EP1716350A1 - Disc brake with floating caliper, in particular for high brake horsepower - Google Patents

Abstract

The invention concerns a disc brake with floating caliper for a vehicle, said brake developing high horsepower. The invention aims at providing a floating caliper disc brake having high rigidity and heat resistance while having a reduced weight. Therefor, the inventive disc brake comprises a floating caliper (1, 41) forming a housing above the brake disc (2) and above the friction pads (3, 4) arranged on either side of the disc (2), said floating caliper being mounted mobile on a fixed component (15) of the vehicle by means of guide bolts (14, 57). The floating caliper (1, 41) in the form of a housing consists of inner caliper section (5, 45), provided with at least one actuating device (12, 52), and of an outer caliper section (6, 46) coupled with the inner caliper section (5, 45) by at least two housing sections (7, 47) located above the brake disc (2). The invention is characterized in that the caliper sections (5, 6, 45, 46) have a lightweight construction of the high-rigidity lattice type.

Description

Floating caliper disc brake, especially for high braking performance

The present invention relates to a floating caliper disc brake for a motor vehicle, which is in particular able to implement high braking powers. Such high-performance brakes are used, among other things, in highly motorized motor vehicles and in automobile racing.

For example, a fixed caliper brake for highly motorized motor vehicles is known from EP 1 016 804 A]. The fixed caliper brake described there has hydraulic actuating devices with corresponding brake pistons on both sides of the brake discs, each of which interacts with the associated brake pads. This enables high brake application forces, which allow the implementation of large braking powers. The large braking powers lead to high operating temperatures within the fixed caliper brake or the brake fluid. One of the reasons for this is that the brake fluid is relatively close to the hot components of the fixed caliper brake, e.g. B. the brake disc and the brake pads is passed. On the other hand, high brake caliper or brake fluid temperatures can cause undesired braking performance. Therefore, the fixed caliper brake has a device for brake cooling to reduce the operating temperatures that causes a cooling air flow through the fixed caliper. Overall, the fixed caliper brake with a device for brake cooling has a high overall weight, which is highly undesirable, especially in racing applications.

Furthermore, DE 196 22 209 AI describes a floating caliper disc brake for a motor vehicle with a frame Meniform floating caliper, which is slidably mounted on a vehicle-mounted brake holder by means of bolt guides. The brake holder projects beyond the associated brake disk with two holder arms, the brake pads arranged on both sides of the brake disk being guided axially displaceably on the holder arms and supported in the circumferential direction. The frame-shaped floating caliper engages over the friction pairing formed by the brake pads and the brake disc and ensures the introduction of the necessary brake application force. Although this floating caliper disc brake is also suitable for implementing high braking powers, this design requires appropriately designed components with high weight.

Proceeding from this, it is the object of the invention to provide a motor vehicle brake, in particular for high braking powers, which is improved compared to known arrangements with regard to the mechanical and thermal load-bearing capacity and the overall weight.

This object is achieved by a floating caliper disc brake for a motor vehicle with a floating brake caliper arranged on both sides of the brake disc and frame-shaped floating caliper, which is displaceably mounted on a vehicle-fixed component by means of bolt guides. The frame-shaped floating caliper comprises an inner saddle section which has at least one actuating device and an outer saddle section which is connected to the inner saddle section via at least two bridge sections projecting over a brake disc. It is conceivable to supply the actuating device with, for example, hydraulic, electro-hydraulic, electromotive or, for example, purely electrical energy. For weight reduction at least the saddle sections each form a truss-like lightweight structure, as a result of which the entire frame-shaped floating saddle additionally has an advantageously high rigidity. In detail, each saddle section is composed of several rib, web or cylinder elements. The saddle section is preferably designed to be comparable to a double-T beam in order to achieve high rigidity. At the same time, the truss-like structure of the saddle sections facilitates the flow of cooling air and thus ensures safe brake operation even at high operating temperatures. This is preferably achieved in that the outer caliper section has at least one cooling channel in order to allow a cooling air flow to the outer brake pad. Such a cooling channel can be formed, for example, by a cylindrical element or a correspondingly acting element of the truss-like lightweight structure.

