EP3140165A1

EP3140165A1 - Control device for a compressed-air-operated brake system, brake system with such a control device and vehicle with such a brake system

Info

Publication number: EP3140165A1
Application number: EP15715984.9A
Authority: EP
Inventors: Ralph-Carsten Lülfing; Robert Otremba; Wolfgang Strache
Original assignee: Wabco GmbH
Current assignee: ZF CV Systems Hannover GmbH
Priority date: 2014-05-08
Filing date: 2015-04-11
Publication date: 2017-03-15
Also published as: DE102014006613A1; CN106132793A; WO2015169418A1

Abstract

The invention relates to a control device (23) for a compressed-air-operated brake system (1, 1') of a vehicle according to Claim 1, to a brake system (1,1') having such a control device (23) according to Claim 8 and to a vehicle having such a brake system (1, 1') according to Claim 15. In the prior art, it is known to arrange control devices separately in utility vehicles. It is disadvantageous here that all the control devices have to be connected to one another by means of leads, which entails a high level of outlay and high costs. In addition, a large amount of space is required. In order to solve the problem, a control device (23) is proposed which comprises an axle control module (25) with a control function for modulating a pneumatic pressure for making available a service brake function, and a vehicle movement dynamics sensor unit (27) with acceleration and/or rotational speed sensors which serve for regulating the vehicle movement dynamics of the vehicle.

Description

Control unit for a compressed-air-operated brake system, brake system with such a control unit and vehicle with such a brake system

The invention relates according to claim 1, a control device for a compressed air-driven brake system of a vehicle, in particular a commercial vehicle, wherein the control unit has a Achssteuermodul with a control function for controlling a pneumatic pressure to provide a service brake function au. The invention further relates to a brake system with such a control device and according to claim 15, a vehicle with such a brake system.

It is known from the prior art, a brake system, in which control devices are arranged separately. The control units each contain independent control functions. The control devices may be, for example, an axle modulator, a parking brake device or a vehicle dynamics control device. As a result of increasing technology in vehicles, the number of control units is constantly being increased.

A disadvantage is therefore in the known prior art that all control devices must be connected to each other with electrical and possibly pneumatic lines, which brings high costs and high costs. In addition, a high space requirement is necessary.

The object of the invention is therefore to avoid the above-mentioned disadvantages.

The object is achieved by the invention according to claims 1, 8 and 15. The invention provides according to claim 1, a control device for a compressed-air-driven brake system of a vehicle that has a Achssteuermodul with a control function. The control function of the axis control module is used thereby for the modulation of compressed air or a pneumatic pressure, preferably on an axle of the vehicle. In particular, the pneumatic pressure on the rear axle or the rear axles is controlled by the control function of the axis control module. The vehicle is preferably a commercial vehicle, in particular a truck.

In addition, the control unit has a vehicle dynamics sensor unit with at least one acceleration and / or rotation rate sensor, which is used for vehicle dynamics control of the vehicle. Preferably, the vehicle dynamics sensor unit comprises a lateral acceleration sensor and optionally further acceleration sensors, such as e.g. a yaw rate sensor and / or a tilt sensor. Particularly preferably, a vehicle dynamics control function of a central control module evaluates the data of the sensors and compares the real vehicle state with the theoretically permitted vehicle state. If the real vehicle state differs from the theoretically permitted vehicle state, the vehicle dynamics control function causes the targeted control of individual wheels for correction.

Due to the fact that the control unit has the axis control module and the vehicle dynamics sensor unit, less space is required and the outlay for laying and connecting electrical and pneumatic lines is reduced. At the same time the assembly costs and the installation costs are reduced. In particular, when mounting the controller on the support frame of the vehicle, a small footprint of great advantage.

As a module in the context of the invention, a section on a board or a software part is to be regarded. For example, several modules may be located on a common board. This saves the cost and space of a second board. In addition, the board can be controlled by means of a single connection, so that here too the cost of laying cables or assembly work is reduced. Alternatively, the modules are individual pieces of software that can be executed, for example, by a common processor or a data processing logic unit. In a preferred embodiment, the control unit additionally has a parking brake control module with a control function for detecting the vehicle. The parking brake control module may be formed, for example, in addition to the portion on a board for the axis control module as another portion on the board. The fact that the control unit has a further module with a further control function, the cost of laying cables and the installation costs and costs and space requirements are further reduced. A separate connection of the modules with each other is therefore no longer necessary. As a result, the susceptibility is reduced.

