EP4259497A1 - Method for emergency engagement of a holding brake, and electropneumatic brake system - Google Patents

Abstract

A method for emergency engagement of a holding brake (PB) of a vehicle (FG), wherein - a service brake system (SBS) with service brake (SB) and a holding brake system (PBS) with the holding brake (PB) are constituent parts of an electropneumatic brake system (10), - the holding brake system (PBS) has spring brake cylinders, - the service brake system (SBS) comprises a service brake control unit (ECU) for actuating components (AMV, AMH) of the service brake (SB), - at least one brake circuit (BK1, BK2, BK3) for the service brake (SB) and the holding brake (PB) is provided, wherein the brake circuits (BK1, BK2, BK3) for service brake (SB) and holding brake (PB) may also be separate, and - the spring brake cylinders can be ventilated if a supply pressure (RP1, RP2) in at least one brake circuit (BK1, BK2) for the service brake (SB) falls, and wherein the service brake control unit (ECU) effects a lowering of the supply pressure (RP1, RP2) in at least one brake circuit (BK1, BK2) for the service brake (SB) in program-controlled fashion under defined conditions.

Description

Procedure for emergency application of a parking brake and electropneumatic

braking system

The invention relates to a method according to the preamble of claim 1 .

In particular, it is about a method for emergency engagement of a parking brake of a vehicle, wherein

- a service braking system with a service brake and a parking braking system with the parking brake are components of an electropneumatic braking system,

- the parking brake system has spring brake cylinders,

- the service brake system includes a service brake control unit for controlling components of the service brake,

- at least one brake circuit is provided for the service brake and the parking brake, it also being possible for the brake circuits for the service brake and the parking brake to be separate, and

- The spring-loaded brake cylinders can be vented when a reservoir pressure drops in at least one brake circuit for the service brake.

Modern commercial vehicles have an electropneumatic braking system.

Part of the braking system are spring-loaded brakes as parking brakes. These are also known as parking brakes. The parking brakes work

Spring force and can be released by venting spring brake cylinders or locked by venting.

Within the service braking system, valves are used to control the

Electronically controlled service brake pressure. The valves can be provided in so-called axle modulators or outside of them. The parking brakes are also electronically controlled. Actuating a solenoid valve regulates the ventilation or venting of the spring-loaded brake cylinders. For safety reasons, the solenoid valve must always assume a clear switching position, which must be maintained if the power supply fails. The solenoid valve is therefore designed as a bistable solenoid valve.

The spring-loaded brake cylinders can be combined with service brake cylinders, so that the spring-loaded brake and service brake act on the same brake pistons. Suitable design measures can be taken to avoid mechanical overloading of the brake pistons due to the addition of braking forces from the service brakes and the spring-loaded brakes. If the service brakes are actuated while the parking brakes are in effect, the spring-loaded brake cylinders are also pressurized to prevent the braking forces from being added together.

In some markets, for safety reasons, the spring-loaded brake cylinders are vented if the reservoir pressure in the service brake system drops. Service brake and parking brake can be assigned to different brake circuits. When different brake circuits are assigned, a so-called bleed-back function is used in part to ensure that a reservoir pressure drop in the brake circuit for the service brake also bleeds the brake circuit for the spring-loaded brake. In some countries, the service brake and parking brake do not have to have separate brake circuits. The brake circuit for the parking brake is then also the brake circuit for the service brake, so that if the reservoir pressure drops in the brake circuit, the spring brake cylinders are vented anyway.

The parking brake must be able to be engaged by the driver. In the event of a fault, the driver is required to bleed the spring-loaded brake cylinders and thus activate the parking brake by deliberately reducing the reservoir pressure in the brake circuit for the service brake. To do this, the driver brakes the vehicle with the service brake, switches off the engine so that the compressed air supply is interrupted, and then actuates the service brake several times. As a result, the brake circuit for the service brake is gradually vented. As a result, the spring brake cylinders are also vented. The process described requires the attention and timely intervention of the driver.

The object of the present invention is to create a method for emergency application of a parking brake, independently of driver intervention.

To solve the problem, the method according to the invention has the features of claim 1. In particular, under defined conditions, the service brake control unit brings about, under program control, a reduction in the reservoir pressure in at least one brake circuit for the service brake. The defined conditions are stored in the program of the service brake control unit and can be adapted there to different conditions, for example by installing new software or by updating the same. The spring-loaded brake cylinders are also vented as a result of the reduction in reservoir pressure in the brake circuit for the service brake. The reservoir pressure is reduced to such an extent that the spring-loaded brakes are effective. The procedure does not depend on the attention and intervention of the driver. The driver should only bring the vehicle to a standstill.

According to a further idea of the invention, it can be provided that several brake circuits are provided for the service brake and the service brake control unit brings about a reduction in the reservoir pressure in only one brake circuit for the service brake. Preferably, the reservoir pressure is maintained in brake circuits on other axles. It is then possible to pressurize the spring brake cylinder again more quickly. The service brake can also continue to be used. Advantageously, the reservoir pressure in a brake circuit is lowered with controllable valves that are particularly well suited for venting the brake circuit. In particular, the reservoir pressure is lowered in a brake circuit for a front axle. However, it is also possible to use a brake circuit for a rear axle, particularly when if a greater braking effect can be achieved on the front axle and the service brake should continue to be used there.

According to a further idea of the invention, it can be provided that the service brake control unit brings about a reduction in the reservoir pressure in all brake circuits for the service brake. This ensures that the spring brake cylinders are vented to a particularly high degree.

