GUIDING SYSTEM FOR A BRAKE PISTON OF A MOTOR VEHICLE DISK BRAKE

Abstract

A guiding system for a brake piston of a motor-vehicle disk brake comprises a brake piston, a cylindrical brake-piston bore for accommodating the brake piston in a housing in such a way that the brake piston can be axially displaced, and a ring seal supported in the housing in an axially immovable manner, which ring seal is elastically clamped between a cylindrical brake-piston wall and a recess in the brake-piston bore. In order to improve the NVH behavior in the avoidance of disturbing noises of motor-vehicle disk brakes, a reversibly elastically preloaded guiding means is clamped between the brake-piston bore and the brake-piston wall, which guiding means is supported on the housing and couples the brake piston to the brake-piston bore in such a way that the brake piston is oriented in a specific manner.

Claims

1. A guiding system for a brake piston of a motor vehicle disk brake comprising: a brake piston; a housing defining a brake piston bore for accommodating the brake piston, wherein the brake piston is axially displaceable relative thereto; a guide device, which is elastically clamped between a cylindrical brake piston wall and a groove in the brake piston bore; a sealing ring; and wherein the brake piston is reversibly elastically clamped in the brake piston bore by the guide device, impelled in a radial direction by a defined action of lateral forces, in order to afford the brake piston wall a directed modal-acoustic coupling to the brake piston bore.

2. The guiding system of claim 1, wherein the guide device and the sealing ring are arranged in the groove of the brake piston bore.

3. The guiding system of claim 2, wherein the guide device comprises at least one component formed at least partially from a plastic material.

4. The guiding system of claim 1, wherein the guide device and the sealing ring are formed as separate components from another.

5. The guiding system of claim 1, wherein the guide device and the sealing ring are arranged at an axial interval from one another in separate recesses in the brake piston bore.

6. The guiding system of claim 5, wherein the recesses comprise fixing elements.

7. The guiding system of claim 6, wherein the fixing elements are bearing faces for the sealing ring and the guide device.

8. The guiding system of claim 1, wherein the forces applied to the brake piston by the guide device in a radial direction is distributed symmetrically and equally over a brake piston circumference.

9. The guiding system of claim 1, wherein the forces applied to the brake piston by the guide device in a radial direction is distributed asymmetrically and unequally over a brake piston circumference, in such a way that a resultant lateral force impresses one of a preferred orientation and a predefined setting angle on the brake piston in relation to the brake piston bore.

10. The guiding system of claim 1, wherein the guide device comprises one of multiple convex projections such as ribs and multiple recesses distributed over its circumference.

11. The guiding system of claim 1, wherein the guide device is provided with at least one of: at least ventilation duct and at least one aperture for the equalization of pressure and for returning fluid into a pressure chamber.

12. The guiding system of claim 1, wherein the guide device comprises at least one arm, which is resiliently clamped between the housing and the brake piston.

13. The guiding system of claim 12, wherein the guide device is formed as an elastic clip having multiple arms radiating radially from a center with free ends, wherein the arms are accommodated in fixing depressions of the housing, and wherein the free ends each additionally comprise at least one spring element.

14. The guiding system of claim 1, wherein at least one of the guide device and the sealing ring is formed eccentrically.

15. The guiding system of claim 1, wherein the groove for accommodating the at least one of the guide device and the sealing ring is arranged offset with an axial offset in a radial direction relative to the bore axis.

15. The guiding system of claim 1, wherein one of the guide device and the sealing ring is formed from elastomer material having at least two moduli of elasticity designed for differing pliability, and wherein the different moduli of elasticity are provided alternately on the circumference.

16. The guiding system of claim 1, wherein one of the groove and the recess is provided with a profiled bearing surface, which comprises at least one base surface having an irregularity.

17. The guiding system of claim 16, wherein the irregularity is formed as one of: a sectoral flattening, a protuberance, a recess, and another deformation of the base surface in order to obtain a radially directed pressure modulation on the piston orbitally at the circumference though correspondingly interlocking action on one of the sealing ring and the guide device.

18. The guiding system of claim 17, wherein the irregularity is provided as a radially directed variation in the radius of the recess.

19. The guiding system of claim 16, wherein the groove comprises multiple irregularities staggered by an angle at the circumference.

