DE102017007021A1 - Brake pad assembly for a vehicle brake - Google Patents

Abstract

A brake pad assembly (300) for a vehicle brake has at least one friction pad (308) and a brake pad carrier (302) on which the at least one friction pad (308) is mounted. The brake pad carrier (302) has at least two guide extensions (304, 306) formed on opposite sides of the brake pad carrier (302). Each of the guide extensions (304, 306) has at least one insertion bevel (310, 312) which extends between two angled surfaces (314, 316, 318) of the respective guide extension (304, 306). The at least one introduction chamfer (310, 312) has a predetermined length (l) and at least one predetermined angle (α) to at least one of the angled surfaces (314, 316, 318).

Description

The present invention relates to a brake pad assembly for a vehicle brake. The invention further relates to a disc brake for a vehicle brake system, which is equipped with such a brake pad assembly.

Generic brake pad arrangements for vehicle brakes have a brake pad carrier and a friction lining attached to the brake pad carrier. The brake pad carrier is provided with guide extensions, which serve to guide the brake pad assembly to a brake carrier of a vehicle brake.

Such a brake lining arrangement is for example in the published patent application WO 2006/141135 disclosed. This brake lining arrangement has a friction lining, which is arranged on a brake lining carrier plate. The brake pad carrier plate has on its sides in each case a guide extension, which serves to guide the brake pad assembly to a brake carrier.

It is an object of the present invention to provide a brake pad assembly which can be easily inserted into the brake carrier even with a narrow installation space.

This object is achieved by a brake pad assembly with the features of claim 1.

Further advantageous embodiments are the subject of the dependent claims.

The brake pad arrangement for a vehicle brake comprises at least one friction lining and a brake lining carrier to which the at least one friction lining is attached. The brake pad carrier has at least two guide extensions formed on opposite sides of the brake pad carrier. Each of the guide extensions has at least one insertion chamfer, which extends between two angled surfaces of the respective guide extension. The at least one Einführfase has a predetermined length and at least one predetermined angle to at least one of the angled mutually extending surfaces.

With the introduction chamfer on the guide extensions of the brake pad assembly according to the invention, the brake pad assembly can be used in an inclined or tilted state in the corresponding guides on a brake carrier. In the tilted or inclined position, the brake pad assembly requires less space to be used in the guides on the brake carrier can. After insertion into the guides of the brake carrier in the tilted position, the brake pad assembly can be brought into its operating position due to the Einführfasen on the guide extensions, in which it extends substantially parallel to a brake disc. In other words, the brake pad assembly can be erected after insertion into the guides from the tilted position and brought into a vertical operating position.

The predetermined angle and the predetermined length of the Einführfase can be selected depending on the available installation space. The predetermined angle may for example be between 1 ° and 70 ° and preferably between 5 ° and 45 °. Decisive for the determination of the angle is how much installation space on the brake carrier for the onset of the brake pad assembly in the tilted state and the raising in the vertical position of the brake pad assembly are needed. The predetermined length at which the Einführfase extends between the two angled to each other extending surfaces may be between 1 mm and 5 mm. Preferably, the predetermined length of the Einführfase be 2 mm. The length of the Einführfase can be determined or determined starting from one of the two angled surfaces extending to each other.

The guide extensions are adapted to guide the brake pad assembly in guides on the brake carrier. The brake pad carrier may be plate-shaped. The brake pad carrier can be made of metal. The plate-shaped brake pad carrier has a front and a back. The chamfers may be provided at the front of the brake pad assembly, i. on the side to which the friction lining is attached. The friction lining may be formed achssymetrisch and cover the brake pad carrier for the most part. The guide extensions of the brake pad carrier may extend transversely to the axis of symmetry of the friction lining.

One of the two angled surfaces may be the surface of the brake pad carrier to which the friction lining is attached. The front surface of the brake pad assembly may be planar so that a continuous surface extends along the guide extensions and along the friction lining region. However, the surfaces on the guide extensions with the Einführfasen can also be offset from the surface of the brake pad carrier, on which the friction lining is mounted. Alternatively, therefore, one of the two angled surfaces may also be an area on the guide extensions, the extends substantially parallel to the surface of the brake pad carrier to which the friction lining is attached.

One of the two angled surfaces may be a contour surface on the guide extension. In this context, a contour surface is to be understood as meaning the surface which adjoins a contour edge. The contour surface on the guide extension can be shortened by the Einführfase. The contour surface with the Einführfase can in particular be shortened compared to the opposite surface of the guide projections.

