EP1853469A1

EP1853469A1 - Braking system for motor vehicles

Info

Publication number: EP1853469A1
Application number: EP06708283A
Authority: EP
Inventors: Stefan Drumm
Original assignee: Continental Teves AG and Co OHG
Current assignee: Continental Teves AG and Co OHG
Priority date: 2005-02-18
Filing date: 2006-02-15
Publication date: 2007-11-14
Also published as: CN101124111A; KR20070102715A; CN100569566C; WO2006087338A1; US20080265665A1; JP2008529892A

Abstract

The invention relates to a braking system comprising: a master cylinder (1) and a master cylinder housing (20), to which wheel-brake cylinders can be connected; a first piston (2), which is coupled to a brake pedal (3) via a pressure rod (34) that transmits actuating forces; a second piston (4), which is used to actuate the master cylinder (1); a third piston (5), which can be hydraulically actuated by the first piston (2); at least one elastic element (6, 7), which forms a pedal travel simulator and which during the brake-by-wire mode gives the vehicle driver a comforting pedal sensitivity; elements for coupling the displacement of the first (2) and the third piston (5); an intermediate chamber (11) that can be subjected to a hydraulic pressure, the influence of the latter causing a hydraulic force to act on the second (4) and third piston (5); and an electrically controlled pressure-provision module (9), which permits the intermediate chamber (11) to be filled with hydraulic fluid and to be evacuated. The aim of the invention is to assist the actuating force even when the electronic controller or the electric energy supply fails. To achieve this, the system is equipped with a fourth piston (8), which can be subjected to two opposing forces by means of the elastic element (6, 7) on the input side and the hydraulic pressure in the intermediate chamber (11) on the output side, and elements (14,19,15) that allow the pressure-provision module (9), in addition to being electrically controlled, to be controlled in accordance with the position of the fourth piston (8), obtained by the aforementioned exertion of forces.

Description

Brake system for motor vehicles

The invention relates to a brake system for motor vehicles comprising: a master cylinder with a master cylinder housing, are connected to the wheel brake cylinder, a first piston, which is coupled via an actuating forces transmitting push rod with a brake pedal, a second piston, via which the master cylinder is actuated, a third Piston hydraulically actuated by the first piston, having at least one elastic element forming a pedal travel simulator providing the driver with a comfortable pedal feel in the brake-by-wire mode, means for coupling the movements of the first and third pistons , with a pressurizable hydraulic pressure gap, the pressurization causes a hydraulic force on the second and the third piston, as well as with an electrically controllable pressure supply module, which allowed both a filling of the space with pressure medium and its emptying light.

In brake systems, the brake can also be operated "externally" by electronic signals without the driver having to actively intervene, for example by means of an electronic stability program ESP If a superposition of such a third-party operation occurs with a driver's operation, the driver of the motor vehicle senses a reaction in the brake pedal.This retroactive effect on the brake pedal can be surprising and unreliable for the driver. be pleasant, so that the driver does not operate the brake pedal in a situation adapted to this situation in a critical situation of road traffic, since it is irritated by the reaction caused by the external operation of the brake reaction to the brake pedal.

A brake system of the type mentioned is known from DE 10 2004 025 638 Al. A "foreign operation" of the prior art brake system or a pressurization of the gap in the "brake-by-wire" by the electrically controllable pressure supply module by means of a likewise electrically controllable valve means, which releases or shuts off a hydraulic connection between the gap and the pressure supply module , A disadvantage is felt in the prior art brake system the fact that support the force applied by the driver operating force only with intact electronics and existing in the vehicle e- nergieversorgung (battery and electrical system) is possible.

It is therefore an object of the present invention to provide a brake system of the type mentioned, in which a support of the actuating force in case of failure of the control electronics or electrical power supply is still possible until the energy supply of a brake system internal energy storage is exhausted. With the proposed brake system, the driver can safely decelerate his vehicle even in this operating condition with the usual pedal force.

