Pneumatic brake booster

Abstract

A pneumatic brake booster includes a drive piston actuating a master cylinder by a push rod while being returned to rest position by a return spring. The brake booster has a vibration damper having a part made of an elastic material working compressively, of overall parallelepipedic shape, with a length greater than the spacing of two coils of the spring prior to its installation in the brake booster and whose front and back faces are equipped with a longitudinal slit penetrating the material mass of the damper for engagement by way of those slits on the two coils of the return spring.

Claims

1. A pneumatic brake booster, comprising: a drive piston connected by a membrane to a brake booster cylinder to subdivide the brake booster cylinder into a forward chamber and a rear chamber and operate by a pressure drop to push a piston of a master cylinder by means of a push rod, the pressure drop in the brake booster cylinder driving the drive piston being controlled by a plunger valve actuated by the movement of a control rod connected to a brake pedal, the drive piston being thrust into rest position by a return spring supported by a wall of the brake booster cylinder; and a vibration damper, included with the return spring, wherein the vibration damper includes a part made of an elastic material working compressively, of parallelepipedic external shape, with a length greater than a spacing of two neighboring coils of the return spring prior to installation in the brake booster and whose front and back faces are each equipped with a longitudinal slit penetrating the material mass of the vibration damper, for engagement by way of the two longitudinal slits on the two neighboring coils of the return spring, wherein each of the longitudinal slits penetrates into the material mass of the vibration damper to a respective depth, and the length of the vibration damper minus a sum of the respective depths is less than a spacing of the two neighboring coils of the return spring at rest.

2. The pneumatic brake booster of claim 1, wherein there are multiple vibration dampers distributed around the return spring.

3. The pneumatic brake booster of claim 1, wherein the longitudinal slits are each terminated by a cavity forming a retention housing for securing the neighboring coils of the return spring.

4. The pneumatic brake booster of claim 1, wherein one of the longitudinal slits is equipped with an entrance sized to have a width greater than a width of a remaining portion of the one of the longitudinal slits.

5. The pneumatic brake booster of claim 4, wherein the entrance is sized to accommodate one of the neighboring coils of the return spring when the vibration damper is in an undeformed state.

6. The pneumatic brake booster of claim 4, wherein the entrance has an opening at the one of the front or back faces sized greater than a thickness of the neighboring coils of the return spring.

7. The pneumatic brake booster of claim 6, wherein the entrance decreases in size from the opening to where the entrance joins the remaining portion of the one of the longitudinal slits.

8. The pneumatic brake booster of claim 1, wherein the longitudinal slits are planar.

9. The pneumatic brake booster of claim 1, wherein the vibration damper is an elastic foam.

10. The pneumatic brake booster of claim 1, wherein there are two vibration dampers distributed around the return spring, the two vibration dampers being located in symmetrical positions about a longitudinal axis of the return spring.

11. The pneumatic brake booster of claim 1, wherein the vibration damper includes a portion of the elastic material extending between the longitudinal slits.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is an axial cutaway of a pneumatic brake booster according to the invention.

(2) FIG. 2 is an isometric view of an example of a damper.

(3) FIG. 3A shows the relaxed return spring, prior to its installation in the brake booster.

(4) FIG. 3B shows the state of the return spring after installation in the brake booster at rest.

(5) FIG. 3C shows the state of the return spring and damper in compressed braking position.

(6) FIG. 4A shows the damper mounted on the return spring before installation of the return spring in the brake booster.

(7) FIG. 4B shows the damper on the return spring installed in the brake booster.

(8) FIG. 4C shows the compression of the damper during the braking phase.

(9) FIGS. 5A, 5B and 5C show an embodiment of a damper shown in three states corresponding to the states shown generally in FIGS. 4A, 4B and 4C.

(10) FIG. 6A shows the damper mounted on the relaxed return spring, prior to its installation in the brake booster;

(11) FIG. 6B shows the return spring with the damper in installed position in the brake booster.

DETAILED DESCRIPTION

(12) FIG. 1 shows generally and schematically, the structure of a pneumatic brake booster 100 according to the invention, represented in combination with master cylinder 200.