In a preferred embodiment, the controller has multiple processors. Preferably, the control function of the axle control module and the control function of the parking brake control module are each executable by means of different processors. The processors are independently operable. This embodiment has the advantage that additional redundancy is created. If one processor fails, the other processor can nevertheless initiate or control a braking process. Due to the independent operability of the processors from each other takes place in the event of an error, no influence on the respective non-faulty processor.

Particularly preferably, the processors take over the function of the other processor in case of failure of one processor. If, for example, the processor fails with the axis control module and the vehicle can no longer be braked by means of the service brake, the other processor can intervene with the parking brake control module and still bring the vehicle to a standstill by means of the parking brake. If, for example, the processor fails with the parking brake control module, the vehicle can still be braked and detected by means of the service brake. Although the frequently used service brake pressure system loses pressure in the brake line after a certain time, the vehicle can be secured at least until the time of the pressure drop. In addition, wedges can be used for securing, which must always be carried in the vehicle.

In a preferred embodiment, the controller has a data connection between the parking brake control module and the central control module on. The central control module comprises a control function by means of which an electronic brake system can be controlled or regulated and monitored. The central control module receives data from different sources, processes them via the control function and distributes them to other modules. The central control module determines, for example, a target deceleration of the vehicle from the signal of a brake value transmitter. The desired deceleration and wheel speeds, which are measured by speed sensors, together form an input signal for the electropneumatic control. From the input signal, the central module calculates the pressure setpoints for the front axle, the rear axle or rear axles and for a trailer control valve. In addition, the central control module performs an ABS control.

The data connection between the parking brake control module and the central control module provides further redundancy. Preferably, there is a data connection between the parking brake control module and a parking brake signal generator. If the parking brake control module does not receive a signal from this parking brake signal transmitter in the event of a fault, then the signal for determining the brake can also be transmitted from the central control module to the parking brake control module. The central control module receives the signal from, for example, a brake value transmitter.

If the parking brake control module is integrated in the control unit, the data connection preferably comprises a data line between interfaces on a housing of the central control module and on the control unit. Particularly preferably, the data line is a bus connection. Between the interfaces and the modules then takes place a data exchange. For example, a data exchange between the controller and the parking brake control module takes place.

In a preferred embodiment, the control unit additionally has the central control module with the control function. In this case, the data connection between the parking brake control module and the central control module is not provided. Because the control unit now likewise has the central control module with the corresponding control function, additional cher space, effort for the laying of cables and the assembly costs saved. This also reduces the costs and susceptibility.

The axle control module, the vehicle dynamics sensor unit, the parking brake control module and the central control module can thus be combined in a control unit. Within the controller, the modules can preferably communicate with each other and exchange data. Nevertheless, dedicated processors can be provided for the axle control module, the parking brake control module and the central module. This increases the reliability. Alternatively, the control functions of several modules can be executed by means of a processor. For example, the control functions of the axis control module and the central control module could be performed by a first processor while the control functions of the parking brake control module are performed by a second processor. In the event of failure of one of the processors, then the other processor can still decelerate the vehicle, i. to control a braking process.

In a preferred embodiment, the vehicle is detectable by means of an electro-pneumatic parking brake. As a result, combined spring brake cylinder can be used, which in turn costs, space and effort for the installation of cables can be saved. Alternatively, an electromechanical parking brake may be used to lock the vehicle. This can also be controlled by the control function of the parking brake module.

In a preferred embodiment, the control unit has a common housing for the modules. The modules may be, for example, the axle control module, the vehicle dynamics sensor unit, the parking brake control module and / or the central control module. By using a single, common housing for the modules, the housings for the individual modules are saved, which in turn reduces the cost and assembly costs as well as the expense of laying cables. In addition, less space is needed. Particularly preferably, the control device in the region of the rear axle or rear axles, in particular preferably on the support frame of the vehicle attached. An axle modulator is also particularly preferably used, in which the functions of the vehicle dynamics sensor unit, the parking brake control module and / or the central control module are integrated.

By integrating the modules in a common housing, moreover, only one common connection or a common interface is to be provided, via which or which all modules can receive and / or transmit data. This also reduces the effort required to lay cables.