According to a further idea of the invention, it can be provided that the service brake control unit brings about a reduction in the reservoir pressure in at least one brake circuit for the service brake after at least one of the following conditions occurs: a) the service brake control unit detects a fault in the parking brake system, b) due to defined boundary conditions, c) after actuation of a separate control element, d) after actuation of a brake pedal for the service brake in combination with a detected fault in the parking brake system, e) due to a dedicated signal from an additional electronic control unit.

The detection of a fault in the parking brake system can result from a wide variety of events. The defined boundary conditions under which the reservoir pressure in the brake circuit for the service brake is lowered can also be of many kinds. A separate control element can be provided in the vehicle/driver's cab as a separate control element, which must also be actuated, for example after a program-controlled warning signal has been emitted and/or a program-controlled reduction in vehicle speed to a standstill. To improve safety, the detection of the fault in the parking brake system can also be combined with the actuation of a brake pedal for the service brake as the triggering condition for the reduction in the reservoir pressure in the brake circuit for the service brake. Finally, the reservoir pressure in the brake circuit for the service brake can also be lowered on the basis of the dedicated signal from an additional electronic control unit. At the control unit It can be an electronic control unit of the braking system or external to the braking system.

According to a further idea of the invention, it can be provided that the service brake control unit detects an error in the parking brake system because at least one of the following events has occurred: aa) the service brake control unit has received an error message

Parking brake control unit before, ab) the service brake control unit has an expected signal from the parking brake control unit not present, ac) the service brake control unit detects a failure of signals on a connected CAN bus.

The parking brake control unit can be configured in such a way that the transmission of an error message to the service brake control unit is possible. The parking brake control unit can be configured in such a way that signals are transmitted directly or indirectly to the service brake control unit cyclically or at predetermined times or as a function of events. Accordingly, the service brake control unit can expect a signal. If this does not happen, the service brake control unit determines that there is a fault in the parking brake system. Signals can also fail if a connected CAN bus no longer transmits any signals. In particular, there is then a so-called CAN timeout.

According to a further idea of the invention, it can be provided that for the reduction of the reservoir pressure in the brake circuit for the service brake, on the basis of defined boundary conditions, at least one of the following boundary conditions must be met; ba) dedicated emergency parking signal from a virtual driver, bb) general parking request from a virtual driver to the braking system, in combination with a detected standstill of the vehicle, bc) general parking request from a virtual driver to the braking system, in combination with a detected error in the parking brake system, bd) general parking request from a virtual driver to the electronic braking system, in combination with non-active compressed air supply.

A virtual driver is intended here to be a program-controlled automation that takes over part or all of the control of vehicle functions, corresponding to automation levels 2 to 5. The parking request by the virtual driver is preferably a CAN signal or another electrical signal.

According to a further idea of the invention, it can be provided that the service brake control unit deactivates compressed air delivery into the brake circuits. The aim is to avoid the possibility of a pressure increase in the brake circuit for the service brake. Compressed air can be fed back into the brake circuit by generating compressed air using a compressor or by supplying compressed air from a compressed air reservoir. The supply of compressed air is preferably stopped by shutting down the compressor. However, it is also possible to switch off the compressor indirectly by shutting off the compressed air supply via a program-controlled switchable valve. After reaching a pressure limit, the compressor switches off automatically. A program-controlled valve can also shut off the supply of compressed air from a compressed air supply.

According to a further idea of the invention, it can be provided that the service brake control unit brings about the lowering of the reservoir pressure in at least one of the brake circuits for the service brake by actuating the service brake. This means that the reservoir pressure in the brake circuit is lowered by the particular multiple actuation of the service brake, ie preferably by multiple pressurizing and venting of brake cylinders of the service brake.

According to a further idea of the invention, it can be provided that the service brake control unit causes the reservoir pressure to be reduced in at least one of the brake circuits for the service brake by actuating the service brake if the electronic brake system detects a standstill of the vehicle or a fault in the parking brake system and a brake pedal for the service brake is fully actuated for a defined minimum period of time. the Accordingly, the service brake control unit takes into account two secondary conditions. On the one hand, the driver must fully actuate the brake pedal for the service brake for a minimum period of time. The minimum period of time is preferably between three and ten seconds or is greater than five seconds. As a second secondary condition, the electronic brake system must detect a standstill of the vehicle or a fault in the parking brake system. In this way, when the vehicle is stationary, the parking brake can be engaged simply by pressing the brake pedal. If there is a fault in the parking brake system, rapid braking is required anyway.

According to a further idea of the invention, it can be provided that the reservoir pressure in at least one of the brake circuits for the service brake is lowered by venting via a valve in the service brake system. It is then not necessary to actuate the service brake, but it can remain possible. A separate valve or a valve that is provided in any case can be used for venting. The latter saves additional effort. If a separate valve is only used for this purpose, functional collisions can be safely avoided. Valve devices, which in turn have a plurality of valves, such as inlet valves and outlet valves, are also considered valves for venting.

According to a further idea of the invention, it can be provided that the reservoir pressure in at least one of the brake circuits for the service brake is lowered by venting via a valve for controlling a blocking prevention. It is preferably a so-called ABS solenoid valve, via which the brake pressure in the brake cylinders of the service brake can be reduced. Such valves can also be integrated into a so-called axle modulator.

According to a further idea of the invention, provision can be made for the reservoir pressure to be reduced in at least one of the brake circuits for the service brake via valves with an above-average nominal diameter, based on all the valves present in the service brake system. The nominal size is advantageously 8-12 mm, 9-11 mm or 10 mm and refers in particular to vent outlets of the valves. It is preferably the valves already mentioned for controlling the blocking prevention, in particular on a front axle of the vehicle. The ABS valves are intended to ensure rapid pressure reduction if the wheels are about to lock and therefore have a relatively large nominal width. This circumstance is used to advantage for venting the reservoir pressure in the brake circuit of the service brake.