The contour surface may extend substantially at a 90 ° angle to the surface of the brake pad carrier to which the friction lining is attached. The contour surface can form the upper side of the guide extensions in the direction of the axis of symmetry of the friction lining. The brake lining carrier may have lateral contour surfaces which run parallel to one another and parallel to the axis of symmetry of the friction lining. The Einführfase may extend along a transition between the contour surface with the Einführfase and one of the lateral contour surfaces of the brake pad carrier. The lateral contour surfaces of the brake pad assembly and the contour surfaces with the Einführfase go rounded into each other. The Einführfase can extend along the rounded transition portion and then leak.

The guide extensions can extend perpendicularly or transversely to the axis of symmetry of the friction lining. The contour surfaces of the guide extensions with the Einführfasen can also extend perpendicular to the axis of symmetry of the friction lining. The Einführfase can extend along the guide extensions transverse to the axis of symmetry of the friction lining.

The brake pad assembly may include at least one compensation chamfer. The at least one compensation chamfer may extend between the surface of the brake lining carrier to which the friction lining is attached and a contour surface of the brake lining carrier. The compensation bevel may have a predetermined length and a predetermined angle. By Kompensationsfase the length of the contour surface of the brake pad carrier can be shortened in the area of Kompensationsfase. The predetermined length with which the compensation chamfer extends between the surface of the brake lining carrier on which the friction lining is mounted and a contour surface of the brake lining carrier can for example be between 1 mm and 5 mm. The predetermined angle of the compensation bevel can be, for example, between 1 ° and 70 °. Preferably, the predetermined angle may be 10 ° and the predetermined length 2 mm. The length of the compensation chamfer can be determined or determined on the basis of the surface of the brake lining carrier to which the friction lining is attached or on the basis of the contour surface of the brake lining carrier.

In each case a contour surface can be assigned to a Einführfase. The symmetry axis of the friction lining subdivides the brake pad arrangement. The Einführfase and the Einführfase associated Kompensationsfase can be arranged on the same side of the axis of symmetry of the brake pad assembly. The compensation chamfer may be provided with the chamfer to stabilize the brake pad assembly in the operative position, i. in the vertical position, interact.

The at least one compensation chamfer can be arranged on a lower contour surface of the brake pad carrier. The lower contour surface can connect the two lateral contour surfaces of the brake pad carrier. The lower contour surface of the brake pad carrier can be curved or wave-shaped. The at least one compensation chamfer may be provided on a curved portion of the lower contour surface which extends in the direction of the guide extensions. The Kompensationsfasen may be formed in a direction transverse to the axis of symmetry of the friction lining within the extension of the friction lining. The brake lining carrier may have two compensation chamfers, one of which is assigned to each of the Einführfase on the adjacent guide extension. The two compensation chamfers are preferably provided laterally below the guide extensions in the direction of the axis of symmetry of the friction lining.

The length of the Einführfase and the length of Kompensationsfase can be coordinated. The length of the insertion chamfer and the length of the compensation chamfer can be coordinated with one another such that the contour surface of the guide extension and the contour surface of the brake lining carrier are substantially the same length in the area of the compensation chamfer. This can prevent that in the mounted state of the brake pad assembly due to the Einführfasen on the guide extensions a torque is exerted on the brake pad assembly. Such torque may result in tilting of the brake pad assembly during operation of the vehicle about the extensions acting as axles in this case. By matching the length of the Einführfase and the length of Kompensationsfase each other, this can be prevented.

The position of the compensation bevel on the brake pad carrier may be dependent on a point of force application of a biasing force for Biasing the brake pad assembly are set in a predetermined position. For example, a spring arm of a guide element engage the brake pad assembly and bias the brake pad assembly against a surface of the guide on the brake carrier, wherein this surface of the brake pad carrier acts as a stop surface.

The present invention further relates to a disc brake for a vehicle brake system. The disc brake has a caliper and a brake carrier. On the brake carrier of the caliper is mounted. The disc brake further comprises at least two brake pad assemblies of the type described above. The brake pad assemblies are received displaceably in trained on the brake carrier guides.

The disc brake may be, for example, a floating caliper disc brake. In such a disc brake, the brake carrier may be rigidly attached to a vehicle brake. The caliper is slidably mounted on the brake carrier. The caliper can be actuated via a hydraulic actuator. The hydraulic actuator has for this purpose a piston which is slidably received in a recess in the brake caliper. The caliper may engage around a brake disc coupled to the vehicle wheel. The brake carrier may guide the brake pad assemblies. The caliper may exert tensioning forces to displace the brake pad assemblies onto the brake pad assemblies to perform a braking operation by clamping the rotating brake disk.

