DE2248195C3 - Brake booster for hydraulic vehicle brake systems - Google Patents

Description

The invention relates to a brake booster for hydraulic vehicle brake systems, the has a working piston that can be pressurized in a pressure chamber and in which the pressure chamber Pressure medium can be supplied from a pressure medium source via a valve and in which the valve also passes through an arbitrarily actuatable push rod can be actuated via a lever mechanism which is displaceable on a on the push rod arranged sleeve is articulated, the sleeve by a spring in Is pressed towards the working piston against a stop provided on the push rod and the The end of the push rod protrudes into a blind hole provided in the working piston.

Such a brake booster is known from DT-OS 21 11 260. Falls on this well-known Booster the pressure medium source off, so the working piston can pass through directly with the push rod Muscle force can be operated. To do this, however, the push rod must first be moved until it rests against a stop on the working piston. However, during this additional push rod movement a brake pressure cannot be built up, which leads to a feeling of insecurity when operating the Brake can lead.

Pedal travel converters for brake boosters are also known, which press the brake pedal when the brake pedal is missing Increase servo pressure by 3 to 3 cm. This pedal travel has changed compared to the mui'inal porridge however, it can also lead to uncertainty when using the device.

The invention is therefore based on the object of providing a brake booster of the type mentioned at the beginning Kind to train so that if the servo power fails, the working piston without significant loss of pedal travel can be actuated directly by the push rod. According to the invention, this object is achieved by that the space enclosed by the push rod end and the blind bore via one of the sleeve controlled valve device is connected to the pressure chamber, the sleeve of this valve device ίο normally holds open and closes when it is lifted from the stop.

In the case of the brake booster designed according to the invention, if the pressure medium source fails the sleeve located on the push rod closed a valve device, so that the in the Blind bore located liquid is included. This trapped liquid forms a hydraulic one Linkage via which the push rod can act on the working piston. As the actuation path can be small for the valve device, a significant pedal travel does not occur.

It is advantageous if the sleeve itself forms the closing element of the valve device and the connection between said space and the pressure chamber via a channel formed in the push rod and an opening which opens laterally in the displacement path of the sleeve on the push rod runs.

In the case of a known brake booster (DT-OS 20 14 890), in which the connection to the pressure medium source can be actuated by the push rod Is controlled by tilting valves, a loss of pedal travel in the event of failure of the pressure medium source is also avoided. that the working piston can be actuated by the push rod via a hydraulic linkage. This is on the working piston is attached to a telescopic tube projecting in the direction of the push rod, which is used for the Push rod is open. The opening of this pipe is in the event of failure of the pressure medium source through the then the push rod resting against the pipe end is closed. The push rod end thus forms there at the same time a valve member. This requires an exact concentric alignment of the push rod to the working piston and thus considerable demands on machining and assembly.

An exemplary embodiment of the invention is explained in more detail below with reference to the drawing; it shows

Fig. 1 is a longitudinal section through an inventive trained hydraulic brake booster when arranged in the hydraulic system of a motor vehicle,

F i g. 2 shows the partial section along the line 2-2 in FIG. 1. According to FIG. 1, a brake booster 10 is arranged in the hydraulic system of a motor vehicle, which contains a motor-driven servo pump 12 for the steering, a steering gear 14 being coupled in the usual manner to the associated vehicle wheels, not shown. The brake booster 10 has a housing 16 which has an inlet 18, an outlet 20 and a vent opening 22. The inlet 18 is connected to the pressure side of the pump 12 via a line 24. The outlet 20 is connected to the inlet of the steering gear 14 via a line 26. The vent opening 22 is sen 28 CONNECTED ⁶ S to a line that forms the Rückiührieitung from the outlet of the steering gear to the suction side of the pump 12th

The housing 16 is divided into a pressure chamber 30 and two parallel bores 32 and 34. One