According to a further idea of the invention, it can be provided that parallel to the lowering of the reservoir pressure in at least one of the brake circuits for the service brake, at least part of the service brake system is activated for braking, in particular another brake circuit. This allows the vehicle to be secured or braked until the parking brake becomes effective. In particular, a sufficiently high braking effect should always be ensured.

According to a further idea of the invention, it can be provided that at least part of the service brake system is or is still activated for braking, and that the service brake system is then vented via at least one valve in order to reduce the reservoir pressure in at least one of the brake circuits for the service brake, and in doing so At least one other valve holds back a brake pressure in at least one service brake cylinder, so that this brake cylinder is not vented. This means that the vehicle can be held securely even if the spring-loaded brakes are not yet effective.

Advantageously, the brake pressure is retained in the service brake cylinder by targeted activation of the aforementioned ABS valve. The brake pressure is preferably held back in all the service brake cylinders of an axle or axle group, while the service brake cylinders of another axle are vented. In many countries, it is customary and mandatory to divide the brake circuit for the service brake into two or more sub-brake circuits, at least with one sub-brake circuit for the front axle and another sub-brake circuit for the rear axle. A separation according to partial brake circuits is then advantageous, so that the Service brake cylinders of a sub-brake circuit are vented while the service brake cylinders of the other sub-brake circuit remain ventilated.

According to a further idea of the invention, it can be provided that the service brake system is vented via at least one valve on a front axle in order to reduce the reservoir pressure in at least one of the brake circuits for the service brake, and a brake pressure is retained in at least one service brake cylinder on at least one valve of a rear axle , so that this brake cylinder is not vented. This division is advantageous for the braking behavior of the vehicle. The brake pressure is preferably held back in all service brake cylinders of the rear axle.

According to a further idea of the invention, it can be provided that the reservoir pressure in at least one of the brake circuits for the service brake is reduced in a pulsed manner, namely by alternating pressurization and venting of service brake cylinders. In particular, the service brake cylinders are pressurized and vented alternately by actuating corresponding inlet valves and outlet valves.

According to a further idea of the invention, it can be provided that the reservoir pressure is reduced continuously in at least one of the brake circuits for the service brake. This embodiment is particularly advantageous since the vehicle standstill is better safeguarded by a permanent braking effect while the reservoir pressure is being reduced.

The invention also relates to an electropneumatic brake system with the features of claim 18. The brake system is intended for a vehicle and has a service brake system with a service brake control unit for controlling components of a service brake, a brake circuit for the service brake, a parking brake system with a parking brake and a spring brake cylinder , The spring-loaded cylinders are vented due to the system when a reservoir pressure drops in at least one of the brake circuits for the service brake. In particular, points the service brake control unit has software for performing the method according to one of claims 1 to 17, so that the service brake control unit can programmatically lower the reservoir pressure in at least one of the brake circuits for the service brake under defined conditions.

According to a further idea of the invention, it can be provided that compressed air delivery into the brake circuits can be deactivated by the service brake control unit. The service brake control unit can influence the delivery of the compressed air, in particular by switching off a compressor or by shutting it off via a correspondingly controllable valve.

According to a further idea of the invention, it can be provided that the service brake control unit in conjunction with an actuation of the brake pedal for the service brake can be used to vent a brake circuit for the parking brake if the electronic braking system detects that the vehicle is stationary or a fault in the parking brake system is detected and the brake pedal for the service brake is fully actuated for a defined minimum period of time. The brake system can have separate brake circuits or partial brake circuits for the service brake and the parking brake. A common brake circuit for the parking brake and the service brake can also be provided.

According to a further idea of the invention, at least the brake circuit for the service brake can be vented by activating a separate valve with simultaneous activation of the service brake. While braking with the service brake, the brake circuit is vented via the separate valve.

According to a further idea of the invention, the separate valve can be connected to the service brake system. The separate valve is preferably connected to the brake circuit for the service brake. According to a further idea of the invention, at least one valve in the brake circuit for the service brake can be activated to bleed at least one of a plurality of existing brake circuits. If there are several brake circuits, the spring-actuated brake cylinders can be vented by a known bleed-back function. If there is only one brake circuit, the venting takes place within this brake circuit.

According to a further idea of the invention, the parking brake system can have a relay valve with pilot control unit and check valve for electropneumatic actuation of the parking brake, with an input of the pilot control unit being connected to an input of the relay valve via the check valve. This ensures the desired ventilation.

According to a further idea of the invention, a connection from the inlet of the pilot valve to the check valve can be connected to a connection to a brake circuit for the service brake. The desired venting then takes place in the connection to the brake circuit for the service brake.

According to a further idea of the invention, it can be provided that the service brake system and the parking brake system are electrically independent of one another, so that braking by actuating the service brake system remains possible in the event of an electrical failure of the parking brake system. This configuration is particularly fail-safe. In particular, a separate power supply is provided for the service brake system.

According to a further idea of the invention, a separate operating element with a connection to the service brake control unit and specifically for triggering the program-controlled reduction in the reservoir pressure in at least one of the brake circuits for the service brake can be provided. A program-controlled sequence of the desired pressure reduction can be initiated by the operating element. The subject matter of the invention is also a service brake control unit according to claim 26, in particular with software for carrying out the method according to one of claims 1 to 17.

Finally, the subject matter of the invention is also a vehicle according to claim 29, in particular with a braking system according to one of claims 18 to 27.

