FR2706543A1 - Pneumatic control device with reduced load. - Google Patents

Abstract

The invention relates to a pneumatic control device for a vacuum brake booster using, inside a piston (5), a tubular closure member (21) cooperating with a fixed seat (18) and with a mobile seat (19). The tubular closure member (21) defines, with the interior of the piston (5), a chamber (22) pierced with an orifice (23) which places it in communication with a passage (20) formed between the two seats. This arrangement eliminates the need to apply a large elastic force to the closure member (21).

Description

REDUCED LOAD PNEUMATIC CONTROL DEVICE
The present invention relates to a pneumatic control device for a vacuum booster, comprising: three ways including a first inlet connected to a first pressure source delivering a relatively high pressure, a second inlet connected to a front chamber of the booster and to a second source pressure delivering a relatively low pressure, and an outlet connected to a rear chamber of the booster, the pressure of which is to be checked; a substantially cylindrical hollow piston into which each of the channels opens to allow the establishment of selective communication between any of the inputs and the output; a first annular seat formed by an internal crown of the piston outside of which the second inlet opens; a second annular seat, axially closed, mounted in the first seat with a clearance defining a passage connected to the outlet, and sliding axially inside this first seat between a rest position, in which it is further from the chamber before the first annular seat, and a working position, in which it is closer to the chamber before the first annular seat; and a tubular obturation member having on the one hand a rear part mounted in a sealed manner in the 7th piston at a distance from the first seat and the interior of which is connected to the first source, and on the other hand an annular face movable along a axis of the piston, urged by an elastic force in a first axial direction pointing towards the front chamber, and suitable for cooperating with the second seat in the latter's rest position to connect the outlet to the second source through the passage, and with the first seat in the working position of the second seat, to connect the output to the first source through this passage, while prohibiting communication between the two inputs in all cases.

 Devices of this type are well known in the prior art and have been used for a long time for the control of vacuum actuators integrated in the braking systems of any motor vehicle.

 A problem conventionally encountered in the design of any device of this type is that which consists in ensuring that the effort restored by this device when it returns to its state of rest is as close as possible to the effort required for its actuation, and that the latter is as low as possible.

 However, insofar as the shutter member must cooperate with seats of different diameters since one is inside the other, and insofar as these seats are subjected to different pressures, the shutter member is subjected to a differential pressure which on the one hand produces a difference between the attack and return forces of the control device, and which on the other hand requires to stress the annular face of this shutter member by means of a relatively large elastic force, which increases the value of the attack force.

 In this context, the present invention aims to provide a control device of the type defined above, but which nevertheless escapes the aforementioned drawback.

 To this end, the device of the invention is essentially characterized in that the annular face of the shutter member is connected to the rear part by its internal diameter, in that it slides tightly inside of the piston by its external diameter to define with the rear part of this obturation member a state storage chamber, and in that it is pierced with at least one orifice suitable for making this storage memory chamber communicate state with the passage formed between the two seats.

Other characteristics and advantages of the invention will emerge clearly from the description which is given below, by way of indication and in no way limiting, with reference to the appended drawings, in which
- Figure 1 is a schematic sectional view of a system of
air-assisted braking using a servomotor
classic
- Figure 2 is a sectional view of a device according to
the invention, in which the shutter member is shown
in its rest position; and
- Figure 3 is a sectional view of the same device, but in
which the shutter member is shown in its position of
job.

 Insofar as the invention relates only to an improvement made to pneumatic assistance braking systems, and where the general constitution and the operation of these are well known to those skilled in the art, these systems will not be quickly recalled here only to allow a complete understanding of the improvement represented by the invention.

 Schematically, a system of this type comprises a servomotor 1 and a master cylinder 2.

 The booster itself comprises a rigid casing 3 separated into two chambers 3a and 3b, in leaktight manner, by a movable partition 4 capable of driving a pneumatic piston 5 movable inside the casing 3.

 The front chamber 3a, the front face of which is closed in a sealed manner by the cylinder 2, is permanently connected to a low pressure source D through a non-return valve 6.

 The rear chamber 3b is however capable of being selectively connected either to the low pressure source D or to a high pressure source, for example to the atmosphere A.

 To this end, access to the rear chamber 3b is controlled by a valve 7 and a plunger 8, the latter being connected to a brake pedal 9 via a control rod 10.

 When the control rod 10 is in the rest position, in this case pulled to the right, the valve 7 normally establishes communication between the two chambers 3a and 3b of the booster.

 The rear chamber 3b then being subjected to the same vacuum as the front chamber 3a, the piston 5 is pushed to the right, in the rest position, by a return spring 11.

 The actuation of the plunger 8 by a movement of the control rod 10 to the left has the effect, firstly, of moving the valve 7 so that it isolates from each other the chambers 3a and 3b then, in a second step, to move this valve so that it opens the rear chamber 3b at atmospheric pressure A, through a filter 14.

 The pressure difference between the two chambers, then felt by the movable partition 4, exerts on the latter a thrust which tends to move it to the left and allow it to drive the piston 5 which in turn moves by compressing the spring 11.

 The braking force exerted on the plunger 8 by the control rod 10, or input force ", and the braking assistance force, or" assistance force ", resulting from the thrust of the movable partition 4, combine on a reaction disc 12 to constitute an actuating force transmitted to the master cylinder via a push rod 13.

 The assembly of the valve 7 and of the members which interact with it constitute the pneumatic control device of the booster.

