Method for Verifying the Parking Brake Force in a Vehicle

Abstract

A method for verifying the parking brake force in a vehicle includes comparing a travel of a brake booster with a reference travel. The method further includes producing an error signal in case of a predetermined deviation between the travel of the brake booster and the reference travel. The vehicle includes a hydraulic vehicle brake with a brake booster and an electromechanical brake mechanism with an electric brake motor for producing a braking force to displace a brake piston.

Claims

1. A method for verifying a parking brake force in a vehicle, the vehicle including a hydraulic vehicle brake with a brake booster and an electromechanical brake mechanism with an electric brake motor for producing a braking force to displace a brake piston, the method comprising: comparing a travel of the brake booster with a reference travel; and producing an error signal in case of a predetermined deviation between the travel of the brake booster and the reference travel.

2. The method as claimed in claim 1, further comprising: determining, using a sensor, the travel of the brake booster or of a brake master cylinder that is acted upon by the brake booster.

3. The method as claimed in claim 1, further comprising: determining the reference travel using a pressure difference between a hydraulic target parking brake pressure and a lower brake pressure, at which one or more brake circuits of the hydraulic vehicle brake are hydraulically isolated.

4. The method as claimed in claim 3, further comprising: determining a relative displacement of the brake booster, which corresponds to the pressure difference of the lower brake pressure from the higher hydraulic target parking brake pressure; and calculating the reference travel using the relative displacement of the brake booster.

5. The method as claimed in claim 4, further comprising: calculating a stiffness of a brake caliper of the vehicle brake from the relative displacement of the brake booster or the brake master cylinder and the pressure difference; determining from the stiffness of the brake caliper and an equivalent pressure, which corresponds to an electromechanical target parking brake force, an equivalent volume; and calculating the reference travel using: $c_{\mathrm{Cal}}=\frac{?.Math..Math.p}{?.Math..Math.V}.Math.\frac{?.Math..Math.p}{?.Math..Math.s.Math.A_{\mathrm{Hz}}}=\frac{4.Math.?.Math..Math.p}{.Math.?.Math..Math.s.Math.?.Math.d_{\mathrm{Hz}}^2}$ $?.Math..Math.V_{\mathrm{em}}=\frac{p_{\mathrm{em}}}{c_{\mathrm{Cal}}},.Math.p_{\mathrm{em}}=\frac{F_{\mathrm{em}}}{A_{\mathrm{pist}}}$ $s_{\mathrm{ges}}=\frac{?.Math..Math.V_{\mathrm{em}}}{A_{\mathrm{Hz}}}$ wherein ?p denotes the pressure difference between the lower brake pressure and the higher hydraulic target parking brake pressure, ?s denotes the relative displacement of the brake booster for the pressure difference ?p, ?Vem denotes an equivalent volume, ?Hz denotes a piston area of the brake booster or the brake master cylinder, ccal denotes the stiffness of the brake caliper of the vehicle brake, Fem denotes the electromechanical target parking brake force, pem denotes the equivalent pressure of the electromechanical target clamping force, Apist denotes a brake piston area of the brake piston, and sges denotes the reference travel.

6. The method as claimed in claim 1, further comprising: determining the reference travel taking into account an electromechanical target clamping force.

7. The method as claimed in claim 1, further comprising: actuating an electric motor included in the brake booster to produce a hydraulic braking force, wherein the electric motor is configured for boosting.

8. The method as claimed in claim 1, further comprising: indicating the error signal at least one of visually and audibly.

9. The method as claimed in claim 1, further comprising: producing an additional braking force by actuating the electric brake motor during a further clamping process due to the error signal.

10. The method as claimed in claim 1, further comprising: producing an additional braking force by actuating the brake booster of the hydraulic vehicle brake during a further clamping process due to the error signal.

11. The method as claimed in claim 1, further comprising: carrying out the method once a build-up of a clamping force starts on actuating the electromechanical brake mechanism.

12. The method as claimed in claim 1, wherein the method is carried out by a regulating unit or a control unit.

13. A brake system in a vehicle, comprising: a hydraulic vehicle brake having a brake booster; an electromechanical brake mechanism including an electric brake motor configured to produce a braking force to displace a brake piston; and a regulating unit configured to actuate the adjustable components of the brake system and further configured to carry out a method, the method including: comparing a travel of the brake booster with a reference travel; and producing an error signal in case of a predetermined deviation between the travel of the brake booster and the reference travel.