Further features of the invention emerge from the rest of the description and from the drawings. Show it:

1 shows a schematic representation of an electropneumatic braking system for a vehicle,

2 shows a circuit diagram with electropneumatic components of a parking brake system,

3 shows a valve arrangement within a service brake system,

4 shows a structural representation of the electropneumatic braking system, FIG. 5 shows a simplified schematic representation of a vehicle with the braking system according to FIG. 1 ,

6 shows a simplified representation of a logic for condition checking in the brake system,

7 shows a simplified representation of a brake pressure after actuation of a brake pedal in connection with a vehicle speed,

8 shows a simplified representation of a brake pressure profile for lowering a reservoir pressure in a brake circuit.

According to the exemplary embodiment of FIGS. 1, 4 and 5, an electropneumatic brake system 10 for a vehicle FG, in particular for a truck, has an electronic brake control unit ECU, which here has the function of a service brake control unit, and an axle modulator AMV via signal lines 11, 12 controls for a front axle AXV and an axle modulator AMH for a rear axle AXH. The brake control unit ECU is also connected to a vehicle data bus 14 via a signal line 13 . Vehicle data bus 14 is preferably a CAN bus or another vehicle-specific data bus, via which electronic devices in vehicle FG can exchange information and instructions. Accordingly, the signal lines 11-13 are preferably CAN connections, with or without a power supply.

The brake control unit ECU is connected via electrical lines 15, 16, 17 to a brake pedal BP and two solenoid valves MV. The solenoid valves MV are so-called ABS valves here.

The axle modulator AMH for the rear axle AXH is part of a first brake circuit BK1 and receives reservoir pressure RP1 from a storage tank V1 via pneumatic lines 18, 19. Due to the specifications of the brake control unit ECU, a brake pressure is generated in the axle modulator AMH and fed via lines 20, 21 to combination brake cylinders KBZ . In the combination brake cylinders KBZ, a spring-loaded brake cylinder FZ of a parking brake PB and a service brake cylinder BZ of a service brake SB are combined in one unit in a known manner.

The lines 20, 21 supply the service brake cylinders BZ in the combination brake cylinders KBZ with brake pressure. The axle modulator AMH is designed here with two channels, so that the brake pressure in the lines 20, 21 can be different. The AMH axle modulator also includes valve arrangements for the anti-lock function.

The axle modulator AMV is part of a second brake circuit BK2 and is supplied with supply pressure RP2 from a supply tank V2 via a line 22 . A brake pressure is generated in the AMV axle modulator according to the actuation by the brake control unit ECU, which is fed to service brake cylinders BZ via lines 23, 24, 25, 26 and the solenoid valves MV. The AMV axle modulator is a single-channel system here, so that lines 23, 25 equal brake pressures are controlled. The braking pressures can be differentiated via the solenoid valves MV, in particular to prevent blocking.

Wheel speed sensors S are connected to the axle modulators AMH and AMV via lines 27, 28, 29, 30, so that current information about the actual wheel speeds is always available.

A brake pedal BP is arranged in a driver's cab, not shown, and is operated by the driver. The brake pedal BP is connected to the storage tank V1 and to the storage tank V2. By actuating the brake pedal BP, control pressure is supplied to the axle modulators AMH, AMV via pneumatic control lines 31 , 32 .

The parts described so far are components of a service brake system SBS, which is a subsystem of the electropneumatic brake system 10, see in particular Fig. 4.

Another sub-system is a parking brake system PBS. This is also referred to as an electronic handbrake. Its main component EPH has an electropneumatic valve arrangement VA with a brake control unit PCU. The brake control unit PCU is connected to an operating device PX for a parking brake PB via an electrical line 33 . Like the brake pedal BP, the operating device PX is arranged in a driver's cab, which is not shown.

The brake control unit PCU is connected to the data bus 14 via a signal line 34 . The signal line 34 is also preferably a CAN connection. The valve arrangement VA is part of a third brake circuit BK3 and is supplied with supply pressure RP3 from a supply tank V3 via a pneumatic line 35 .

The task of the brake control unit PCU is to control the ventilation and venting of the spring-loaded brake cylinders FZ in the combination brake cylinders KBZ. For this are the Combination brake cylinder KBZ via pneumatic lines 36, 37 connected to the valve assembly VA. In addition, brake pressure from the axle modulator AMH for the rear axle AXH is supplied to the valve arrangement VA via a pneumatic control line 38 as control pressure, see also connection point 39 between the lines 20, 38.

The three brake circuits BK1, BK2, BK3 (with the respective storage tanks V1, V2, V3) are preferably connected to one another according to FIG Pressure drop in one of the other brake circuits. However, what is known as a bleed-back function is provided in a known manner from the third brake circuit BK3 to at least one of the other two brake circuits BK1, BK2. This ensures that a sharp pressure drop in the first brake circuit BK1 or second brake circuit BK2 also causes a pressure drop in the third brake circuit BK3, so that the spring brake cylinders FZ are vented.

Alternatively, the brake circuits BK1, BK2, BK3 can also be partial brake circuits of a single larger brake circuit. Accordingly, only reservoir pressure is then supplied via a reservoir (not shown).

The braking system 10 is provided for a motor vehicle and contains additional components for connecting a trailer braking system. For reasons of clarity, these components are not shown here. The same applies to possible further brake circuits for other consumers or pneumatic devices.

The valve arrangement VA of the parking brake system PBS is explained in more detail below with reference to FIG.

A pneumatic relay valve 40 is supplied with reservoir pressure RP3 from V3 via line 35 and an internal line 41 . On the output side, the relay valve 40 feeds a internal line 42 with connection 43 to the lines 36, 37, which lead to the spring brake cylinders FZ.