The valve assembly 36 for regulating the pressure level in the chamber 30 is disposed in the bore 34 and includes a valve body 38. The valve body 38 slidably seated in the bore 34 is provided with annular recesses 40 and 42 which are connected to the vent opening 22 and the inlet 18, respectively keep in touch. The bore 34 is also provided with annular grooves 44 and 46. The annular groove 44 is constantly connected to a central channel 48 of the valve body via radial channels 50. Radial channels 51 connect the central channel 48 of the valve body with the pressure chamber 30. The valve body 38 is held in the bore 34 by a spring 52 arranged between a stop 54 of the valve body 38 and a closure piece 56 in the rest position shown in FIG. The closure piece 56 is held in a counterbore 58 of the bore 34 by a ring 60 which is seated in a groove 62 of the counterbore. A seal 64 prevents hydraulic fluid from escaping between the closure piece 56 and the counterbore 58. A stop ring 66 seated in a groove 68 of the valve body interacts with a shoulder 70 of the counterbore 58, which limits the displacement of the valve body to the right and positions the valve body in this way that its recess 40 and 42 occupy the correct position with respect to the grooves 44 and 46 of the bore 34. In its in the sense of F i g. 1 right rest position, the valve body guides the fluid from the inlet 18 via the recess 42 and the groove 46 to the outlet 20. In this rest position, the valve body also connects the pressure chamber 30 via radial channels 51, the central channel 48, the radial channels 50, the groove 44 and the recess 40 with the ventilation opening 22. The recess 40 and the groove 44 overlap so that an unimpeded flow of fluid can be established between them when the valve arrangement 36 is in the rest position. The recess 42 and the groove 46 have an overlap area 72, which prevents a complete shut-off of the hydraulic supply to the outlet 20 and to the steering gear 14 when the valve body is in the direction shown in FIG. 1 full actuation position on the left. However, if the valve body in the sense of FIG. 1 is shifted to the left, i.e. in the brake actuation direction, the mutual connection of the recess 40 and the groove 44 is closed and the recess 42 is connected to the groove 44, whereby the inlet 18 is connected to the pressure chamber 30.

In the bore 32, a working piston 74 is arranged such that it can be pushed back and forth, one end of which is acted upon by the pressure in the chamber 30. At the other end of the piston, the working piston 74 is provided with a pocket 76, against which one end of a power transmission tappet 78 rests, which connects the piston 74 in a conventional manner with a conventional motor vehicle master cylinder, not shown, in a non-positive manner. A return spring 80 presses the working piston 74 into the position shown in FIG. 1 brake release position shown. A seal 82 prevents hydraulic leakage from the fto chamber 30 between the bore 32 and the working piston 74.

The valve arrangement 36 and the working piston 74 are actuated by a pedal-actuated control device 84 which comprises the force transmission members 86 and a lever mechanism 88. The force transmission members 86 act between the piston 74 and a brake pedal 90. The brake pedal 90 is suspended from a bracket 92 arranged in the driver's compartment of the motor vehicle. The force transmission members 86 contain a push rod 94, which is divided into three pivotally connected sections 94Λ, 945 and 94C for reasons of simple manufacture, construction and assembly. The section 94ß is slidably seated in an axial bore 96 of a projection 98 which is attached to the housing 16 in one piece. The section 94ß forms a thrust piston which is provided at its ends with pockets 100 and 102 in which the sections 94Λ and 94C sit in a pressure-locking manner. Seals 101 on section 94ß prevent fluid from escaping from chamber 30. To prevent detachment of section 94/4 from pocket 100 , a flange 104 of section 94ß is rolled over tapered end 106 of push rod section 94Λ . At its end opposite the spherical end 106, the push rod section 94A is provided with a head 108 which is slidably movable in a cavity in the form of an axial recess 110 of the actuating piston 74. Before the flange 104 is rolled over the spherical end 106 , a sleeve 112 and a coil spring 114 are placed on the push rod section 94A. The sleeve 112 is provided at one end with a U-shaped section which has two laterally arranged, axially extending arms 116 , the other end of the sleeve abutting the head 108 . The coil spring 114 is inserted with a predetermined preload between the U-shaped section of the sleeve 112 and the flange 104 of the push rod section 94ß. A slot 118 is formed in each of the arms 116 , in each of which a pivot pin 120 is seated, which is drivingly connected to the lever 122 of the linkage 88 . At its lower end, the lever 122 is articulated to a pivot pin 124 which is fastened to a bracket 126 connected to the actuating piston 74 in a manner locked in motion. At its upper end, the lever 122 is coupled by the pivot 123 to the valve body 38 via a shut-off valve 128 which includes a cylindrical valve body 129 which is slidably mounted on the valve body 38 and serves to establish communication between the central channel 48 and the Interrupt chamber 30. In order to enable an axial displacement of the push rod 94 to the left in the sense of the figures during a normal braking process in which the valve body 38 is displaced via the pedal 90 and the lever 122 in such a way that the chamber 30 is supplied with pressure medium, there is an axial displacement between the head 108 and the closed end 109 of the recess 110 has a play "Λ". This play "Λ" must be dimensioned such that the pedal and the push rod can be moved so far that the valve assembly 36 is fully opened before the pretensioned spring 114 is compressed. During the normal braking process with servo amplification, this play "A" increases by perhaps the distance "B " as a result of the design of the lever mechanism 88, especially after a violent brake actuation, since the working piston 74 covers a greater distance than the pin 120 arranged on the lever 122 at this time, a disturbance, for example, the valve assembly 36 as a result of insufficient Strömungsmiüeldrucks is present and the gap between the head 108 and the closed end 109 of the recess 10 is about 1 "B" is, the pedal 90 must by the distance

