DE102022206203A1 - Control of a friction clutch in a motor vehicle - Google Patents

Abstract

A method (200) for controlling a hydraulically operated friction clutch (145) in a drive train of a motor vehicle (100) comprises steps of electrically controlling a hydraulic valve (145) for controlling the friction clutch (145) with an actuating signal and a superimposed dither signal; wherein the control signal depends on a desired degree of closure of the friction clutch (145) and the dither signal has a predetermined frequency and a predetermined amplitude; determining a current driving situation of the motor vehicle (100); and controlling the dither signal depending on the specific driving situation.

Description

The present invention relates to the control of a friction clutch in a motor vehicle. In particular, the invention relates to the control of a hydraulically operated friction clutch in a drive train of a motor vehicle.

A motor vehicle includes a drive train with a drive motor, a manual transmission and a drive wheel. The drive motor is preferably designed as an internal combustion engine and the manual transmission includes a controllable friction clutch for interrupting a torque flow when the motor vehicle is at a standstill with the drive motor running or when changing an engaged gear. The controllable friction clutch can be actuated hydraulically, with a degree of closure of the friction clutch depending on a hydraulic pressure. A closing degree of zero corresponds to an open friction clutch; the higher the pressure, the greater the degree of closing can be until the friction clutch is completely closed at a predetermined maximum pressure. For example, while the motor vehicle is starting, the friction clutch can be controlled to assume a medium degree of closure in which it is in slippage, so that only part of the torque provided by the drive motor is transmitted to the drive wheel.

To control the friction clutch, a hydraulic valve is provided, which can be electrically controlled with an actuating signal in order to gradually open or close. The hydraulic valve usually includes an electromagnet with an armature that acts on a hydraulic control piston. In order to prevent the control piston from coming into static friction with a surrounding cylinder (stick-slip effect) and prevent sensitive control of the friction clutch, a dither signal can be superimposed on the control signal, which has a predetermined frequency and amplitude, in order to control the control piston in a to maintain minimal oscillation. The frequency is generally in the audible range above approx. 20 Hz.

US 5,222,417 A proposes to reduce a dither frequency of a hydraulic valve in an automatic transmission depending on a flow rate of hydraulic fluid.

It has been shown that in certain driving situations the dither signal can act on a vehicle body via a surrounding hydraulic system, so that an excitation can be heard. This can be perceived by a person in the area of the motor vehicle as unpleasant or as an indication of an existing defect.

One object underlying the present invention is to provide an improved technique for controlling the friction clutch in such a way that acoustic effects are reduced or prevented. The invention solves this problem by means of the subject matter of the independent claims. Subclaims reflect preferred embodiments.

According to a first aspect of the present invention, a method for controlling a hydraulically actuated friction clutch in a drive train of a motor vehicle comprises steps of electrically controlling a hydraulic valve for controlling the friction clutch with an actuating signal and a superimposed dither signal; wherein the control signal depends on a desired degree of closure of the friction clutch and the dither signal has a predetermined frequency and a predetermined amplitude; determining an existing driving situation of the motor vehicle; and controlling the dither signal depending on the specific driving situation.

The dither signal is preferably chosen in terms of frequency and amplitude so that the control piston is reliably prevented from entering into static friction. The lower the frequency and the larger the amplitude, the safer the precise control of the hydraulic valve can be. Both factors also encourage the stimulation of a surrounding system to emit sound. According to the invention, it was recognized that the acoustic excitation preferably leads to audible noises in predetermined driving states of the motor vehicle. By adjusting the dither signal depending on a detected driving situation, such noises can be specifically reduced without reducing the control ability of the hydraulic valve, and thus the friction clutch, in other driving conditions.

The friction clutch includes a drive side that is coupled to a drive motor and an output side that is coupled to a drive wheel of the motor vehicle. The driving situation can be determined depending on a torque transmitted in the drive train and/or an output-side speed of the friction clutch. The output-side speed is an indication of a driving speed of the motor vehicle, so that in another embodiment the driving situation can also be determined with regard to the torque and the driving speed.