This object is achieved in accordance with the invention in that a fourth piston is provided, which can be acted upon on the input side via the elastic element and on the output side by the hydraulic pressure in the intermediate space with two oppositely directed forces and that means are provided. see are to make the pressure delivery module in addition to the electrical controllability also in dependence on the resulting from the application of force position of the fourth piston controllable.

To concretize the idea of the invention, it is provided that the means for controlling the pressure supply module in dependence on the position of the fourth piston, a both mechanically and electrically controllable control valve and mechanical elements for transmitting the position of the fourth piston on the control valve.

The mechanical elements for transmitting the piston position preferably comprise a disc and a control sleeve.

In another advantageous embodiment of the invention, at least one connection of the mechanical elements is designed as a one-way mechanical stop.

Another advantageous embodiment of the subject invention provides that a fourth piston is provided, which is designed as a hollow piston and receives both the first and the third piston such that between the first and the third piston, a hydraulic chamber is limited by a Relative movement of the fourth piston relative to the master cylinder housing is shut off and forms the means for coupling the movement of the first and the third piston.

In an advantageous development of the invention, an axially effective mechanical power transmission connection is provided between the second and the third piston.

Another advantageous development of the invention genständes consists in that the pressure supply module is designed as an actuatable by means of a pneumatic actuator piston-cylinder assembly and that the pneumatic actuator by means of a control valve by both the brake pedal and independent of the brake pedal is externally actuated.

In another embodiment of the subject invention, the elastic element is operatively disposed between the push rod and the fourth piston.

A further advantageous embodiment of the invention provides that the hydraulic chamber in the unactuated state of the brake pedal is in communication with a pressure medium reservoir.

In another embodiment variant, the pneumatic actuator has a housing whose interior is subdivided by a movable wall into a vacuum chamber and a working chamber which can be acted upon by means of the control valve with a negative pressure or the atmospheric pressure.

In another preferred embodiment of the subject invention, the vacuum chamber is connected to an air suction device, for. B. connected to a vacuum pump.

In another embodiment of the subject invention, the control valve is arranged in the input region of the master cylinder housing and consists of a vacuum sealing seat, an atmospheric sealing seat and a valve body, wherein the vacuum sealing seat on a guided on the master cylinder housing, axially movable first ring and the atmospheric sealing seat on a likewise guided in the master cylinder housing, coaxially with the first ring axially movable second ring are formed. In another preferred embodiment of the invention, the external operation of the control valve by means of an electromechanical actuator, preferably an electromagnet whose armature is connected to the first ring and formed by the first ring.

Another advantageous development of the subject invention is that operatively disposed between the first and the fourth piston a response spring.

In order to meter the desired braking force exactly by the driver, another variant provides that at least one sensor for detecting brake pedal position and movement is provided, the output signal of which, for example, a pedal rotation angle and / or a pedal travel path is fed to an electronic control unit and serves to control the control valve ,

Furthermore, at least one pressure sensor and at least one piston travel sensor can be mounted on the master cylinder, which detect the pressure applied in the master cylinder and the travel of the second piston and forward this information to the electronic control unit.

In another embodiment of the subject invention, electrical control and monitoring means are provided in the electronic control unit to control and monitor the vacuum pump.

Another advantageous development of the invention provides that the electronic control unit generates a brake light signal and transmits it via an electronic active connection to the motor vehicle. The electronic connection is either formed by a data bus or is designed as a direct line connection.

In another embodiment, communication means for exchanging data with other vehicle components are provided in the electronic control unit.

Finally, another advantageous development of the subject invention is that the electronic control unit is adapted to receive from other vehicle components brake pressure requirements and implement them by driving the electrically controllable pressure supply module in a monitored by the pressure and piston stroke sensor ü master cylinder actuation.

In the following text, an embodiment of the invention will be explained in more detail with reference to the accompanying schematic representation in the drawing.

