DE4422518A1 - Hydraulic brake system for a motor vehicle, in particular a passenger car, with an anti-lock device - Google Patents

Abstract

The operation of the braking system during braking with or without the risk of locking is to be improved. The braking system (1) has a diagonally divided braking circuit. In a first line (11) between a master cylinder (3) and a wheel cylinder (12) on the front axle there is a first 2/2-way valve (13). A second line (14) branches off from the first (11) on the wheel brake side to a wheel cylinder (15) on the rear axle and has a second 2/2-way valve (16) fitted in it. Between the two valves (13, 16) starts a third line (17) with a pump (18) by means of which pressurising agent may be conveyed from the wheel cylinders (12, 15) to the master cylinder (3). Braking force distribution dependent on the dynamic shift in axle loading and limited brake pressure control in individual wheel brakes when there is a risk of locking is thus possible.

Description

State of the art

The invention is based on a hydraulic brake system according to the preamble of claim 1. In such a Brake system is the second 2/2-way valve in the third Line arranged. It has a spring-operated locking position and an electromagnetically switchable open position. By appropriate switching of the two directional valves is with the help the pump in anti-lock control mode in the respective Brake circuit a brake pressure modulation possible, which phases for pressure reduction, pressure maintenance and pressure build-up in the Includes wheel brake cylinders. A wheel-specific pressure control is not possible due to the valve equipment. In addition, to achieve the best possible braking effect with different loading conditions of the vehicle in the As a rule, a load-dependent pressure reducer in the respective Wheel brake cylinder of the rear axle leading second line required.

Such brake systems are used in  Cars in the lower price segment. These Motor vehicles have front-wheel drive, and theirs Wheel brakes assigned to rear wheels are used in a Braking is relieved relatively much. The inexpensive known brake system is not in this vehicle class meet all requirements.

Advantages of the invention

The hydraulic brake system according to the invention with the characteristic features of claim 1 has in contrast the advantage that with the same number of valves per brake circuit also a wheel-specific regulation in normal Service braking and in anti-lock control operation possible is. Pressure reducers on the rear axle are not necessary. It is also possible to determine the influence of the engine drag torque on the brake pressure and thus the braking effect on the Rear axle with anti-lock control operation on lanes with to partially compensate for a very small coefficient of friction.

The measure set out in claim 2 makes it possible to when braking is stopped, pressure fluid from the Wheel brake cylinders of the rear axle accelerate to To return the master brake cylinder.

drawing

An embodiment of the invention is in the drawing based on a circuit diagram of a hydraulic brake system shown with anti-lock device.

Description of the embodiment

A hydraulic brake system 1 , shown schematically in the drawing, is intended for use in front-wheel drive passenger cars with a diagonal brake circuit division. The brake system 1 is equipped with an anti-lock device 2 . The brake system 1 has a double-circuit, pedal-operated master brake cylinder 3 with a pressure medium reservoir 4 . A first brake circuit I is intended for actuating wheel brakes 5 and 6 , which are assigned to the left front wheel and the right rear wheel of the vehicle.

The wheel brakes 7 and 8 of the right front wheel and the left rear wheel are connected to a second brake circuit II. Both brake circuits I and II are equipped the same. The brake circuit I is therefore described in more detail below.

In brake circuit I, a first line 11 leads from master brake cylinder 3 to a wheel brake cylinder 12 of wheel brake 5 assigned to the left front wheel. A first 2/2-way valve 13 is located in the first line 11 . This takes its open position spring-actuated and its blocking position electromagnetically operated. A second line 14 extends from the first line 11 between the first directional control valve 13 and the wheel brake cylinder 12 , to which a wheel brake cylinder 15 of the wheel brake 6 assigned to the right rear wheel is connected. In the second line 14 there is a second 2/2-way valve 16 with a spring-operated passage position and an electromagnetically switchable blocking position.

In addition, a third line 17 is provided with a pump 18 for conveying pressure medium from the wheel brake cylinders 12 and 15 to the master brake cylinder 3 . The part 17.1 of the third line leading to the suction side of the pump 18 is connected to the second line 14 between the two directional valves 13 and 16 . The pressure-side part 17.2 of the third line 17 is connected to the first line 11 between the first directional valve 13 and the master brake cylinder 3 . Check and pressure valves of the pump 18 are in the third line 17 check valves 19 and 20 , which prevent a pressure medium flow from the master cylinder 3 to the wheel brake cylinders 12 and 15 through the third line 17 . The check valves 19 and 20 can be integrated in the pump 18 . The pump 18 can be driven by an electric drive motor 21 common to both brake circuits I and II.

The second directional valve 16 and the pump 18 are bypassed by a fourth line 22 . In this a check valve 23 with the passage direction from the wheel brake cylinder 15 to the master cylinder 3 is arranged. In addition, a fifth line 24 is provided, which bypasses the first directional valve 13 . In this line 24 there is a check valve 25 with the passage direction from the wheel brake cylinder 12 to the master brake cylinder 3 . The brake circuits I and II of the brake system 1 do not contain any further hydraulic elements. The aforementioned elements are combined in a hydraulic unit 26 , which is indicated in the drawing by a dash-dotted border.

Finally, the anti-lock device 2 also includes wheel rotation sensors 27 assigned to the vehicle wheels, which are connected to an electronic control unit 28 . The control unit 28 is intended for the slip-dependent switching of the directional control valves 13 and 16 and the pump drive motor 21 .

