WO2012000481A2

WO2012000481A2 - Method for carrying out volume compensation in a dual clutch gearbox with hydrostatic engagement system

Info

Publication number: WO2012000481A2
Application number: PCT/DE2011/001272
Authority: WO
Inventors: Carsten Mohr; Jörg LÖSCH
Original assignee: Schaeffler Technologies Gmbh & Co. Kg
Priority date: 2010-06-29
Filing date: 2011-06-20
Publication date: 2012-01-05
Also published as: WO2012000481A3; DE102011105027A1

Abstract

The invention relates to a method for reducing the vibrations occurring in a hydraulic system (1) and to an arrangement for carrying out the method, in which method the occurring vibrations are determined, and the occurring vibrations are superimposed through targeted actuation of certain components (5) of the hydraulic system, such that the occurring externally excited vibrations are reduced.

Description

Method for carrying out a volume compensation on a dual-clutch transmission with hydrostatic engagement system

The invention relates to a method and a system for reducing the in one

Hydraulic system for actuating a double clutch occurring vibrations.

In hydraulic systems, such as clutch disengagement systems with hydraulic transmission path, it comes due to different mechanisms (for example, slip-stick effects between clutch lining and pressure plate, axial / torsional vibrations of the pressure plate, disc spring-tongued stroke) to excite the hydraulic path in the hydraulic line. Such a hydraulic circuit is an oscillatory system in which the oil column or a greater or lesser portion of it can oscillate as a mass against system rigidity (e.g., pipe rigidity). Therefore, such hydraulic lines have unavoidable line or system resonances which, for example, in clutch release systems, are frequently accompanied by vibration and / or acoustic problems such as, for example, Eek-Noise, Groa-Groa-Noise, pedal vibrations, clutch clatter etc. lead. The vibration excitation of peripheral components or assemblies can cause problems through such pressure pulsations to functionality loss.

In order to reduce the above-mentioned pressure pulsations due to system resonances, different approaches are often followed.

In some cases, it is possible to at least mitigate the problem by changing the line geometries (diameter, length of the line, etc.) by attempting to remove as much as possible the line resonance of resonance frequencies of other elements of the transmission path. In many cases, however, even this limited effective approach is unacceptable, as it otherwise unwanted changes system properties and often interferes with the same-part principle of clutch or engine families.

A targeted design of hydraulic reservoir containers such as in WO

03/093680 for active suspension systems also can not provide a remedy for resonance-induced pressure swing overshoots. The reason for this is that the frequency excitation to be combated and thus the associated wavelength of the pressure fluctuation tion directly related to the geometric dimensions of the coupled fluid volume of the reservoir container, which would lead to unacceptably large component dimensions at low frequencies.

A damping device for hydraulic lines as described in KR 1020030006113 A, works on the principle of pressure calming in discontinuous cross-sectional widening. Although this allows quite broadband damping characteristics to be generated, the center of gravity of the resonance frequency to be controlled is determined by the chamber length. Correspondingly, the above-mentioned relationship between the wavelength of the pressure oscillation to be reduced and the geometrical dimensions also results here, which would lead to unrealistically large component dimensions, especially at low frequencies. An application of this method therefore only makes sense in the frequency range f <2000 Hz. Furthermore, the achievable damping depends directly on the "cross-sectional jump" of the diameter expansion, so that a reduction of the pressure pulsations is limited.

A damper for hydraulic lines as described in WO 2004/015290, is also able to combat resonant pressure peaks by using two different membranes (tuned for selected frequency ranges). Due to the principle of pure material damping limited its effectiveness for the above problem to an insufficiently low level. Thus, the pressure pulsations can only be reduced in the order in which these elastic membranes are able to absorb work.

Against this background, the invention is based on the object, the occurrence of

To prevent or reduce pressure pulsations in hydraulic lines.

The solution of this problem arises from the features of the main claim, while advantageous embodiments and further developments of the invention are the dependent claims can be removed.

The object is achieved in the method for reducing the vibrations occurring in a hydraulic system by the vibrations occurring are determined and by targeted control of certain components of the hydraulic system, the occurring Vibrations are superimposed, so that the vibrations occurring are reduced.

Preferably, this should already be achieved on the frequency side in the region of the first oscillation modes / first natural frequencies of the hydraulic system, wherein in particular these low natural frequencies have large pressure fluctuation ampoules, which usually also entails hidden consequential problems.

A preferred embodiment of the method is characterized in that the targeted control is carried out by an active control.

A preferred embodiment of the method is characterized in that the active control is performed by a control system comprising at least one actuator, at least one sensor, and a controlled system.

A further preferred embodiment of the method is characterized in that the vibrations occurring are detected by a sensor in the hydraulic system. Hydraulic systems usually already have pressure sensors for determining the pressure present on the hydraulic system. This pressure sensor can be used for example for detecting the vibrations present in the system and serve as a sensor of the control system.