(13) Brake booster 100 consists of housing 110 (here called a cylinder), accommodating drive piston 120 connected by membrane 121 to the housing to subdivide the latter into a forward chamber, CHAV, and a rear chamber, CHAR. Plunger piston 120 bears plunger valve 130 connected to control rod 131, itself connected to the brake pedal. Drive piston 120 acts on push rod 140 borne by piston 210 of master cylinder 200 by reaction disk 122. Drive piston 120 is pushed into rest position (the position represented in FIG. 1) by return spring 150, resting against piston 120 and against forward wall 111 of housing 110 around the opening traversed by the master cylinder and its piston 210.

(14) The structure of brake booster 100 described above is known in itself and does not require more detailed description.

(15) Master cylinder 200 is attached to the firewall of the vehicle passenger compartment near the brake pedal, in general by two anchors 220.

(16) During action on the brake pedal, which is transmitted by control rod 131 to plunger valve 130, the latter controls the pressure drop in the forward chamber, CHAV, which draws drive piston assembly 120 and membrane 121 forward (toward the left in FIG. 1) to push, by reaction disk 122, push rod 140 of piston 210 of the master cylinder and control the flow of pressurized hydraulic fluid through the brake circuit or circuits connected to the master cylinder.

(17) The movement of drive piston 120 occurs against the force developed by return spring 150, which, at the conclusion of the braking phase, pushes drive piston 120 into the position shown in FIG. 1.

(18) Return spring 150 is equipped with vibration damper 160, shown very schematically as being installed on two coils Si, Sj, of spring 150. This damper 160 can consist of one or more dampers, for example, two dampers in symmetrical position with respect to axis xx of spring 150.

(19) In the example of FIG. 1, spring 150 is a cylindrical helical spring, but it could also be a frustoconical helical spring. That example is not shown.

(20) According to the schematic representation of FIG. 2, damper 160 is an elongated part, parallelepipedic or, more generally, cylindrical in the geometric sense of the term, of round or polygonal section, which may be rectangular. This part has length L and two faces, 161, 162, a front face, 161, and a rear face, 162, according to the customary orientation of a brake booster.

(21) Two slits, 163, 164, with the same orientation divide each extremity by penetrating the mass of the body of damper 160 in such a way that the damper can be installed to straddle two neighboring coils, Si, Sj, of the spring; slits 163, 164 are terminated by a small terminal cavity with a round cross-section, 165, 166, forming a pocket to accommodate a coil segment of the spring and take hold there, while also constituting a rounded surface, thereby avoiding the creation of an incipient fracture.

(22) Slits 163, 164 have a depth 11, 112 from respective faces 161, 162.

(23) Slits 163, 164 are here planar but they can also be curved. Each extremity straddles an associated coil sector, straddling it in such a way that the damper works compressively whenever the return spring locally deforms the slit (or groove) created by the curve of the coil, which increases the contact between the segment of the coil and the absorbing elastic material and not only prevents the damper from migrating by twisting along the two coils but this significant contact also absorbs the vibrations of the coil and, more generally, those of the spring.

(24) As shown in FIGS. 3A-3C, in combination with the diagrams of FIGS. 4A-4C, damper 160 may be installed on two coils, Si, Sj, not at an extremity of spring 150 but more or less in the middle of its length, which is thereby divided into two portions for its resonant properties, without this interfering with the spring's operation as a return spring. To avoid unbalancing, even slightly, spring 150, damper 160, which is only associated with a reduced arc of coils Si, Sj, may also be symmetrically complemented, with respect to axis xx of the cylindrical or conical spring, by another damper 160.

(25) As can be seen in FIGS. 3A and 4A, damper 160 consists of a part made of elastic material operating compressively, such as a block of elastic foam, of parallelepipedic shape, of length (L) greater than the distance Dr separating two coils Si, Sj of the return spring when not installed in position in the master cylinder along longitudinal slits 163, 164, along axial direction xx of return spring 150.