An advantageous embodiment of the floating caliper disc brake results from the fact that at least the external brake lining is fixed to the caliper and thus basically follows the caliper displacement during a brake application. The floating caliper is supported tangentially on the vehicle-fixed component for the transmission of peripheral forces. This means that the circumferential brake forces applied to the brake lining, which is axially external to the vehicle, are introduced into a vehicle-fixed component via the floating caliper.

According to a sensible variant of the floating caliper disc brake, the actuating device comprises a displaceable actuating element, the guide length of which within the actuating device is greater than the sum of the maximum wear dimension of both brake pads and the maximum wear dimension of both brake disc sides. Due to the floating caliper arrangement, an increased guide length is required for the actuating element in order to take into account the corresponding friction wear on the brake pads and on both sides of the brake disc. This is particularly important for high-performance brakes, which are subject to high friction wear. The large guide length thus ensures that the actuating element is still reliably guided in the associated actuating device even with heavily worn brake pads. The actuating element is designed, for example, as a brake piston, as is used, inter alia, in disc brakes with a hydraulic actuating device. The large guide length of the actuating element also ensures a large spatial distance between the components of the brake which are usually subjected to high thermal loads, for. B. the brake pads and the brake disc, and the temperature-sensitive actuator. This particularly affects hydraulic or electro-hydraulic actuators with temperature-sensitive brake fluid.

An additional increase in the rigidity of the floating saddle is achieved in that at least one bridge section is designed as a central web that connects the saddle sections to one another in the region of the actuating device. For reasons of weight, this central web is narrower than the bridge sections on the side in the circumferential direction, which together with the saddle sections form the actual frame-shaped floating saddle. Nevertheless, the central web significantly strengthens the frame-shaped floating saddle. Depending on the embodiment, several bridge-like webs can also be provided. A first advantageous embodiment of the floating caliper disc brake provides a vehicle-mounted brake holder which projects with its holder arms into the frame-shaped floating caliper and extends only on the inside to the brake disc. The floating caliper is slidably mounted on the brake holder, the brake holder either being designed as a separate component, which is preferably fastened to the steering knuckle or on the wheel carrier of the motor vehicle, or integrated directly into the steering knuckle or the wheel carrier. In particular, the brake holder is designed to be weight-optimized in that it does not protrude axially from the brake disc and preferably projects into the frame-shaped floating caliper with U-shaped holder arms. Alternatively, it is conceivable that the brake holder does not have U-shaped holder arms, but is designed to be closed, in order to increase its mechanical strength. In any case, it makes sense to support the brake pad tangentially on the brake holder at least on one side of the brake disc in order to transmit the circumferential brake forces. A further development of the first embodiment of the floating caliper disc brake results from the fact that the floating caliper is not only mounted axially displaceably on the brake holder, but is also supported tangentially on the holder arms of the brake holder for the transmission of peripheral forces. Occurring peripheral braking forces can be introduced directly into the brake holder fixed to the vehicle as a component so that ^'the floating caliper.

To improve the axially displaceable floating caliper guide on the brake holder, each pin guide has a guide pin which is fastened to the caliper sections of the floating caliper and is slidably mounted in the brake holder. In general, the guide bolts either do not transmit circumferential braking forces at all or only to a very small extent. fang. This allows a very slim design of the guide pin, since the axially displaceable floating caliper guide is clearly in the foreground. In particular, the guide bolts are each detachably connected, preferably by screwing, to the caliper sections and slidably received within an associated bore of the brake holder. The guide bolts thus move together with the floating caliper in relation to the brake holder during a brake application. In addition, it makes sense for the guide bolts to connect the two saddle sections together as tie rods. This in turn increases the rigidity of the floating saddle.

Another advantageous variant of the pin guide is achieved in that the guide pin has a suitable, permanent surface coating or surface treatment for protection against temperature or other environmental influences, in particular a diamond-like coating, a galvanic nickel coating, a ceramic coating or a cermet coating. This prevents the smooth-running floating caliper guidance from being impaired, for example as a result of brake lining wear (brake dust) or high brake operating temperatures.

