DE3903532A1 - Hydraulic motor-vehicle brake system with an anti-lock control device - Google Patents

Abstract

In a known hydraulic motor-vehicle brake system with an anti-lock control device, a controllable hydraulic pump connected to the wheel-brake cylinders is provided, this pump taking over the function of brake boosting when the anti-lock control system is inactive and assuming the function of a brake-pressure modulator when the anti-lock control system is active. For this purpose, its output pressure is, in the first case, controlled by the output pressure of the master brake cylinder and, in the second case, by a control signal output by the anti-lock control device. In the new hydraulic motor-vehicle brake system, the intention is that a hydraulic pump should likewise assume both the function of brake boosting and the function of pressure modulation but that the outlay for this purpose, particularly the outlay for control, should be comparatively low. The hydraulic pump, which is preferably designed as a gear pump whose direction of delivery can be reversed and can be switched on automatically when the service brake is operated, is in each case inserted in the brake line leading from the master brake cylinder to the wheel-brake cylinders. Connected in parallel with it is a proportional-pressure control valve, the low-pressure port of which is connected to the hydraulic pump on the master-brake-cylinder side and the higher-pressure port of which is connected to the hydraulic pump on the wheel-brake-cylinder side. <IMAGE>

Description

The invention relates to a hydraulic motor vehicle brake system with anti-lock control device in the preamble of the patent claim 1 Art.

Hydraulic motor vehicle braking systems, where as a brake pressure generating servo device not mechanically with the main brake cylinders coupled standard hydraulic or vacuum Brake booster are used, but - preferably For example, hydraulic pumps operated by hydraulic motors known from DE-OS 33 42 552 or 33 42 555.

In these known hydraulic motor vehicle braking systems becomes when the service brake is applied by the master brake cylinder generated hydraulic pressure as a reference variable for the with the arranged wheel brake cylinders related hydraulic pump used. This is done through an electronic control and regulation device above a predetermined low minimum pressure the master brake cylinder on the one hand the pressure connection between the master brake cylinder and the brake circuits interrupted and on the other hand the outlet pressure of the hydraulics pump regulated to a value that corresponds to the outlet pressure of the main brake cylinder proportional, but higher than this. In ver binding with an anti-lock control device (DE-OS 33 42 555) the output pressure of the hydraulic pump, however, during such Operating phases in which the anti-lock control device regulates is effective, depending on one of the anti-lock rule device supplied control signal regulated.

The invention is based on the object, the total effort, especially the control engineering effort for a hydrau lische automobile braking system in the preamble of the patent claim 1 type while ensuring a reliable Servo support during normal braking phases as well noticeable while ensuring normal anti-lock control functions to lower.

This object is achieved by the features of the patent claim 1 solved.

Advantageous further developments and refinements of the invention are specified in the subclaims.

According to the invention, the combination of in their funding direction switchable hydraulic pump and parallel Ratio pressure control valve during normal braking phases the function of the brake booster and during such loading drive phases in which the anti-lock control device regulates is effective, the function of a pressure modulator is perceived.

Based on a principle shown in the drawing example, the invention is explained in more detail below.

In the single figure of the drawing there is only one for the Understanding the invention necessary section of a conventional hydraulic dual-circuit braking system shown, and only one of the master cylinder to one of the wheel brake cylinders leading brake line branches. The anti-lock control device the braking system is not shown. It corresponds usual with regard to signal acquisition and signal processing Anti-lock control devices.

According to the invention, in the brake line 5 leading from the master cylinder 1 to the assigned wheel brake cylinder 3, a hydraulic pump 4 is interposed, which in the illustrated embodiment is designed as a gear pump.

The hydraulic pump can be switched in its conveying direction and is switched on automatically when the service brake is actuated, ie when the brake pedal 2 is actuated. The gear pump is preferably designed as an electric motor-driven gear pump, so that its switching on and off can be controlled in the simplest way via the electric brake light switch usually present in a hydraulic brake system.

A known ratio pressure control valve 6 is connected in parallel to the hydraulic pump as a bypass. A ratio pressure control valve, formerly also called a pressure ratio valve, keeps the ratio between an inlet pressure and an outlet pressure itself constant, regardless of the variable inlet pressure. The pressure ratio is inversely proportional to the area ratio of the end faces A ₂ or A ₁ of the stepped piston 9 which is effective in the ratio of the pressure control valve and which is exposed to the inlet pressure or outlet pressure.

The ratio pressure control valve 6 is arranged such that its with the larger end face A _{2 of} the stepped piston 9 immediately cooperating first port 7 , at which the lower pressure is applied when the regulator function is active, the master brake cylinder on the side and the one interacting directly with the smaller end face A _{1 of} the stepped piston Connection 8 , at which the higher pressure is present when the controller function is active, is connected to the hydraulic pump 4 on the wheel brake cylinder side.

In the operating phases in which the anti-lock control device (not shown) is not effective when the service brake is actuated, the hydraulic pump 4, in conjunction with the ratio pressure control valve 6 connected in parallel, takes over the function of the brake booster.