Furthermore, the invention relates to a brake system. The brake system includes a controller having some or all of the above features.

In a preferred embodiment, the brake system has a brake value transmitter. From this brake value transmitter electrical and pneumatic brake request signals can be provided, wherein preferably pneumatic brake request signals are provided only at the front axle. In this case, therefore, the front axle electrical and pneumatic brake request signals are provided, while the rear axle or the rear axles only electrical braking request signals are provided. It is also conceivable that the rear axle and the rear axles pneumatic and electrical braking request signals are provided while the front axle purely electrical braking request signals are provided. The fact that either the front axle or the rear axle or rear axles is not supplied with pneumatic signals, pneumatic lines are saved.

Alternatively, the brake value transmitter exclusively provides electrical brake request signals. The brake system in this case has no pneumatic redundancy. This saves additional pneumatic lines and reduces costs.

In a preferred embodiment, the brake value transmitter and the parking brake control module are connected directly or indirectly to each other for establishing a data connection. A brake request signal can be transmitted via the data connection. If, for example, pneumatic redundancy does not exist on one of the axles (front or rear axle), this can be done via this Data connection a braking request signal to the parking brake control module are transmitted, which is used redundantly for braking the vehicle when the service brake system is not functional. By means of the data connection thus a redundant braking capability is created, whereby the vehicle remains braked even in case of failure of the service brake system. The vehicle remains namely even in this case with the parking brake still braked.

In a preferred embodiment, the data connection comprises a data line, wherein the data line is either a LIN bus and / or a CAN bus. Alternatively, a PWM signal can be transmitted via the data line. However, the data line is particularly preferably a LIN bus. As a result, the data connection is particularly inexpensive to produce.

In a preferred embodiment, the braking system has an electric parking brake signal generator for providing a desired braking value for detecting the vehicle. In this case, the brake value transmitter for establishing the data connection via this parking brake signal generator is connected to the parking brake control module. In this case, there is therefore a data connection between the brake value transmitter and the parking brake signal transmitter and a further data connection between the parking brake signal transmitter and the parking brake control module. If there is already a data connection between the parking brake signal transmitter and the parking brake control module, only the less long section between the brake value transmitter and the parking brake signal transmitter can be equipped with a data connection for retrofitting the brake system. Thus, additional lines are saved.

Alternatively, the brake value transmitter, the parking brake signal transmitter and the parking brake control module each have a data connection with each other, so that in each case there is a data connection between the brake value transmitter and the parking brake signal transmitter, the brake value transmitter and the parking brake control module and between the parking brake signal generator and the parking brake control module. Furthermore, the parking brake signal transmitter may be indirectly connected to the parking brake control module via the brake value transmitter. As mentioned above, the data links preferably include data lines. If the parking brake control module is integrated into the control unit, it is particularly preferable for, for example, in each case one data line to be present between the control unit and the brake value transmitter and / or the parking brake signal transmitter. Within the control unit data is then passed to the parking brake control module or there is a data exchange between the control unit and parking brake control module instead.

If several data lines are provided in the data connection, then the individual data lines can be designed differently. For example, while one of the data lines is configured as a LIN bus, another data line may be formed as a CAN bus, for example. Preferably, however, only one line is used, which is particularly preferably designed as a LIN bus.

In the event that the parking brake control module is integrated into the control unit, a data connection to the control unit is produced by the brake value sensor and / or the parking brake signal, for example on the housing of the control unit by means of a plug or an interface, wherein within the control unit the corresponding brake request signals to the parking brake control module be passed on.

In a preferred embodiment, the brake system has a first power supply. In addition to this first power supply, the brake system further includes a second power supply that is operable independently of the first power supply. The power supplies in each case comprise one or more batteries, in particular vehicle batteries, and are preferably arranged at different locations in the brake system. For example, both power supplies provide power to the parking brake signal transmitter, the brake value transmitter, and the parking brake control module. The first power supply also provides power for the central control module. The second energy supply continues to supply energy for the control of the brake cylinders by means of wheel modules on the front axle. In addition, the second power supply may also be connected to the central control module. In addition, an electrical supply between the central control module and the wheel modules is preferably provided. If therefore one of the two power supplies fails, all the braking functions can be maintained by the respective other power supply. If, for example, the first power supply fails, the wheel modules for braking the wheels of the front axle are still supplied via the second power supply. This supply is either directly or via the central module. On the other hand, if the second power supply fails, the wheel modules are fed by the first power supply via the central control module. The redundant power supplies therefore allow higher reliability. In particular, in a brake system without pneumatic redundancy, such an embodiment of great advantage.

