CS213337B2 - Vacuum boosting facility - Google Patents

Description

The invention relates to a vacuum booster device for use in a vehicle hydraulic braking system or similar hydraulic system.

In vacuum boosters in which the active booster piston consists of a valve body disposed in the central portion of the booster main body and a piston plate surrounding the valve body and accommodating the differential pressure forces acting on the diaphragm, the piston plate is usually attached to the valve body by a plurality The inner circumference of the diaphragm is inserted between the two components. To this end, the screws are usually screwed into the threaded holes in the valve body and pass through the through holes of the piston plate. However, since an air passage is provided in the valve body to interconnect opposite sides of the diaphragm in the rest position of the booster, it is necessary to arrange threaded holes outside the air passage, which increases the diameter of the valve body. Furthermore, the depth or length of the threaded holes must be sufficiently large that the screw connection has sufficient contact force, so that the thickness of the valve body must also be large. The threaded holes are stressed mechanically by tightening the screws and, moreover, thermally when the valve body is made of synthetic resin, so that strength problems arise. As the screw heads protrude from the surface of the piston plate, it is difficult to reduce the size of the booster.

In order to overcome these problems, a vacuum booster device has been proposed, as described in Japanese Application No. 178794/75, wherein the piston plate applied to the differential pressure force between the two chambers formed in the main body of the vacuum booster has a bore and a cylindrical body. The valve, provided with a valve device for interconnecting or breaking the connection between the two chambers and between one of the chambers and the atmosphere, has at one end a shaped head mounted on a neck that can only be inserted into the piston plate aperture in a particular position of the valve body and the piston plate. The piston plate, the diaphragm and the valve body are joined together by sliding the valve body head into an opening in the piston plate, the diaphragm lying between the valve body and the piston plate, and then rotating the piston plate around the neck of the valve body by a predetermined angle. Thus, relative diaphragm rotation between the valve body and the piston plate is prevented only when clamped together; after a longer period of operation, as a result of this, there is a mutual

213 337 rotates the valve body and the piston plate under vibration and releases their joint due to permanent deformation of the diaphragm so that in the extreme case the piston plate is released from the valve body.

SUMMARY OF THE INVENTION The present invention is directed to a vacuum booster device comprising a main body, a piston plate and a resilient diaphragm dividing the interior of the main body into two chambers, a cylindrical valve body accommodating a valve device for making or breaking connections between the chambers and between and a bayonet connection provided between the piston plate and the valve body.

The bayonet connection consists of a non-circular opening formed in the central part of the piston plate and a non-circular head of corresponding shape formed at one end of the valve body, and. a rotation control member mounted on a piston plate, a portion of which is arranged. near the outer circumference of the valve body head to control relative rotation between the valve body and the piston plate when the non-circular valve body head has passed through the non-circular opening in the piston plate and the piston plate is rotated relative to the valve body to connect the piston plate to the valve body.

The construction according to the invention has the disadvantage that the piston plate is connected to the valve body completely reliably, so that the booster system operates without failure for virtually unlimited time; At the same time, the connection is very simple in terms of both parts and assembly and allows a substantial reduction in production costs.

The invention will be explained in detail in conjunction with. Fig. 1 is a longitudinal cross-sectional view of the vacuum booster; Fig. 2 is an enlarged side view showing a substantial part of the booster; Fig. 3 is a section taken along line III-III in Figs. 2, 4 and 5; 2 'and 3', but showing another embodiment, and FIG. 6 shows a side view of a modified embodiment of the booster according to the invention.

The vacuum booster device (FIG. 1) comprises a main body 1, a valve body 2 slidably mounted in a sealing member 2 'attached to the main body 1, a piston plate 3 and a diaphragm 4 which divides the interior of the main body 1 into two chambers A, B The piston plate 3 is loaded with a differential pressure by a differential pressure force At the inner end of the valve body 2, a non-circular cross-section head 2a is formed (FIG. 2) and a hole 3a is formed in the central part of the piston plate. The valve body 2 and the piston plate opening 3a may have any non-circular shape into which a suitable size circle can be inscribed, for example a square, hexagon, octagon or a circle with a cut-out or projection on the circumference, so that the two components can be aligned with each other in a certain relative position. connecting continuously to the head 2a of the valve body 2 allows rotation of the piston plate 3 if the head 2a of the valve body 2 has passed through the opening 3a. The cross-section of the neck 2b may have any suitable shape allowing relative rotation of the piston plate 3 when the neck 2b lies in the opening 3a, but preferably has the shape of a circle inscribed in the head 2a to give the neck 2b a high strength. The annular projection 2c adjoins the neck 2b and serves to clamp the inner periphery of the diaphragm 4 between the piston plate 3 and the valve body 2. On the inner periphery of the diaphragm 4 is an annular protrusion 4a which projects (FIG. 3) in the thickness direction of the diaphragm 4 when the compressive force is not applied.