The brake system according to the invention shown in the drawing has a brake pedal 3, which is operatively connected via an actuating rod 34 with a first piston 2. The brake pedal travel can be detected via a rotation angle sensor 31. Furthermore, a second piston 4 is provided which constitutes an actuating piston of a master cylinder 1. In the example shown, the master cylinder 1 is designed as a tandem master cylinder, in the master cylinder housing 20, the second piston 4, a further piston 21 is connected downstream. The wheel brakes of the vehicle can be connected to the master brake cylinder 1 via a controllable wheel brake pressure modulation module (not shown), wherein an electronic control unit (also not shown) is assigned to the wheel brake pressure modulation module. Alternatively or in addition to the illustrated rotation angle sensor, a displacement sensor can be provided which detects the actuating travel of the push rod (34) or the first piston (2). The first piston 2 is slidably guided together with a third piston 5 in a fourth piston 8, wherein the first (2) and the third piston 5 delimit a hydraulic chamber 12, which comprises a means for coupling the movements of the first (2) and the third piston 5 forms. The hydraulic chamber 12 is on the one hand via an opening or a passage 46 in the fourth piston 8 with an otherwise closed hydraulic chamber 45 and on the other hand via a hydraulic passage 35 in the fourth piston 8 with a master cylinder 1 associated, under atmospheric pressure pressure medium reservoir 32 in connection , A mounted in the master cylinder housing 20 sealing member 36 causes the passage 35 is separated in a relative movement of the fourth piston 8 relative to the master cylinder housing 20 from the connection to the pressure fluid reservoir 32 and connected on further displacement with the closed hydraulic chamber 45. For pressure relief of this chamber in the unactuated state, it makes sense to form the only schematically illustrated sealing element 36 as a path-dependent überströmbare piston seal.

In addition, a compression spring 6 is operatively arranged between the actuating pedal 3 and the first piston 2 and the fourth piston 8, which brings the first piston 2 via a disc 14 for engagement with a fourth piston 8 formed stop 44 with unconfirmed actuating pedal. An elastic element 7, for example an elastomer spring, is also operatively arranged between the actuating rod 28 and the fourth piston 8, preferably coaxially or parallel to the compression spring 6, and together with the pressure spring 6 forms a pedal travel simulator which is used by the driver when actuating the brake system conveys the usual pedal feel, which corresponds to a common brake pedal characteristic. This means that at ringem brake pedal travel, the resistance increases slowly and increases disproportionately with a larger brake pedal travel. In addition, acts between the disc 14 and the fourth piston 8, a response spring 29th

The previously mentioned pistons 4, 5, 8, 21 are housed in the master cylinder housing 20, wherein between the second piston 4 and the third piston 5, a gap 11 is limited, which is connected by means of a hydraulic connection 37 with an electrically controllable pressure supply module 9, the allows pressurization of the gap 11.

The pressure supply module 9 is essentially formed by an actuatable by means of a pneumatic actuator 10 piston-cylinder assembly 13, at the pressure chamber 38, the aforementioned hydraulic connection 37 is connected. The piston-cylinder assembly 13 is provided with a pressure medium reservoir 39. Instead of the illustrated, the piston-cylinder assembly 13 associated pressure medium reservoir 39, a hose connection to the aforementioned pressure medium reservoir 32 may be used. The pneumatic actuator 10 has an actuator housing 16 in which a vacuum chamber 22 connected to a vacuum pump 18 or an equivalent air suction device and a ventilatable working chamber 23 are separated from each other by a movable wall 17. The movable wall 17 is in a force-transmitting connection with the only schematically indicated piston 40 of the piston-cylinder assembly 13, which limits the above-mentioned pressure chamber 38.

