CENTERING MECHANISM WITH A BRAKE PISTON OF A DISK BRAKE

Abstract

A centering mechanism with a brake piston of a disk brake of a motor vehicle, with a spindle extending into a cavity in the brake piston, has dimensions that prevent a force equilibrium of a nut-spindle assembly moved completely out of the vertical position. A force vector of the gravitational force on the nut-spindle assembly extends within a contact surface between a nut and the brake piston. Thus, the brake piston can be easily assembled with the nut-spindle assembly.

Claims

1. A centering mechanism having a brake piston (7) of a disk brake of a motor vehicle, having a spindle (9) that projects into a recess (11) of the brake piston (7), having a nut (10) that is screwed onto the spindle (9), and having support surfaces (13, 14) of the nut (10) and of the brake piston (7) that lie opposite one another, wherein in the case of a vertical arrangement, with the brake piston (7) below the spindle (9) and the nut (10), a force equilibrium is avoided when the nut/spindle module (12) has been completely moved out of the vertical position.

2. The centering mechanism according to claim 1, wherein in the case of the vertical arrangement, the distance of the center of gravity (SP) of the nut/spindle module (12) that has been completely moved out of the vertical position from a contact plane of the support surfaces (13, 14) is less than half the diameter (D1) of the contact plane of the support surfaces (13, 14).

3. The centering mechanism according to claim 1, wherein one of the support surfaces (13) is conical with a cone angle (A) of at least 90°.

4. The centering mechanism according to claim 1, wherein a support surface (14) that lies opposite the conical support surfaces (13) is structured to be spherical, in order to produce a circumferential linear contact surface (15).

5. The centering mechanism according to claim 1, wherein the diameter (D1) of the contact plane of the support surfaces (13, 14) is greater than 15 mm.

6. The centering mechanism according to claim 1, wherein an outer edge (16) of the nut (10), which edge faces away from the support surface (13), lies against the inner side of the brake piston (7) in the position moved completely out of the vertical position.

7. The centering mechanism according to claim 1, wherein the outside diameter (D2) of the nut (10) is at least as great as the distance of the outer edge (16) of the nut (10), which edge faces away from the support surface (14), from the support surface (14).

Description

[0013] The invention permits numerous embodiments. For a further clarification of its basic principle, one of these is shown in the drawing and will be described below. This drawing shows, in

[0014] FIG. 1 a sectional representation through a brake caliper with a brake piston and a nut/spindle module,

[0015] FIG. 2 the brake piston and the nut/spindle module from FIG. 1 during installation,

[0016] FIG. 3 the brake piston and the nut/spindle module in a vertical position,

[0017] FIG. 4 the brake piston and the nut/spindle module in a deflected position with force vectors.

[0018] FIG. 1 shows a brake caliper 1 of a disk brake of a motor vehicle, having a brake caliper housing 2 having two brake pads 3, 4 that lie opposite one another. A brake disk of the disk brake, which is arranged between the brake pads 3, 4, is not shown. A stepped bore 5 is arranged in the brake caliper housing 2. In a large-diameter section 6 of the stepped bore 5, a brake piston 7 is arranged in axially displaceable manner. The brake piston 7 supports one of the brake pads 3. A spindle 9 is arranged in a small-diameter section 8 of the stepped bore 5. A nut 10 is screwed onto the spindle 9. The brake piston 7 has a recess 11 for holding the nut 10 and a partial region of the spindle 9.

[0019] FIG. 2 shows the brake caliper housing 2 from FIG. 1 during installation of the brake piston 7 with the nut 10 and the spindle 9. The brake caliper housing 2 is in a position in which the stepped bore 5 is open downward with the large-diameter section 6. The brake piston 7 is pre-assembled with a nut/spindle module 12 for installation, and is introduced into the stepped bore 5 from below. In this regard, it is significant that the spindle 9 and thereby the nut/spindle module 12 are in the vertical and centered position relative to the brake piston 7, as shown.

[0020] FIG. 3 shows a sectional representation of the brake piston 7, on a larger scale, in the vertical position of the nut/spindle module 12, in which the components can be introduced into the brake caliper housing 2. The nut/spindle module 12 is furthermore arranged centered in the recess 11 of the brake piston 7. The nut 10 and the brake piston 7 have support surfaces 13, 14 that lie opposite one another. The support surface 13 in the recess 11 of the brake piston 7 is structured conically, with a cone angle A of at least 90°. The support surface 14 of the nut 10 is structured spherically. As a result, a linear contact surface 15 having a diameter D1 is formed circumferentially around the nut 10. The distance of a center of gravity SP of the nut/spindle module 12 from the contact plane formed by the contact surface 15 is less than half the diameter D1 of the contact surface 15. As a result, the force vector FG of gravity, shown in FIG. 4, always runs within the region delimited by the contact surface 15. The nut 10 is arranged almost completely within the recess 11 of the brake piston 7. Therefore an outer edge 16 of the nut 10, which faces away from the contact surface 15, makes contact with the inside of the brake piston 7 when the nut/spindle module 12 is tilted. This restricts the possible tilt tendency of the nut/spindle module 12. An outside diameter D2 of the nut 10 is at least as great as the distance of the outer edge 16 from the contact surface 14.

[0021] FIG. 4 shows the position of the nut/spindle module deflected out of the vertical position, with force vectors. The force vectors are designated as FN for a normal force, FR for a friction force, and FG for a weight force. In this regard, it can be recognized that in the position shown, with the nut/spindle module 12 moved out of the vertical position, no force equilibrium occurs. Instead, the weight force FG will generate a reset force that moves the nut/spindle module 12 back into the position shown in FIG. 3. This reset force is established by means of the geometries of the components, in such a manner that friction forces that are also shown are overcome.

[0022] In comparison with the position according to FIG. 3, in FIG. 4 the center of gravity of the nut/spindle module 12 has been raised due to the deflection. However, the geometries of the components as described have been established in such a manner that the reset force is sufficient for achieving the position shown in FIG. 3.