When the brake pedal 2 on the one hand from the nachge off the master cylinder 1 pressure is built and on the other hand, z. B. via a conventional brake light switch, the hydrau likpump 4 turned on with the direction of the solid arrow conveying direction. The hydraulic pump works first through the open passage 10 of the ratio pressure control valve 6 in a short circuit, wherein at most a certain dynamic pressure arises in the downstream wheel brake cylinders 3 . At the same time, the stepped piston 9 is axially displaced under the effect of the starting pressure P _{Hz of} the master brake cylinder 1 , which acts on the differential surface A ₂ - A _{1 of} the stepped piston, so that the passage 10 of the ratio pressure control valve is ultimately closed.

After the short circuit has ceased, a pressure P _servo , which is regulated by the ratio pressure control valve 6, builds up at the outlet of the hydraulic pump 4 and thus also in the wheel brake cylinder 3 , the level of which depends on the area ratio of the ratio pressure control valve and on the output pressure P _{Hz of} the master brake cylinder 1 acting as input pressure. The ratio pressure control valve keeps the ratio between its inlet pressure corresponding to the outlet pressure P _{Hz of} the master brake cylinder 1 and its outlet pressure corresponding to the hydraulic pump outlet pressure P _servo constant irrespective of the variable inlet pressure

The wheel brake cylinders 3 are thus fed with a controlled servo pressure P _servo , which can be increased or decreased continuously in accordance with the actuation of the brake pedal 2 .

As in the exemplary embodiment , a gear pump is advantageously used as hydraulic pump 4 . Then it is ensured that the basic function of the hydraulic motor vehicle brake system is retained even in the event of a failure of the pump drive, ie in the event of failure of the function of the brake booster, because hydraulic fluids are conveyed from the master cylinder 1 to the wheel brake cylinders 3 in the usual manner via the gears which then rotate freely can be.

In the operating phases in which the anti-lock control device becomes regulatingly effective when the service brake is actuated, the hydraulic pump 4 is used for pressure modulation. In the case of the control requirement "pressure reduction", the hydraulic pump 4 is switched by a corresponding control signal of the control and regulating electronics (not shown) of the anti-lock control device in its conveying direction in the direction of the master brake cylinder, which is indicated in the figure by dashed arrows. Due to the given pressure conditions, the passage 10 in the ratio pressure control valve 6 is closed by the step piston 9, which is located in the ver, and hydraulic fluid from the wheel brake cylinders - the hydraulic pressure of which reduces the control requirements accordingly - is returned to the master brake cylinder 1 , for as long as the control requirement "lowering pressure"" consists.

As soon as the control requirement "pressure lowering" has ceased to exist because the wheels are no longer at risk of locking, the hydraulic pump 4 is switched back into its original delivery direction. It is advantageous that the delivery rate of the hydraulic pump 4 can be regulated in a simple manner, for. B. by controlling the pump speed. This makes it possible in an advantageous manner to influence the characteristic of the pressure reduction taking place in the case of anti-lock control, for. B. in dependence on the assigned wheel speed.

In the illustrated embodiment, the hydraulic pumps / Ver ratio pressure control valve arrangement 4/6 is directly assigned to the one wheel brake cylinder 3 ; in a corresponding manner, such an arrangement can be assigned to the remaining three wheels of a four-wheel motor vehicle. Basically, however, it depends on the structure and type of the hydraulic motor vehicle brake system and the anti-lock control device used, whether all the wheels individually or groups of them is assigned such an arrangement.

It is also conceivable to use the hydraulic pump 4 additionally in the context of a known traction control system (ASR) in order to brake the drive wheels concerned, without the driver's intervention , when the appropriate control requirement is met. To do this, the hydraulic pump 4 must only be switched on by the control electronics of the traction control device (conveying direction in the direction of the solid arrow) and, on the other hand, the path via the parallel pressure control valve 6 must be blocked, which, for. B. can be done in a simple manner with the help of an upstream solenoid valve.

Claims (3)

1.Hydraulic motor vehicle brake system with anti-lock control device, with a pedal-operated master brake cylinder and at least one controllable hydraulic pump which is connected to associated wheel brake cylinders and which, when the anti-lock control is inactive, increases the function of a braking force and, when the anti-lock control is active, takes over the function of brake pressure modulation, characterized in that
that the hydraulic pump ( 4 ) in each of the master brake cylinder ( 1 ) to the associated wheel brake cylinders ( 3 ) leading brake line ( 5 ) is switched,
that the hydraulic pump ( 4 ) can be switched in its conveying direction and can be switched on automatically when the service brake is applied,
and that the hydraulic pump ( 4 ) has a ratio pressure regulating valve ( 6 ) connected in parallel as a bypass, which with its lower pressure first connection ( 7 ) when the controller function is active and on the master cylinder side with its then higher pressure second connection ( 8 ) wheel brake cylinder side with the hydraulic pump ( 4 ) communicates. 2. Hydraulic motor vehicle brake system according to claim 1, characterized in that the hydraulic pump ( 4 ) is designed as a gear pump, preferably as an electric motor driven gear pump. 3. Hydraulic motor vehicle brake system according to claim 1 or 2, characterized in that the hydraulic pump ( 4 ) can be switched over in the direction of the master cylinder ( 1 ) as part of the anti-lock control during the control requirement "lower pressure" in its conveying direction.