To control the relay valve 40, a pilot control unit 44 is provided, which is designed here as an electromagnetically controllable 3/2-way valve and has an input 45, output 46 and venting output 47. In Fig. 2, the relay valve 40 is shown in the venting position or blocking position, in which the outlet 46 and vent outlet 47 are connected to one another. In an open position, not shown, the input 45 and output 46 are connected to one another, so that control pressure can be supplied to a control input 49 of the relay valve 40 via an internal line 48 . Depending on the control pressure, a pressure present at the inlet 50 is fed into the internal line 42 via an outlet 51 . The internal line 41 connected to the input 50 is connected to the line 35 via a connection 52 and a line 53 to the input 45 .

Downstream of the pilot control unit 44 is a 2/2-way valve, which enables the pressure in the internal line 48 to be modulated and is of secondary importance in connection with the present invention. For simplification, it is assumed that the 2/2-way valve 54 is in the open position shown in FIG.

If the line 35 is acted upon by reservoir pressure RP3 and the pilot control unit 44 is in the open position (not shown), the relay valve 40 is controlled so that the spring-loaded brake cylinders FZ are pressurized via the lines 36, 37.

A shuttle valve 55 (also referred to as an OR valve) is provided between the control input 49 and the internal line 48 . Its output 56 is connected to the control input 49. In addition to the internal line 48, the shuttle valve 55 is fed from an internal line 57 which is connected to the control line 38. Service brake pressure can be supplied to the relay valve 40 as a control pressure via the shuttle valve 55, so that the Spring-loaded brake cylinders FZ are ventilated to approximately the same extent as the service brake cylinders BZ. In this way, mechanical overloading of the combination brake cylinder KBZ and the components that interact with it is avoided.

A non-return valve 58 is provided in the internal line 41 between the inlet 50 and the connection 52 and prevents a backflow to the connection 52 . Due to the arrangement of the check valve 58 between the connection 52 and the relay valve 40, a return flow from the relay valve 40 to the input 45 of the pilot control unit 44 is also not possible.

The pilot control unit 44 and the 2/2-way valve 54 can be controlled by the brake control unit PCU. The pilot control unit 44 is designed as a bistable switching element. In contrast, the 2/2-way valve 54 is in its open position without current and changes to its blocked position only after it has been energized.

Finally, a pressure sensor 59 connected to the brake control unit PCU detects the pressure behind the outlet 51 of the relay valve 40.

The relay valve 40 also has a vent outlet 60 which leads via an internal line 61 , connection 62 and internal line 63 to a vent outlet 64 of the valve arrangement VA. In addition, the vent outlet 47 is connected to the line 63 via an internal line 65 and the connection 62 . In the venting position of the pilot control unit 44 shown in FIG. 2, the spring brake cylinders FZ can vent via the relay valve 40.

3 shows the structure of one of the solenoid valves MV. In particular, it is a valve arrangement with two electromagnetic switching valves SV1, SV2. Both switching valves are designed as 2/2-way valves. Switching valve SV2 connects the pneumatic lines 23, 24 or 25, 26 in the open position. The braking pressure can be modulated via the switching valve SV2. Switching valve SV1 is connected to an internal line 65 between switching valve SV2 and line 24 or 26, see also connection 66. Switching valve SV1 is in the closed position when not energized, while switching valve SV2 is in the open position when not energized.

In the open position, the brake pressure in the line 24 or 26 can be vented via the switching valve SV1 and its outlet 67 . This function is required in connection with blocking prevention. At the same time, the venting via the outlet 67 can be used in connection with the present invention.

The two switching valves SV1 and SV2 are controlled by the brake control unit ECU, see electrical lines 16'1, 16'2, 16'3, which are summarized as line 16 in FIG.

In the present context, the brake control unit ECU is regarded as the control unit of the service brake system SBS, while the brake control unit PCU is the control unit of the parking brake system PBS. The brake control unit ECU includes special software for emergency application of the parking brakes PB by indirect venting of the spring brake cylinders FZ. The lowering is program-controlled only by means of the brake control unit ECU of the SBS service brake system. In other words, the brake control unit PCU is bypassed in this case or remains inactive or has failed anyway.

The parking brake PB is activated by lowering the reservoir pressure RP3 in the third brake circuit BK3 due to the lowering of the reservoir pressure RP1, RP2 in the first or second brake circuit BK1, BK2 of the service brake system SBS. This is possible by connecting the brake circuit BK3 for the parking brake PB with the brake circuits BK1, BK2 for the service brake SB in conjunction with the so-called bleed-back function or if the brake circuits BK1, BK2, BK3 mentioned are only connected partial brake circuits of a common brake circuit anyway are. The brake circuits BK1, BK2, BK3 are preferably connected via a multi-circuit protection valve MSV, which can also have the bleed-back functionality. The brake control unit ECU lowers the reservoir pressure RP1, RP2 in the brake circuit BK1 or BK2 for the service brake SB under specially provided secondary conditions BE1, BE2, BE3 and in particular in connection with a standstill of the vehicle FG, for example:

1 . the brake control unit PCU reports a malfunction via the data bus 14;

2. The brake control unit ECU expects regular status messages PS from the brake control unit PCU but does not receive any within a defined period of time;

3. Another electronic control unit ZEC of the vehicle FG connected to the data bus 14 transmits a dedicated signal ZS to the brake control unit ECU;

4. the vehicle has automation functions in what is known as automation level 2, 3, 4 or 5 and as part of these functions the brake control unit ECU is actuated to engage the parking brakes PB;

5. A virtual driver provided as part of the automation (as part of the control software) sends a corresponding request to the brake control unit ECU via the data bus 14 .