The torque can be determined based on a hydraulic pressure controlled by the hydraulic valve, which acts on the friction clutch or a hydraulic actuator of the friction clutch. In addition, an input speed can be set the friction clutch must be taken into account. The torque can be determined, for example, using a characteristic map.

The frequency of the dither signal is preferably increased during a detected predetermined driving situation. For example, the frequency can usually be approximately 48 Hz and can only be increased to approximately 63 Hz during the predetermined driving situation. This allows the acoustic excitation to be reduced just enough to prevent audible annoyance.

The driving situation further preferably includes starting the motor vehicle. Starting includes the transmission of torque through the friction clutch to set the stationary motor vehicle in motion, with the friction clutch in slippage. Starting is complete as soon as the friction clutch is completely closed. In order to minimize wear on the friction clutch, the friction clutch is usually controlled so that starting takes as short a time as possible, in a practical example less than approximately one second. Starting can be determined easily and safely using parameters that can be determined on the friction clutch, so that the control of the dither signal is advantageously not dependent on external parameters. At the same time, it has been shown that the acoustic excitation in the motor vehicle can be perceived as particularly disturbing when starting off.

Starting can be determined when the transmitted torque is in a first predetermined range and/or the output-side speed is in a second predetermined range. During starting, the torque can in particular be above a first predetermined threshold value, below which the motor vehicle is not set in motion. An upper limit of the torque can correspond to a maximum torque that can be provided by the drive motor. The output-side speed can be above a second predetermined threshold value, which relates to the input-side speed at which the drive motor is idling. In other words, a starting situation can only exist if the drive motor is at a higher speed than its idle speed.

Should the motor vehicle be set in motion from a standstill without the drive motor leaving its idle speed and/or without a sufficiently large torque being transmitted through the friction clutch, no start can be determined and the change in the dither frequency can be omitted. Such a process can occur, for example, if the motor vehicle is on a sloping surface and all brakes are released.

The amplitude of the dither signal is further preferably adjusted depending on the frequency. If the frequency is increased, the amplitude can also be increased in order to prevent the stick-slip effect with sufficient security. A relationship between frequency and amplitude can be predetermined, for example by means of a corresponding map. In a further embodiment of the present invention, the amplitude can also be controlled in reverse of the process described above and the frequency can be adjusted accordingly.

The dither signal can be switched off if a gradient of the control signal exceeds a predetermined threshold value. The control signal usually relates to an electrical current that flows through an electromagnetic element of the hydraulic valve. If this current changes faster than predetermined, it can be assumed that there is no driving situation that requires the dither signal to be adjusted. The dither signal can be switched on again when the gradient falls below another predetermined threshold value. Switching off can be done, for example, by setting the amplitude and/or frequency of the dither signal to zero.

According to a further aspect of the present invention, a control device for controlling a hydraulically operated friction clutch in a drive train of a motor vehicle is set up to control an electric hydraulic valve for controlling the friction clutch with an actuating signal and a superimposed dither signal; wherein the control signal depends on a desired degree of closure of the friction clutch and the dither signal has a predetermined frequency and a predetermined amplitude; and further to determine a driving situation of the motor vehicle; and to control the dither signal depending on the specific driving situation.

The control device is preferably designed electronically and can be set up to partially or completely carry out a method described herein. For this purpose, the control device can comprise a programmable microcomputer or a microcontroller and the method can be in the form of a computer program product with program code means. The computer program product can also be stored on a computer-readable data carrier. The control device can also include a discrete circuit or an integrated circuit that implements the method in the manner of a switching network or Rear derailleur executes. Features or advantages of the method can be transferred to the control device or vice versa.

According to yet another aspect of the present invention, a hydraulic control for a friction clutch in a drive train of a motor vehicle comprises a control device described herein and a hydraulic valve for controlling the friction clutch. Furthermore, the hydraulic control may include a source and/or a sink for a hydraulic fluid. The source may be configured to control the pressure of the hydraulic fluid to a predetermined value. The hydraulic system can also be provided for controlling yet another process, which can be operatively connected to the function of the friction clutch.

