KR20190020754A - Method and apparatus for operating a brake system, brake system - Google Patents

Abstract

The present invention relates to a hydraulic system comprising at least one hydraulically operable wheel brake (2); A brake pedal device (3) having an operable brake pedal (7) for predefining a set braking torque; And a pressure generator (15) electrically driven according to a set braking torque to generate a hydraulic pressure, wherein the pressure generator (15) The electrical operating current is limited to a first limit value that can be preset in the normal operating mode. A configuration is proposed in which the brake pedal apparatus 3 is monitored for the type of operation of the brake pedal 7 and the limitation of the operating current is released upon detection of the high dynamic operation of the brake pedal 7. [

Description

Method and apparatus for operating a brake system, brake system

The present invention relates to a hydraulic system comprising at least one hydraulically operable wheel brake; A brake pedal device having an operable brake pedal for predefining a set braking torque; And a pressure generator electrically driven in accordance with the set braking torque to generate the hydraulic pressure, wherein the electric actuating current of the pressure generator is controlled in advance in a normal operation mode, Is limited to the first limit value that can be set.

The invention also relates to a device for carrying out the method as described above and to a brake system with such a device.

Methods, apparatus and brake systems of the type mentioned in the preamble are already known in the prior art. In the conventional brake system, a vacuum braking force amplifier is used in the brake pedal apparatus to amplify the braking force applied to the brake pedal by the driver and to introduce the braking force into the hydraulic circuit of the brake system, while a vacuum braking force amplifier A brake system is also known in which an electrically actuated pressure generator is used instead of omitting it. Such a pressure generator generates hydraulic pressure without having to be mechanically coupled to the brake pedal. Rather, the operation of the brake pedal is detected and monitored by one or a plurality of sensors, and the pressure generator is driven according to the brake pedal operation. The pressure generator is, for example, a pump to which an electric motor is assigned to set the pressure in the brake system electro-hydraulic. In this case, the pressure generator is driven such that the set braking torque required by the brake pedal operation by the driver is set in one or a plurality of wheel brakes of the braking system, so as to decelerate the automobile.

In order to prevent overheating of the pressure generator or overheating of the electric motor of the pressure generator, the electric motor is configured such that the torque and thus the operating current are limited to the first limit value when the number of revolutions is low.

The method according to the invention with the features of claim 1 has the advantage that the brake pedal device is monitored for the type of operation of the brake pedal and the limitation of the operating current upon detection of the high dynamic operation is released. The method according to the present invention has the advantage that a desired braking torque can be provided to the driver in a short period of time in the high dynamic braking process, but in this case it is ensured that the overheating of the pressure generator, in particular the overheat of the motor of the pressure generator, is permanently prevented do. By releasing the restriction for the high dynamic braking process, the user can inquire the braking torque within a short time during the high dynamic braking process. Since the high dynamic braking process is not long-lasting, but rather is characterized by a short time in particular, the motor overheating due to the motor load that rises for a short time is almost eliminated.

According to a preferred embodiment of the present invention, it is proposed that when the detected brake pedal operation speed exceeds a preset second threshold value, it is recognized as a high dynamic operation. To this end, the operating speed of the brake pedal is monitored in a preferred manner and compared with a second limit value. When the detected speed exceeds the second limit value, the limitation of the above-mentioned operating current is released. The operating speed of the brake pedal is determined by the path sensor assigned to the brake pedal in particular. Through a simple differentiation of the path signal over time, the kinetic speed of the brake pedal can be calculated, and as a result, within a short period of time, the detected braking process or whether the detected brake pedal operation is a high dynamic operation or a normal operation Can be determined.

Further, preferably, it is proposed that if the detected brake pedal travel exceeds a preset third threshold value, a high dynamic actuation is recognized. Particularly, in this case, the brake pedal travel is compared with the third threshold regardless of the consideration of the brake pedal operation speed. The third limit value is selected so as to prevent, in particular, a situation in which a brake pedal operation requiring only a small braking torque, although being performed at a high speed, is not detected as a high dynamic brake pedal operation.

Furthermore, preferably, it is proposed that the first limit value is preset according to the operating temperature of the pressure generator. This has the advantage that the dynamic drive of the pressure generator, which depends on the current operating temperature of the pressure generator, is performed. In particular, the current operating temperature is compared with the maximum permissible operating temperature to determine whether this temperature may continue to rise. Correspondingly, by changing the first limit value, it is surely prevented that the limit temperature is exceeded. In this case, it is assumed that the high dynamic braking process raises the operating temperature only for a short time, and thus only negligible.

