DE3542824A1 - Hydraulic differential pressure warning switch - Google Patents

Abstract

The invention relates to a hydraulic differential pressure warning switch for hydraulically operated vehicle brake systems equipped with wheel slip control, which have a brake booster (16) connected to a brake pressure master cylinder (3) and a servo pressure supply system with pump (8) and a pressure medium reservoir (9). In order to ensure that a switch of this type takes up as little volume as possible, it is proposed that a step piston (42, 58, 81, 86), which defines two brake circuit pressure chambers, to each of which the pressure of one master cylinder circuit can be admitted, is arranged in a housing, the active piston areas (42a, 42b; 58a, 58b, 81a, 85) assigned to the brake circuit pressure chambers acting in a first direction, with a pump circuit pressure chamber, to which the pump pressure can be admitted, the active piston areas (42c, 66, 89) assigned to the pump circuit pressure chamber acting in opposition to the piston areas assigned to the brake circuit pressure chambers, and that a spring (50, 64, 88) acts on the step piston (42, 58, 81, 86), which spring preloads the step piston into a first position, and that in the case of brake operation without any locking tendency a control element (62, 72, 12) can be operated, which returns into its starting position if there is any locking tendency and the pump (8) is intact. <IMAGE>

Description

The invention relates to a hydraulic differential pressure warning switch according to the preamble of the main claim.

Known differential pressure warning slats of this type indicate particular the disadvantage of a relatively large volume record.

The invention is therefore based on the object Differential pressure warning switch in the preamble of the patent to create 1 specified type of a ge lower volume uptake from the master cylinder circles points.

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

With the solution according to the invention there is a differential pressure warning switch created, except by very little Volume absorption also through a very compact, simple and construction that is cheap to manufacture is marked. The Piston of the warning switch only moves slightly, so that springs with small travel, e.g. Corrugated springs ver can be turned to the piston in the starting position bring.  

The subclaims contain advantageous refinements the invention.

The invention is shown in the drawing Exemplary embodiments explained in more detail. Show it

Fig. 1 is a schematic Dasrtellung a hy metallic brake system;

Fig. 2 is a partial section through a differential pressure switch and

Fig. 3 is a mounting arrangement of a differential pressure warning switch.

The brake system shown in Fig. 1 consists Wesent union of a brake pressure master cylinder 3 with a primary piston (or push rod piston) 4, a secondary piston (or floating piston) 5, the closable by means of central valves pressure medium passages comprise an actuated via a brake pedal 6 brake booster 16 , A pressure medium reservoir 9 , a pump 8 with auxiliary pressure control valve 7 , two to the wheel brakes 20 , 21 , 22 , 23 on closed brake lines 14 , 15 , the directional valves 12 , 13 switched on in the brake lines 14 , 15 , the pressure lines 28 , 29 with the check valves 24 , 25 switched on and the return lines 31 , 32 , 56 with the directional valves 17 , 18 switched into these, and the differential pressure warning switch 2 , which via a line 30 with the pump 8 , a line 35 with the primary piston circuit, a Line 32 with the primary piston circuit, a line 33 with the secondary piston circuit and a line 34 with the loading container 9 is connected.

Fig. 2 shows a hydraulic differential pressure warning switch which has a housing 41 in which a step piston 42 is sealingly guided. The housing 1 has pressure medium connections 43 , 44 , 45 and 46 . Reference numeral 43 here designates the connection assigned to the pump 8 , 44 the connection assigned to the primary circuit, 45 the pressure circuit assigned to the secondary circuit and finally 46 the connection leading to the reservoir 9, which is under atmospheric pressure. Integrated in the stepped piston 2 is a known valve 52 , e.g. B. a ball seat valve, beak valve or the like. On the side opposite the floating piston pressure there is a switch pressure chamber 49 with a spring element 50 , for example a wave spring. The switch pressure chamber 49 is connected to a piston-cylinder unit 51 , which in turn actuates an electrical switch 62 which can be moved between two positions. The piston-cylinder unit 51 together with the switch 62 are part of an information system with which the switch position is given an indication (not shown) as an electrical signal.

The hydraulic differential pressure warning switch works like follows:

When the brake is not actuated, the piston 42 is displaced to the right due to the force exerted by the spring element 50 , that is, it assumes the starting position shown in FIG . When the brake is applied without a tendency to lock, the piston 42 is pressurized by pressure medium from the secondary or floating piston pressure circuit and from the primary or pressure rod circuit, namely on the active surfaces 42 a and 42 b . This causes a displacement of the piston 42 to the left in the direction of the switch pressure chamber 49 . The pressure increase resulting there causes a displacement of the piston of the piston-cylinder unit 51 , which ultimately changes the switch position. When the brake is applied with a tendency to lock and the wheel sensors, which are not shown here, is determined, a control command is issued to the pump unit 8 via a control electronics (also not shown), which activates the pump. If a sufficient pressure is fed in via the connection 13 , which corresponds to the pressures in the floating piston circuit and master cylinder pressure circuit, the piston 42 is displaced to the right, which ultimately results in the switch position 1 shown . This switch position is therefore only reached again when the pressure difference between the pump pressure of the pump 8 and the pressures from the master cylinder circuits 14 and 15 assumes a defined amount.

