DE19716855A1 - Vehicular disc brake saddle secured radially to brake frame - Google Patents

Abstract

The vehicle disc brake (1) has a disc (8) on both side of which are callipers (6) linked by a brake saddle (3) which is supported on a frame (2). The brake saddle is slide-mounted on axial rests (10,27) located between the saddle and frame. The brake saddle is radially secured to the frame by a spring unit (12,28). The spring unit is secured and may be detached from both the frame and saddle.

Description

The invention relates to a floating caliper partial covering disks brake, preferably for motor vehicles, according to the Oberbe handle of claim 1. In such disc brakes is usually the floating caliper in the direction of the brake application displaceable to a generally fixed to the vehicle Brake carrier stored. From the state of the art different types of management concepts of such an axial ver sliding bearing of the brake caliper on the brake carrier been beaten, all of which have disadvantages with regard to incurred costs or in the case of assembly only allow unnecessarily complex handling.

For example, DE 42 03 318 A1 discloses one Floating caliper disc brake, at which on the vehicle Brake carrier inserted two axially aligned guide bolts are screwed to which the floating saddle has elastic Guide sleeves is axially displaceably mounted. Are there the guide bolts within the bearing eyes of the floating sat included. For maintenance or repair work such a floating caliper disc brake, for example in the case a brake pad change, it is necessary by removing the guide bolts either screw the floating caliper away collapse or com due to the small space requirement to remove. In addition to the cost-intensive design the guide pin with  elastic guide sleeves is therefore using a Screwing tool an additional assembly step necessary, for example, to replace the brake pads.

DE 42 36 075 A1 is also a floating saddle part to take the brake disc brake at which the brake ger as an integral part of a steering knuckle immediately bar is formed on the vehicle. The brake has here two differently designed axially aligned bolts guides that are firmly connected to the brake carrier and slidable within the bearing eyes of the brake caliper be taken. Here too is for mounting such Brake caliper on the integrated brake carrier a screw on the pin guides, which are also necessary when changing the pads sel incurs.

Against the background of the listed prior art the object of the invention is to provide an inexpensive Concept for guiding a floating saddle on a Fahr Specify sturdy brake carrier, the floating caliper to be releasably attached to the brake carrier as an easily assembled unit consolidate it.

The task is fulfilled by the combination of features of Claim 1. Then the floating saddle Teilbe disc brake the outer edge of a brake disc encompassing caliper that is radially removable and axial slidably mounted on a vehicle-mounted brake carrier is. The storage takes place via at least one between Brake carrier and brake caliper sliding element, about the caliper is slidable radially on the brake carrier rests radially and by means of at least one spring element is braced against the brake carrier. Thereby are preferred  as two spring elements each on the brake carrier or brake caliper attached and at the same time on the other brake component (Brake caliper or brake carrier) with a spring section locked in place. Advantageously, the brake caliper exclusively by the spring elements under essentially radial preload held on the brake carrier and it can on an additional screwing of guide elements, ver similar to the known designs in the prior art, to be dispensed with.

According to advantageous variants according to claims 2 and 3 each spring element is movable on the brake carrier or brake saddle attached. A pivotable fi is preferred xation of the spring element, which is particularly favorable affects the assembly and disassembly of the brake caliper. in the The assembly and disassembly of the brake caliper can be done here completely dispensed with a screw machining step will. The bracket of the brake caliper on the brake carrier follows solely through the pivoting movement and verra stung of the spring elements, starting from the assembled state in an operating state.

In a particularly simple version of the spring elements these are U-shaped, with a first arm inside half an opening, preferably the brake carrier, pivotable is attached and a second arm with spring preload at least radial force component on a guide surface the brake caliper is axially slidable. Preferably comes a spring element made of simple spring wire Application.

In a further development of the invention, the lubricity the floating saddle guide improved by the between  Brake carrier and caliper arranged sliding element as elastic sliding cap that runs on a radial protruding leg of the brake carrier or the brake saddle is attached. Here are sliding cap as well Spring element fixed in the operating state on the brake carrier and the brake caliper is axially movable for this purpose.