According to a preferred improvement, it is also proposed that the limitation of the operating current by the first limit value is carried out only when the revolution number is below the fourth limit value. Therefore, in particular, when the rotation speed is low, the torque for driving the pressure generator is high, so that a high operating current is generated, which induces heating of the pressure generator, in particular, heating of the motor of the pressure generator. However, if the pressure generator operates within a range of rotational speeds with a high number of revolutions requiring a high operating current likewise, a low torque is required due to the high number of revolutions, resulting in less heating and, in this respect, Limitation to the limit value of 1 may be omitted.

Particularly, it is proposed that the first limit value is preset according to the allowable operating temperature of the pressure generator during the long-time braking. In this case, the first limit value is particularly fixed and not dynamically preset, and corresponds to an operating current which may occur at maximum in the long time without the operating temperature of the pressure generator exceeding the threshold value.

According to a preferred refinement of the present invention, it is proposed that the brake pedal device generates a status message according to the type of brake pedal operation detected and sends it to the control device which drives the pressure generator. Thereby, the brake pedal device itself transmits information on whether or not the high dynamic brake pedal operation has been performed to the control device, and the control device then drives the pressure generator in accordance with the information, and the limit by the first limit value Or set it.

An apparatus according to the invention having the features of claim 8 is characterized in that it comprises a control device specially configured to carry out the method according to the invention when used in accordance with the regulations. In this case, the advantages already mentioned are derived.

A brake system according to the present invention having the features of claim 9 is characterized by including a device according to the present invention. This leads to the advantages already mentioned above.

Further advantages and desirable features and combinations of features are set forth in particular above and in the appended claims.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

1 is a schematic view of a hydraulic brake system of a motor vehicle.
2 is a flow chart illustrating a preferred method for operating the brake system.

1 schematically shows a brake system 1 for a motor vehicle which is not shown in detail in this figure. The brake system 1 has a plurality of wheel brakes 2, which can be operated by the vehicle operator as an operating brake by means of the brake pedal device 3. Here, the wheel brake 2 is indicated as LR, RF, LF and RR, through which the position of the wheel brake or the assignment in the vehicle is explained, in which case LR indicates the left rear, LF indicates the left front, and RR indicates the rear right. Two brake circuits 4 and 5 are formed between the brake pedal device 3 and the wheel brake 2. In this case, the brake circuit 4 is assigned to the wheel brakes LF and RR, Are assigned to the wheel brakes LR and RF. As the two braking circuits 4 and 5 are configured identically, the structure of the two braking circuits 4 and 5 will be described in more detail below with reference to the braking circuit 4. [

The brake circuit 4 is first connected to the brake master cylinder 6 of the brake pedal apparatus 3 and in this case the brake master cylinder 6 is mainly formed as a double piston cylinder or tandem cylinder, The brake pedal device 3 also has a brake pedal 7 operable by the driver. The brake circuit (4) has a switching valve (8) following the brake master cylinder (6). The switching valve 8 is normally open and allows the flow of the hydraulic medium of the braking circuit, i. E. The flow of the braking fluid in both directions. The switch valve 8 is also connected to the two wheel brakes 2 under the presence of a respective one of the intake valves 10, which are normally open bi-directionally open. The wheel brake 2 of the braking circuit 4 is further provided with one discharge valve 11, which is formed in a normally closed state. The discharge valve 11 is connected to the hydraulic tank 9 at the discharge side, and the hydraulic tank supplies the hydraulic medium to the brake master cylinder 6. The discharge valve 11 on the discharge side is also connected to the suction side of the pump 13 and the suction side of the pump is connected to the braking circuit 4 between the switching valve 8 and the suction valve 10 on the discharge side. The pump 13 is principally formed as a piston pump and is mechanically coupled to the motor 14 in which case the pump 13 and the motor 14 together form the pressure generator 15 of the brake system 1. A configuration is proposed in which the electric motor 14 is assigned to the pump 13 of the two brake circuits 4 and 5. Alternatively, a configuration may also be proposed in which each of the braking circuits 4, 5 has its own electric motor 14. The brake master cylinder 6 is also assigned a hydraulic pedal feel simulator 12.

When the two switching valves 8 of the braking circuits 4 and 5 are closed, the hydraulic pressure in the section of the braking circuits 4 and 5 lying behind the switching valve 8, that is, the hydraulic pressure between the switching valve and the wheel brake 2, Or when the brake pedal 7 is relieved of the load by the driver. The pressure generator 15 is driven to amplify the braking force so that the hydraulic pressure is further raised in the brake system 1 by the pressure generator 15 in addition to the operation of the brake pedal 7, So that a high braking torque can be generated.