The reservoir pressure RP1, RP2 in the brake circuit BK1, BK2 for the service brake SB can be lowered in different ways. The supply of compressed air from a compressed air source, in particular a compressor K, is preferably first interrupted. Subsequently or parallel to this, the service brake SB is actuated in order in this way to use up compressed air and to lower the reservoir pressure in the brake circuit BK1, BK2. Typically, the compressed air is consumed when the service brakes SB are released. the

Service brake cylinders BZ are then vented, for example via the solenoid valves MV, in particular the switching valve SV1, or in the axle modulators AMV, AMH. It is also possible for the brake circuit BK1, BK2 for the service brake SB to be vented in a program-controlled manner without prior actuation of the same, namely also via the switching valve SV1. Venting via this valve SV1 is particularly favorable since the cross sections provided here are relatively large because of the function as an ABS valve.

Parallel ventilation and venting in the area of the same service brake cylinder BZ is also possible. If brake pressure is controlled into the solenoid valve MV by the axle modulator AMV via the line 23, so that the service brake cylinder BZ is pressurized via the line 24, the switching valve SV1 can be switched to its open position. A back pressure with a residual braking effect then forms in the line 24, while at the same time venting takes place via the switching valve SV1. As a result, the service brake SB is at least partially active, while the brake pressure in the brake circuit BK2 is reduced and the spring brake cylinders FZ are vented.

Control that is separate according to brake circuits BK1, BK2 or according to axes AXV, AXH is also possible. For example, the axle modulator AMH for the rear axle is controlled by the brake control unit ECU to pressurize the service brake cylinder BZ, while the brake circuit BK2 is vented via the solenoid valves MV and their switching valves SV1. As a result of this venting, the brake circuit BK3 is also depressurized and the spring brake cylinders FZ are vented.

Especially with separate brake circuits BK1, BK2 in the service brake system SBS, an overlapping of the braking effects of the service brake system SBS and the parking brake system PBS can be achieved. The vehicle FG is braked or stopped via a brake circuit BK1 of the service brake system SBS, while the venting of the other brake circuit BK2 causes venting of the brake circuit BK3 of the parking brake system PBS. n the structural representation of FIG. 4, the division into brake circuits BK1, BK2, BK3 and their assignment to the service brake system SBS and to the parking brake system PBS can be seen, as well as the connection of the brake circuits BK1, BK2, BK3 via the multi-circuit protection valve MSV. The latter is not shown in FIG. 1 only for reasons of clarity.

The compressor K fills the storage tanks V1, V2, V3 via the multi-circuit protection valve MSV. The latter are not shown in FIG. 5 for the sake of simplicity.

A possible sequence is explained using Fig. 6-8:

In the brake control unit ECU of the service brake system SBS, suitable software continuously monitors whether at least one of a number of stored secondary conditions BE1, BE2, BE3 has occurred. If so, the brake control unit ECU controls measures to lower the reservoir pressure RP1, RP2 in the brake circuits BK1, BK2. A so-called secondary condition BE1, BE2, BE3 can also contain a group of conditions that must be fulfilled at the same time.

For example, the constraint BE1 in Fig. 6 contains the conditions

1 . Vehicle standstill, corresponding to speed v = vO = 0 and

2. Brake pedal fully depressed for a period of time dt after the vehicle has come to a standstill, corresponding to brake pressure p=p1.

If these two conditions are met, the reservoir pressure RP1, RP2 is lowered by the brake control unit ECU. The brake control unit ECU receives a signal representing the speed from the wheel speed sensors S or via the data bus 14. The brake pressure p can be provided by a pressure sensor (not shown) in the brake circuit BK1 or BK2.

7 shows that the driver actuates the service brake SB at time t1 due to a warning signal, causing the brake pressure p to increase from p0 to p1 and parallel to this the speed of the vehicle FG falling from v1 to v0 (standstill). Despite the standstill reached at point in time t2, the driver continues to brake with full brake pressure p1.

After the time dt = t3 - 12 has elapsed, the stated conditions are met. That

The brake control unit ECU recognizes this, deactivates the compressor K and controls, for example, the axle modulators AXH and AXV in pulses, so that the service brake cylinders BZ are pressurized and vented in pulses while the vehicle FG is stationary. As a result, the reservoir pressure in the brake circuits BK1, BK2 drops, as does the possible brake pressure p, as can be seen in FIG.

Due to the bleed back function in the multi-circuit protection valve MSV, the reservoir pressure RP3 in the parking brake circuit BK3 also drops and the spring-loaded brake cylinders FZ are vented. The parking brake PB is effective without being operated by the driver.

Secondary condition BE2 in FIG. 6 can relate, for example, to a signal PS from the brake control unit PCU. Either the PS signal here represents an internal error recognized by the PCU brake control unit, which is transmitted to the ECU brake control unit, or it is a cyclical status signal whose absence triggers an action by the ECU brake control unit.

Secondary condition BE3 in FIG. 6 can, for example, relate to a signal ZS of the additional control unit ZEC connected to the data bus 14, for example an engine control unit.

The reservoir pressure RP1, RP2 in the service brake system SBS can be reduced in different ways. One possibility is to bleed all brake circuits BK1, BK2 as quickly as possible. Another possibility is the venting of only one brake circuit BK2 or BK1, while the other brake circuit BK1 or BK2 is not vented. Another possibility is differentiation within a brake circuit BK1, BK2. For example, in the brake circuit BK2 of the front axle AXV, a service brake cylinder BZ is kept ventilated, i.e. braked, while the Solenoid valve MV of the other service brake cylinder BZ is vented, i.e. reservoir pressure RP2 is lowered.

