DE102022206480A1 - Controlling a parking brake for a motor vehicle - Google Patents

Abstract

A parking brake (100) for a motor vehicle (102) comprises a first actuator (108) which can be controlled to bring the parking brake (100) into an engaged or disengaged state; and a second actuator (110) that can be controlled to hold or release the state of the parking brake (100). A method (300) for controlling such a parking brake (100) comprises steps of detecting a request to disengage the parking brake (100) while the parking brake (100) is in the engaged state; controlling the second actuator (110) to maintain the state of the parking brake (100); controlling the first actuator (108) to apply the parking brake (100); determining the status of the parking brake (100); and determining an error if the parking brake (100) is designed.

Description

The present invention relates to controlling a parking brake for a motor vehicle. In particular, the invention relates to ensuring correct control.

A motor vehicle includes a drive train with a drive motor that acts on a drive wheel via an output shaft. In order to keep the motor vehicle at a standstill, a parking brake is provided, which is designed to fix the output shaft relative to the motor vehicle so that the drive wheel cannot rotate. The parking brake usually includes a wheel that can be rotated on the output shaft and has a series of recesses and a locking element that can engage positively in a recess. If the parking brake is engaged, a torque of the output shaft is transmitted directly to the motor vehicle by means of the locking element. If the parking brake is designed, the locking element does not transmit any force to the wheel and the drive wheel can roll or be driven freely.

The parking brake can be engaged or disengaged using a first actuator. For security purposes, a second actuator is provided, which can prevent a change in the status of the parking brake. Actual states of both actuators can be determined and monitored. This can prevent a single error - for example on the first or second actuator - from unintentionally engaging or disengaging the parking brake.

In certain arrangements, for example, due to mechanical wear, the interaction between the actuators can become unreliable, so that the engaged parking brake can be disabled by a single error (single error) by controlling the first actuator accordingly.

US 2021 388 897 A1 describes a method for controlling a manual transmission with a controllable friction element for engaging or disengaging a gear. It is proposed to bring the friction element into an open state and change an engaged reduction ratio in the transmission after an abnormal condition of the manual transmission is determined. The friction element should only be closed again when the abnormal condition no longer exists.

One object underlying the present invention is to provide an improved technology to ensure improved functional reliability of a parking brake. The invention solves this problem by means of the subject matter of the independent claims. Subclaims reflect preferred embodiments.

A parking brake for a motor vehicle includes a first actuator that can be controlled to place the parking brake in an engaged or disengaged state; and a second actuator that can be controlled to hold or release the state of the parking brake.

According to a first aspect of the present invention, a method for controlling such a parking brake comprises steps of detecting a request to apply the parking brake while the parking brake is in the applied state; controlling the second actuator to maintain the state of the parking brake; controlling the first actuator to apply the parking brake; determining the status of the parking brake; and determining a fault if the parking brake is disengaged.

It was recognized that a safe test of the parking brake, which can be actuated using two actuators, can best be checked at the moment when there is a request to release it. To do this, both actuators are controlled appropriately in order to provoke possible malfunction. If the test fails so that the parking brake is opened, there is no dangerous condition because the parking brake assumes the requested state.

The second actuator preferably acts on the first actuator. For this purpose, the second actuator can lock or block a movement of the first actuator. More preferably, locking only takes place in predetermined states of the first actuator, whereby a first state can correspond to an engaged parking brake and a second state can correspond to a deployed parking brake. If the second actuator is controlled to maintain the state of the parking brake while the first actuator is not in any of the predetermined states, further movement of the first actuator may be possible. If the first actuator then reaches one of the predetermined states, the state reached can be maintained as long as the second actuator is controlled to maintain the state.

In a particularly preferred embodiment, the second actuator acts on the first actuator in the manner of a roller closure. Both actuators provide a linear movement, preferably along a common axis. A movement of the first actuator relative to a housing can be achieved by a positive radial engagement of rollers, balls or similar bodies between the first Actuator and the housing must be prevented. The second actuator carries an axial profile and can be axially displaced in order to control a radial movement of the bodies in such a way that the positive connection is canceled and the first actuator is movable, or in such a way that the positive connection exists and the first actuator is thus held in its state is.