Finally, the invention also relates to a vehicle having a braking system with one or more of the above features. Particularly preferably, the vehicle is a commercial vehicle, in particular a truck.

Further embodiments will become apparent from the claims and from the embodiments explained in more detail with reference to the drawing. In the drawing show:

1 shows a brake system according to a first embodiment of the invention,

Fig. 2 shows a brake system according to a second embodiment of

Invention,

Fig. 3 shows a control device according to a first embodiment of the invention and

Fig. 4 shows a control device according to a second embodiment of the invention.

Solid lines in Figs. 1 and 2 denote electrical lines, dotted lines indicate pneumatic lines, and dotted lines denote data lines. In all figures, like reference numerals designate like parts. Fig. 1 shows a brake system 1 according to a first embodiment of the invention. Schematically, six wheels 3 are shown, which are placed on the front axle 5 and on the rear axle 7. In the area of the wheels 3, speed-sensing means 9 are respectively arranged, which respectively determine the wheel rotational speed. For this purpose, the speed sensing means 9 comprise, for example, in a known manner in each case preferably a pole wheel, which is connected in a rotationally fixed manner to the wheel and which is electromagnetically coupled to an inductively operating wheel sensor.

Furthermore, 3 brake cylinders 11 are arranged in the region of the wheels, wherein at least on the rear axle 7 combined spring brake cylinders 12 are used. On the front axle are still ABS valves 13 for controlling the brake pressure of the brake cylinder 11. For this purpose, the ABS valves 13 are connected via compressed air lines with a front-axle brake control unit 15. Via an electrical line, the ABS valves 13 are connected to a central control module 17 and a housing of the central control module 17. The speed-sensing means 9 are also electrically connected via the front-axle brake control unit 15 to the central control module 17 or a housing of the central control module 17.

A brake value transmitter 19 serves to detect the driver's braking request. The brake value transmitter 19 has a sensor which detects a mechanical actuation of a brake pedal. The resulting signal from the sensor is transferred via an electrical line to the central control module 17 or to the housing of the central control module 17. Furthermore, the brake value transmitter 19 has a pneumatic output for controlling a brake pressure on the front axle 5. Supply pressure tank 21 supply the compressed air lines with supply pressure.

On the rear axle 7 is a control unit 23 with an axle control module 25, which controls the service brake function of the rear axle 7. The axis control module 25 or the control unit 23 is connected to the central control module 17 via data connections comprising electrical lines and data lines. The axle control module 25 or the control unit 23 is pneumatically connected to the combined spring brake cylinders 12 on the rear axle 7. prevented. Furthermore, there is an electrical connection between the axle control module 25 and the control unit 23 with the speed-sensing means 9 of the rear axle 7.

Furthermore, the brake system 1 comprises a vehicle dynamics sensor unit 27, which is likewise arranged in the control unit 23. The driving dynamics sensor unit 27 or the control unit 23 is likewise connected to the central control module 17 via data connections which comprise electrical lines or data lines. In particular, the vehicle dynamics sensor unit 27 has acceleration and / or rotation rate sensors and, in cooperation with a vehicle dynamics control function in the central control module 17, increases the stability of the vehicle in extreme driving situations. Especially in abrupt lane changes, evasive maneuvers and tight and / or fast cornering commercial vehicles can easily tilt, roll or roll due to their high center of gravity and their large mass. Using the various sensors in the vehicle dynamics sensor unit 27 detects the vehicle dynamics control such critical situations and intervenes, if necessary, correcting the engine power and the brake. This increases driving safety.

Also disposed within the controller 23 is a parking brake control module 29 which controls the brake pressure to detect the vehicle. For this, the parking brake control module 29 is connected to a parking brake signal generator 31. Particularly preferably, this connection 30 comprises a data bus, in particular a LIN or CAN data bus. About this connection, the parking brake signal generator 31 sends the target braking value for controlling the pressure on the rear axle. 7

A first power supply 33 supplies the parking brake signal generator 31, the brake value transmitter 19, the central control module 17 and the parking brake control module 29 with energy. In addition, a steering angle sensor 37 is connected to the central control module 17 and the parking brake control module 29 via a vehicle bus 35.