List of reference symbols (part of the description)

10 electropneumatic 37 pneumatic line

Brake system 38 pneumatic control line

11 signal line 39 connection

12 signal line 40 relay valve

13 signal line 41 internal line

14 data bus 42 internal line

15 electric line 43 connection

16 electrical line 44 pilot control unit

16'1 electric line 45 entrance

16'2 electric line 46 output

16'3 electrical line 47 vent outlet

17 electrical line 48 internal line

18 pneumatic line 49 control input

19 pneumatic line 50 input

20 pneumatic line 51 exit

21 pneumatic line 52 connection

22 pneumatic line 53 internal line

23 pneumatic line 54 2/2-way valve

24 pneumatic line 55 shuttle valve

25 pneumatic line 56 output

26 pneumatic line 57 internal line

27 electrical line 58 non-return valve

28 electrical line 59 pressure sensor

29 electrical line 60 vent outlet

30 electrical line 61 internal line

31 pneumatic control line 62 connection

32 pneumatic control line 63 internal line

33 electrical line 64 vent outlet

34 signal line 65 internal line

35 pneumatic line 66 connection

36 pneumatic line 67 exit AMH axle modulator rear axle VA valve arrangement

AMV axle modulator front axle V1 storage tank brake circuit BK1

AXH rear axle V2 storage tank brake circuit BK2

AXV front axle V3 storage tank brake circuit BK3

BE operating element ZEC additional control unit

BE1 1st condition ZS signal

BE2 2nd condition

BE3 3rd condition

BK1 brake circuit

BK2 brake circuit

BK3 brake circuit

BP brake pedal

BZ service brake cylinder

ECU brake control unit

EPH main component

FG vehicle

FZ spring brake cylinder

K compressor

KBZ combination brake cylinder

MSV multiple circuit protection valve

MV solenoid valves

PB parking brake

PBS parking brake system

PCU brake control unit

hp signal

PX control device

RP1 reservoir pressure brake circuit BK1

RP2 reservoir pressure brake circuit BK2

RP3 reservoir pressure brake circuit BK3

S wheel speed sensors

SB service brake

SBS service braking system

SV1 switching valve

SV2 switching valve

Claims

patent claims

1. A method for emergency engagement of a parking brake (PB) of a vehicle (FG), wherein

- a service brake system (SBS) with service brake (SB) and a parking brake system (PBS) with the parking brake (PB) are components of an electropneumatic brake system (10),

- the parking brake system (PBS) has spring-loaded brake cylinders (FZ),

- The service brake system (SBS) includes a service brake control unit (ECU) for controlling components (AMV, AMH) of the service brake (SB),

- At least one brake circuit (BK1, BK2, BK3) for the service brake (SB) and the parking brake (PB) is provided, with the brake circuits (BK1, BK2, BK3) for the service brake (SB) and parking brake (PB) also being able to be separate , and

- The spring-loaded brake cylinder (FZ) can be vented when a reservoir pressure (RP1, RP2) drops in at least one brake circuit (BK1, BK2) for the service brake (SB), characterized in that the service brake control unit (ECU) under defined conditions ( BE1, BE2, BE3) programmatically causes a reduction in the reservoir pressure (RP1, RP2) in at least one brake circuit (BK1, BK2) for the service brake (SB).

2. The method according to claim 1, characterized in that several brake circuits (BK1, BK2) are provided for the service brake (SB) and the service brake control unit (ECU) lowers the reservoir pressure (RP2) in only one brake circuit (BK2) for the Service brake (SB) causes.

3. The method according to claim 1 or 2, characterized in that the service brake control unit (ECU) causes a reduction in the reservoir pressure (RP1, RP2) in all brake circuits (BK1, BK2) for the service brake (SB).

4. The method according to any one of claims 1 to 3, characterized in that the service brake control unit (ECU) after the occurrence of at least one of the following conditions (BE1, BE2, BE3) causes a drop in the reservoir pressure (RP1, RP2) in at least one brake circuit (BK1, BK2) for the service brake (SB): a) the service brake control unit (ECU) detects an error (PS) in the parking brake system (PBS), b) due to defined boundary conditions (BE1, BE2, BE3), c) after actuation of a separate control element (PX), d) after actuation of a brake pedal (BP) for the service brake (SB) in combination with a recognized Error (PS) in the parking brake system (PBS), e) due to a dedicated signal (ZS) from an additional electronic control unit (ZEC).

5. The method according to claim 4, characterized in that the service brake control unit (ECU) detects an error (PS) in the parking brake system (PBS) because at least one of the following events has occurred: aa) the service brake control unit (ECU) has a Error message (PS) from a parking brake control unit (PCU) before, ab) the service brake control unit (ECU), an expected signal (PS) from the parking brake control unit (PCU) is not present, ac) the service brake control unit (ECU) provides a Failure of signals (ZS, PS) on a connected CAN bus.

6. The method according to claim 4 or 5, characterized in that for the reduction of the reservoir pressure (RP1, RP2) in the brake circuit (BK1, BK2) for the service brake (SB) based on defined boundary conditions (BE1, BE2, BE3) at least one of the following Boundary conditions (BE1, BE2, BE3) must be met: ba) dedicated emergency parking signal (ZS) of a virtual driver, bb) general parking request (ZS) of a virtual driver to the braking system (10), in combination with a detected standstill (vO) of the vehicle (FG), bc) general parking request (ZS) from a virtual driver to the braking system (10), in combination with a detected error (PS) in the parking brake system (PBS), bd) general parking request (ZS) from a virtual driver to the electronic braking system (10), in combination with non-active compressed air delivery (K).

7. The method according to any one of claims 1 -6, characterized in that the service brake control unit (ECU) disables compressed air delivery (K) in the brake circuits (BK1, BK2, BK3).