It is further preferred that the second actuator is designed to be electrically controlled. In one embodiment, the second actuator comprises an electromagnet with an armature, which further preferably works against a restoring force of an elastic element. A position of the second actuator can be determined using a suitable sensor. However, it is preferred that the position is determined by means of a method that determines an effect of a permanent magnet of the second actuator relative to an electrical coil of the second actuator and derives the position from the determined effect.

If the error has been determined, an actuation force that can be exerted by the first actuator can be limited. In particular, the force can be limited in such a way that changing the state of the parking brake is less likely or less possible. The actuation force can be limited as long as there is no request to apply the parking brake. If there is a request to apply the parking brake, the force limitation can be ended.

The actuating force can in particular be reduced below a predetermined value that is required to apply the parking brake. This can safely prevent the parking brake from being disengaged as long as there is no request for disengagement. The predetermined value can be achieved, for example, by means of an elastic element which counteracts a movement of the first actuator.

The first actuator can be set up to be actuated hydraulically in order to apply the parking brake. An available hydraulic pressure can be reduced below a predetermined value in order to further reduce the actuation force to such an extent that a change in the state of the parking brake by the first actuator is not possible. The hydraulic pressure can be controlled by controlling a proportional valve or a fluid pump. The first actuator may be controlled by another valve that controls a flow of pressurized fluid from a source into or out of a working space of the first actuator.

It is further preferred that an elastic element is provided to counteract the force of the first actuator for deploying the parking brake. The elastic element can comprise a spring, in particular a helical spring, which acts along a movement of the first actuator. The elastic element can provide a restoring force to empty the working space of fluid and bring the first actuator to a predetermined state.

The parking brake is preferably used on a motor vehicle. If the error is determined, a warning signal can be provided. The warning signal can be directed to a device or to a person on board the motor vehicle. The person may include a driver of the motor vehicle, so that the driver can take an appropriate measure to prevent the motor vehicle from rolling unintentionally, for example by actuating a service brake.

In a further embodiment, an entry indicating the particular error may be written to an error memory. The error memory can record entries from various devices on board the motor vehicle. The entry may indicate possible wear or a mechanical defect in the area between the first and second actuators.

If no error has been determined, the second actuator can be controlled to release the state of the parking brake and the first actuator to disengage the parking brake. This may correspond to a common sequence performed to disengage the parking brake. In a particularly preferred embodiment, a predetermined time is waited after the first actuation of the first actuator to disengage the parking brake, and no error is determined if it cannot be determined during this time that the parking brake is in a state other than the engaged state . This time can be chosen to be short depending on an actuation speed of the first actuator in order to carry out the sequence mentioned with the shortest possible delay if there is no error.

According to a second aspect of the present invention, a control device for a parking brake for a motor vehicle described herein is configured to detect a request to disengage the parking brake while the parking brake is in the engaged state; to control the second actuator to maintain the parking brake in its state; to control the first actuator to apply the parking brake; to determine the status of the parking brake; and one Determine errors if the parking brake is designed.

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 control device can also include an integrated circuit that carries out the method in the manner of a switching network or switching mechanism. The computer program product can also be stored on a computer-readable data carrier. Features or advantages of the method can be transferred to the device or vice versa.

According to yet another aspect of the present invention, a parking brake for a motor vehicle includes a control device described herein, a first actuator controllable to place the parking brake in an engaged or disengaged state; and a second actuator that can be controlled to hold or release the parking brake in its state. The parking brake can additionally include a sensor for determining the status of the parking brake. Another sensor can be provided to determine a position of the second actuator. Alternatively, the control device can be set up to determine the position of the second actuator using a determination method. The parking brake can include further elements, in particular one or more elastic elements for one-sided decoupling of movements or an engagement mechanism for positively locking a shaft in a drive train of the motor vehicle. The shaft is further preferably connected to a wheel of the motor vehicle in a torque-locking manner.