A second preferred embodiment of the floating caliper disc brake results from the fact that at least one pin guide has a supporting pin for transmitting peripheral forces. Such a supporting bolt acts directly between the floating saddle and a component fixed to the vehicle; in particular, the supporting bolt is fastened to a component fixed to the vehicle and is mounted displaceably in an associated bore in the floating saddle. Starting from the floating caliper, braking circumferential forces can thus be transmitted directly via the support bolts into a vehicle-fixed component, for example the wheel carrier or the steering knuckle. An intermediate brake holder is not absolutely necessary. If an additional brake holder is not required, the brake pads are supported tangentially in the floating caliper on both sides of the brake disc for the transfer of brake circumferential forces. An advantageous variant of the floating caliper disc brake provides that at least the axially inner brake lining, based on the associated brake disc axis, is guided displaceably on at least one central web. This brake pad interacts with the actuating device and is thus arranged to be displaceable relative to the floating caliper. The displaceable brake pad arrangement on the central web is particularly easy to implement, since it requires little or no reworking of the floating caliper.

Further useful detailed features of the invention can be found in the exemplary embodiments in the figures, which are explained in more detail below.

It shows:

Figure 1 shows a first embodiment of a floating caliper disc brake according to the invention in a spatial view.

Fig. 2 shows a second embodiment of a floating saddle according to the invention in a spatial view.

The exemplary embodiments of floating caliper disc brakes shown in the figures are suitable, inter alia, for implementing high braking powers. There is one for each Frame-shaped floating caliper 1, 41, which is specifically designed for high braking powers and is axially displaceably mounted on a vehicle-fixed component, for example a steering knuckle or a wheel carrier. In this case, the illustration of such a vehicle-fixed component was omitted in the figures. The frame-shaped floating caliper 1, 41 overlaps an associated brake disc 2 and brake linings 3, 4 arranged on both sides of the brake disc 2. The floating caliper 1, 41 is essentially formed by two caliper sections 5, 6, 45, 46, each of which extends in the secant direction extend a brake disc side, and two circumferential lateral bridge sections 7, 47, which axially project beyond the associated brake disc 2. The bridge sections 7, 47 connect the two saddle sections 5, 6, 45, 46. In addition to the side bridge sections 7, 47, depending on the application, at least one central bridge-shaped web 8, 48 can also be provided, which also connects the saddle sections 5, 6, 45 , 46 connects and contributes to increasing the saddle stiffness.

Overall, the floating saddles 1, 41 from the figures are consistently designed for high rigidity with low weight. Among other things, the saddle sections 5, 6, 45, 46 each have a truss-like lightweight structure. Then the saddle sections 5, 6, 45, 46 are composed primarily of struts 9, 49, ribs 10, 50 and cylinder elements 11, 51. This results in a truss-like lightweight structure for the saddle sections 5, 6, 45, 46 in the manner of a double T-beam, which has a very high rigidity and low weight. The high rigidity of the saddle sections 5, 6, 45, 46 advantageously results in uniform contact conditions during brake actuation on the brake pads 3, 4, even with high brake application forces. This leads to a uniform, parallel wear pattern, particularly for the axially external brake lining related to the vehicle. In addition, the half-timbered lightweight structure facilitates cooling air to flow around the floating caliper 1, 41, as a result of which high operating temperatures in the brake can be reduced more quickly. This is preferably achieved in that the outer caliper section (6, 46) has at least one cooling channel (11, 51) in order to allow cooling air to flow to the outer brake lining (4). Such a cooling channel (11, 51) can be formed, for example, by a cylindrical element (11, 51) or a correspondingly acting element of the lattice-like lightweight structure. In the present exemplary embodiments, a plurality of cylinder elements (11, 51) form the cooling channels (11, 51), the cooling channels each being passed axially through the outer saddle section (6, 46).