Via an electrical connector 39 and a trailer control valve 41, the brake system 1 is further connected to the brake system of a trailer. The plug connection 39 is connected to the central control module 17 via a data connection comprising a data bus, while the trailer control valve 41 is connected via an electrical and a pneumatic line to an interface of the central control module 17 and the brake value transmitter 19. A brake signal can therefore be forwarded from the brake value transmitter 19 or from the central control module 17 via the plug connection 39 and / or the trailer control valve 41 to the trailer.

The integration of the parking brake control module 29, the axle control module 25 and the vehicle dynamics sensor unit 27 in the control unit 23 with a common housing less space, effort for the installation of cables and installation work is necessary. Overall, costs are reduced.

In the brake system 1 shown in FIG. 1, no pneumatic redundancy is provided on the rear axle 7. A pneumatic redundancy is provided only on the front axle 5 and for the trailer control valve 41. There are therefore increased requirements for reliability. Preferably, therefore, the control functions of the parking brake control module 29 and the axis control module 25 are executed on different processors. As a result, the vehicle can be braked even if one of the processors fails. If, for example, the axle control module 25 fails and the vehicle can no longer be braked by means of the service brake, the vehicle can continue to be braked by means of the parking brake. For this purpose, the parking brake control module 29 is informed by the parking brake signal generator 31 of a desired braking value.

Furthermore, the brake value sensor 19 is connected to the parking brake signal generator 31, preferably via a LIN bus 42. Therefore, signals of the brake value transmitter 19 can be transmitted indirectly via the parking brake signal generator 31 and the connection 30 to the parking brake control module 29. With these brake signals then the vehicle can be braked.

FIG. 2 shows a brake system 1 '. At the front axle, the front axle brake control unit 15 and the ABS valves 13 (see FIG. 1) are replaced by wheel modules 43 (see FIG. 2). The wheel modules 43 receive electrical signals or data from the brake value transmitter 19 or the central control module 17 and control then the brake pressure pneumatically by means of the brake cylinder 11 on the wheels 3 of the front axle 5.

In FIG. 2, the brake value transmitter 19 has no pneumatic outputs. The brake value sensor 19 therefore outputs only electrical signals. These are transmitted via electrical connections or data connections to the wheel modules 43, the central control module 17 and the parking brake signal generator 31. The brake system 1 'is therefore a purely electropneumatic brake system without pneumatic redundancy.

In addition, a second energy supply 45 is present in the brake system Γ. Like the first power supply 33, this second power supply 45 is connected to the parking brake control module 29, the parking brake signal generator 31, the brake value transmitter 19 and the central control module 17 and supplies these components with energy. Furthermore, the second power supply 45 is connected to the wheel modules 43 of the front axle 5. Thus, the power supplies 33, 45 can jump in if the other power supply 33, 45 fails. The power supply of the above-mentioned components is thus still secured and thus braking of the vehicle possible. The power supplies 33, 45 are each preferably a vehicle battery. The two power supplies 33, 45 are independently operable, so that they form a redundancy for the respective other power supply 33,45.

FIG. 3 shows the control unit 23 '. In the control unit 23 ', the axis control module 25 and the driving dynamics sensor unit 27 are arranged. In this case, the control unit 23 'forms a common housing for the axle control module 25 and the vehicle dynamics sensor unit 27. As a result, the expense of laying cables and installation effort is saved. In addition, separate housings are saved, so that less space is needed overall. In particular, in the arrangement of the control unit 23 'on the support frame of the vehicle is a small footprint of great advantage. In addition, only one connection, namely a common connection for the axle control module 25 and the vehicle dynamics sensor unit 27 is necessary. 4 shows a particularly preferred embodiment of the control unit 23 ". The control unit 23" has the axle control module 25, the vehicle dynamics sensor unit 27 and the parking brake control module 29 with their respective control functions. As described for FIG. 3, the control unit 23 "also forms a common housing for the axle module 25, the vehicle dynamics sensor unit 27 and the parking brake control module 29.