According to yet another aspect of the present invention, a transmission arrangement for a motor vehicle includes a parking brake described herein. The transmission arrangement can include a continuously variable transmission or a manual transmission that is designed to act between a drive motor and a drive wheel of the motor vehicle. The drive motor can be designed as an electric drive machine or as an internal combustion engine. In a particularly preferred embodiment, the transmission is designed as a hybrid transmission and includes an electric drive motor, the torque of which can be coupled to a torque of the drive motor.

According to yet another aspect of the present invention, a motor vehicle includes a transmission arrangement described herein. The motor vehicle can in particular include a passenger car, a truck, a motorcycle or a bus.

• 1 eine Parkbremse für ein Kraftfahrzeug;
• 2 Aktuatoren für eine Parkbremse; und
• 3 ein Ablaufdiagramm eines Verfahrens;

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

• 1 a parking brake for a motor vehicle;
• 2 Parking brake actuators; and
• 3 a flowchart of a method;

represents.

1 shows a parking lock or parking brake 100 for a motor vehicle 102, in particular a passenger car. The motor vehicle 102 includes a drive train with an output shaft 104, which is usually coupled in a rotationally fixed manner to a drive wheel of the motor vehicle. A speed of the drive wheel is thus directly coupled to a speed of the output shaft 104. The parking brake 100 may be comprised of a transmission 106, which is located in the drive train to couple a drive motor to the drive wheel.

The parking brake 100 is designed to allow or prevent rotation of the output shaft 104 relative to the motor vehicle 102. For this purpose, the parking brake 100 can be brought into an engaged state in which rotation is prevented, or into a disengaged state in which rotation is permitted. For this purpose, the parking brake 100 preferably comprises a first actuator 108 and a second actuator 110 for actuating an engagement mechanism 112. Furthermore, a control device 114 is preferably provided for controlling the actuators 108 and 110. More preferably, a sensor 116 is provided for determining the state of the parking brake 100.

In the embodiment shown, the first actuator 108 is designed to be hydraulically controlled. An exemplary hydraulic system 118 includes a controllable valve 120 that is in a first position in 1 is shown, a flow of hydraulic fluid from a source 122 to the first actuator 108 and, in a second position, a flow of fluid from the first actuator 108 into a sink 124 permitted. Here the valve 120 is shown as a 3/2-way valve. In another embodiment, a 3/3-way valve can also be used, which can additionally assume a third position in which a flow of fluid into or out of the first actuator 108 is prevented. The valve 120 can be controlled by the control device 114 using one or more electromagnets or another drive.

In the representation of 1 the sink 125 is designed as a container and the source 122 comprises a pump that is fed from the container. A hydraulic pressure under which the source 122 provides the fluid can be controlled by the control device 114. For this purpose, the control device 114 can act on the pump 114 as shown or also on a control valve that controls the pressure provided. The pump 122 may be driven by the motor vehicle's drive motor, the transmission 106, or by a dedicated pump motor. Fluid under pressure can also be used for other control tasks, for which additional valves and associated actuators can be provided. In particular, a gear selected in the transmission 106 can be controlled hydraulically. The pressure of the fluid provided by the source 122 can therefore also be referred to as the system pressure. The control is preferably designed in such a way that a predetermined system pressure is required to produce a torque flow through the transmission 106; If this is not achieved, no gear may be engaged or a clutch to the drive motor may be open.

The first actuator 108 includes a cylinder 130 in which a piston 132 is slidably accommodated, so that a hydraulic working space 134 for receiving hydraulic fluid is limited. The piston 132 can move along an axis 136 in the cylinder 130. In the representation of 1 There is a movement to the right when fluid flows into the working space 134. This movement is counter to the force of an elastic element 136, which can press the piston 132 in the opposite direction into the cylinder 130 while fluid flows from the working space 134.