A further increase in the lubricity of a genus according saddle guidance can be achieved in that the Brake caliper by means of at least one bolt-like guide element axially displaceable relative to the brake carrier gela device. In practice, two of these are preferred tion elements used, wherein each of the guide elements on Brake carrier or caliper is fixed and relative to egg ner guide surface of the other brake component in Brake application direction is slidably guided, each bolt-like guide element also axially for this purpose movable sliding element is surrounded with spring element. The guide element can be a solid guide pin material or hollow guide sleeve. The variant as a guide sleeve, which is next to their weight advantage in a bore of the Brake carrier or the brake caliper can be pressed. In practice, two are usually separated from each other axially aligned guide elements in use, the of course also in another way on one of the two Brake components can be releasably or non-releasably attached nen. The sliding element is in the case of such an embodiment tion preferably designed as an elastic sliding sleeve extends around the guide element. The is included elastic sliding sleeve especially from a spiral Sheet metal spring according to claim 10, which the sliding sleeve on her Extends around and together with this by means of a free  Spring arm on the brake caliper or brake carrier in radial as well is releasably clipped in the axial direction. It follows from this a variant in which the bolt-like guide elements on Brake carriers are fixed, the sliding sleeve and the spiral sheet metal spring together with the brake caliper axially movable relative to the brake carrier or guide elements is. Such an embodiment takes advantage of known ones Bolt guides for floating saddles and combine them with the inventive inexpensive and simple assembly or disassembly of the brake caliper.

Embodiments of the invention are based on the drawing shown and explained in more detail below.

Show it:

Fig. 1 shows three partially cutaway views is of a floating-caliper spot-type disc brake in which the floating caliper by means of sliding caps and spring wire elements held on the brake carrier and is axially slidably guided ver,

Fig. 2 shows two views of a floating-caliper spot-plate brake ticket in FIG. 1 with a modified embodiment of the spring wire elements,

Fig. 3 shows two partially sectional views of a floating-caliper spot-type disc brake according to Fig. 1 with a cheerful variant of spring wire elements,

Fig. 4 shows two views of a floating caliper partial brake disc with brake-like guide elements and sheet metal springs, which serve to hold and guide the brake caliper on the brake carrier.

The embodiment shown in FIGS. 1a to 1c of a floating caliper partial brake disc brake 1 consists essentially of a brake carrier 2 and an axially displaceable brake caliper 3 . The brake carrier 2 can be screwed to the vehicle by means of two threaded holes 4, for example on the steering knuckle (not shown) of a motor vehicle. The brake carrier 2 has two axially extending support arms 5 projecting beyond the outer edge of a brake disc, not shown, on which brake shoes 6 arranged on both sides of the brake disc are guided and supported axially displaceably. The brake caliper 3 engages around the outer edge of the brake disk and likewise encloses the brake shoes 6 arranged on both sides of the brake disk. In addition, the brake caliper has on one side of the brake disc a hydraulic actuating device 7 , by means of which the axially inner brake shoe 6 directly and the axially outer brake shoe 6 can be pressed indirectly by axial displacement of the entire brake caliper 3 against the brake disk 8 shown in FIG. 1c. For storage fixing arrangements and supply of the brake caliper 3 on the brake carrier 2 has the floating-caliper spot-type disc brake 1 at its brake carrier 2 has two radially protruding legs. 9 At the end of each leg 9 is an elastic sliding cap 10 is fitted, which is arranged so that between the brake support legs 9 and a ent speaking guide surface 11 on the brake caliper. 3 The brake caliper 3 can thus slide axially along the elastic sliding cap 10 during a braking operation, taking advantage of the damping properties. To hold the brake caliper 3 on the brake carrier 2 , two U-shaped spring wire elements 12 are provided. The spring wire elements 12 are fastened with a first arm 13 in an opening or bore 14 of the brake support arm 9 and lie with a two th substantially extending in the axial direction spring arm 15 under radial spring preload on an associated guide surface 16 on the caliper 3 . The spring wire element 12 is pivotable about the axis of the bore 14 , but is axially immovably fixed to the brake carrier 2 . The two te spring arm 15 , in contrast, moves during a braking operation relative to the brake caliper 3 by sliding along the guide surface 16 . The suitable design of the U-shaped spring wire element 12 and the associated guide surface 16 on the brake caliper 3 , in particular on its radial outer side, allows a radially preloaded support of the brake caliper 3 on the sliding caps 10 and thus does not require any in contrast to the known prior art for example screwable fastener. This results in an extremely inexpensive and easy-to-install holding and guiding of the brake caliper 3 on the brake carrier 2 .