A further preferred embodiment of the method is characterized in that the actuator of the control system is controlled so that it generates a vibration. Hydraulic systems usually have hydraulic valves that can be used as actuators for a control system. Here, the existing hydraulic valve can be controlled by the control system, for example, so that an oscillation is generated, which leads by superposition with the pressure to be combated pressure pulsation to a pressure swing reduction in the hydraulic system.

A further embodiment of the method is characterized in that the control system has a unit which detects the data of the sensor. The control system further includes an active phase rotation unit and a unit for outputting the data to the actuator. In this case, the unit for collecting the data is furthermore preferably also suitable for filtering the acquired data. The unit for active phase Rotation is preferably suitable to perform a time correction. The output unit is preferably designed such that an amplification of the output data can take place.

A further embodiment of the method is characterized in that in the event of a failure of the control system, that is to say as an emergency-running characteristic (fail-safe), no activation of the actuator by the control system takes place.

Furthermore, a system for reducing the vibrations occurring in a hydraulic system, which is suitable for carrying out a method described above, is provided. In this case, the system has at least one actuator, at least one sensor and a controlled system

A preferred embodiment of the system is characterized in that the actuator is formed by a hydraulic valve of the hydraulic system. Depending on the specific individual case, it may happen that the stroke of the existing hydraulic valve of the hydraulic system is insufficient and / or its placement in the hydraulic system is unfavorable to counteract in the sense of an actuator low frequencies. In these cases, however, another suitable valve can be selected as a rule from a standard program, which can be used as an actuator in addition to a suitable position in the hydraulic system.

A further preferred embodiment of the system is characterized in that the sensor is formed by a pressure sensor of the system. Also, the present in the hydraulic system pressure sensor similar to the hydraulic valve sitting in an inappropriate position or not be present from the outset. In these cases, a suitable sensor, which can also be selected from the standard program as a rule, must be used as a sensor for the control system in a suitable position in the hydraulic system.

In hydraulic systems, the existing hydraulic line can be used as a controlled system.

Thus, hydraulic systems have the advantage that the already existing components can be used to provide an active control system for reducing vibration. build up. As a result, no or only a few new components are needed, resulting in a cost-effective and space-saving solution for actively reducing the vibrations in hydraulic systems.

By the method described above and the system for reducing the vibrations occurring in a hydraulic system, a reduction or cancellation of the disturbing pressure pulsations is achieved by an active vibration compensation, in which a controlled superposition of antiphase pressure oscillations is performed.

Further advantages, features and details of the invention will become apparent from the following description in which, with reference to the drawings, an embodiment is described in detail.

It shows:

1 shows schematically the structure of a system according to the invention for reducing the vibrations occurring in a hydraulic system.

FIG. 1 schematically shows the structure of a system according to the invention for reducing the vibrations occurring in a hydraulic system 1. In this case, the hydraulic system 1 has a fluid-sounding component 2, which is connected to a hydraulic line 3. The hydraulic line 3 has a pressure sensor 4 and a hydraulic valve 5. To carry out the method described above for reducing the vibrations occurring in a hydraulic system, the hydraulic system 1 is equipped with a control system 6. The control system 6 is connected on the input side to the pressure sensor 4 of the hydraulic line 3. For the detection and filtering of the data output by the pressure sensor 4, the control system 6 has a detection unit 7. The acquired and filtered data from the detection unit 7 are transferred to a phase rotation unit 8, which performs an active phase rotation and time correction of the transferred data. To output the data and to control the hydraulic valve 5 of the hydraulic system 1, the control system 6 has an output unit 9. The output unit 9 amplifies the data from the phase rotation unit 8 and transfers the data to the hydraulic valve 5. The running between the pressure sensor 4 and the pressure valve 5 hydraulic line 3 forms the control path for the control system. 6

List of Reference Numerals Hydraulic system

vibrating component

hydraulic line

pressure sensor

hydraulic valve

control system

acquisition unit

Phase rotating unit

output unit

Claims

claims

1. A method for reducing the vibrations occurring in a hydraulic system, in which the vibrations occurring are determined and wherein the vibrations occurring are superimposed by targeted AnSteuerung certain components of the hydraulic system, so that the vibrations occurring are reduced.

2. The method of claim 1, wherein the targeted activation is carried out by an active control.

3. The method of claim 2, wherein the active control is performed by a control system comprising at least one actuator, at least one sensor, and a controlled system.

4. The method according to any one of the preceding claims, wherein the vibrations occurring are detected by a sensor in the hydraulic system.

5. The method according to any one of claims 3 to 4, wherein the actuator is driven so that it generates a vibration.

6. The method of claim 3, wherein the control system comprises a unit that detects the data of the sensor, an active phase rotation unit, and a unit for outputting the data to the actuator.

7. The method according to any one of claims 3 to 6, wherein in case of failure of the control system no activation of the actuator by the control system takes place.

8. System for carrying out a method for reducing the vibrations occurring in a hydraulic system according to one of the preceding claims, wherein the system comprises at least one actuator, at least one sensor and a controlled system.

9. System according to claim 8, wherein the actuator is formed by a hydraulic valve of the hydraulic system.

10. System according to any one of claims 8 or 9, wherein the sensor is formed by a pressure sensor of the hydraulic system.