The first actuator 108 acts on the engagement mechanism 112 to engage or disengage the parking brake 100. The engagement mechanism 112 includes a wheel 140 which is non-rotatably connected to the output shaft 104 and has a series of recesses 142. A lever 144 is rotatably mounted about an axis of rotation 146 and can be pivoted so that its first end engages in a form-fitting manner in one of the recesses 142. A second end of the lever 144 is connected to the first actuator 108 so that engagement of the lever 144 in one of the recesses 142 can be established by moving the piston 132 of the first actuator 108 to a first position and releasing the engagement, by moving the piston 132 to a different position along the axis 136.

The lever 144 preferably includes a spring-loaded joint 148, so that the first actuator 108 can be moved into the first position even if the first end of the lever 144 cannot engage in a recess 142 due to the rotational position of the wheel 140. Such a position is also called tooth-on-tooth (ZaZ) position. In this case, an elastic element on the joint 148 absorbs an actuating force of the first actuator 108 and moves the first end of the lever 144 into a recess 142 as soon as the wheel 140 has been rotated sufficiently far; further optionally, a lock 150 is provided around the lever 144 in the position engaging the wheel 140. To explain the control of the parking brake 100 by means of the actuators 108 and 110, the exact functioning of the lock 150 is not important.

2 shows actuators 108, 110 for a parking brake 100 in a further embodiment. The second actuator 110 is partially shown in a left area and the first actuator 108 is partially shown in a right area.

In the first actuator 108, the piston 132 is designed to be hollow and radially symmetrical. On the outside it rests on the cylinder 130 and on the inside on a bell 205 which is connected to the cylinder 130. The bell 205 has a radial recess in which a ball 210 lies. A slide 215 is accommodated in the bell 205, which can be moved along the axis 136 and has a conical section so that it can press the ball 210 radially outwards. The piston 132 has a radial recess 220 for receiving a section of the ball 210 at two axially spaced locations. In the representation of 2 the ball 210 lies in sections in an inner annular groove; further to the left a shoulder for holding the ball 210 can be seen.

If the slide 215 is in a right position as shown, the ball 210 is pressed radially outwards in the recess of the bell 205 and into a recess 220 in the piston 132. A movement of the piston 132 in the cylinder 130 is then prevented by the positive fit of the ball 210. If the slide 215 is pulled to the left relative to the bell 205, the ball 210 can move radially inwards so that no section of it is in the recess 220. The piston 132 can then be moved along the axis 136 in the cylinder 130.

The second actuator 110 is provided to move the slide 215 into the positions mentioned. In the present case, the second actuator 110 is designed in the manner of an electromagnet and comprises a fixed yoke 230, an armature 232 which can be displaced along the axis 136 and a coil 234. A housing 236 accommodates these elements and is attached to the cylinder 130. The anchor 232 is connected to the slider 215 via a rod 238 coupled. An elastic element 240 is in this case attached axially between the slide 215 and the bell 205 and is designed to press the slide 215 into the locking position, in this case to the right.

If a working current is caused by the coil 234, the armature 232 is pulled to the yoke 230, in the present illustration to the left. In this position, the piston 132 is released and the first actuator 108 can be controlled to move the lever 144 to engage or disengage the parking brake 100.

If the working current is switched off, the armature 232 is pushed into the opposite position by the elastic element 240, in the present illustration to the right. In this position, the piston 132 is locked, so that the first actuator 108 cannot move the lever 144 and the parking brake 100 remains in an engaged or disengaged state.

A position of the slider 215 can be determined by determining an electromagnetic effect of the armature 232 on the coil 234. For this purpose, an impedance of the coil 234 can be determined by applying an alternating voltage to the coil 234 and observing a current flowing through the coil 234. If the slide 215 is not pulled completely into the locking (here: right) position after switching off the working current, this can be detected.

