EP1565364A2

EP1565364A2 - Method for operating a hydraulic vehicle-braking system

Info

Publication number: EP1565364A2
Application number: EP03796018A
Authority: EP
Inventors: Erhard Beck; Dieter Burkhard; Ralph Gronau; Jürgen WOYWOD
Original assignee: Continental Teves AG and Co OHG
Current assignee: Continental Teves AG and Co OHG
Priority date: 2002-11-16
Filing date: 2003-11-13
Publication date: 2005-08-24
Also published as: JP2006506269A; DE10393699D2; WO2004045934A3; WO2004045934A2; US20060091724A1

Abstract

The invention relates to a method for operating a hydraulic vehicle-braking system. Said method is characterised in that a hydraulic pressure is fed directly to a brake-master cylinder (11) via a hydraulic booster (7), which is connected upstream of said cylinder, and that the hydraulic pressure is regulated in accordance with a variable that represents the braking request of the driver. To achieve the latter, the pressure in the hydraulic booster (7) that is located upstream of the brake-master cylinder is regulated by controlling at least two valves (6) that are similar or that operate in a similar manner.

Description

Method for operating a hydraulic vehicle brake system

The invention relates to a method for operating a hydraulic vehicle brake system, in which a hydraulic pressure is controlled by means of a hydraulic booster.

In the course of new engine technology, such as Diesel or petrol direct injection, a sufficient vacuum supply to assist the braking force is increasingly rare. This requires brake systems with active hydraulic brake power assistance or with an additional vacuum pump to operate a vacuum brake booster.

Systems with a vacuum brake booster and with additional, active hydraulic brake force support, which additionally support the driver in actuating the brake pedal by means of a controllable hydraulic pump, for example the ABS return pump, are known. These systems increase the control point of a Vacuum brake booster without replacing it. However, they can lead to disadvantages in the comfort area. In some situations, a pedal feel can set which deviates negatively from a "usual ^'" vacuum brake booster support.

Furthermore, methods are known in which a brake pressure is generated by electronic control of an external pressure source, the brake pedal being decoupled from the hydraulic brake system in the normal braking case (brake-by-wire systems). These systems require a high level of technical effort so that sufficient braking power can be achieved even in the event of a fault.

The invention has for its object to provide a control of a hydraulic amplifier with little technical effort, which enables safe and comfortable hydraulic brake power assistance.

According to the invention, this object is achieved by the features of the independent claims. Preferred configurations are specified in the subclaims.

The object is accordingly achieved in that the hydraulic pressure is controlled directly into a master brake cylinder via an upstream hydraulic booster, and in that the hydraulic pressure is regulated in accordance with a variable representative of the driver's brake request by regulating the pressure in the upstream hydraulic booster at least two analog or analog valves is controlled. An analog or analog valve can take all positions between "OPEN ^λ and" CLOSED by means of an electrical or electronic external control, so that the brake pressure for. Control or comfort braking can be continuously increased or decreased. The analog or analogized valve is preferably set with a current value.

The master brake cylinder is preferably a two-circuit system and is designed in particular as a tandem master cylinder (THZ).

It is provided according to the invention that the hydraulic pressure in the upstream hydraulic booster by controlling a first analog or analogized valve, which leads the pressure fluid away from the hydraulic booster into a

Regulates pressure medium reservoir, and is controlled by controlling a second analog or analog valve, which regulates the supply of the pressure fluid from an external pressure source in the hydraulic amplifier.

The pressure medium reservoir is preferably designed to be depressurized.

According to the invention, it is provided that the pressure of the external pressure source is generated by controlling a motor of a motor-pump unit and is stored in a hydraulic high-pressure accumulator.

A hydraulic return pump or a return motor pump unit that is already present in a braking system is preferably used.

According to the invention, it is provided that the analog or analogized valves are actuated for the purpose of applying a specific hydraulic pressure to an booster piston of the hydraulic booster, which is driven into the wheel brakes of the vehicle via a master brake cylinder piston that is operatively connected to the booster piston in the direction of force output.

It is provided according to the invention that the brake pressure is regulated and / or the hydraulic pressure builds up in the high-pressure accumulator by controlling electronically controllable valves.

According to the invention, it is provided that a hydraulic pressure can be introduced into the brake system by the driver through a direct operative connection of the upstream hydraulic booster with a brake pedal.