The control of the pneumatic actuator 10 is a fixed to the master cylinder housing 20 control valve, which is provided with the reference numeral 15 and can be controlled both mechanically and electromechanically. The steering- Valve 15 consists of a first or a vacuum sealing seat 24, a second or an atmospheric sealing seat 25 and a cooperating with the sealing seats 24, 25 annular valve body 26. The vacuum sealing seat 24 is preferably formed on a run on the master cylinder housing 20 first ring 27, whose position can be controlled by electromechanical means, while the atmospheric sealing seat 25 is formed on a likewise guided in the master cylinder housing 20 second ring 28 whose position can be controlled by mechanical means. For positioning of the first ring 27, an electric actuator - for example, an electromagnet 30 is provided, whose armature is integrally formed with the first ring 27, and allows independent of the operating pedal 3 external actuation of the control valve 15. For positioning of the second ring 28, a control sleeve 19 is provided, which is connected on one side with the above-mentioned disc 14 and on the other side with the second ring 28, wherein at least one of these compounds is designed as a single-acting stop, so that the Control sleeve 19 only has to transmit tensile forces. In order to allow an unimpeded passage of air under atmospheric pressure to the control valve 15, the control sleeve 19 is provided with radial openings.

In a brake pedal operation shifts due to a suitable feathering first, the first piston 2 together with the disc 14, the control sleeve 19, the second ring 28 and the valve body 26 relative to the Hauptzylin- dergehäuse 20. By placing the valve body 26 on the vacuum seat 24 is this closed and the atmospheric sealing seat 25 is opened, whereby the working chamber 23 of the pneumatic actuator 10 is vented in the pressure supply module 9 and the resulting force Effect on the movable wall 17, the piston 40 of the piston-cylinder assembly 13 is actuated. The hydraulic pressure thus generated in the pressure chamber 38 is supplied via the hydraulic connection 37 to the intermediate space 11 in the master cylinder housing 20.

Thus, on the one hand the master cylinder 1 is actuated and on the other hand, the hollow piston 8 is pressed back against the actuation direction. This closes the atmosphere sealing seat 25, and stops a further pressure build-up in the intermediate space 11, in that the hollow piston 8 remains in an equilibrium position in which the actuating force cancels with a portion of the actuator force determined by the area ratios in the intermediate space 11. With a change in the pedal force is set by a corresponding opening and closing of valve seats 24 and 25 a new equilibrium position. This arrangement could also be referred to as a pneumatic position controller for the hollow piston 8, which compensates for different pedal actuating forces by automatically adapted actuator forces. Characterized in that the hollow piston 8 is always held in the same position, the pedal force is determined only by the forces of the springs 6 and 7, but not by the operating state of the master cylinder. 1

In case of insufficient or missing booster pressure in the intermediate space 11, the hollow piston 8 shifts into the intermediate space 11 as a result of the forces exerted by the actuating rod 34 via the springs 6 and 7. As a result, the passage 35 provided in the wall of the fourth or hollow piston 8 passes over the seal 27 , whereby the connection of the hydraulic chamber 12 is interrupted with the pressure medium reservoir 32. The resulting in the hydraulic Kam- Since the first piston 2 is coupled via the actuating rod 34 to the pedal 3 and the third piston 5 in the direction of actuation with the master cylinder piston 4, is in the presence of an insufficient or missing Amplifier pressure in the space 11 automatically made a direct penetration of the brake pedal 3 to the master cylinder. This hydraulic coupling is controlled exclusively by a relative movement of the fourth piston 8 relative to the master cylinder housing 20 and is therefore independent of the operating state of the master cylinder 1. To activate the coupling, only the small travel of the hollow piston 8 relative to the housing 20 for closing the passage 35 is necessary. Thereby, a pedal travel loss is avoided, which would be unavoidable in a direct passage from the pedal to the master cylinder piston (4) via a mechanical contact of the first 2 and with the third piston 5. Such a mechanical penetration is also possible in the brake system according to the invention and here represents a lowest fallback level, which allows failure of the hydraulic coupling - for example due to leakage - although a pedalwegverlustbehaftete master cylinder operation.

The brake system according to the invention can operate in different modes. In an unactuated state, the same pressure exists in both chambers 22, 23 of the pneumatic actuator 10, since the vacuum sealing seat 24 is open.