Engaging or disengaging the parking brake 100 requires a predetermined actuation of the first actuator 108 and the second actuator 110. This allows double security to be achieved, so that a simple error, for example in one of the actuators 108, 110, does not result in an unintentional change in the state the parking brake 100 can lead. However, if mechanical wear occurs in the area of the ball 210 or another mechanical defect in the interaction of the actuators 108, 110, double security can no longer be guaranteed. Such defects can have sporadic effects, making them difficult to diagnose.

It is proposed to determine the existence of such a defect by appropriately controlling the actuators 108, 110 and, if necessary, to initiate a measure to ensure the status of the parking brake 100.

3 shows a flowchart of a method 300, which is described below with reference to the embodiments of 1 and 2 is described.

In a step 305, the parking brake 100 is engaged. One end of the lever 144 engages in a recess 142 of the wheel 140 and the output shaft 104 is blocked against rotation. The piston 132 of the first actuator 108 is in a corresponding position, which is in 2 is shown as an example. The armature 232 of the second actuator 110 is in a locking position, as also shown in FIG 2 is shown as an example. The ball 210 creates a positive connection between the piston 132 and the bell 205 or the housing 236 and thus the motor vehicle 102.

In a step 310, a request to apply the parking brake 100 is recorded. The request may come from a driver of the motor vehicle 105, for example by moving a selector lever for controlling the transmission 106 from a P position to another position, such as a D position or an R position.

In a step 315, the securing of the actuation of the parking brake 100 is held in a closed position or brought into this position if necessary. Usually, the second actuator 110 is already in the securing position, in which movement of the first actuator 108 is prevented. Optionally, the position of the second actuator 110 can be checked, with the method 300 only continuing if the second actuator 110 has assumed the securing position.

In a step 320, the first actuator 108 can be controlled to apply the parking brake. Due to the securing position of the second actuator 110, this should not succeed if there is no error.

In a step 325 it can be determined whether the parking brake 100 is designed. For this purpose, the state of the parking brake 100 or the position of the lever 144 can be determined, for example, by means of the sensor 116. Preferably, only a predetermined time is waited for a corresponding signal from sensor 116, for example a few 10 ms.

If the parking brake 100 is designed, it can be determined in a step 330 that there is an error in the interaction of the actuators 108, 110 with the engagement mechanism 108. A corresponding message can be entered into an error memory on board the motor vehicle 102. In addition, a warning signal can be provided, which can be provided to a driver of the motor vehicle 102 or a control device.

In a step 335, the control of the first actuator 108 can be changed for a subsequent operation of the motor vehicle 102. The system pressure in the hydraulic system 118 can always be reduced to a predetermined value when there is a request to engage the parking brake 100. Such a request occurs, for example, when the driver moves the selector lever to control the transmission 106 into the P position. The predetermined value is preferably so low that the system pressure is not sufficient to move the piston 132 of the first actuator 108 against the force of the elastic element 136 with appropriate control of the valve 120 in such a way that the parking brake 100 is applied.

After an error has been determined once in step 330 for the parking brake 100 engaged, the system pressure can be reduced each time until the error is eliminated. A further check of the correct function of the actuators 108, 110 using the described steps of the method 300 can be carried out again when the parking brake 100 is subsequently disengaged or a further test can be dispensed with.

If it is determined in step 325 that the parking brake 100 is not designed, this indicates that the actuators 108, 110 are functioning correctly. In this case, no error is determined and a usual sequence of activations of the actuators 108, 110 can be controlled to design the parking brake 100. Beforehand, the first actuator 108 can be controlled to engage the parking brake 100 in order to facilitate subsequent actuation of the second actuator 110 and to avoid mechanical wear in the area of the ball 210.

For the usual deployment of the parking brake 100, the second actuator 110 can be moved into the non-locking position. If this has not already happened, the first actuator 108 can be controlled in order to apply the parking brake 100. The second actuator 110 can then be controlled into the securing position. The correct design of the parking brake 100 can be checked using the sensor 116. A position of the second actuator 110 can be determined using a sensor or a method based on an electrical parameter of the second actuator.