In general, the spring wire elements 12 between an assembly position 17 (see FIG. 1 a) and an operating position 18 are pivotally attached to the brake carrier leg 9 for mounting or dismounting the brake caliper 3 on the brake carrier 2 . In the mounting position 17 of the spring elements 12 , the brake caliper 3 can be removed radially in a simple manner or placed on the sliding cap 10 . Is the brake caliper 3 radially, so the spring wire elements are each pivoted about the axis of the bore 14 and locked within a recess 19 on the brake caliper 3 , on which the guide surface 16 is formed. A depression can be formed particularly inexpensively on casting the brake caliper 3 , preferably on its radial outside. Of course, such a recess 19 can also be produced by machining, which at the same time increases the smoothness of the guidance of the second spring arm 15 . The same also applies to the guide surface 11 of the sliding cap 10 , which can be formed both when casting the brake caliper 3 and by subsequent mechanical processing.

The sliding caps 10 are preferably made of an elastic plastic and have a hat-like shape, as a result of which they can be fitted onto the brake carrier legs 9 in a manner that is easy to assemble. The sliding caps 10 are held on the legs 9 by a through-hole 20 coaxial with the bore 14 , which is penetrated by the first spring arm 13 and thus fixes the sliding cap 10 on the brake carrier 2 . Ideally, the sliding cap 10 has, for example, a wavy structure on its contact surface with the brake caliper 3 , which on the one hand increases the slidability of this reduced contact surface 21 and on the other hand improves the radial damping properties of the elastic sliding cap 10 . In addition, the contact surface 21 can still be arched in the axial direction, which again reduces the sliding resistance by reducing the contact surface between the sliding cap 10 and the brake caliper 3 .

FIGS. 2a and 2b is a floating caliper spot-type discs brake to remove 1, which has, in contrast to the entspre sponding brake of Fig. 1, another variant of spring wire elements 12 for holding and guiding the brake caliper 3 on the brake carrier 2. As already described, the spring wire elements 12 also have a U-shaped shape with a first spring arm 13 , which also serves to hold the sliding cap 10 and the spring wire element 12 on the brake support arm 9 , and a second spring arm 15 , which is in a corresponding recess 19 with guide surface 16 abuts axially slidably on the brake caliper 3 . In this case, 1 the spring arm 15 is as in the embodiment of FIG. Executed swung such that yields 15 to improve the sliding ability approximate a point-like support of the Fe derarmes on the guide surface 16. Analog to that already described, in the variant according to FIG. 2, the spring wire elements 12 for mounting or dismounting the brake caliper 3 between an assembly position 17 and a loading operating position 18 are pivotally fixed to the brake carrier leg 9 . A locking of the spring wire elements 12 in Be operating position 18 takes place by snapping the Fe derarmes 15 under bias in the recess 19 which extends radially directly at the edge of the brake caliper 3 in the circumferential direction. This results in the possibility of forming the recess 19 during a machining operation on the tangential brake caliper edge, this machining step being required anyway for the provision of a corresponding contact surface for the brake shoes 6 . This means that only very little additional effort is required for the production of corresponding depressions 19 on the brake caliper 3 .

The actual functioning of the sliding caps 10 as well as the spring wire elements 12 does not change compared to that already described in FIG. 1.

FIGS. 3a and 3b show a further embodiment of spring wire elements 12 ßenseite in addition to their pivoting cash bracket on the brake carrier arms 9 are each connected to the second spring arm 15 against a shoulder 22 at the radial Au of the hydraulic actuator 7 in axis direction are supported slidably. At paragraph 22 , the guide surface 16 is provided in a known manner, on which the spring arm 15 lying against the spring tension can slide along in the brake application direction during braking. The paragraph 22 is advantageously formed directly when casting the brake caliper 3 on the outside of the hydraulic actuation device 7 and thus represents a particularly cost-effective embodiment. In addition, the guide surface 16 can be mechanically reworked to improve the sliding properties. Similarly, in this embodiment, the substantially U-shaped spring wire element 12 about the axis of the bore 14 between a mounting position 17 and an operating position 18 pivotally fixed to the brake carrier leg 9 . In operating position 18 , the spring wire elements 12 are under spring preload at the paragraphs 22 that there is a sufficient ra diale force component that allows a secure radial fit of the brake caliper 3 on the sliding caps 10 . As with the variants already described, a release of the spring wire elements from the operating position 18 into the mounting position 17 , preferably without the use of additional tools, enables the extremely easy-to-install ra diale removal of the brake caliper 3 , for example in the event of a brake pad change.