In a purely electrically controlled operating mode, the control valve 15 is actuated via the electromechanical actuator 30 in the sense of aeration of the working chamber 23 of the pneumatic actuator 10. In this case, the previously mentioned vacuum sealing seat 24 is closed and the atmosphere sealing seat 25 opened. Due to the force effect of the inflowing air on the movable wall 17, a hydraulic pressure is built up in the pressure chamber 38 of the piston-cylinder arrangement 13, which is supplied via the line 37 to the intermediate space 11. By this pressure, the second (4) and the further piston 21 of the master cylinder 1 are shifted in the drawing to the right, so that pressure medium flows in both only indicated brake circuits.

In a first pedal-controlled operating mode actuation of the brake pedal 3 causes a mechanical actuation of the control valve 15, which has the effect described above result. Of course, a combined operating mode with simultaneous pedal-controlled and electrical control of the control valve 15 is possible. This mode is used, for example, to accomplish the brake assist function well known in the art of brake technology, which is to accelerate and intensify certain brake pedal controlled braking events.

In a further pedal-controlled operating mode, which corresponds to a first fallback level, no hydraulic pressure can be built up in the intermediate space 11 due to a fault in the above-described processes, whereby a displacement of the hollow piston 8 can not be counteracted by a restoring pressure force and the above-described state of a hydraulic coupling of first and third piston unamplified power transmission from the actuating rod via the first piston 2, the pressure medium enclosed in the hydraulic chamber 12, the third piston 5 and the latter coupled to the second piston 4 to the master cylinder 1 causes. Due to the use of the hydraulic lock with the aid of the chamber 12, there is no loss of pedal travel, unless there is no pressure due to a further disturbance in this chamber. can be built. In this case, a purely mechanical power transmission from the first piston 2 to the third piston 5 by direct mechanical contact takes place in a further fallback level. In the fallback modes, the operation of the master cylinder 1 is done exclusively with muscle power.

The present invention achieves a simply constructed brake system in which the brake pedal characteristic does not depend on the operating state of the rest of the brake system, whereby the pedal feel in a driver's braking neither by the simultaneous presence of external braking nor by other control activities of the braking system such as anti-skid control, traction control or Fahrstabili- tätsregelung can be disturbed.

The brake system also has the advantage that it is simpler in design than conventional brake systems. For example, vehicles with an Electronic Stability Control (ESP) feature require special ESP hydraulics, which are more complicated than normal ABS hydraulics because they also have the ability to build up wheel brake pressures above the master cylinder pressure, unlike ABS hydraulics. The proposed brake system, however, comes on the downstream side of the master cylinder with a simple, containing only eight solenoid valves "ABS" hydraulic module.

Claims

claims

1. brake system for motor vehicles with

A master cylinder (1) with a master cylinder housing (20), to which wheel brake cylinders can be connected,

A first piston (2) which is coupled to a brake pedal (3) via an actuating rod (34) transmitting actuating forces,

A second piston (4), via which the master cylinder (1) is actuated,

A third piston (5) which is hydraulically actuated by the first piston (2),

With at least one elastic element (6, 7) forming a pedal travel simulator, which gives the driver a pleasant pedal feel in the brake-by-wire mode,

Means for coupling the movements of the first (2) and third (5) pistons,

With an intermediate space (11) which can be acted upon by hydraulic pressure, the pressurization of which causes a hydraulic force action on the second and the third piston (4, 5),

• and with an electrically controllable pressure supply module (9), which allows both a filling of the intermediate space (11) with pressure medium and its emptying,

characterized in that a fourth piston (8) is provided, the input side via the elastic element (6,7) and the output side by the hydraulic pressure in the intermediate space (11) can be acted upon with two oppositely directed forces and means (14, 19, 15 ) are provided to the pressure supply module (9) in addition to the electrical control ability to make controllable depending on the resulting from the application of force position of the fourth piston (8).

2. Brake system according to claim 1, characterized in that the means for controlling the pressure supply module (9) in dependence on the position of the fourth piston (8) a mechanically and also electrically controllable control valve (15) and mechanical elements (14, 19) for transmitting the position of the fourth piston (8) to the control valve (15).

3. Brake system according to claim 2, characterized in that the mechanical elements for transmitting the piston position a disc (14) and a control sleeve

(19).