For actuating the floating caliper disc brake, at least one actuating device 12, 52 is provided in the vehicle-related axially inner saddle section 5, 45, which acts directly on the axially inner brake lining 3. In order to realize higher brake application forces and thus also higher braking powers, it is advisable to use several actuating devices. Basically, any type of actuator can be used, for. B. electrical, electromechanical, electromotive, electrohydraulic or purely hydraulic. Hydraulic actuators are characterized by their high power density.

According to a first embodiment of the floating caliper Disc brake according to FIG. 1, the floating caliper 1 has three hydraulic actuation devices 12 in the vehicle-related inner caliper section 5, which act on the inner brake lining 3 via slidably received brake pistons 13. Due to the one-sided arrangement of the actuating devices 12 with respect to the brake disk 2, the total wear dimension of both brake pads 3, 4 and both brake disk sides must be maintained in the guide length of the brake pistons 13. This requires a large brake piston length in order to ensure that each brake piston 13 is securely received in the associated actuating device 12 even when the brake linings 3, 4 are badly worn. At the same time, the adequately dimensioned guide length of the brake pistons also prevents possible leaks in the hydraulic brake circuit. The considerably larger brake piston length compared to known arrangements also ensures a greater spatial distance between the temperature-sensitive brake fluid from the hot brake disc 2 and the brake pads 3, 4 during operation. FIG. 1 shows a floating caliper disc brake with very heavily worn brake pads 3, 4 and a worn brake disc 2, so that almost the full guide length of the individual brake pistons 13 comes into play. The alignment of the cup-shaped brake pistons 13 with their closed end to the center of the vehicle further ensures that all of the brake fluid in the floating caliper 1 can be optimally flowed by cooling air. This means a decisive advantage over known high-performance brakes in fixed caliper design, in which the outer caliper areas are difficult to access for cooling. On the other hand, the present frame-shaped floating caliper 1 significantly reduces the brake fluid temperature. The axially displaceable guidance of the floating caliper 1 relative to a component fixed to the vehicle, which is required for the brake actuation, is ensured by two bolt guides 14, which are effective between a component fixed to the vehicle and the floating caliper 1. In this case, a brake holder 15 is provided, which is fastened to a component fixed to the vehicle, in particular to a steering knuckle or a wheel carrier. Each pin guide 14 comprises a guide pin 16, via which the floating caliper 1 is slidably mounted on the brake holder 15. According to the embodiment according to FIG. 1, each guide pin 16 is connected, in particular screwed, to both saddle sections 5, 6 of the floating saddle 1 and is slidably received in the holder arm 17. The brake holder 15 is essentially U-shaped and has two holder arms 17 which protrude into the frame-shaped floating caliper 2. In one variant, the brake holder 15 can also form a closed shape in order to increase the brake holder stiffness. Specifically, the brake holder 15 with its holder arms 17 forms a brake lining shaft within the frame structure of the floating caliper 1, which directly supports the axially inner brake lining 3 in the circumferential direction with its inner sides and supports the peripheral braking forces of the floating caliper 1 with its outer sides. As a result, the braking circumferential forces of the axially inner brake lining 3 which occur during braking are transmitted directly via the respective holder arm 17 into the wheel carrier or steering knuckle fixed to the vehicle. The floating caliper 1 is not subjected to these braking circumferential forces of the inner brake pad 3. In contrast, the axially external brake pad 4 is fixed to the caliper and the braking circumferential forces occurring there are dissipated via the floating caliper 1. For this purpose, the floating caliper 1 is supported with its lateral bridge sections 7 tangentially on the outside of the neck. arms 17. This means that the bolt guides 14 transmit no or only a very small amount of circumferential braking forces. The components of the bolt guides 14 can accordingly be designed to be smaller or to save weight. The two guide pins 16 each extend through a holder arm 17 and at the same time axially protrude beyond the brake disc 2. Furthermore, the guide pins 16 are advantageously connected as a tie rod to the saddle sections 5, 6 of the floating saddle 1 in order to additionally increase the rigidity of the floating saddle. The guide bolts 16 each run in direct spatial proximity to the brake pad support areas through the holder arm 17, so that the brake holder 16 can be designed to save weight with minimal use of materials. Basically, the brake holder 16 is either designed as a separate component that is to be mounted fixed to the vehicle, or it is integrated directly in one piece into a component fixed to the vehicle, for example a wheel carrier or steering knuckle.