In this way, the system can ensure an emergency braking function in the event of a failure.

According to the invention, it is provided that the pedal travel of a brake pedal and / or a variable derived from the pedal travel, in particular a pedal speed or acceleration, is used for the driver brake request detection. This means that the pedal travel of the brake pedal and / or a variable derived therefrom is used as a variable that represents the driver's braking request.

It is provided according to the invention that the pressure in the upstream hydraulic booster is based a measured hydraulic pressure in the master brake cylinder is determined or estimated.

According to the invention, the pressure in the hydraulic high-pressure accumulator is monitored by a pressure sensor.

According to the invention, it is provided that only one hydraulic valve is switched to charge the hydraulic high-pressure accumulator.

It is provided according to the invention that the charging process of the hydraulic high-pressure accumulator begins before a lower switching point of a pressure sensor on the high-pressure accumulator is reached.

According to the invention, the hydraulic high-pressure accumulator is charged in phases of increasing and / or constant engine load of the drive motor of the vehicle.

According to the invention, it is provided that the charging process of the hydraulic high-pressure accumulator is interrupted when the brakes are applied and / or an engine load of the drive motor of the vehicle.

According to the invention, the hydraulic high-pressure accumulator (4) is charged when the engine load of the drive motor of the vehicle is equal to zero (0) or less than 0 (<0), ie when the drive motor is being towed, and / or when the vehicle is at a substantially constant speed.

According to the invention, it is provided that an additional pressure increase by means of a pressure increase unit, preferably a hydraulic pump, takes place when the control point of the hydraulic amplifier is exceeded.

It is also provided for certain applications that the amplifier is designed only for a relatively low amplifier output and that an additional pressure increase is then carried out by a pressure increase unit, preferably a hydraulic pump.

According to the invention, it is provided that a variable representing the driver's brake request is used as the guide variable for the additional pressure increase.

In this case, the pedal travel of a brake pedal and / or a variable derived from the pedal travel, in particular a pedal speed or acceleration, is preferably used as a variable representing the driver's braking request.

According to the invention, it is provided that a modulation point of the hydraulic booster is determined on the basis of a ratio of the pressure in the hydraulic accumulator to the pressure in the master brake cylinder and a constructive ratio of the area of a hydraulic piston in the hydraulic booster to the area of a hydraulic piston in the master brake cylinder.

According to the invention it is provided that a control of the brake pressure in the wheel brakes by switching two electronically controllable valves is provided in a closed hydraulic system in particular.

The invention is described in more detail below by way of example with reference to a drawing (FIG.).

The figure shows a braking system according to the invention.

The brake pressure transmitter has a hydraulic booster (7) which is designed as an extension of the actuating unit (THZ) 11 with the container 13. The booster piston 41 is guided in an booster housing, a push rod 42 of the booster piston 41 being supported in the piston 51 of the push rod circuit of the THZ 11 or being guided through a corresponding disk-like enlargement of the diameter in the THZ bore (not shown). Behind the booster piston 41, which is in the rest position, a control line 50 opens into a space 47, which lies behind the booster piston 41. A push rod 46 of the brake pedal 26 penetrates the amplifier 7, which enables the THZ 11 to be actuated in an emergency if the amplifier 7 should fail. This emergency operation corresponds to the emergency operation of a vacuum brake booster.

The area ratio of booster piston 41 and THZ area, in conjunction with the pressure made available by a high-pressure source, gives the THZ pressure to be achieved with reinforcement. It is envisaged to achieve a corresponding structural design of the surface conditions and / or to achieve the maximum requested pressure Design high-pressure accumulator for a corresponding maximum pressure to be stored.

A hydraulic high-pressure accumulator is preferably used as the high-pressure source, which supplies a pressurized brake fluid, ie “charged ¹ ”, by means of a hydraulic pump. For this purpose, a return pump already present in the system is advantageously used for charging a accumulator.