According to yet another aspect of the present invention, a transmission arrangement for a drive train of a motor vehicle includes an integrated friction clutch and a hydraulic control described herein.

The friction clutch can be designed as a starting element integrated into the transmission, which is preferably opened to interrupt a flow of torque through the transmission and closed to enable the flow. A separate device for separating the transmission from a drive motor, for example a hydrodynamic converter or a dedicated input-side friction clutch, can be omitted. The transmission can comprise an epicyclic transmission, in particular a planetary transmission, wherein the friction clutch can be designed to brake an element of the epicyclic transmission relative to the motor vehicle in order to allow the torque flow between two further elements of the epicyclic transmission. In this sense, the friction clutch can also be referred to as a brake or friction brake.

The integrated starting element can also be involved in a switching process of the transmission. The transmission can include several stages of epicyclic transmissions that can be activated or coupled to one another using clutches and/or brakes. By controlling the clutches or brakes, different gear levels can be selected in the transmission. The integrated starting element can be opened or closed in different gear stages. The transmission is preferably set up for use on an internal combustion engine. The transmission can be designed to be integrated with an electric drive machine, which can act on the input side or the output side of the friction clutch. A ratio of torques introduced by the electric machine and another drive machine onto an output shaft can be controllable.

According to yet another aspect of the present invention, a motor vehicle includes a transmission assembly described herein. The motor vehicle can in particular include a passenger car, a truck or a bus. More preferably, the motor vehicle is designed as a hybrid vehicle and includes a first drive machine in the form of an internal combustion engine and an electric second drive machine.

• 1 ein Kraftfahrzeug; und
• 2 ein Ablaufdiagramm eines Verfahrens

darstellt.The invention will now be described in more detail with reference to the accompanying figures, in which:

• 1 a motor vehicle; and
• 2 a flowchart of a procedure

represents.

1 shows a motor vehicle 100 with a drive train 105. The drive train includes a drive motor 110, a transmission 115 and a drive wheel 120. The drive motor 110 is preferably designed as an internal combustion engine, in particular as a piston engine. The transmission 115 is set up to engage one of several predetermined gear ratios in order to realize a predetermined reduction ratio between an input side connected to the drive motor 110 and an output side connected to the drive wheel 120. Optionally, the transmission 115 is coupled or integrated with an electric machine 122, which can be used in combination or as an alternative to the drive machine 110 to drive the motor vehicle 100.

The transmission 115 is coupled to a friction clutch 125, which is designed to establish or interrupt a transmission of torque between the drive motor 110 and the drive wheel 120. The friction clutch 125 is preferably included in the transmission 115 or is designed to be integrated with it.

A hydraulic control 130 is provided to control the friction clutch 125, and preferably also one or more other functions of the transmission 115. The controller 130 includes a source 135 for a pressurized hydraulic fluid, a sink 140 for fluid, a hydraulic valve 145 and a control device 150. In a preferred embodiment, the controller 130 is designed to be integrated with the transmission 115.

The source 135 typically includes a pump driven by the drive motor 110, an electric ment of the gearbox 115 or a dedicated pump motor can be driven. Hydraulic pressure of the fluid provided by source 135 may be controllable by controller 150 or another device. For this purpose, the pump itself, a pump drive or a hydraulic valve for pressure control can be appropriately controlled. The sink 140 is usually designed as a tank or trough and the source 135 is usually supplied with hydraulic fluid from the sink 140.

The hydraulic valve 145 is shown as an example as a 3/2-way valve that is connected to the source 135, the sink 140 and the friction clutch 125. The friction clutch 125 includes a hydraulic actuator to close the friction clutch 125 when a hydraulic pressure is high and open when it is low. A reverse connection can be implemented in a corresponding manner. The hydraulic valve 145 can be electrically controlled between two positions using an integrated electromagnet. In a first position that it in 1 assumes, a flow of fluid from the source 135 to the friction clutch 125 can be enabled, and in a second position a flow of fluid from the friction clutch 125 to the sink 140.