(26) Damper 160 is installed between two coils Si, Sj by simply fitting each of the two coils into longitudinal slit 163, 164. Longitudinal slits 163, 164 have length 11, 12, such that the difference in the total length L, less the sum of lengths 11, 12, is less than the distance Dr of two coils Si, Sj at rest. Thus, when damper 160 is mounted on the two coils of return spring 150 prior to installation in brake booster 100, the two coils Si, Sj are not at the cavities 165, 166 of the two longitudinal slits 163, 164, as shown in greater detail in FIG. 4A. To the right of FIG. 3A, we have shown damper 160 installed on coil segment Si, Sj and deforming slit 163, 164, which receives this coil segment.

(27) In addition to coils Si, Sj housed in slots 163, 164 of damper 160, the coils are also shown above damper 260 in each of the positions to facilitate identification of the spacing in the three positions of FIGS. 4A, 4B, and 4C.

(28) The same remark applies to FIGS. 5A, 5B, and 5C, which are also complemented by coils Si, Sj, shown above damper 260 in each representation.

(29) To install spring 150 equipped with damper(s) 160 in the brake booster, it must be compressed (FIG. 3B) so that the two coils Si, Sj engaged in damper 160, slide to cavities 165, 166 of slits 163, 164 of damper 160 (FIG. 4B), which need not be compressed in this position.

(30) Finally, during braking, which results in the advance of the drive piston and compression of return spring 150 (FIG. 3C), damper 160 is compressed as the two coils Si, Sj approach one another. When the brake is released, return spring 150 relaxes and damper 160 transitions from its deformed position, shown in FIG. 4C, to its rest position, shown in FIG. 4B. This deformation, as with the compression of damper 160, absorbing the vibrations of return spring 150.

(31) FIG. 5 shows a practical embodiment 260 of damper 160, presented in a general manner in FIGS. 2 and 4A-C.

(32) Damper 260 consists of a parallelepiped of elastic material, notably a foam, of length L, as described above, having two longitudinal slits 263, 264 issuing from each of end faces 261, 262 for engagement with two neighboring coils Si, Sj of spring 150. Slits 263, 264 terminate in rounded pocket 265, 266, for example, of circular section, which prevents the extremity of each slit from becoming an incipient fracture, while enabling retention of damper 260 on coils Si, Sj by a positive fit when spring 150 is in installed position (FIG. 5B) in the cylinder of the brake booster.

(33) In this embodiment, damper 260 remains securely attached to the two coils Si, Sj of the spring whenever the latter is compressed and released, as shown in FIGS. 5B and 5C. In FIG. 5B, damper 260 is not compressed and its two end faces 261, 262 are flat, whereas in FIG. 5C, spring 150 compresses damper 260, whose faces 261, 262 are thereby curved into a concave shape and the longitudinal sides are mushroom shaped.

(34) FIG. 6 illustrates a variant embodiment of damper 360, whose longitudinal slits 363, 364 are not symmetrical. Slit 363 is terminated by pocket 365 for attachment by positive fit on coil Si once damper 360 is installed on the spring, prior to its installation in the brake booster. In this position, shown in FIG. 6A, the other coil, Sj, is found in an enlarged entrance 367, which initiates longitudinal slit 364 of the other face 362 of damper 360. This slit 364 is also terminated by a rounded pocket 366, for example, of circular section.

(35) FIG. 6A illustrates the pre-assembled position of damper 160, while FIG. 6B illustrates the position of spring 150 when installed in the brake booster. At this moment, the other coil Sj is engaged and retained in pocket 366 at the extremity of second longitudinal slit 364.

(36) The reference list is as follows: 100 Brake booster 110 Housing 111 Front wall 120 Drive piston 121 Membrane 122 Reaction disk 130 Plunger 131 Control rod 140 Push rod 150 Return spring 160, 260, 360 Dampers 161, 162 Damper faces 261, 262 Damper faces 361, 362 Damper faces 165, 166 Terminal cavities 265, 266 Terminal cavities 365, 366 Terminal cavities 163, 164 Longitudinal slits 263, 264 Longitudinal slits 363, 364 Longitudinal slits 367 Enlarged entrance 200 Master cylinder 210 Piston 220 Anchor