The store is loaded after braking, for example when the hydraulic pressure in the store reaches less than 40 to 50 bar, which corresponds to a brake pressure (modulation pressure) of 80 to 90 bar. A charging time of approx. 2 to 3.5 seconds is required by the pump until an upper limit value for the hydraulic pressure in the accumulator from 50 to 70 bar, corresponding to an actuation pressure of 100 to 110 bar, is reached. Is caused by repeated braking, e.g. a number of approx. 15 braking operations, the hydraulic accumulator empties completely, then the pump needs approx. 30 to 40 seconds to refill the hydraulic accumulator up to a hydraulic pressure of 50 to 70 bar. With this design, an adequate supply of the hydraulic brake booster and thus support of the driver's foot power can be ensured by auxiliary energy.

Furthermore, the FIG. Shows a brake circuit (of a total of two brake circuits) connected to the actuation unit 11, which acts on two wheel brakes 30, 31. The structure and function of the second brake circuit for the two other wheel brakes is identical to the brake circuit shown and therefore need not be described in more detail.

The brake circuits are acted upon by the master cylinder (THZ) 11, which is supplied with hydraulic fluid (hydraulic fluid) via a hydraulic reservoir 13. The master cylinder 11 is actuated via the hydraulic brake booster 7 described above. The pressure requested by the respective control or regulation of an electronic unit 28 is generated via the hydraulic amplifier 7 and the master cylinder 11.

By means of an actuating element (push rod, 46), however, in the event of a malfunction or a failure of the hydraulic pressure on the piston 41, the driver can directly, i.e. mechanically. The system thus guarantees a fail-safe function by means of a direct hydraulic-mechanical access.

The wheel brakes 30, 31 are supplied with pressure by normally open (SO) valves 15.1 and 15.2 directly from the THZ 11 via a line 14, an SO isolating valve 9 and subsequent lines 14.1 and 14.2, the THZ 11 via the hydraulic amplifier 7 is actuated, which can be acted upon by a pressure source 4, 19, 20 with hydraulic pressure.

Brake pressure is reduced via a return line 17 and normally closed (SG) valves 16.1 and 16.2, a low-pressure accumulator 18 and the pump.

As a rule, the charge of a high-pressure accumulator 4 is carried out by the valve 2 which is open when de-energized. Here, when the pressure in the high-pressure accumulator is below one Predetermined setpoint, in particular below 50 bar to 70 bar, falls, brake fluid is sucked in from the THZ 11 via the open changeover valve 8 and by means of the pump 19 operated with the motor 20. The brake fluid is pumped into the high-pressure accumulator 4 via a check valve 23 connected to the pressure side 21 of the pump 19, a damping chamber 57, via a line branch 22 and a line 24 into which the valve 2 and a pressure sensor 3 are inserted. The motor 20 is controlled until a predetermined target pressure is reached. The pressure is measured by a pressure sensor (pressure sensor 3). When filling the high-pressure accumulator 4 (accumulator charging), the valve 5 arranged in a line 50 between the high-pressure accumulator 4 and the amplifier 7 is closed. The pressure side of the pump is also connected to the wheel brakes 30, 31 via the branch 22 and an adjoining line 25, into which a valve 1 is inserted. Valve 1 is preferably closed when de-energized (SG valve) and valve 2 is open when de-energized (SO valve). Then these valves are not energized during the store charging, advantageously only the changeover valve 8 then being energized for filling.

By switching valves 1 and 2 during normal brake pressure control, as in the case of ABS or ESP control, control in a closed hydraulic system is possible. Media separation is thus ensured, which brings advantages in the event of a high-pressure accumulator which may gas out. The boost pressure of the high-pressure accumulator is designed depending on the design, the booster and the desired TH pressure.

It is also possible to design valve 1 as an SO valve and valve 2 as an SG valve, with the switching states then having to be reversed accordingly.

At high control frequencies with low volume requirements in the wheel brake, all or part of the volume removed can be used to charge the high-pressure accumulator 4.

The charging process is preferably carried out in phases in which the engine load of the drive motor or a variable representing the engine load, such as

Throttle valve position and / or accelerator pedal position, approximately constant or with an increasing gradient. A steeply decreasing gradient of the engine load interrupts the charging process. In phases of no engine load (engine load = 0) and / or brake application, no charging process is carried out or ongoing charging processes are interrupted. In phases in which an engine drag torque is present (engine load <0) and / or a constant vehicle speed is detected, charging processes of the high-pressure accumulator are permitted if no other control functions, e.g. a brake intervention of a higher-level control system, such as distance and follow-up control (ACC system), is engaged.