The bayonet connection of the individual parts of the vacuum booster device is formed by placing the inner periphery of the diaphragm 4 on the annular projection 2c of the valve body 2, the head 2a of the valve body 2 being inserted into the opening 3a of the piston plate 3. a certain relative position is maintained, the piston plate 3 being compressed in the direction of the axis of the valve body 2 against the action of the elastic force of the inner peripheral portion of the diaphragm 4 so that the head 2a of the body. 2, the piston plate 3 is rotated about the neck 2b by a predetermined angle. In the embodiment shown in FIG. 2, it is possible to reliably clamp the diaphragm 4 between the piston plate 3 and the valve body 2 by rotating the piston plate 3 by an angle of less than 90 °, preferably 45 °, due to the resilience of the inner peripheral portion of the diaphragm 4. . The annular protrusion 4a of the diaphragm 4 can be replaced by an annular protrusion (not shown) on the inner circumference of the piston plate 3 on the side facing the diaphragm 4. The active piston according to the invention comprises a valve body 2, diaphragm 4 and piston plate 3 joined together by a bayonet connection or similar fasteners by rotating the piston plate 3 relative to the valve body 2. by a predetermined angle. Then, the outer peripheral portion of the membrane 4 is clamped between the portions 1a, 1b of the main body 1.

The ring 4 ', located in the annular groove in the diaphragm 4, prevents the material flow of the inner peripheral portion of the diaphragm 4 radially outward, which could be caused by the compressive stress exerted by the piston plate 3 and the valve body 2 and the tensile stress applied to the outer periphery of the diaphragm during use of the vacuum booster.

The vacuum booster apparatus further comprises reaction levers 7 and pins 8 disposed between the cover plate 9 and the plate 10, which form a rotation control member. The latches 9a, on the cover plate 9, are inserted into the holes 10a in the plate 10 so that the two plates are joined in one piece. The plate 10 further has a flange 10b inserted into the annular groove 2d of the valve body 2, and a latch portion 10d leaning on the outer peripheral portion 2e of the valve body 2a to control the relative rotational movement between the valve body 2 and the piston plate 3. on the left surface of the valve body 2 and the piston plate 3 [FIG. after the active piston has been assembled as described, so that the flange 10b of the plate 10 fits into the groove 2d of the valve body 2 and thus adjusts the relative position of the piston plate 3 and the plate 10 in the radial direction. The pawl portion 10d of the plate 10 is inserted into one of the gaps 11 between the piston plate 3 and the valve body 2, lying close to the flat outer peripheral portion 2e of the head 2a of the valve body 2. Since, in this position, the latch portion 10d, as clearly shown in FIG. 3, protrudes to the inner periphery of the bore 3a in the piston plate 3, the plate 10 cannot rotate relative to the piston plate 3 when the latch portion 10d engages the inner periphery of the bore 3a. . Once the piston plate is rotated relative to the valve body 2, the latch portion 10d engages the inner periphery of the opening 3a of the piston plate 3 as well as the outer peripheral portion 2e of the valve body head 2a, thereby limiting their relative rotation to a lesser extent than a predetermined assembly angle.

Giant. 4 and 5 show another embodiment in which a latch portion 3b is formed on the piston plate 3 to engage a corresponding aperture 10c in the plate 10 so as to control the relative rotation between the piston plate 3 and the plate 10. In this embodiment, the latch portion 10d acts only in terms of limiting the relative rotation between the plate 10 and the valve body 2. Since the relative rotation of the plate 10 and the piston plate 3 can be controlled within a very small range given by the dimensional tolerance, the relative rotation between the piston plate 3 and the valve body 2 is limited to a small range. It will be appreciated that a plurality of equally spaced latch portions 3b, as shown in Fig. 6, may be formed on the piston plate for individual engagement with holes of the corresponding shape formed in the plate 10 to facilitate assembly. In the embodiment of Fig. 6, the latch portion 10d of the plate 10 normally abuts on the generally flat outer peripheral portion 2e of the valve body head 2a, while in the embodiment of Fig. 2 it is between the radially inner surface of the latch portion 10d and the outer peripheral portion 2e of the head 2a. valve body 2 space.

In the illustrated embodiments, the plate 10 supports the reaction lever 7 and is provided with pins 8 which serve as pivot points for the pivoting movement of the reaction levers 7, thereby effectively controlling the relative rotation of the valve body 2 and the piston plate 3 to the desired range without increasing the number of components. However, it is possible to use a member separate from the main components of the booster device which is fixed non-rotatably to the piston plate and engages the outer peripheral surface of the head 2a of the valve body 2.