By integrating a further module, namely the parking brake control module 29, the positive effects described for FIG. 3 are further enhanced. This further reduces the cost of laying cables, space requirements, costs and assembly costs.

The control unit 23 "has a plurality of processors, for example the control unit 23" has a first processor 47 and a second processor 49. The control function of the axis control module 25 and the control function of the parking brake control module 29 are carried out on different processors. For example, the control function of the parking brake control module 29 on the first processor 47 and the control function of the axis control module 25 on the second processor 49 are executed.

In addition, the control function of the central control module 17 (not shown) can also be carried out on the second processor 49 or on another processor (not shown).

All mentioned in the foregoing description and in the claims characteristics can be combined both individually and in any combination with the features of the independent claims. The disclosure of the invention is therefore not limited to the described or claimed feature combinations. Rather, all in the context of the invention meaningful combinations of features are to be regarded as disclosed.

Claims

claims

1. Control device for a compressed air-operated brake system (1, 1 ') of a vehicle, in particular a commercial vehicle, wherein the control device (23, 23', 23 ") has a Achssteuermodul (25) with a control function for controlling a pneumatic pressure to provide a service brake function .

characterized in that

the control unit (23, 23 ', 23 ") additionally has a vehicle dynamics sensor unit (27) with at least one acceleration and / or yaw rate sensor which serves for vehicle dynamics control of the vehicle.

2. Control device according to claim 1,

characterized in that

the control unit (23, 23 ") additionally has a parking brake control module (29) with a control function for detecting the vehicle.

3. Control device according to claim 2,

characterized in that

the control device (23, 23 ") has a plurality of processors (47, 49) and the control function of the axle control module (25) and the control function of the parking brake control module (29) are each executable by means of different processors (47, 49), the processors (47, 49) are independently operable.

4. Control device according to one of the preceding claims,

characterized in that

the control unit (23) has a data connection between the parking brake control module (29) and a central control module (17), wherein an electronic brake system (1, 1 ') can be controlled or regulated and monitored by means of a control function of the central control module (17).

5. Control device according to one of claims 1 to 3,

characterized in that the control unit additionally has a central control module (17) with a control function, wherein an electronic brake system can be controlled or regulated and monitored by means of the control function of the central control module (17).

6. Control device according to one of claims 2 to 5,

characterized in that

the vehicle can be detected by the control function of the parking brake control module (29) by means of an electro-pneumatic parking brake.

7. Control device according to one of the preceding claims,

characterized in that

the control functions having modules (25, 27, 29) in a common housing of the control device (23, 23 ', 23 ") are arranged.

8. brake system with a control device (23, 23 ', 23 ") according to one of claims 1 to 7.

9. Braking system according to claim 8,

characterized in that

the brake system (1, V) has a brake value transmitter (19), from which only electrical brake request signals can be provided or from which in addition to electrical brake request signals exclusively for the front axle (5) pneumatic brake request signals can be provided.

10. Braking system according to one of claims 8 or 9,

characterized in that

the brake system (1, 1 ') has a brake value transmitter (19) for generating a brake request signal and the brake value transmitter (19) is connected directly or indirectly to the parking brake control module (29) for establishing a data connection (30, 42) and the brake request signal is via this data link (30, 42) is transferable.

11. Brake system according to claim 10, characterized in that

the data connection (30, 42) comprises a LIN bus and / or a CAN bus and / or that a PWM signal can be transmitted via the data connection.

12. Brake system according to one of claims 10 or 11,

characterized in that

the brake system (1, 1 ') has an electric parking brake signal generator (31) for providing a desired braking value for detecting the vehicle, wherein for establishing the data connection (30, 42) the brake value transmitter (19) is indirectly connected to the parking brake control module (29) via the parking brake signal transmitter (29). 31) is connected.

13. Brake system according to one of claims 10 or 11,

characterized in that

the braking system (1, 1 ') has an electric parking brake signal generator (31) for providing a desired braking value for detecting the vehicle, wherein for establishing the data connection (30, 42) the parking brake signal generator (31) with the parking brake control module (29) indirectly via the brake value transmitter ( 19) is connected.

14. Braking system according to one of claims 8 to 13,

characterized in that

the brake system (1, Γ) in addition to a first power supply (33) has at least one further second power supply (45) independent of the first power supply.

15. Vehicle with a brake system (1, 1 ') according to one of claims 8 to 14.