Figure 2 shows a simplified flow diagram for illustrating a preferred method for operating the brake system. By the operation of the brake pedal 7 of the braking device 3, the method starts in the first step S1. In the following inquiry step S2, it is checked whether or not the brake pedal operation is a high dynamic brake pedal operation. To this end, the operating speed and operating path of the brake pedal 7 are detected and compared with one limit value, respectively. If the detected brake pedal travel exceeds the associated threshold value and the operating speed is higher than the corresponding threshold value, it is recognized that a high dynamic braking operation is performed (Yes). However, if the operating speed is lower / lower than the threshold value, or if the brake pedal is not actuated beyond the pedal travel allowed by the associated limit value, then the high dynamic brake pedal actuation is recognized as not present (NO) ). In this step, the operating current for the pressure generator 15 is limited to the first limit value allowed.

It is proposed that in order to prevent overheating of the pressure generator 15 or overheating of the motor of the pressure generator 15, the operating current of the pressure generator in the normal operating mode is limited by the first limit value. This will be described in more detail with reference to the method shown in Fig.

By the limited operating current as described above, the pressure generator 15 is then driven to generate the hydraulic pressure in step "S4 ". However, in step S2, when the brake pedal operation is recognized as a high dynamic brake pedal operation (YES), the process proceeds from step S2 to step S4, so that the limitation of the operating current is not performed or released. As a result, an increased operating current can be supplied to the pressure generator 15 during the high dynamic braking process, so that the pressure generator can use a high torque even at a low rotation speed. As a result, Hydraulic pressure is formed in time. It is ensured that the operating temperature is not exceeded in the normal operating mode by the limit being released only for the high dynamic braking process. In the high dynamic braking process, the thermal load depends on the level and duration of the operating current. Since the operating current is high only for a short time during high dynamic braking, the adverse effect on operating temperature for such a short period of time can be neglected, especially when the number of revolutions is still low. Correspondingly, an increase in the operating current exceeding the first threshold value is allowed in a preferred manner by the method described above. As a result, in the high dynamic braking process, the torque of the electric motor 14 is increased as in the normal braking process. In this case, the accurate level or torque increase depends on the motor design and the current limit imposed.

3 shows the relationship between the torque characteristic curve of the electric motor 14 of the pressure generator 15 and the torque characteristic curve for the rotational speed n in the normal operation mode K1 and the high dynamic braking process K2, (M _d ). Here, in the high dynamic braking process, it is understood that the higher curves K1 and K2 are superimposed on each other at a higher revolution speed over 2000 revolutions while a higher torque is allowed than when the revolution is lower.

Claims (9)

A method for operating a hydraulic brake system (1) of an automobile, the hydraulic brake system comprising: at least one hydraulically operable wheel brake (2); A brake pedal device (3) having an operable brake pedal (7) for predefining a set braking torque; And a pressure generator (15) electrically driven according to a set braking torque to generate a hydraulic pressure, wherein the operating current of the pressure generator (15) is limited to a first limit value that can be preset in a normal operating mode, A method of operating a brake system,
Characterized in that the brake pedal device (3) is monitored for the type of operation of the brake pedal (7) and the limitation of the operating current is released upon detection of a high dynamic actuation of the brake pedal (7) Way. The method according to claim 1, characterized in that it is recognized as a high dynamic operation when the detected brake pedal operation speed exceeds a preset second threshold value. 3. A method as claimed in claim 1 or 2, characterized in that it is recognized as a high dynamic operation if the detected brake pedal travel exceeds a preset third threshold value. 4. A method according to any one of claims 1 to 3, characterized in that the first limit value is preset according to the operating temperature of the pressure generator. 5. A method according to any one of claims 1 to 4, characterized in that the limitation by the first limit value is carried out only when the rotation number is below the fourth limit value. 6. A method according to any one of claims 1 to 5, characterized in that the first limit value is preset according to the permissible operating temperature of the pressure generator (15) during the long braking time. 7. A method according to any one of claims 1 to 6, characterized in that the brake pedal device (3) generates a status message according to the type of brake pedal operation detected and transmits it to the control device driving the pressure generator (15) Characterized in that the hydraulic brake system of the vehicle is operated. The brake system (1) comprises at least one wheel brake (2); A brake pedal device (3) having an operable brake pedal (7) for predefining a set braking torque; And at least one pressure generator (15) for hydraulic operation of the wheel brake (2), wherein the pressure generator (15) is driven according to the operation of the brake pedal The apparatus comprising:
An apparatus for operating a brake system of a motor vehicle, comprising a control device, which is configured to perform the method according to one or more of claims 1 to 7 when used in accordance with the regulations. At least one wheel brake (2); A brake pedal device 3; A brake system (1) for an automobile comprising at least one pressure generator (15) for hydraulic operation of a wheel brake (2), the pressure generator (15) being driven in accordance with the operation of a brake pedal (7)
An automotive brake system (1) comprising an apparatus according to claim 8.

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