To protect the guide pin 16 from temperature or other environmental influences, such as brake lining and brake disk abrasion, it is useful to provide these with a suitable surface coating or treatment. As advantageous coating variants come, for. B. diamond-like coatings, galvanic nickel coatings, ceramic coatings or cermet coatings into consideration. Such a coating permanently maintains the surface quality of the guide bolts 16 and thus ensures smooth-running floating saddle guidance.

A particularly positive design feature of the floating caliper disc brake 1 in comparison with known arrangements consists in the higher degree of utilization of the friction lining of the brake linings 3, 4. This higher degree of utilization is achieved by tracking the brake pads 3, 4 at the associated brake pad support areas with progressive wear of the brake discs or friction pads. As a result, in contrast to a vehicle-fixed support, the brake pads 3, 4 can be worn down to a minimal residual thickness of the friction lining while the support is still clean. The brake disc wear therefore no longer has to be kept in the friction lining mass, which is advantageous in terms of the necessary brake lining weight. This condition is achieved by the fact that the axially outside brake lining 4 is connected to the outside caliper section 6, preferably embedded in it, and moves with the floating caliper 1 while the friction lining or brake disc is worn while maintaining the brake lining support. The axially inner brake lining 3 shifts relative to its support area on the brake holder 15 when the friction lining or brake disk is worn. Taking into account the wear on both sides of the friction lining and brake disk, the axial extent of the support area on the brake holder 15 must therefore be dimensioned sufficiently for the axially inner brake lining 3 to enable safe tangential brake pad support even with heavily worn friction pads.

Figure 2 illustrates a second embodiment of a floating caliper 41 according to the invention, in which, in contrast to the variant already described, both the axially inner and the outer brake lining are slidably guided and supported directly in the frame-shaped floating caliper 41. The brake pads, not shown, are axially displaceably guided by appropriately shaped lugs on axially extending central webs 48. For this purpose, 48 guide surfaces 53, 54 for the inside and molded on the outside brake pad, which are above all sufficiently dimensioned axially to ensure reliable brake pad guidance in any wear condition. Furthermore, the webs 48 have recesses 55 which are used for mounting or removing the brake lining. In particular, the brake pads with their guide lugs can be threaded onto the webs 48 via the recesses 55 in the course of such an assembly process.

In order to transmit the circumferential brake forces applied to the brake linings, support surfaces 56 are also formed on the inside of the side bridge sections 47, on which the brake linings (not shown) bear axially displaceable in the circumferential direction and are supported tangentially. The support surfaces 56 in the floating caliper 41 are designed in such a way that they permit reliable support of the brake circumferential forces in every state of wear of the brake linings or the brake disc. In particular, the support surfaces 56 have a sufficient axial extent which extends as far as the plane of the brake disk interacting with the brake pad and thus enables correct support of the brake pad even in the worn state. The direct support of the brake pads in the floating caliper 41 makes a brake holder according to FIG. 1 superfluous. Weight can thereby advantageously be saved.

The floating caliper 41 itself is mounted axially displaceably on a vehicle-fixed component, in particular a steering knuckle or a wheel carrier, via pin guides 57. The bolt guides 57 are effective between the floating caliper 41 and the component fixed to the vehicle and not only ensure that the floating caliper is guided axially 41, but also for a simultaneous transmission of the braking circumferential forces occurring on the floating caliper 41. Both the circumferential brake forces occurring on the inside and on the outside brake lining are to be transmitted by means of the bolt guides 57. The pin guides 57 preferably form a system with a support pin and a guide pin, the pin guide 57 with a support pin being basically suitable for transmitting circumferential braking forces. The second pin guide 57 with guide pin essentially serves to position the floating saddle 41 on the vehicle-fixed component. Carrier and guide bolts are in particular directly connected to the vehicle-fixed component, wheel carrier or steering knuckle, for example screwed, and slidably received in the floating caliper 41. This results in a minimal amount of parts for the floating caliper 41 with bolt guides. Furthermore, the sliding surfaces necessary for an axially displaceable floating caliper guide lie within the bolt guides 57 in a vehicle-related manner in an area which is easily accessible for a cooling air flow. As a result, there is a desired low operating temperature in the pin guides 57. Furthermore, the hot brake lining dust resulting from wear is kept away from the sliding surfaces within the pin guides 57 by the cooling air flow.