The brake system 1 has the following mode of operation:
When braking, the brake pressure is built up in the wheel brake cylinders 12 and 15 of the brake circuit I. The same takes place in the brake circuit II in the wheel brake cylinders 29 and 30 , which are assigned to the wheel brake 7 of the right front wheel or the wheel brake 8 of the left rear wheel. Depending on the dynamic axle load shift, higher braking forces occur on the wheels of the front axle than on the rear axle. With regard to the effective vehicle speed, these lead to different slippage at the wheels of the front axle and the wheels of the rear axle or to different wheel peripheral speeds between the wheels of the two axles. This behavior is monitored by the electronic control unit 28 on the basis of the signals from the wheel rotation sensors 27 . If the control unit 28 detects an excessive slip or speed difference between the wheels of both axles, it switches the second directional control valves 16 in the brake circuit I and 31 in the brake circuit II into the blocking position, so that further brake pressure build-up on the rear axle is prevented. By appropriately retaining the pressure in the wheel brake cylinders 15 and 30 of the rear axle, the braking force is adjusted to the ideal braking force distribution during braking. A pressure reducer in the second lines 14 leading to the wheel brake cylinders 15 and 30 of the rear axle in the brake circuit I and 32 in the brake circuit II is therefore unnecessary.

If there is a risk of locking on the right rear wheel during braking, for example, the anti-lock device 2 operates as follows: The control unit 28 blocks the first line 11 with the aid of the first directional valve 13 and puts the pump 18 into operation. By removing pressure medium from both wheel brake cylinders 12 and 15 of brake circuit I, this causes a pressure reduction on both wheel brakes 5 and 6 . In order to raise the brake pressure again when the wheel turning behavior stabilizes, the control unit 28 switches the first directional valve 13 into the open position, so that pressure medium can flow in from the master brake cylinder 3 to the two wheel brake cylinders 12 and 15 while the pump 18 is running.

If there is a risk of locking on the left front wheel during braking, the following measures are taken: To reduce the brake pressure, both directional control valves 13 and 16 in brake circuit I are closed and the pump 18 is started. This conveys pressure medium from the wheel brake cylinder 12 to the master brake cylinder 3 . The brake pressure in the wheel brake cylinder 15 of the right rear wheel is maintained. For renewed pressure build-up on the wheel brake 5 of the left front wheel, the first directional valve 13 is transferred into the open position and pressure medium flows from the master brake cylinder 3 into the wheel brake cylinder 12 while the pump 18 continues to deliver.

With the anti-lock device 2 , it is thus possible to reduce brake pressure on one or both wheel brake cylinders 12 and 29 of the front axle in accordance with the above-described mode of operation, so that rapid acceleration of the wheel subject to the risk of locking or of the two wheels subject to locking is achieved. While maintaining the pressure in the wheel brakes of the rear axle, the braking effect of the vehicle on road surfaces with z. B. improved by ice or snow low coefficient of friction compared to conventional 2-channel systems. This applies in particular to front-wheel drive vehicles under the influence of engine drag torques.

Claims (2)

1. hydraulic brake system ( 1 ) for a motor vehicle, in particular a passenger car, with an anti-lock device ( 2 ),
with a two-circuit master brake cylinder ( 3 ) for diagonal brake circuit division,
with a first line ( 11 ) leading from the master brake cylinder ( 3 ) to the wheel brake cylinder ( 12 ) of the front axle of the vehicle in the respective brake circuit (I; II),
with a spring-operated, open, electromagnetically switchable first 2/2-way valve ( 13 ) in the first line ( 11 ),
with a second line ( 14 ) leading from the first line ( 11 ) between the first 2/2-way valve ( 13 ) and the wheel brake cylinder ( 12 ) of the front axle and leading to a wheel brake cylinder ( 15 ) of the rear axle of the vehicle, with one side to one of the two lines ( 11 , 14 ) between the first 2/2-way valve ( 13 ) and the wheel brake cylinders ( 12 , 15 ) and on the other hand between the first 2/2-way valve ( 13 ) and the master brake cylinder ( 3 ) to the first line ( 11 ) connected third line ( 17 ), in which a pressure medium from the wheel brake cylinders ( 12 , 15 ) to the master brake cylinder ( 3 ) pump ( 18 ) is arranged,
with a second 2/2-way valve ( 16 ) in the respective brake circuit (I, II) and with an electronic control unit ( 28 ) for switching the directional control valves ( 13 , 16 ) and the pump drive ( 21 ) depending on slip, characterized by the following features:

• - The second 2/2-way valve ( 16 ) is arranged in the second line ( 14 ),
• - The second 2/2-way valve ( 16 ) is spring-actuated in its open position and electromagnetically actuated in its blocking position,
• - The part ( 17.1 ) of the third line ( 17 ) leading to the suction side of the pump ( 18 ) is between the two directional valves ( 13 , 16 ) and the wheel brake cylinder ( 12 ) of the front axle to one of the two first and second lines ( 11 , 14 ) connected.

2. Hydraulic brake system according to claim 1, characterized in that in the respective brake circuit (I, II) the second 2/2-way valve ( 16 ) and the pump ( 18 ) are bypassed by a fourth line ( 22 ) in which a check valve ( 23 ) with the passage direction from the wheel brake cylinder ( 15 ) of the rear axle to the master brake cylinder ( 3 ).