In an embodiment of the spring wire elements 12 according to FIG. 3, depending on the type of brake caliper 3 and the position of the brake caliper center of gravity resulting in the axially displaceable holding of the brake caliper 3 on the brake carrier, an additional housing retaining spring is required, which is known in the prior art on the axial outside brake caliper 3 and brake carrier 2 axially displaceable against each other radially clamped.

Of course, the design of the Federdrahtele elements 12 is not limited to the variants shown in FIGS. 1 to 3. There are also other design forms conceivable (for example, spring elements made of sheet metal), which ensure an axially slidable guidance of the brake caliper 3 on the brake carrier 2 with sufficient radial support. This also includes the possibility of axially fixing the spring element to the brake caliper, for example, and of allowing it to rest axially displaceably under spring tension with a section along a corresponding guide surface of the brake carrier 2 . The axial fixation of the Federele element on the brake carrier 2 or brake caliper 3 can be done in a variety of ways. In addition to the design forms that provide a detachable fastening, variants with spring elements that cannot be detachably attached to the brake carrier or to the brake caliper are also to be realized while observing the boundary conditions for easy assembly and disassembly of the brake caliper 3 . This can be ensured, for example, by a pivotable arrangement of the spring element between the mounting position 17 and the operating position 18 .

Is FIGS. 4a and 4b, finally, a floating-caliper spot-type disc brake to remove 1, wherein the brake caliper 3 by using spring elements is guided axially displaceably on the brake carrier 2 and maintained using a similar prior art fastener guide system 23 with very gun Stigen sliding properties is used. The Bolzenfüh tion 23 here consists essentially of a preferably obtained by sheet metal guide sleeve 24 which is pressed with a first end in a through hole 25 on the Bremsträ gerschen 9 . Preferably, the floating caliper disc brake 1 has two such pressed-in guide sleeves 24 , which are spaced substantially axially apart. On its guide section 26 , the guide sleeve is axially displaceably surrounded by an elastic sliding element designed as a sliding sleeve 27 . The sliding sleeve 27 in turn is encompassed by an essentially spiral sheet metal spring 28 , which is provided for the radial bracing of the brake caliper 3 on the brake carrier 2 .

In particular, the brake caliper extends in the circumferential direction on both sides of approaches 29 with which the brake caliper 3 rests radially on the bolt guides 23 . Each of the approaches 29 has a nose 30 which is gripped in the operating state of the brake by a holding claw 31 of the plate spring 28 . The holding claw 31 is formed at the free end of the plate spring 28 , the plate spring either alone or together with the sliding sleeve 27 around the axis se of the guide sleeve is arranged pivotably thereon. As a result, the sheet metal spring 28, starting from a Mon day position with the brake caliper 3 resting radially, can be latched into the operating position shown in FIG . The latching is effective not only in the radial direction, but also ensures an axially displaceable hold of the plate spring 28 with an elastic sliding sleeve 24 on the brake caliper 3 by an axial securing means 32 . The axial securing means 32 preferably consists of an elevation formed on the projection 29 , which engages in a corresponding recess in the holding claw 31 . In addition, the position of the elastic sliding sleeve 27 relative to the brake calipers 29 is axially fixed by radially projecting collars 34 .

During a braking operation and the resulting axial displacement of the brake caliper 3 , the sheet metal spring 28 with sliding sleeve 27 thus follows the axial movement of the brake caliper 3 , the sliding sleeve 27 sliding along with its radially inner lying sliding surface on the associated guide section 26 of the guide sleeve 24 . Such a con construction allows an extremely simple radial assembly and disassembly of the brake caliper 3 without the use of a screw connection when using inexpensive tools for axially displaceable guidance and mounting of the brake caliper 3 on the brake carrier 2 . Analogous to the variant shown in FIG. 3, a housing retainer 33 which is hooked onto the brake caliper 3 is also required for the embodiment according to FIG. 4 axially outwardly, which brake caliper 3 and brake carrier 2 can be axially slid in ver in a manner known from the prior art clamped in the radial direction.