20. The guiding system of claim 1, wherein the location of the irregularity produces a resultant lateral force at the circumference of the brake piston.

Description

DETAILED DESCRIPTION

[0025] Each hydraulic actuator such as, in particular, a motor vehicle disk brake 1 comprises at least one guiding system 2 for at least one translationally displaceable brake piston 3, which is accommodated in a housing 4, such as, in particular, in a brake caliper or cylinder. Here the guiding system 2 may relate equally both to the guiding systems of the brake pistons of input actuators (that is hydraulic brake master cylinders, for example) or to the guiding systems for brake pistons of output actuators (such as motor vehicle hydraulic disk brakes, for example).

[0026] Brake master cylinders generally comprise two brake pistons (primary and secondary piston), hydraulically connected independently of one another and accommodated so that they are translationally displaceable in a bore, which pistons as a displaceable wall define pressure chambers, which are connected to pressure chambers of associated motor vehicle disk brakes, which are in turn defined by brake pistons. In a motor vehicle disk brake 1 of the floating-caliper type at least one brake piston 3 defines a pressure chamber 5, which is actuated by a hydraulic upstream input actuator. Motor vehicle disk brakes 1 of the fixed-caliper type, however, comprise at least one brake piston 3 on each side of a brake disk 6.

[0027] When actuated by a master cylinder, incompressible brake fluid in each volumetrically closed hydraulic system (master cylinder, pipelines, brake hose lines, motor vehicle disk brake 1, brake piston 3) is subjected to hydraulic pressure in accordance with the law of volume constancy, in such a way that at least one friction lining 7, 8 is directly or indirectly pressed against a rotor (brake disk 6) by the brake piston 3 after overcoming a so-called free travel. A surface unit pressure (cf. brake pressure), which correlates with a specific brake application force, serves as a measure of this braking action. For releasing the motor vehicle disk brake 1 the master cylinder is released, unactuated. The sealing ring 9 is accommodated in a recess/groove 10. The elasticity and elastic roll-back effect of the sealing ring 9 is exploited for returning the brake piston 3. Consequently, the desired clearance after braking is produced substantially by a reversible return deformation of the sealing ring 9.

[0028] A brake piston 3 is basically of cup-shaped construction and comprises a brake piston head 11 and a cylindrical brake piston wall 12. According to the type of disk brake, either the brake piston head 11 or an exposed edge of the brake piston wall 12 may act directly on the friction lining 7, 8.

[0029] The guiding system 2 for a brake piston 3 of a motor vehicle disk brake 1, or other actuators, comprises a brake piston bore 13 arranged concentrically with and cylindrically around the brake piston 3 for the axially displaceable accommodation of the brake piston 3 in the housing 4 (in particular a brake caliper housing), and a sealing ring 9 which is supported in the brake caliper housing and is elastically clamped between the cylindrical brake piston wall 12 and the recess 10 of the brake piston bore 13, and which serves the functions described above.

[0030] A guide means 15 is provided in a reversibly elastically clamped manner in a gap 14 between the brake piston bore 13 and the brake piston wall 12, which guide means is supported on the brake caliper housing and permanently clamps the brake piston 3 with a defined action of forces in a radial direction in such a way that the brake piston wall 12 is coupled, with a specific orientation, to the brake piston bore wall. This accordingly results in an oriented accommodation of the brake piston 3 in the housing 4. A guide means 15 clamping with a defined elastic pliability affords an improved introduction of lateral forces into the housing 4.

[0031] The guide means 15 is to be integrally formed with the sealing ring 9 and arranged in a common recess of the brake piston bore 13, so as to reduce the assembly and machining outlay. If the machining and assembly outlay are of lesser concern, and a facility for separate replacement is desired, the guide means 15 and the sealing ring 9 may be formed and accommodated side-by-side as separate components. For this purpose, the guide means 15 and the sealing ring 9 are located at an axial interval from one another, each in separate recesses 10, 16 of the brake piston bore 13. The recesses 10, 16 may comprise fixing means such as, in particular, parallel bearing faces 17, 18 for the sealing ring 9 and the guide means 15. In principle, there is scope for providing the guide means 15 with a uniform clamping force over the circumference of the brake piston. In service this automatically results in the provision of a brake piston axis A substantially at right angles to the friction surfaces of the brake disk 6.

