This application is a national stage of International Application No. PCT/EP2010/003191 filed May 26, 2010, the disclosures of which are incorporated herein by reference in entirety, and which claimed priority to German Patent Application No. 10 2009 022 763.6 filed May 27, 2009, the disclosures of which are incorporated herein by reference in entirety.
The invention relates to an active chassis stabilization system including at least one hydraulic actuator, a pump for acting upon the actuator with a hydraulic pressure, a reservoir for receiving hydraulic fluid, and a return line for a fluid flow from the actuator to the reservoir, a check valve being provided in the return line.
Active chassis stabilization systems for roll stabilization of motor vehicles are generally known. They are more particularly able to counter rolling motions of the vehicle body, that is, rotational motions about the longitudinal axis of the vehicle, in order to generate a desired vehicle handling. A desired roll moment may be realized by means of a rotational actuator, for example, which is integrated in a torsion rod of a stabilizer bar, or by means of a linear actuator which is arranged between a stabilizer bar arm and a wheel suspension.
In the event of an external excitation of the vehicle wheels, for example as caused by road damage, the stabilizer bars of conventional passive chassis stabilization systems are deformed and generate a possibly undesirable stabilizer bar moment on the vehicle body. In active chassis stabilization systems, the actuator is deflected/moved passively (i.e. without a pressure build-up) in the case of external, forced wheel motions and thus allows a compensation of the wheel deflection without exerting a stabilizer bar moment upon the vehicle body.
This passive actuator deflection causes a pressure chamber of the actuator to become smaller, which means that hydraulic fluid flows out of the pressure chamber, whereas a different pressure chamber of the actuator increases in size, which means that an inflow of hydraulic fluid is necessary. Preferably, within the scope of the usual system function, one pressure chamber is always connected with the pump line and the other pressure chamber with the reservoir line.
In the event that the pressure chamber associated with the reservoir line becomes larger, a pressure drop below atmospheric pressure is possible since the actuator is required to pull hydraulic fluid from the reservoir through the respective lines and, if required, an electrohydraulic control unit. In particular in the case of rapid actuator movements there is a high probability of a heavy pressure drop. The necessary fluid flow to the actuator is determined here by the pressure gradient between the reservoir and the expanding pressure chamber of the actuator. Since the reservoir is usually a tank under atmospheric pressure, that is, under a pressure of about 1 bar, the pressure in the expanding pressure chamber may drop sharply especially in the case of a rapid actuator movement forced from outside. If the pressure of the hydraulic fluid in the pressure chamber drops below a predetermined value (for example 0.7 bar, depending on the boundary conditions), this results in cavitation phenomena, that is, in a temporary formation of small gas bubbles in the pressure chamber of the actuator which implode again after a short time. This phenomenon of cavitation leads to an undesirable noise nuisance and may also cause damage to the material in the longer run.
To reduce the risk of cavitation, the generic document WO 2007/020052 proposes a chassis stabilization system in which the fluid return flow, at least in sections, also has a minimum pressure, that is, a pressure that is above the reservoir pressure. The minimum pressure is adjusted here by means of a throttle valve connected into the return line.
When the delivery rate of the pump is substantially constant, a largely constant minimum pressure develops upstream of the throttle valve, depending on the opening cross-section of the throttle valve. However, it has meanwhile been found that considerable savings on energy can be realized if the pump operates with a variable delivery rate that is adapted to the demand. But this leads to the undesirable effect that the minimum pressure in the return flow is dependent on the delivery rate of the pump.
It is therefore a feature of the invention to provide an active chassis stabilization system which provides a largely constant return flow pressure for the prevention of cavitation even in the case of a variable hydraulic fluid flow rate.
This feature is achieved by an active chassis stabilization system of the type mentioned at the outset, in which the check valve in the return line blocks the fluid flow from the reservoir to the actuator and allows the fluid flow from the actuator to the reservoir as of a predeterminable return pressure. This passive check valve is a low-cost and reliable component for controlling the fluid flow; it can, in a simple manner, replace the throttle valve provided in the prior art and can therefore keep the return pressure substantially constant even with a variable delivery rate of the pump.
The check valve preferably includes a spring member which urges the check valve into its blocking position. The predeterminable return pressure can thus be set at a desired value in a simple manner by means of a spring stiffness of the spring member.
In a particularly preferred embodiment, an anti-cavitation valve that is connected in parallel with the check valve is provided in the return line, the anti-cavitation valve blocking the fluid flow from the actuator to the reservoir and allowing the fluid flow from the reservoir to the actuator below a predeterminable anti-cavitation pressure. Should the return pressure drop below the reservoir pressure, for example as a result of a forced external movement of a vehicle wheel, this anti-cavitation valve ensures the possibility of pulling hydraulic fluid from the reservoir into the expanding pressure chamber of the actuator.
In an advantageous further development of the invention, the chassis stabilization system comprises a plurality of actuators which can be acted upon with a hydraulic pressure by the pump.
Provision may be made here for one single hydraulic channel, so that exactly one degree of freedom results therefrom for the hydraulic pressure for acting upon the actuators. Alternatively or additionally, a plurality of hydraulic channels may be provided in communication with a plurality of actuators, so that the number of resultant degrees of freedom for the hydraulic pressure corresponds to the number of hydraulic channels.
Further advantageous and expedient configurations of the inventive concept will be apparent from the dependent claims.
Other advantages of this invention will become apparent to those skilled in the art from the following detailed description of the preferred embodiments, when read in light of the accompanying drawings.
As shown in
The actuator 20 is in the form of a cylinder/piston unit 22, a cylinder 24 being connected with the stabilizer bar 18, and a piston 26 that is accommodated for longitudinal displacement in the cylinder 24 being connected with the right-hand semi-trailing arm 14.
In an alternative embodiment, the actuator 20 may be in the form of a rotational actuator rather than in the form of a linear actuator and may be integrated in the stabilizer bar 18.
The actuator 20 is connected with a motor pump unit 30 via hydraulic lines 28, the motor pump unit 30 preferably including a pump 32, a motor 34 for operating the pump 32, a reservoir 36 (cf. also
As an alternative, the actuator 20 may also be connected to a flow controlled pump which exerts a hydraulic pressure on the actuator 20. Such a flow controlled pump may be driven by means of the internal combustion engine, with other types of drive also being possible.
Connected between the motor pump unit 30 and the actuator 20 in
As shown in
As shown in
In the valve position illustrated, the pressure chamber 50 of the actuator 20 is connected with the pump 32 and the pressure chamber 52 of the actuator 20 is connected with the reservoir 36. When a displacement of the piston 26 toward the pressure chamber 52 (downward in
When the piston 26 is displaced toward the pressure chamber 50 (upward in
When the return pressure is suitably selected, it is almost excluded that the hydraulic pressure in the pressure chamber 52 decreases to a cavitation-critical range. It is of particular advantage here that this desired return pressure is kept largely constant by the check valve 42 even in the case of a variable delivery rate of the pump 32.
When the actuator 20 is moved due to an external excitation while the 4/2-way valve 56 connects the pressure chamber 50 with the reservoir 36 and the pressure chamber 52 with the pump 32, the above explanations are applicable analogously, but for opposite piston movements.
In the embodiment according to
The embodiments according to
In accordance with the provisions of the patent statutes, the principle and mode of operation of this invention have been explained and illustrated in its preferred embodiment. However, it must be understood that this invention may be practiced otherwise than as specifically explained and illustrated without departing from its spirit or scope.
Number | Date | Country | Kind |
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102009022763.6 | May 2009 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP10/03191 | 5/26/2010 | WO | 00 | 12/13/2011 |