Hereinafter, the entire structure and operation of the vacuum booster shown in FIG. 1 will be briefly described. Unless the inlet rod 5 associated with a brake pedal (not shown) or the like is depressed, the valve body 2 and the piston plate 3 are pushed to the right in the drawing by a return spring 6; so that the stops 4 ”on the membrane 4 abut the side wall of the part 1b of the main body 1. In this state the chamber is

A, permanently connected to a vacuum source, such as an engine intake manifold (not shown), in communication with chamber B through the space between the support plate 23 and the cover plate 9, the spaces between the reaction levers 7, through the passage 2Ϊ formed in the valve body 2 via the annular seat 12 and the poppet 13, through the annular space 14 in the valve body 2 and through the radial channel 15, the inlet rod 5 being maintained in the idle position shown in the drawing by a return spring 16. When the inlet rod 5 moves to the left against the action of the return spring 16, for example by depressing the brake pedal, the poppet valve 13 moves to the left relative to the valve body 2, which at this time is stationary, so that it engages the valve seat 12 and breaks the connection between the chambers A,

B. When the inlet rod moves further to the left, the second valve seat 17 'formed on the plunger 17, which is arranged slidably in the valve body 2 and connected to the inlet rod 5, moves away from the poppet valve 13. Thus, the chamber 18, connected permanently with the atmosphere through the filter 20 and the atmospheric air inlet 19 'provided in the anti-dust boot 19, communicates with chamber B through space 14 and channel 15. The pressure in chamber B increases to atmospheric pressure and between chambers A, B creates pressure. so that the diaphragm 4, the piston plate 3 and the valve body 2 move to the left in the drawing. The differential pressure force is transmitted to the piston of the master cylinder or similar device (not shown) via the piston plate 3, the reaction levers 7, the support plate 23 and the output rod 21.

The inlet rod 5 is subjected to a reaction force because the outer ends of the reaction levers 7 lie between the piston plate 3 and the annular projecting portion 23a of the support plate 23 and the inner ends of the reaction levers 7 are supported on the plunger 17. transmitted by the support plate 23 and the reaction levers 7 to the plunger 17 and the inlet rod 5.

As a result of the reaction force against the pressure of the inlet rod 5 and the movement of the valve body 2 to the left, the poppet 13 rests on the second valve seat 17 'again and breaks the connection between chamber B and the atmosphere.

As the pressure applied to the inlet rod 6 is reduced, a clearance is created between the valve seat 12 and the poppet valve 13, thereby reducing the pressure in chamber B and bringing the booster to a new equilibrium state, determined by the position of the inlet rod 5, or by reaction in the outlet rod 21, the force of each of the springs 6, 16, the differential pressure applied to the diaphragm 7, and the force applied to the inlet rod 5. If the downward force acting on the inlet rod 5 drops to zero, the vacuum booster returns to of the state shown in FIG. 1.

It goes without saying that the invention is not limited to the vacuum booster of the described design and function, and that it can be applied to the active pistons of vacuum boosters of any other type provided the active piston is a valve body and a piston plate connected to each other by a bayonet connection. .

In the vacuum booster according to the invention, the plate 10 is a rotation control member and its latch portion 10d lies close to the head 2a of the valve body 2 and regulates the rotation of the valve body 2 relative to the piston plate 3 to a predetermined range so effectively preventing relative rotation between the valve body 2. the piston plate 3 due to vibrations or the like during prolonged use and avoids separation of the valve body 2 from the piston plate 3. Since the plate 10 is mounted non-rotatably on the piston plate 3, the relative rotation range between the piston plate 3 and the valve body 2 can be limited to a minimum and reliably prevent them from disconnecting.

According to the invention, the active piston is formed by the bayonet connection of the piston plate 3, the diaphragm 4 of the valve body 2 and the plate 10 forming the rotation control member. The assembly consists of inserting the head 2a of the valve body 2 into the opening 3a of the piston plate 3 and turning them at a small angle relative to each other, so that it is very easy and fast compared to conventional devices using a plurality of clamping screws. membrane 4 and valve body 2.

The valve body 2 is free of threaded holes so far necessary, so that it can have a small outer diameter and thickness and hence the dimensions of the entire vacuum booster device are small. In addition, there is no stress concentration observed around the threaded holes in the prior art devices. The invention is particularly suitable for vacuum boosters with reaction levers, since screw heads do not protrude from the side walls of the valve body 2 and there is sufficient space inside the main body 1 of the vacuum booster.

Claims (1)

SUBJECT OF THE INVENTION A vacuum booster device comprising a main body, a piston plate and a resilient diaphragm dividing the interior of the main body into two chambers, a cylindrical valve body accommodating a valve device for establishing or breaking the connection between the two chambers and between one of the chambers and the atmosphere, and bayonet a connection provided between the piston plate and the valve body, characterized in that the bayonet connection is formed by a non-circular bore (3a) formed in the central part of the piston plate (3) and a non-circular head (2a) of corresponding shape formed at one end of the body (2) a valve member (10) mounted on the piston plate (3'1), a portion (10d) of which is disposed near the outer periphery of the valve head (2a) of the valve body (2) to control relative rotation between the body (2) valve and piston plate (3) if the non-circular head (2a) of the valve body (2) has passed through the non-circular bore (3a) in the piston The piston plate (3) and the piston plate (3) are rotated relative to the valve body (2) to connect the piston plate (3) to the valve body (2).