4. Brake system according to claim 2 or 3, characterized in that at least one compound of the mechanical elements is designed as a one-way mechanical stop (47).

5. Brake system according to one of claims 2 to 4, characterized in that the fourth piston (8) is designed as a hollow piston and receives both the first (2) and the third piston (5) such that between the first (2) and the third piston (5) is delimited by a hydraulic chamber (12) which can be shut off by a relative movement of the fourth piston (8) relative to the master cylinder housing (20) and the means for coupling the movement of the first (2) and third pistons (5) forms.

6. Brake system according to claim 5, characterized in that between the second (4) and the third piston (5) an axially effective mechanical power transmission connection is provided.

7. Brake system according to one of claims 1 to 6, characterized in that the pressure supply module (9) as a means of a pneumatic actuator (10) operable piston-cylinder assembly (13) is formed and that the pneumatic actuator (10) by means of a control valve ( 15) is externally operable both by the brake pedal (3) and independently of the brake pedal (3).

8. Brake system according to one of claims 1 to 7, characterized in that the elastic element (6) is operatively arranged between the push rod (34) and the fourth piston (8).

9. Brake system according to one of claims 5 to 8, characterized in that the hydraulic chamber (12) in the unactuated state of the brake pedal (3) with a pressure medium reservoir (32) is in communication.

10. Brake system according to claim 7, characterized in that the pneumatic actuator (10) has a housing (16) whose interior is divided by a movable wall (17) in a vacuum chamber (22) and a working chamber (23) by means of of the control valve (15) can be acted upon by a negative pressure or the atmospheric pressure.

11. Brake system according to claim 10, characterized in that the vacuum chamber (22) to an air suction device, for. B. a vacuum pump (18) can be connected.

12. Brake system according to one of claims 2 to 11, characterized characterized in that the control valve (15) is arranged in the inlet area of the master cylinder housing (20) and consists of a vacuum sealing seat (24), an atmospheric sealing seat (25) and a valve body (26), wherein the vacuum sealing seat (24) is located on one of the Main cylinder housing (20) guided, axially movable first ring (27) and the Atmospheric sealing seat (25) on a likewise in the master cylinder housing (20) out, coaxial with the first ring (27) axially movable second ring (28) are formed.

13. Brake system according to one of claims 3 to 12, characterized in that the external actuation of the control valve (15) by means of an electromechanical Aktua- sector, preferably an electromagnet (30 takes place, whose armature with the first ring (27) connected or by the first ring (27) is formed.

14. Brake system according to one of the preceding claims, characterized in that operatively disposed between the first (2) and the fourth piston (8) is a response spring (29).

15. Brake system according to one of the preceding claims, characterized in that a rotation angle sensor (31) for detecting brake pedal position and movement is provided, the output of an electronic control unit (33) is supplied and the control of the control valve (15).

16. Brake system according to claim 15, characterized in that on the master cylinder (1) at least one pressure sensor (42, 43) and at least one piston displacement sensor (41) are mounted, the in the master cylinder (1) controlled pressure and the path of the second piston ( 4) and transmit this information to the electronic tax forward unit (33).

17. Brake system according to one of the preceding claims, characterized in that in the electronic control unit (33) electrical control and monitoring means are provided to control the vacuum pump (18) and to monitor.

18. Brake system according to one of the preceding claims, characterized in that the electronic control unit (33) generates a brake light signal and passes on an electronic active connection to the motor vehicle.

19. Brake system according to one of the preceding claims, characterized in that in the electronic control unit (33) communication means are provided for exchanging data with other vehicle components.

20. Brake system according to one of the preceding claims, characterized in that the electronic control unit (33) is adapted to receive from other vehicle components brake pressure requirements and this by driving the electrically controllable pressure supply module (9) in one of the pressure (42, 43) and Piston stroke sensor (41) monitored master cylinder actuation implement.

21. Brake system according to one of the preceding claims, characterized in that the electronic control unit (33) is assigned to the pressure supply module (9).