»Β« must be adjusted before the brakes are actuated by muscle power alone. This loss of pedal feel could confuse the driver. A safety device 111 is therefore provided which regulates the displacement path of the brake pedal and the push rod with respect to the working piston 74 in the event of insufficient servo amplification, which requires an additional pedal force that exceeds the preload of the spring 114. This safety device 111 in the form of a control valve arrangement limits or reduces the push rod and pedal travel with respect to the piston 74 when the brake pedal force exceeds the spring preload, namely in that the end 113 of the sleeve 112 is connected to an axial channel 117 of the push rod section 94 A standing radial channel 115 closes off. This relative displacement between the sleeve 112 and the push rod section 94/4, by means of which the channel 115 is closed, interrupts the fluid connection of the recess 110 with the chamber 30, with which it is in connection with: servo amplification during normal braking processes. When the recess 110 is sealed, the hydraulic medium, which is only very slightly compressible, is put under pressure when the head 108 is pushed further into the recess HO ^1. The additional pedal force is now transmitted to the working piston 74 via the push rod 94 and the hydraulic medium enclosed in the recess 110. The relative displacement of the push rod is essentially only as great as is necessary to shut off the channel 115 , namely only a fraction of a centimeter. Therefore, the displacement of the push rod is slightly less than the play "A" and never reaches the distance "B" so that the displacement of the brake pedal and the push rod with respect to the working piston are kept extremely small when the brake pedal force exceeds the preload of the spring 114. During normal braking with servo amplification, the fluid connection between the recess 110 and the chamber 30 via the channels 117 and 115 is maintained, since the spring preload is selected such that the sleeve 112 is held in contact with the head 108 and the radial channel 115 is thus released. This open fluid communication between the recess 110 and the chamber 30 allows free hydraulic flow into and out of the recess 110 during normal braking as the head 108 changes the volume of the recess 110.

According to FIG. 1, the cylindrical valve body 129 of the shut-off valve 128 is pressed against a stop ring 130 of the valve body 38 by a spring 132, which sits between a stop 134 of the valve body 38 and an annular flange 36 of the valve body 129. In this position of the valve body 129 resting on the stop ring 130 , the chamber 30 is connected to the central channel 48 of the valve body 38 via the radial channels 51 of the valve body 38 and the radial channels 138 of the valve body 129 . The cylindrical valve body 129 is moved into the closed position by the lever 122, which at its upper end cooperates with an annular slot 140 of the cylindrical valve body 129, in which the connection between the central channel 48 and the pressure chamber 30 is interrupted. In the closed position of the shut-off valve, the radial channels 51 of the valve body 38 are displaced with respect to the radial channels 138 of the cylindrical valve body 129 and there: the end 142 of the valve body 129 rests against an enlarged section 144 of the valve body 38 . The cylindrical valve body 129 is closed by a front wall 150 which delimits a volume-variable chamber 152. A throttle opening 15 * connects the chamber 152 with the chamber 30. The throttle opening 154 is dimensioned such that you initial relative movement between the valve body

ίο regulated by 38 and the cylindrical valve body 129 in such a way that a closure of the radial channels 51 and 138 due to the inertia of the valve body 38 is excluded during an emergency braking.