 More specifically, such a device traditionally comprises three channels 15, 16 and 17; the pneumatic piston 5 itself; first and second annular seats 18, 19; and a shutter member 21, of tubular shape.

 The three channels themselves comprise a first input 15 connected to a first source delivering a relatively high pressure, in this case atmospheric pressure A, a second input 16 connected to the front chamber 3a of the booster and to a second source delivering a relatively low pressure, in this case depression D, and an outlet 17 connected to the rear chamber 3b of the booster, and making it possible to control the pressure in this chamber.

 Each of these channels opens into the hollow pneumatic piston 5 to allow the establishment of selective communication between any of the inputs 15 and 16 and the output 17.

 The first annular seat 18 is formed by an internal crown of the piston, on the outside of which the second inlet 16 opens, while the second annular seat 9 is formed by the periphery of the plunger 8, and is therefore closed axially by the bottom. of this diver.

 By sliding the plunger 8, the second seat 19 can move between a rest position, in which it is more distant from the front chamber 3a than the first annular seat 18, and which is that illustrated in FIGS. 1 and 2 , and a working position, in which it is closer than this first seat 18, and which is that illustrated in FIG. 3.

 As shown in FIG. 1, the second seat 19 is arranged inside the first seat 18, with a clearance which makes it possible to define a passage 20 connected to the outlet 17.

The shutter member 21, of tubular shape, has on the one hand a rear part 21a mounted leaktight in the piston 5 at a distance from the first seat 18 and the interior of which is connected to the first source A, and on the other hand share an annular face 21b movable along an axis of the piston and urged by an elastic force in a first axial direction
X pointing to the front chamber 3a.

 The annular face 21b cooperates with the second seat 19 in the rest position of the latter (Figures 1 and 2) to connect the outlet 17 to the second source D through the passage 20, and cooperates with the first seat 18 in the position of the second seat 19 (FIG. 3), to connect the output 17 to the first source A through this same passage 20, any communication between the two inputs 15 and 16 being prohibited regardless of the position of the plunger 8.

 According to the invention (Figures 2 and 3), the annular face 21b of the shutter member is connected to the rear part 21a by its internal diameter, and slides in leaktight manner inside the piston 5 by its external diameter to define with the rear part 21a of this closure member a state storage chamber 22.

 Furthermore, the annular face 21b of the shutter member is pierced with at least one orifice 23 suitable for making this state storage chamber 22 communicate with the passage 20 formed between the two seats 18 and 19.

 Thanks to this arrangement, the spring 24 intended to push the shutter member 21 in the axial direction X can apply only a very weak force, compared to that which it is necessary to provide in the prior art.

In fact, when the plunger 8 is in the rest position, as illustrated in FIG. 2, the chamber 22 communicates with the second source
D through orifice 23 and passage 20, and is therefore at low pressure.

 Under these conditions, the annular face 21b of the closure member 21 is pressed against the first seat 18 by the difference between the atmospheric pressure A and the depression D, so that it does not in theory need no additional solicitation.

 On the other hand, when the plunger 8 is in the working position, as illustrated in FIG. 3, the chamber 22 communicates with the first source A through the orifice 23 and the inlet 15 and is therefore at high pressure, that is to say in this case at atmospheric pressure.

 Under these conditions, the annular face 21b of the shutter member 21 is pressed against the second seat 19 by the difference between the atmospheric pressure A and the depression D, and in theory does not need any more additional stress. whether it be.

Claims (1)

CLAIM  1. A pneumatic control device for vacuum servomotor (1), comprising: three ways including a first inlet (15) connected to a first pressure source (A) delivering a relatively high pressure, a second inlet (16) connected to a front chamber (3a) of the booster and a second pressure source (D) delivering a relatively low pressure, and an outlet (17) connected to a rear chamber (3b) of the booster, the pressure of which is to be controlled; a substantially cylindrical hollow piston (5) into which each of the channels opens to allow the establishment of selective communication between any of the inputs (15, 16) and the output (17); a first annular seat (18) formed by an internal ring of the piston outside of which the second inlet (16) opens; a second annular seat (19), axially closed, mounted in the first seat (18) with a clearance defining a passage (20) connected to the outlet (17), and sliding axially inside this first seat (18) between a rest position, in which it is further from the front chamber (3a) than the first annular seat (18), and a working position, in which it is closer to the front chamber (3a) than the first annular seat (18); and a shutter member (21) of tubular shape having on the one hand a rear part (21a) mounted leaktight in the piston at a distance from the first seat (18) and the interior of which is connected to the first source (A) , and on the other hand an annular face (21b) movable along an axis of the piston, urged by an elastic force in a first axial direction (X) pointing towards the front chamber (3a), and suitable for cooperating with the second seat ( 19) in the rest position of the latter to connect the outlet (17) to the second source (D) through the passage (20), and with the first seat (18) in the working position of the second seat (19 ), to connect the output (17) to the first source (A) through this passage, while preventing communication between the two inputs (15, 16) in all cases, characterized in that the annular face (21b) of the shutter member (21) is connected to the rear part (21a) by its internal diameter, in that it slides in a sealed manner inside the piston (5) by its external diameter to define with the rear part (21a) of this shutter member a state storage chamber (22), and in that it is pierced with at least one orifice (23) suitable for communicating this state storage chamber (22) with the passage (20) formed between the two seats (18, 19).