The control device 150 is set up to control the friction clutch 125 and preferably also at least one further function of the transmission 115, in particular the engagement or disengagement of a predetermined gear stage. To control the friction clutch 125, the control device 150 provides an electrical signal, which is preferably formed from an actuating signal and a superimposed dither signal. The control signal is essentially formed by a direct current that can flow through the electromagnet of the hydraulic valve 145 in order to control it into a predetermined position against the force of an elastic element. A desired degree of opening of the hydraulic valve 145 can be controlled by selecting an appropriate electric current using the control signal.

The dither signal preferably comprises an alternating current in a predetermined shape, for example a square wave or sinusoidal shape, with a predetermined amplitude and a predetermined frequency. The amplitude preferably corresponds to a current intensity caused by the electromagnet. The frequency can be set within a predetermined range. For this purpose, a reference frequency, which is in the range of a few kHz, can be divided appropriately using an adjustable divider. A common frequency of the dither signal can be in the range of approximately 50 Hz. The amplitude of the dither signal can be determined depending on the selected frequency, for example using a table or a map. A connection is preferably in the same direction, so that an increased frequency causes an increased amplitude. The frequency and amplitude of the dither signal usually act in opposite directions on the hydraulic valve 145: a reduced frequency causes increased movement of a hydraulic control piston and at the same time increased acoustic excitation of a surrounding system, while a reduced amplitude causes reduced movement of the control piston and reduced excitation.

It is proposed to control the dither signal depending on a driving situation of the motor vehicle 100. For this purpose, the control device 150 can determine the driving situation in particular depending on a torque that is transmitted via the friction clutch 125 and a speed on the output side of the friction clutch coupled to the drive wheel 120. To determine the speed, a sensor 155 can be provided; alternatively, the speed can be determined based on a driving speed of the motor vehicle 100, which can be determined using another control device.

In particular, it is proposed to adapt the dither signal when the motor vehicle 100 is in a predetermined driving situation, which more preferably relates to starting the motor vehicle 100. In order to reduce acoustic excitation in the motor vehicle 100 due to the dither signal, its frequency can then be increased from a first predetermined value to a second predetermined value, for example from below approximately 50 Hz to above approximately 60 Hz. At the same time, the amplitude of the dither signal be raised in a predetermined manner. If the predetermined driving situation no longer exists, the frequency can be reduced again to the first value. The amplitude can be reduced accordingly.

2 shows a flowchart of a method 200 for controlling the friction clutch 125. The method 200 is preferably implemented by means of the control device 150 on board the motor vehicle 100. In a step 205, an output-side speed of the friction clutch 125 can be determined, preferably by means of the sensor 155 or on the basis of a signal representing the driving speed of the motor vehicle 105.

In a step 210, a torque transmitted via the friction clutch 125 can be determined. The transmitted torque can be determined based on an input speed and a degree of closure of the friction clutch 125 become. The input speed can be determined using another sensor or based on a speed of the drive motor 110. The speed of the drive motor 110 can be determined using another device. A relationship between a speed and a torque provided by the drive motor 110 is generally predetermined by its design and can be taken into account when determining the torque transmitted via the friction clutch 125. The degree of closing can be determined on the basis of a hydraulic pressure at the friction clutch 125, alternatively by means of yet another sensor or on the basis of a control of the hydraulic valve 145 and a system pressure provided by the source 135.

Based on the output-side speed at the friction clutch 125 and the torque transmitted via the friction clutch 125, a driving situation of the motor vehicle 100 can be determined in a step 215. The speed and/or the torque can be compared with an assigned lower and/or an assigned upper threshold value in order to allow the existence of a predetermined driving situation. The driving situation may include starting the motor vehicle 100. The torque can exceed a first predetermined threshold value and the speed can exceed a second predetermined threshold value.

In a step 220, a control signal for the hydraulic valve 145 can be determined. The control signal can be determined depending on a requirement for a torque provided on the drive wheel 120 and/or a torque provided by the drive motor 110. The request can be provided by a driver of the motor vehicle 100 and a speed of the drive motor 110 can also be controlled based on the request.

