term electrorheological fluids is intended to indicate dispersions of finely divided hydrophilic particles in hydrophobic, electrically non-conductive oils (generally colloidal suspensions of electrically polarizable, non-conductive particles) which, under the action of an electric field of sufficiently high electric field strength, rapidly and reversibly change their yield strength or their shear modulus, under certain circumstances over several orders of magnitude. In the process, the ERF may change from the low-viscosity, via the plastic, to the solid state of aggregation.
Examples of suitable electrorheological fluids are mentioned in German Offenlegungsschriften (German Published Specifications) DE 35 17 281 A 1, DE 35 36 934 A 1, DE 39 41 232 A 1, DE 40 26 881 A 1, DE 41 31 142 A 1 and DE 41 19 670 A 1.
Both direct-voltage and alternating-voltage fields are used to excite the electrorheological fluids. Th

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