If braking is recognized by the driver, the charging process of the high-pressure accumulator 4 is stopped immediately. The braking detection takes place via a pedal travel sensor 60 or by means of another sensor which detects the driver's braking request. If a braking request is detected by the sensor system 60, the valve 5, which is preferably to be operated in an analog manner, is opened accordingly depending on the travel path of the push rod 46 of the brake pedal 24 and / or the actuation speed, so that brake fluid from the charged high-pressure accumulator 4 into the space behind the booster piston 47 can flow. The build-up of the pressure in the amplifier 7 is monitored by the pressure in the THZ using a pressure sensor 10. This means that a certain path is assigned and regulated to a certain pressure in the THZ. In this case, the booster piston 41 moves in front of the push rod 46 of the brake pedal 26, which is increasingly penetrating into the booster chamber, without any contact being made or having to be made. It is preferably provided to provide an elastic means, in particular a spring, between the push rod 46 and the booster piston 41 in order to achieve an elastic coupling.

If the driver takes the brake pedal back, ie if the distance becomes smaller again, the valve 5 is closed and a valve 6, which is also preferably to be operated analogously, is opened in a line 12 between the high-pressure accumulator 4 and the container 13, corresponding to the withdrawal of the driver's request, and the Brake fluid can flow back into the reservoir 13. By preferably designing the valve 6 as an SO valve, it is possible to actuate the amplifier in the event of a system failure, without negative pressure being generated in the amplifier 4 (or in the amplifier chamber 47), because volume compensation takes place via the valve 6. The With this braking detection, the driver only has to overcome the additional force which is generated by the pressure already set in the booster 7. This Additional force is only dependent on the surface of the push rod 46 that penetrates into the amplifier 7.

The method according to the invention and the combination of the hydraulic booster and the auxiliary pressure source with high-pressure accumulator 4 can be designed such that the entire required brake pressure is generated by the booster. However, this increases the required storage pressure in the high-pressure accumulator 4.

Another embodiment provides only a reduced maximum brake pressure of the booster

(Control pressure) to provide (similar to a vacuum brake booster). This already covers a large area of all braking operations, e.g. all "normal braking" in a range from a maximum of up to 60 to 80 bar resulting brake pressure, from the braking, which is a brake pressure above this control point

(approx. 60-80 bar) are required, are then built up by means of additional pressure build-up by means of the hydraulic pump 19. This can cause the THZ piston to "pull away". Then, pressure medium is fed into the booster chamber 47 via the line 50 and valve 5 and the piston 41 is thus tracked. This embodiment is preferred since the installation space is further reduced. Another advantage is the fact that only relatively small volume flows of brake fluid are then to be moved, which increases the system dynamics. This also reduces the loading times of the high-pressure accumulator 4. The additional hydraulic support by means of a pump 19 means that the volume of the high-pressure accumulator 4 can also be designed for a lower frequency of braking repetitions. That means it can reduce the number of possible stops interim charging of the high pressure accumulator can be reduced to z. B. 2 times 60 bar to 90 bar, preferably about 80 bar, THZ pressure. In the rare cases of a pressure request going beyond this, a corresponding brake pressure can then be generated by means of pump 19.

In the embodiment described above, it is no longer the THZ that is used for the guide variable for the additional amplification, but rather the pedal travel and / or its derivation for driver request detection. In order to determine the modulation point or its reaching, it is provided that the modulation point is determined by the ratio of accumulator pressure to THZ pressure and the ratio of booster piston area to THZ piston area.

The described method is advantageously suitable for electronic brake control systems, such as ABS (anti-lock braking system), EDS (electronic differential lock, traction control), ESP (electronic stability program), or HDC (hill descent control, downhill regulation). It can also be used for systems with distance and follow-up control (ACC, Adaptive Cruise Control), since the THZ automatically balances the pressure in the circuits.

Claims

claims

1. A method for operating a hydraulic vehicle brake system in which a hydraulic pressure is controlled by means of a hydraulic booster, characterized in that the hydraulic pressure is controlled directly into a master brake cylinder (11) via an upstream hydraulic booster (7), and that the hydraulic Pressure is regulated in accordance with a variable representing the driver's brake request by regulating the pressure in the upstream hydraulic amplifier (7) by actuating at least two analog or analog valves (6).