[0032] In an alternative configuration, wherein a sealed gap 14 runs between the brake piston bore 13 and the brake piston wall 12, and the brake piston axis A is not set at right angles to the friction surface of the brake disk 6 but at a defined oblique angle. This is achieved in one embodiment in that a radial action of force of a clamping of the brake piston wall 12 is not provided uniformly over the brake piston circumference, and the lateral forces do not cancel one another out. What is more, as a result a defined lateral force with a corresponding resultant preferred orientation is impressed on the brake piston 3, wherein the setting angle obtained corresponds to the direction of the resultant lateral force. The action of the forces, in this way non-uniformly distributed over the brake piston circumference, for producing a setting angle can be obtained through corresponding adaptation of the elasticity of a material of the guide means 15.

[0033] Accordingly, according to FIGS. 3-5 a cross section of the guide means 15 is specifically designed to be pliably elastic in a preferred displacement area, for example through raised ribs 19 protruding convexly outwards, lobes or similar projections and at least one correspondingly associated integral cavity 20. The cavity 20 affords the necessary elastic freedom of movement. Moreover, a radial lateral force is impressed on the brake piston 3, where necessary lending it a predefined, desired setting angle . The individual ribs 19 or lobes preferably extend more lengthwise than widthwise and running uniformly in an axial direction, that is to say oriented parallel to the brake piston axis A. The height of the ribs 19 in this context defines the radial clamping of the brake piston 3 in accordance with the outside diameter of the brake piston wall 12 and the inside diameter of the brake piston bore 13.

[0034] In a simple variant according to FIGS. 6-8 a separate guide means 15 may be formed as a simple corrugated ring from a solid material (for example spring steel) of uniform wall thickness, the cross section of which is meander-shaped and has alternating convex and concave portions. A correspondingly adapted coaxial-cylindrical brake piston wall and a coaxial-cylindrical brake piston bore 13 are assigned to this. Alternatively or in addition to this another variant suggests itself, in which the guide means is formed as a bow spring having at least one sprung arm.

[0035] As a further alternative or addition, it is feasible to provide the respective groove seats for the sealing ring and/or guide means axially offset in the housingthat is to say with an axial offset in relation to the piston bore. As a further alternative or addition, it is feasible to form the sealing ring and/or the guide means eccentrically. As a further alternative or addition, it is possible to provide the sealing ring 9 and/or the guide means 15 formed from a material of different elasticity. It is possible for the elastic guide means 15 to comprise at least one component formed at least partially from a metal material, such as, in particular, spring steel. It is in particular possible to provide different, alternating moduli of elasticity in relation to the azimuth angle (Az). This is possible, for example, by virtue of the aforementioned material composite structure and/or another elastomer multi-material construction.

[0036] Alternatively or in addition, the orbital elastic pressure modulation at the circumference, in particular directed radially at the brake piston 3, may be obtained in that a recess 10, 16 for accommodating the sealing ring 9 and/or guide means 15 is provided with a profiled base surface 40 by providing at least one or more irregularities on the circumference of the base surface 40. The irregularity may be formed as a sectoral flattening, protuberance, recess or other deformation of the base surface 40, allowing a correspondingly modified accommodation and action of the sealing ring 9 and/or guide means 15 to achieve correspondingly modified, modulated spring effects, which orbitally at the circumference produce the desired pressure modulation, basically directed radially at the piston 3. Accordingly, the irregularity/irregularities is/are preferably provided radially oriented in the base surface 40 and may preferably be designed as variations in radius, so that the base surface runs as a closed, non-circular, elliptical, ovoidal or other freeform curve around the brake piston 3. Said pressure modulation therefore makes it possible to achieve the spot and/or linear contact at the * point between brake piston wall 12 and brake piston bore wall represented in principle and by way of example in FIG. 12 A-Dwhere necessary maintaining the setting angle described (angle between the brake piston axis A and the bore axis in the housing 4).