The brake booster described above works as follows:

In the in F i g. 1 shown ventilation position of the brake pedal 90 connects the valve assembly 36 of the inlet 18 via the annular recess 42 and the groove 46 with the outlet 20 so that the fluid required by the pump 15 can flow through the hydraulic brake booster 10 unhindered. In this ventilation position, the valve arrangement 36 also connects the ventilation opening 22 via the annular recess 40 and the annular groove 44, the radial ducts 50, the central duct 48 and the radial ducts 51 with the pressure chamber 30, so that the venting pressure prevails in this. To apply the brakes, ie to actuate the hydraulic brake booster 10, the vehicle driver presses

the pedal 90 so that it pivots about the bracket 92! and the push rod 94 is moved to the left in the sense of FIG. 1. Assuming that it is a normal braking process, ie the fluid pressure is sufficiently high and the valve arrangement

is not disturbed, the sleeve 112 is held in contact with the head 108 as a result of the bias of the spring 114 of the force transmission members 86, so that the lever 122 about the pivot 124 when the push rod 94 is displaced counterclockwise

is pivoted. This pivoting movement of the lever 122 acts on the valve body 38 via the shut-off valve 128. However, since the spring 132 of the shut-off valve is so strong that a relative displacement between the valve body 38 and the valve body

129 is omitted, the valve body 38 is adjusted against the force of the return spring 52 in the sense of the figures to the left. As a result of this adjustment of the valve body 38, the fluid connection between the chamber 30 and the vent opening 22 is established

interrupted and the inlet 18 with the pressure chamber 30 brought into communication. In this position of the valve body 38, the annular recess 42 overlaps the annular groove 44, so that a fluid connection with the chamber 30 is established.

At the same time, the fluid connection with the annular groove 46 remains through the annular recess 42 obtained so that the outlet 20, which is connected to the steering gear 14, not completely is separated. The pressure increase in the chamber 30

acts on the end of the working piston 74 and pushes the working piston to the left in the sense of the figures, see above that the master cylinder, not shown, is actuated, with which the plunger 78 is positively connected. at Releasing the brake pedal 70, the pistons 74 and

the valve body 38 is reset by the springs 80 and 52, respectively.

In the event of a fault in the brake booster, be due to a complete failure of the hydraulic

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pressure or because the hydraulic pressure is insufficient to bring about the required vehicle deceleration, or because a valve is stuck, the vehicle brakes can be operated by muscle power. During one Such a disruption, the force applied by the driver of the vehicle to the pedal 90, the spring 114, is sufficient squeeze and release the head 108 from its abutment on the sleeve 112. This relative shift between the push rod portion 94.4 and the sleeve 112 causes the end 113 of the sleeve the radial channel 115 of the push rod closes so that the hydraulic fluid is locked in the recess 110 will.

As a result of the shut-off of the flow medium effected in this way, any further F. limited movement of the head 108 in the recess 11t. The head 108 now acts on encapsulated fluid and tries to compress it as much as possible, but shifts at the same time the working piston 74. This eliminates excessive push rod and pedal displacement which would otherwise be required to dei the push rod ncnds 108 in contact with the base 109 Bring recess HO and thereby close the gap / ι.

1 sheet of drawings

709 650 /

Claims (2)

Patent claims: 1. Brake booster for hydraulic vehicle brake systems, one in a pressure chamber having pressurizable working piston and in which the pressure chamber pressure medium from can be fed to a pressure medium source via a valve and in which the valve can also be supplied by an arbitrary actuatable push rod can be actuated via a lever mechanism, which is slidable on a Push rod arranged sleeve is articulated, the sleeve by a spring in the direction The working piston is pressed against a stop provided on the push rod and the The end of the push rod protrudes into a blind hole provided in the working piston, characterized in that that the space enclosed by the push rod end and the blind bore (110) is controlled by a valve device controlled by the sleeve (112) (112, 113, 115) is connected to the pressure chamber (30), the sleeve (112) this Valve device (112, 113, 115) normally holds open and when it is lifted from the stop closes. 2. Brake booster according to claim 1, characterized in that the sleeve (112) itself that Forms closing member of the valve device and that the connection between said space and the pressure chamber (30) via a channel (117) formed in the push rod (94, 108) and an im The displacement path of the sleeve on the push rod laterally opening opening (115) runs.