Description

[0015] Further advantages and advantageous embodiments are to be found in the further claims, the description of the figures and the drawings. In the figures:

[0016] FIG. 1 shows a schematic representation of a brake system in a vehicle, with a hydraulic vehicle brake comprising a brake booster, wherein an electric brake motor is additionally disposed on the wheel brake device,

[0017] FIG. 2 shows a section through an electromechanical brake mechanism with an electric brake motor,

[0018] FIG. 3 shows a flow chart for producing a braking force that holds the vehicle at a standstill and for verifying the braking force.

[0019] The same components are provided with the same reference characters.

[0020] The brake system 1 for a vehicle that is represented in FIG. 1 comprises a hydraulic vehicle brake with a front axle brake circuit 2 and a rear axle brake circuit 3 for supplying and actuating wheel brake devices 9 on each wheel of the vehicle with a brake fluid under hydraulic pressure. The two brake circuits 2, 3 are connected to a common brake master cylinder 4, which is supplied with brake fluid by means of a brake fluid reservoir container 5. The brake master cylinder 4 is actuated by the driver by means of the brake pedal 6, and the pedal travel exerted by the driver is measured by means of a pedal travel sensor 7. Between the brake pedal 6 and the brake master cylinder 4 there is a brake booster 10, which comprises for example an electric motor that is preferably actuated by means of a gearbox of the brake master cylinder 4 (iBooster). The brake pedal 6 displacement measured by the pedal travel sensor 7 is transmitted as a sensor signal to a regulating unit or a control unit, in which actuating signals for actuating the brake booster 10 are produced. The boosting movement of the brake booster 10 is transferred by means of an actuating rod of the brake booster 10, wherein the travel of the actuating rod is determined by means of a sensor 11 that is integrated within the brake booster 10.

[0021] The travel of the brake master cylinder 4 may be determined by means of the sensor 11.

[0022] Supplying the wheel brake devices 9 with brake fluid is carried out in each brake circuit 2, 3 by means of different switching valves, which, including further units, are part of the brake hydraulics 8. The brake hydraulics 8 also include a hydraulic pump that is a component of an electronic stability program (ESP).

[0023] In FIG. 2, an electromechanical brake mechanism is represented, which is preferably used for detecting a vehicle at a standstill but can also be used during movement of the vehicle, in particular at lower vehicle speeds below a speed limit value. The electromechanical brake mechanism comprises a brake caliper 12 with a claw 19 that overlaps a brake disk 20. As an actuator, the brake mechanism comprises a d.c. electric motor as a brake motor 13, the rotor shaft of which drives a spindle 14 rotationally, on which a spindle nut 15 is rotatably supported. During a rotation of the spindle 14, the spindle nut 15 is displaced axially. The spindle nut 15 moves within a brake piston 16 that carries a brake lining 17 that is pressed against the brake disk 20 by the brake piston 16. On the opposite side of the brake disk 20 there is a further brake lining 18 that is positionally fixedly mounted on the claw 19.

[0024] Within the brake piston 16, the spindle nut 15 can move axially forwards towards the brake disk 20 during a rotary motion of the spindle 14 or axially rearwards during an opposite rotary motion of the spindle 14 until reaching a stop 21. To produce a clamping force, the spindle nut 15 acts on the inner end face of the brake piston 16, whereby the brake piston 16 that is axially movably mounted in the brake mechanism is pressed with the brake lining 17 against the facing end face of the brake disk 20.

[0025] The electromechanical brake mechanism is integrated within the wheel brake device 9 (FIG. 1) of the hydraulic vehicle brake by the hydraulic pressure of the hydraulic vehicle brake, with which the vehicle is decelerated while travelling, acting on the brake piston 16. The hydraulic pressure can also provide assistance when the vehicle is at a standstill when actuating the electromechanical brake, so that the total braking force consists of the electromotive component and the hydraulic component. Likewise, both the hydraulic vehicle brake and also the electromechanical brake mechanism can be actuated while the vehicle is travelling, and each can produce a braking force.

[0026] In order to ensure that the hydraulic component of the parking brake force is sufficiently large during a parking process, in which both the hydraulic vehicle brake and also the electromechanical brake mechanism are actuated, the method represented in FIG. 3 for verifying the parking brake force is carried out. Initially, in a first step of the method 30 the parking brake demand is determined, and the parking brake process is initiated by activating both the hydraulic vehicle brake and also the electromechanical brake mechanism. The parking brake demand, which is triggered either manually by the driver or automatically by means of a driver assistance function, can be detected in an electronic stability program (ESP) in the vehicle. The electronic stability program passes the parking brake demand to the brake booster 10 (iBooster) of the hydraulic vehicle brake and the electromechanical brake mechanism with the electric brake motor.