[0037] The annular guide means 15 according to the invention is furthermore preferably formed entirely or at least partially from a plastic material, such as in particular PTFE or a PTFE constituent. The guide means is more preferably of annular design, wherein at least one ventilation duct 21as it were, as a bypassis provided for the purpose of pressure equalization and for the return flow of fluid (brake fluid) into the pressure chamber 5. Each ventilation duct 21 may be designed as an aperture 22 provided radially or obliquely on the annular guide means 15. It is possible for the guide means 15 to have additional ducts (particularly ducts opening radially inwards and radially outwards) for improved elastic deformation and for pressure equalization in its wall. It is possible to form the guide means 15 as a composite body composed of multiple plastic materials in layers and/or having rigid substrate parts, in order to utilize different material characteristics for optimizing the component characteristics.

[0038] In a particular variant of a guide means according to FIGS. 9-11 it is formed as a sprung clip 23 having multiple arms 24, 25, 26, 27 including free ends radiating from a center Z, and wherein the arms 24-27 are accommodated for locating purposes in fixing depressions 32-35 of the brake caliper housing, and wherein the free ends 28-31 of the clip 23 each comprise one or more arms 36, 37 for resting on the circumference of the brake piston 3. Here the arms 36, 37 are preferably seated at regular intervals on the circumference intermittently elastically sprung radially inwards on the wall of the brake piston 3, thereby clamping the brake piston 3.

[0039] FIG. 13 illustrates an embodiment having a sealing ring 9, wherein corresponding features are identified by corresponding reference numerals. Figure here describes, by way of example, a dual piston application, wherein K.sub.n in each case symbolizes the respective piston. All embodiments provide for a solution through a combination of multiple features. In each pairing the reference numeral 14 denotes a radially measured, maximum play between the brake piston wall 12 and the brake piston bore 13 in the housing 4. Moreover, the groove 10 is located axially offset in the housing 4 by the express offset in the radial direction R to the bore axis B. Furthermore, the groove 10 has multiple peripheral irregularities (flattenings) U.sub.1-U.sub.n on its fundamentally annular base surface 40, staggered by an angle of approximately 60 at the circumference. In conjunction with the clamped sealing ring 9 and the brake piston wall 12, the irregularities U generate an associated, radially directed force F.sub.1-F.sub.N. The addition of forces culminates in a resultant force component F.sub.R directed radially in the 9 o'clock position, which is also partially illustrated in FIG. 12. For additional boosting of this modal-acoustic tuning inside the brake piston guide, it is advisable to add further features to the combination, or to interchange these in order to lend the brake piston 3 a radially directed preferred orientation in the direction of the bore wall in specific modal tuning. Consequently, in accordance with the resultant force component FR on one side, the brake piston wall 12 has an especially effective modal-acoustic coupling to the bore wall of the housing 4. It goes without saying here that the unilaterally boosted coupling between the brake piston wall 12 and the brake piston bore 13 produces an enhanced relief or decoupling on the opposite side.

[0040] With regard to the versions shown according to FIGS. 13 and 14, a correspondingly uniform angular orientation of the irregularity U1, U2 at P1 and P2 is presented for each piston 3, so that a uniformly directed resultant force also ensues. Resorting to positional data on the model of a notional, analog clock face, U1 here in each case coincides with location P1 roughly in a 2 o'clock position, and U2 is situated at location P2, in each case roughly in a 4 o'clock position, always in relation to the center of the respective brake piston 3. This angular orientation may be modified in fine tuning of the modal-acoustic behavior of a vehicle. Thus, it is feasible, advisable and possible for certain modified applications, for example, to specifically modify the positioning P in direction P3, P4 in order to modify the direction of the resultant force FR. Thus in the case of dual-piston applications, for example, a piston 3 arranged on the left, for example, may be acted upon from the direction of position P3 corresponding to the 8 o'clock position and from the direction P4 corresponding to the 10 o'clock position. This has the advantageous effect that the resultant forces F.sub.RK1 and F.sub.RK2 cancel one another out. These possible variations and locations are naturally further enhanced for 3-piston arrangements, without however bringing the core idea of the invention into question.

[0041] The foregoing preferred embodiments have been shown and described for the purposes of illustrating the structural and functional principles of the present invention, as well as illustrating the methods of employing the preferred embodiments and are subject to change without departing from such principles. Therefore, this invention includes all modifications encompassed within the scope of the following claims.