2. The method according to claim 1, characterized in that the hydraulic pressure in the upstream hydraulic amplifier (7) by controlling a first analog or analog valve (6), which leads the discharge of a hydraulic fluid from the hydraulic amplifier (7) into a pressure medium reservoir ( 13), and by controlling a second analog or analogized valve (5) which controls the supply of the pressure fluid from an external pressure source (4, 19, 20) into the hydraulic amplifier (7).

3. The method according to claim 1 or 2, characterized in that the pressure of the External pressure source (4, 19, 20) is generated by controlling a motor of a motor-pump unit (19, 20) and is stored in a hydraulic high-pressure accumulator (4).

4. The method according to any one of claims 1 to 3, characterized in that the analog or analogized valves (5, 6) are controlled for the purpose of acting on an amplifier piston (41) of the hydraulic amplifier (7) with a certain hydraulic pressure, which a master brake cylinder piston, which is operatively connected to the booster piston (41) in the direction of force output, is driven into the wheel brakes of the vehicle.

5. The method according to any one of claims 1 to 4, characterized in that a control of the brake pressure and / or the build-up of a hydraulic pressure in the high pressure accumulator (4) is carried out by controlling electronically controllable valves (1, 2),

6. The method according to any one of claims 1 to 5, characterized in that the driver can introduce a hydraulic pressure through a direct operative connection of the upstream hydraulic amplifier (7) with a brake pedal into the brake system.

7. The method according to any one of claims 1 to 6, characterized in that the pedal travel of a brake pedal and / or a variable derived from the pedal travel, in particular a pedal speed or - acceleration, is used for driver brake request detection.

8. The method according to any one of claims 1 to 7, characterized in that the pressure in the upstream hydraulic booster (7) is determined or estimated on the basis of a measured hydraulic pressure in the master brake cylinder.

9. The method according to any one of claims 3 to 8, characterized in that the pressure in the hydraulic high-pressure accumulator (4) is monitored by a pressure sensor.

10. The method according to any one of claims 3 to 9, characterized in that only one valve 55 is switched to load the hydraulic high-pressure accumulator (4).

11. The method according to any one of claims 3 to 10, characterized in that the charging process of the hydraulic high-pressure accumulator (4) begins before a lower switching point of a pressure sensor on the high-pressure accumulator is reached.

12. The method according to any one of claims 3 to 11, characterized in that the charging process of the hydraulic high-pressure accumulator (4) takes place in phases of increasing and / or constant engine load of the drive motor of the vehicle.

13. The method according to any one of claims 3 to 12, characterized in that the charging process of the hydraulic high-pressure accumulator (4) is interrupted when the brakes are applied and / or an engine load of the drive motor of the vehicle.

14. The method according to any one of claims 3 to 13, characterized in that the loading process of the hydraulic high-pressure accumulator (4) takes place when the engine load of the drive motor of the vehicle is zero (0) or less than O (<0) (towing mode) and / or when there is a substantially constant speed of the vehicle.

15. The method according to any one of claims 1 to 14, characterized in that an additional pressure increase by a pressure increasing unit, preferably a hydraulic pump, takes place when the control point of the hydraulic amplifier is exceeded.

16. The method according to any one of claims 1 to 15, characterized in that the amplifier is designed for a relatively low amplifier power and that an additional pressure increase is carried out by a pressure increasing unit, preferably a hydraulic pump.

17. The method according to claim 15 or 16, characterized in that a variable representing the driver's brake request is used as the guide variable for the additional pressure increase.

18. The method according to claim 16, characterized in that a pedal stroke of a brake pedal and / or a variable derived from the pedal stroke, in particular a variable representing the driver braking request

Pedal speed or acceleration is used.

19. The method according to any one of claims 3 to 18, characterized in that a modulation point of the hydraulic booster is determined on the basis of a ratio of the pressure in the hydraulic accumulator to the pressure in the master brake cylinder and a constructive ratio of the area of a hydraulic piston in the hydraulic booster to the area a hydraulic piston in the master brake cylinder.

20. The method according to any one of claims 3 to 19, characterized in that a control of the brake pressure in the wheel brakes by switching two electronically controllable valves is provided in a closed hydraulic system.