The signal now generated in this switch position means proper operation of the pump or energy supply for the intelligence of the system. If the pump pressure is not sufficiently high, the piston 42 remains in its position, which means for the system that the pressure medium from the master cylinder has to be used for further braking. In practical terms, this means that the master cylinder is "pumped empty".

Fig. 3 shows an embodiment of a differential pressure switch, in which the switch actuation is performed differently than that in Fig. 2. Instead of the valve 52 , the spring element 50 and the piston-cylinder unit 51 , a piston rod 60 is pressed into the piston 58 , which protrudes through a ring 69 and a sealing sleeve 63 and actuates a switch 72 . Otherwise, the same in Fig. 1 analog parts are provided with the same reference numerals. In the switch pressure chamber 65 , a spring element 64 is arranged, which holds the piston and the piston rod in the starting position shown when the brake is not actuated. The operation of the differential pressure switch shown in FIG. 2 is analogous to that shown in FIG. 1:

When the brake is actuated without a tendency to lock, the piston 58 and thus the piston rod 60 are actuated to the left and the switch position 3 is thereby set. If there is a tendency to block, the pump that has to generate a defined pressure is initiated. If the pump pressure reaches the prescribed value, the piston 58 is displaced to the right by the pressure acting on the movable piston surface 66 , as a result of which the switch returns to position A. Accordingly, the differential pressure between the pump pressure and the other working groups is within the defined tolerance band, and no error message is issued. Grooves 61 are embossed on the piston rod end opposite the switch 72 and perform a sealing function.

Fig. 4 shows a further embodiment of the invention, in which instead of a piston, as in Figs. 2 and 3, two displaceable pistons are arranged, one of the pistons being provided with a cam which actuates the switch.

A piston surface of a first piston 81 is acted upon hydraulically via the pressure medium connection 74 of the primary pressure circuit of the tandem master cylinder. Opposite the pressure chamber 82 is a pressure chamber 83 which is subjected to atmospheric pressure. This space is opposite the pressure chamber 84 of the pressure medium connection 76 from the secondary or floating piston pressure circuit. The pressure present there acts on the piston surface 85 of a second piston 86 , which has a slope 87 or cam. A pressure chamber is formed within the second piston 86 , in which the hydraulic fluid delivered by the pump circuit 73 is located. This pressure acts on a larger pressurizing surface than the piston surfaces assigned to the master cylinder circuits. At the same time, a spring element 88 is present in the piston housing, which circuit 49 rests on the opposite side of the housing. The mode of operation of this differential pressure switch is similar to that mentioned at the beginning:

When the brake is not actuated, both pistons 81 and 86 are displaced to the right by the spring force of the spring 88 , as a result of which the switch is set to position 1 .

When the brake is not actuated without a tendency to lock, ie when both pressure circuits 74 and 76 act without a pump circuit 73 , both pistons 81 and 86 are shifted to the left, as a result of which the switch 12 is moved downward into switch position 3 by the slope. When the brake is applied with a tendency to lock, ie when the pump pressure circuit 73 also acts, the pistons are again shifted to the right when there is sufficient differential pressure, which finally results in switch position A.

Claims (6)

1. Hydraulic differential pressure warning switch for hydraulically operated, with slip control equipped vehicle brake systems which have a brake pressure booster connected to a brake pressure master cylinder and an auxiliary pressure supply system with a pump and a pressure medium reservoir, characterized in that a step piston ( 42 , 58 , 81 , 86 ) is arranged, which delimits pressure chambers assigned to two brake circuits, which can be acted upon by the pressure of one master cylinder circuit, the effective piston surfaces assigned to the brake circuit pressure chambers ( 42 a , 42 b ; 58 a , 58 b , 81 a , 85 ) are effective in a first direction and a pump circuit pressure chamber which can be acted upon by the pump pressure, the effective piston surface ( 42 c , 66 , 89 ) assigned to the pump circuit pressure chamber being opposite to the piston surfaces assigned to the brake circuit pressure chambers , and that on the stepped piston ( 42 , 58 , 81 , 86 ) a spring ( 50 , 64 , 88 ) which biases the stepped piston into a first position, a switching element ( 62 , 72 , 12 ) being operable when the brake is actuated without a tendency to lock and which returns to its starting position when there is a tendency to lock and an intact pump ( 8 ). 2. Hydraulic differential pressure warning switch according to claim 1, characterized in that a valve ( 32 ) is installed in the piston ( 62 ) to secure the switch pressure chamber ( 49 ) against loss of liquid. 3. Hydraulic differential pressure warning switch according to claim 1 or 2, characterized in that the stepped piston is formed by two separate pistons ( 81 , 86 ). 4. Hydraulic differential pressure warning switch according to claim 3, characterized in that the separate pistons ( 81 , 86 ) are guided into one another. 5. Hydraulic differential pressure warning switch according to claim 3 or 4, characterized in that the piston associated with the pump circuit ( 86 ) has a shoulder ( 87 ) or the like to actuate the switch. 6. Hydraulic differential pressure warning switch according to one of the preceding claims, characterized in that the spring ( 88 ) is arranged in a cavity of the piston ( 86 ).