8. The method according to any one of claims 1 -7, characterized in that the service brake control unit (ECU) by actuating the service brake (SB) lowering the reservoir pressure (RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB) causes.

9. The method according to claim 8, characterized in that the service brake control unit (ECU) by actuating the service brake (SB) lowering the reservoir pressure (RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB) causes if the electronic brake system (10) detects a standstill (vO) of the vehicle (FG) or a fault in the parking brake system (PBS) and a brake pedal (BP) for the service brake (SB) is fully actuated for a defined minimum period of time (dt). .

10. The method according to any one of claims 1 -9, characterized in that the reservoir pressure (RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB) by venting via a valve (MV) in the service brake system (SBS ) is lowered.

11 . Method according to Claim 10, characterized in that the reservoir pressure (RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB) is lowered by venting via a valve (MV) to regulate anti-lockup.

12. The method according to any one of claims 1 -11, characterized in that the lowering of the reservoir pressure (RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB) via valves (MV, SV1) with an above-average size The nominal size is based on all valves in the service brake system (SBS).

13. The method according to any one of claims 1 -12, characterized in that parallel to the reduction of the reservoir pressure (RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB) at least one part (AMV, AMH) of the Service brake system (SBS) is controlled for braking.

14. The method according to any one of claims 1 -13, characterized in that at least a part (AMV, AMH) of the service brake system (SBS) is activated for braking or is still activated, and in that the service brake system (SBS) then lowers the reservoir pressure ( RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB) via at least one valve (MV) and at least one other valve (MV) a brake pressure (p1) in at least one service brake cylinder (BZ ) is retained so that this brake cylinder (BZ) is not vented.

15. The method according to claim 14, characterized in that the service brake system (SBS) for lowering the reservoir pressure (RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB) via at least one valve (MV) on a Front axle (AXV) is vented and at least one valve (MV) of a rear axle (AXH) brake pressure (p1) is retained in at least one service brake cylinder (BZ) so that this brake cylinder (BZ) is not vented.

16. The method according to any one of claims 1 -15, characterized in that the lowering of the reservoir pressure (RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB) takes place in a pulsed manner, namely by alternating ventilation (p1) and bleeding (pO) of service brake cylinders (BZ).

17. The method according to any one of claims 1 -16, characterized in that the lowering of the reservoir pressure (RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB) takes place continuously.

18. Electropneumatic brake system (10) for a vehicle (FG), with a service brake system (SBS) with service brake control unit (ECU) for controlling components (AMV, AMH, MV) of a service brake (SB), a brake circuit (BK1, BK2 ) for the service brake (SB), a parking brake system (PBS) with parking brake (PB) and spring-loaded brake cylinders (FZ), the spring-loaded brake cylinders (FZ) being vented due to the system when a reservoir pressure (RP1, RP2) is present in at least one of the brake circuits (BK1, BK2) for the service brake (SB), characterized in that the service brake control unit (ECU) has software for carrying out the method according to one of Claims 1 -15, so that the service brake control unit (ECU) under defined conditions (BE1 , BE2, BE3) programmatically lowering the reservoir pressure (RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB) can be effected.

19. Brake system (10) according to claim 18, characterized in that the service brake control unit (ECU) compressed air delivery in the brake circuits (BK1, BK2, BK3) can be deactivated.

20. Brake system (10) according to claim 18 or 19, characterized in that the service brake control unit (ECU) in conjunction with an actuation of the brake pedal (BP) for the service brake (SB) vents (pO) a brake circuit (BK3) for the parking brake (PB) can be effected if the electronic braking system (10) detects a standstill (vO) of the vehicle (FG) or a fault (PS) in the parking brake system (PBS) and the brake pedal (BP) for the service brake (SB) is fully actuated for a defined minimum period of time (dt).

21 . Brake system (10) according to one of Claims 18-20, characterized in that at least the brake circuit (BK1, BK2) for the service brake (SB) can be bled via activation of a separate valve (SV1) with simultaneous activation of the service brake (SB).

22. Brake system (10) according to claim 21, characterized in that the separate valve (SV1) is connected to the service brake system (SBS).

23. Brake system (10) according to any one of claims 18-22, characterized in that for bleeding (pO) at least one of several available brake circuits (BK1, BK2, BK3) at least one valve (SV1) in the brake circuit (BK1, BK2) for the service brake (SB) can be controlled.

24. Brake system (10) according to one of Claims 18-23, that the parking brake system (PBS) has a relay valve (40) with a pilot control unit (44) and a check valve (58) for electropneumatic actuation of the parking brake (PB), with an input (45 ) of the pilot control unit (44) is connected to an input (50) of the relay valve (40) via the check valve (58).

25. Brake system (10) according to claim 24, that a connection (52) from the input (45) of the pilot control unit (44) to the check valve (58) is connected to a connection (35) to a brake circuit (BK3) for the parking brake (PB). is.

26. Brake system (10) according to any one of claims 18-25, characterized in that the service brake system (SBS) and parking brake system (PBS) are electrically independent of one another, so that in the event of an electrical failure of the parking brake system (PBS), braking is performed by actuating the service brake system (SBS) remains possible.

27. Brake system (10) according to any one of claims 18-26, characterized by a separate control element (BE) connected to the service brake control unit (ECU) and specifically for triggering the program-controlled Lowering of the reservoir pressure (RP1, RP2) in at least one of the brake circuits (BK1, BK2) for the service brake (SB).

28. Service brake control unit (ECU) with software for performing the method according to any one of claims 1 -17.

29. Vehicle (FG) with a braking system (10) according to any one of claims 18- 27.