Otherwise, essential design features of the embodiment according to FIG. 1, in particular with regard to the framework-like lightweight structure, can also be transferred analogously to the floating caliper 41 according to FIG. Basically, the floating caliper disc brake according to the invention has the advantage of less heating of the brake fluid or the entire brake compared to known high-performance fixed caliper brakes. Furthermore, with hydraulic actuation The floating caliper disc brake has a smaller volume than a fixed caliper brake because only half the number of brake pistons and therefore half the number of sealing rings is used.

Claims

claims

1. Floating-caliper disc brake for a motor vehicle with a brake pad (3, 4) arranged in a frame-like manner and spanning a frame (1, 41), which is attached to one by means of bolt guides (14, 57) Vehicle-fixed component (15) is slidably mounted, with an inner saddle section (5, 45), which has at least one actuating device (12, 52), and with an outer saddle section (6, 46), which has at least two brake discs (2) projecting bridge sections (7, 47) is connected to the inner saddle section (5, 45), characterized in that the saddle sections (5, 6, 45, 46) have a framework-like lightweight structure with high rigidity.

2. floating caliper disc brake according to claim 1, characterized in that at least the outer brake pad (4) is arranged fixed to the caliper, wherein the floating caliper (1, 41) is tangentially supported on the vehicle-fixed component (15) for the transmission of peripheral forces.

3. Floating caliper disc brake according to one of the preceding claims, characterized in that the actuating device (12, 52) comprises a displaceable actuating element (13), the guide length within the actuating device (12, 52) greater than the sum of the maximum wear dimension of both brake pads (3, 4) and the maximum wear dimension of both brake disc sides.

4. floating caliper disc brake according to one of the preceding claims, characterized in that at least one bridge section is designed as a central web (8, 48) which the caliper sections (5, 6, 45, 46) in the region of the actuating device (12, 52) connects with each other.

5. floating caliper disc brake according to one of the preceding claims, characterized in that at least the outer saddle section (6, 46) has at least one cooling channel (11, 51) in order to allow a cooling air flow to the outer brake pad (4).

6. floating caliper disc brake according to one of the preceding claims, characterized by a vehicle-mounted brake holder (15) which projects with its holder arms (17) into the frame-shaped floating caliper (1) and extends only on the inside to the brake disc (2).

7. floating caliper disc brake according to claim 6, characterized in that the floating caliper (1) for the transmission of circumferential forces is supported tangentially on the holder arms (17) of the brake holder (15).

8. floating caliper disc brake according to one of claims 6, 7, characterized in that the pin guide (14) has a guide pin (16) which is attached to the caliper sections (5, 6) of the floating caliper (1) and slidably in the brake holder ( 15) is stored.

9. floating caliper disc brake according to claim 8, characterized in that the guide pin (16) connects the two caliper sections (5, 6) as a tie rod.

10. floating caliper disc brake according to one of claims 8, 8, characterized in that the guide pin (16) has a suitable, permanent surface coating or surface treatment for protection against temperature or other environmental influences, in particular a diamond-like coating, a galvanic nickel coating , a ceramic coating or a cermet coating.

11. floating caliper disc brake according to one of claims 1- 5, characterized in that at least one pin guide (57) has a support pin for transmitting peripheral forces.

12. floating caliper disc brake according to claim 11, characterized in that both brake pads for the transmission of peripheral forces are supported tangentially in the floating caliper (41).

13. floating caliper disc brake according to claim 12, characterized in that at least the inner brake pad is slidably guided in at least one central web (48) of the floating caliper (41) in any state of wear.