[0027] In the next step 31, a predetermined hydraulic brake pressure is produced by means of the brake booster 10, which may be gradient-dependent in order to ensure that the vehicle does not roll away inadvertently when parked on a slope. If for example there is a pressure demand of 40 bar in the brake booster 10, initially a lower pressure of for example 30 bar is produced. Then in the next step of the method 32, the brake circuit in the hydraulic vehicle brake in which the electromechanical brake mechanism with the brake motor is not effective is isolated by closing the inlet valves; this only occurs on the wheel brake devices of one brake circuit, for example on the rear axle of the vehicle, whereas the second brake circuit is not equipped with an electromechanical brake mechanism.

[0028] After closing the inlet valves in the brake circuit without an electromechanical brake mechanism, in the next step 33 the pressure in the second brake circuit, on which the electromechanical brake mechanism is disposed, is increased further up to the target pressure of for example 40 bar. In the step 34, the associated relative displacement of the brake booster, which corresponds to the pressure increase from 30 bar to 40 bar, is measured by sensor. Thereupon, in the step 35 the stiffness c.sub.cal of the brake caliper of the vehicle brake can be calculated taking into account the pressure difference between the lower brake pressure plow of bar and the higher hydraulic target parking brake pressure p.sub.soll of 40 bar according to

[00001]$c_{\mathrm{Cal}}=\frac{?.Math..Math.p}{?.Math..Math.V}.Math.\frac{?.Math..Math.p}{?.Math..Math.s.Math.A_{\mathrm{Hz}}}=\frac{4.Math.?.Math..Math.p}{.Math.?.Math..Math.s.Math.?.Math.d_{\mathrm{Hz}}^2}$

taking into account the geometry of the actuating piston of the brake booster with the piston area A.sub.Hz and the piston diameter d.sub.Hz.

[0029] In the next step 36, the equivalent pressure p.sub.em, which corresponds to an electromechanical target parking brake force F.sub.em, is calculated according to

[00002]$p_{\mathrm{em}}=\frac{F_{\mathrm{em}}}{A_{\mathrm{pist}}}$

taking into account the piston area A.sub.pist of the brake piston. The electromechanical target parking brake force F.sub.em is for example specified at 10 kN.

[0030] In the subsequent step 37, the equivalent volume ?V.sub.em, which corresponds to the equivalent pressure p.sub.em, is determined from the ratio of the equivalent pressure per, and the stiffness of the caliper c.sub.cal:

[00003]$?.Math..Math.V_{\mathrm{em}}=\frac{p_{\mathrm{em}}}{c_{\mathrm{Cal}}}$

From the equivalent volume ?V.sub.em, the reference travel s.sub.ges can be calculated according to

[00004]$s_{\mathrm{ges}}=\frac{?.Math..Math.V_{\mathrm{em}}}{A_{\mathrm{Hz}}}$

taking into account the piston area A.sub.Hz of the brake booster.

[0031] In the next step 39, the actual travel s.sub.real of the brake booster is determined by sensor. In the step 40, a comparison between the actual travel s.sub.real of the brake booster and the reference travel s.sub.ges is carried out. If the two values agree to within a permissible tolerance range, the yes branch (Y) is followed, there is no fault, so that it can be assumed therefrom that the hydraulic parking brake component is correct. If on the other hand the actual travel s.sub.real of the brake booster and the reference travel s.sub.ges do not agree, the no branch (N) is then advanced to the next step 41, in which an error signal is produced. The error signal can be displayed to the driver and/or further processed in the vehicle, for example leading to a further clamping process in the electromechanical brake mechanism and/or to a pressure increase of the hydraulic brake pressure.

[0032] In this case, it can be distinguished as to whether the actual travel s.sub.real is less than or greater than the reference travel s.sub.ges. If the travel s.sub.real is less than the reference travel s.sub.es, then it can be assumed therefrom that sufficient brake fluid is not passing to the wheel brake device, for example owing to a defective hydraulic line with restricted throughflow. In addition or alternatively, it is also possible that the parking brake force provided by the electromechanical brake mechanism is too small. In both cases, the driver can be advised of the parking brake force being too low.

[0033] If the actual travel s.sub.real is greater than the calculated reference travel s.sub.ges, this indicates an increased leak in the hydraulic vehicle brake in the pressure range under consideration. Accordingly, leaks in the vehicle brakes can be detected earlier than with conventional systems. In the case of a greater actual travel in comparison to the reference travel, the parking brake force provided by the electromechanical brake mechanism may also be too great. An error signal can also be displayed to the driver in this case.