Reference symbols

100

Parking brake

102

motor vehicle

104

output shaft

106

transmission

108

first actuator

110

second actuator

112

Intervention mechanism

114

Control device

116

sensor

118

hydraulic system

120

Valve

122

Source of hydraulic fluid

124

Sink for hydraulic fluid

130

cylinder

132

Pistons

134

working space

136

elastic element

140

wheel

142

recess

144

lever

146

Axis of rotation

148

joint

150

Lock

205

Bell jar

210

Bullet

215

Slider

220

recess

230

yoke

232

anchor

234

Kitchen sink

236

Housing

238

pole

240

elastic element

300

Proceedings

305

Parking brake engaged, transmission blocked

310

Record the driver's request for interpretation

315

Keep fuse closed

320

Disconnect the parking brake

325

Parking brake designed?

330

Determine errors

335

Adjust system pressure in park position

340

no error, control usual layout sequence

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 2021388897 A1 [0005]

Claims (14)

Method (300) for controlling a parking brake (100) for a motor vehicle (102), wherein the parking brake (100) comprises a first actuator (108) which can be controlled to bring the parking brake (100) into an engaged or disengaged state bring to; and a second actuator (110) that can be controlled to hold or release the state of the parking brake (100), the method (300) having the following steps: detecting (310) a request to apply the parking brake (100), while the parking brake (100) is in the engaged state; Controlling (315) the second actuator (110) to maintain the state of the parking brake (100); Controlling (320) the first actuator (108) to apply the parking brake (100); determining (325) the status of the parking brake (100); and determining (330) an error if the parking brake (100) is in the applied state. Procedure (300). Claim 1 , whereby the second actuator (110) acts on the first actuator (108). Procedure (300). Claim 1 or 2 , wherein the second actuator (110) is designed to be electrically controlled. Method (300) according to one of the preceding claims, wherein, if the error has been determined, an actuation force that can be brought about by the first actuator (108) is limited (335). Procedure (300). Claim 4 , wherein the actuating force is reduced below a predetermined value (335) that is required to apply the parking brake (100). Method (300) according to one of the Claims 4 or 5 , wherein the first actuator (108) is adapted to be hydraulically actuated to apply the parking brake (100); and a hydraulic pressure is reduced (335) below a predetermined value. Procedure (300). Claim 6 , wherein an elastic element (136) is provided to counteract the force of the first actuator (108) to deploy the parking brake (100). Method (300) according to one of the preceding claims, wherein if the error has been determined, a warning signal is provided (330). Method (300) according to one of the preceding claims, wherein if the error has been determined, an entry indicating the determined error is written (330) to an error memory. Method (300) according to one of the preceding claims, wherein, if no error has been determined, the second actuator (110) is controlled (340) to release the state of the parking brake (100) and the first actuator (108) is controlled (340 ) is used to set the parking brake (100). Control device (114) for a parking brake (100) for a motor vehicle (102); wherein the parking brake (100) includes a first actuator (108) controllable to place the parking brake (100) in an engaged or disengaged state; and a second actuator (110) that can be controlled to hold or release the parking brake (100) in its state, the control device (114) being adapted to detect a request to apply the parking brake (100) while the parking brake (100) is in the engaged state; to control the second actuator (110) to keep the parking brake (100) in its state; to control the first actuator (108) to apply the parking brake (100); to determine the status of the parking brake (100); and to determine an error if the parking brake (100) is designed. Parking brake (100) for a motor vehicle (102), comprising a control device (114). Claim 11 , a first actuator (108) controllable to bring the parking brake (100) into an engaged or disengaged state; and a second actuator (110) that can be controlled to hold or release the parking brake (100) in its state. Transmission arrangement (106) for a motor vehicle (102), comprising a parking brake (100). Claim 12 . Motor vehicle (102), comprising a transmission arrangement (106). Claim 13 .

Images