In addition to the design of the pin guide 23 according to FIG. 4, it is of course also possible to use different elements of the guide element than the guide sleeve 24 shown there, which can be made of solid material, for example, or can be attached to the brake carrier 2 in a detachable or otherwise manner. In an additional expansion of the inventive concept, it is also possible to fix such a guide element analog to the brake caliper 3 and accordingly to axially slidably with respect to the brake carrier 2. Essential is the sufficient radial hold which is ensured by the biasing force of the plate spring 28 is a bolt guide 23 while maintaining the favorable sliding properties.

Claims (12)

1. floating caliper partial brake disc ( 1 ) with an outer edge of a brake disc ( 8 ) and on both sides of the brake disc ( 8 ) arranged brake shoes ( 6 ) encompass the brake caliper ( 3 ), which is axially displaceably mounted on a brake carrier ( 2 ), thereby characterized in that the brake caliper ( 3 ) rests radially removably on at least one sliding element ( 10 , 27 ) arranged between the brake caliper ( 3 ) and the brake carrier ( 2 ) and the brake caliper ( 3 ) by means of at least one spring element ( 12 , 28 ) radially braced against the brake carrier ( 2 ) and thus fastened, the spring element ( 12 , 28 ) being fastened to the brake carrier ( 2 ) or brake caliper ( 3 ) and to the respective other brake component (brake caliper 3 or brake carrier 2 ) with at least a section is releasably locked. 2. floating caliper disc brake ( 1 ) according to claim 1, characterized in that the spring element ( 12 , 28 ) is pivotally attached to the brake carrier ( 2 ) or brake caliper ( 3 ) be. 3. floating caliper disc brake ( 1 ) according to any one of the preceding claims, characterized in that the spring element ( 12 , 28 ) is releasably attached to the brake carrier ( 2 ) or brake caliper ( 3 ). 4. floating caliper disc brake ( 1 ) according to at least one of claims 2,3, characterized in that two substantially U-shaped spring wire elements ( 12 ) are provided, each with a first arm ( 13 ) within an opening ( 14 ) of the Brake carrier ( 2 ) or Brake caliper ( 3 ) are attached and with a second arm ( 15 ) under spring tension on a guide surface ( 16 ) on the other brake component (brake caliper 3 or brake carrier 2 ) axially slidably. 5. floating caliper disc brake according to one of the preceding claims, characterized in that the sliding element is designed as a radially projecting leg ( 9 ) of the brake carrier ( 2 ) or brake caliper ( 3 ) attachable elastic sliding cap ( 10 ). 6. floating caliper partial brake disc brake ( 1 ) according to any one of the preceding claims, characterized in that the spring element consists of spring wire. 7. floating caliper disc brake ( 1 ) according to one of claims 1 to 3, characterized in that the brake caliper ( 3 ) by means of at least one on the brake carrier ( 2 ) or brake caliper ( 3 ) fixed pin-like Füh approximately element ( 24 ), the relative to A guide surface of the other brake component is axially displaceable, is mounted opposite the brake carrier ( 2 ), the bolt-like guide element ( 24 ) being surrounded by a sliding element ( 27 ) with a spring element ( 28 ) that is axially movable relative to it. 8. floating caliper disc brake ( 1 ) according to claim 7, characterized in that the bolt-like guide element from a in a bore ( 25 ) of the brake carrier ( 2 ) or brake caliper ( 3 ) pressed or riveted to the guide sleeve ( 24 ) becomes. 9. floating caliper partial lining disc brake ( 1 ) according to at least one of claims 7 or 8, characterized in that the sliding element is designed as an axially on the guide element ( 24 ) arranged elastic sliding sleeve ( 27 ). 10. Part floating disc brake ( 1 ) according to at least one of claims 7 to 9, characterized in that the spring element is designed as a spiral plate spring ( 28 ) which engages around the sliding sleeve ( 27 ) on its circumference and together with the sliding sleeve ( 27 ) is clipped radially and axially detachably by means of a free spring arm ( 31 ) on the brake caliper ( 3 ) or brake carrier ( 2 ). 11. floating caliper disc brake ( 1 ) according to at least one of claims 7-10, characterized in that the sliding sleeve ( 27 ) has at least one radially projecting collar ( 34 ) which bears axially on a shoulder ( 29 ) of the brake caliper ( 3 ) .