In a step 225 it can be determined whether a gradient of the control signal exceeds a predetermined threshold value. The control signal may relate to an electrical current flowing through the hydraulic valve 145. The gradient can be specified in A/s. The threshold value can be in a range of approximately 6 A/s. If the gradient exceeds the threshold value, the dither signal can be switched off in a step 230. For this purpose, its amplitude can in particular be set to zero. The frequency can be set to a predetermined maximum value.

Otherwise, in step 230, a frequency of the dither signal can be determined. The frequency can usually assume a first predetermined value and a second predetermined value when the motor vehicle is in a predetermined driving situation. The second value is preferably higher than the first value, more preferably by approximately 30%. In addition, an amplitude of the dither signal can be determined based on the specific frequency. In the predetermined driving situation, the amplitude can also be increased, in one embodiment to a comparable extent to the frequency.

In a step 235, the hydraulic valve 145 can be controlled with a superposition of the control signal and the dither signal. Electrical currents determined by the individual signals can be added together and the sum of the currents can flow through an electrical actuator of the hydraulic valve 145, for example an electromagnet.

The steps of method 200 can be run through cyclically, preferably several times per second. It should be noted that the determination of the control signal can also take place independently of the steps of the method 200.

Reference symbols

100

motor vehicle

105

Drivetrain

110

drive motor

115

transmission

120

drive wheel

122

electric machine

125

Friction clutch

130

hydraulic control

135

source

140

sink

145

Hydraulic valve

150

Control device

155

sensor

200

Proceedings

205

Detect speed

210

Capture torque

215

Determine driving situation

220

Determine the control signal

225

Gradient of the control signal > threshold value?

230

Determine the frequency and amplitude of the dither signal

235

Control hydraulic valve

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 5222417 A [0004]

Claims (11)

Method (200) for controlling a hydraulically operated friction clutch (145) in a drive train of a motor vehicle (100), the method (200) comprising the following steps: electrically controlling (235) a hydraulic valve (145) for controlling the friction clutch (145). a control signal and a superimposed dither signal; wherein the control signal depends on a desired degree of closure of the friction clutch (145) and the dither signal has a predetermined frequency and a predetermined amplitude; Determining (215) a current driving situation of the motor vehicle (100); and controlling (230) the dither signal depending on the specific driving situation. Procedure (200) according to Claim 1 , wherein the driving situation is determined (215) depending on a torque transmitted in the drive train and / or an output-side speed of the friction clutch (145). Procedure (200) according to Claim 1 or 2 , wherein the frequency of the dither signal is increased (215) during a predetermined driving situation. Method (200) according to one of the preceding claims, wherein the driving situation includes starting the motor vehicle (100). Procedure (200) according to Claim 2 and 4 , wherein starting is determined when the transmitted torque is in a first predetermined range and / or the output-side speed of the friction clutch (145) is in a second predetermined range. Method (200) according to one of the preceding claims, wherein the amplitude of the dither signal is adjusted (230) as a function of the frequency. Method (200) according to one of the preceding claims, wherein the dither signal is switched off (225) when a gradient of the control signal exceeds a predetermined threshold value. Control device (150) for controlling a hydraulically operated friction clutch (145) in a drive train of a motor vehicle (100), the control device being designed to control an electric hydraulic valve (145) for controlling the friction clutch (145) with an actuating signal and a superimposed dither signal ; wherein the control signal depends on a desired degree of closure of the friction clutch (145) and the dither signal has a predetermined frequency and a predetermined amplitude; to determine a driving situation of the motor vehicle (100); and to control the dither signal depending on the specific driving situation. Hydraulic control (130) for a friction clutch (145) in a drive train of a motor vehicle (100), comprising a control device according to Claim 8 and a hydraulic valve (145) for controlling the friction clutch (145). Transmission arrangement (115) for a drive train of a motor vehicle (100), comprising an integrated friction clutch (145) and a hydraulic control (130). Claim 9 . Motor vehicle (100), comprising a transmission arrangement (115). Claim 10 .

Images