The brake carrier can serve in addition to the leadership of the displaceable brake pad assemblies also for receiving the reaction forces occurring during braking. The brake carrier may have a projection on which at least one of the two brake pad arrangements can be supported. The projection may be formed in the form of a material thickening. The projection may restrict the necessary clearance for installation of the brake pad assemblies.

The disc brake may further comprise guide elements. The guide elements guide the brake pad assemblies in the guides of the brake carrier. The guide elements may each comprise the at least one spring arm which biases the corresponding brake pad assembly into a predetermined position. The spring arm of the guide element can bias the brake pad assemblies upwards. About the spring arm of the guide member, the brake pad assemblies are resiliently biased against a surface of the guide of the brake carrier, which forms a stop on the brake carrier. As a result, unwanted noise developments such as rattling noises while driving can be prevented, resulting from relative movements between the brake pad assemblies and the brake carrier. The at least one spring arm of the guide member may engage a contour surface of the brake pad carrier to bias the brake pad assembly against a surface of the guide of the brake carrier.

The compensation bevel can be formed in a region on the brake lining carrier in which the spring arm acts on the brake lining carrier. The spring arm engages a lower contour surface of the brake pad carrier and presses it up in the guide.

The length of the Einführfase and the length of Kompensationsfase can be coordinated so that the point of application of the spring force of the spring arm and the point of application of the reaction force on the surface of the guide of the brake carrier lie in the same plane. This prevents that a permanent torque is exerted on the brake pads assembly around the acting as axes guide extensions. Such torque could result in vibrations in the operation of a vehicle to tilt the brake pad assemblies. Such tilting of the brake pad assembly, in turn, could result in sliding contact between a portion of the friction pad and the brake disc that can resist acceleration of the vehicle as a drag and increase fuel or power consumption.

The guide elements may have a return device. With the restoring device can be ensured that the brake pad assemblies release the brake disc after a brake operation, i. to break away from her. The restoring device may comprise a spring with a spring arm. On the spring arm may be provided a nose. The spring arm can engage behind the guide extensions of the brake pad arrangement with its nose. In a brake application, the brake pad assemblies are displaced against the biasing force of the spring of the return device in the direction of the brake disc. After the brake operation, the brake pad assembly is moved back on the spring arm with his nose in its starting position in the leadership of the brake carrier. With the restoring device can be prevented that the brake pad assembly remains in permanent contact with the brake disc and thereby possibly residual grinding torques arise, which can lead to increased energy consumption.

• 1 eine perspektivische Ansicht einer Scheibenbremse mit einem Bremssattel und einem Bremsträger;
• 2 eine Ansicht der Scheibenbremse aus 1 von unten;
• 3 eine Seitenansicht der Bremsbelaganordnung im am Bremsträger angebrachten Zustand;
• 4 eine Schnittansicht der Scheibenbremse aus den 1 bis 3, in der die Bremsbelaganordnungen und die Führungselemente zur Führung der Bremsbelaganordnungen gezeigt sind;
• 5 eine perspektivische Ansicht eines Führungselements;
• 6 eine perspektivische Teilansicht eines Bremsträgers;
• 7 eine Vorderansicht einer Bremsbelaganordnung;
• 8 eine perspektivische Teilansicht eines Bremsbelagträgers und eines daran ausgebildeten Führungsfortsatzes;
• 9 eine Teilschnittansicht, die das Einführen der Bremsbelaganordnung in den Bremsträger zeigt; und
• 10 eine Teilschnittansicht, die die Bremsbelaganordnung im in den Bremsträger eingeführten Zustand zeigt.

An embodiment of a brake pad assembly according to the invention will be described below with reference to the accompanying schematic figures. Show it:

• 1 a perspective view of a disc brake with a caliper and a brake carrier;
• 2 a view of the disc brake 1 from underneath;
• 3 a side view of the brake pad assembly attached to the brake carrier state;
• 4 a sectional view of the disc brake from the 1 to 3 in which the brake pad assemblies and the guide elements for guiding the brake pad assemblies are shown;
• 5 a perspective view of a guide member;
• 6 a partial perspective view of a brake carrier;
• 7 a front view of a brake pad assembly;
• 8th a partial perspective view of a brake pad carrier and a guide extension formed thereon;
• 9 a partial sectional view showing the insertion of the brake pad assembly in the brake carrier; and
• 10 a partial sectional view showing the brake pad assembly inserted in the brake carrier state.

1 shows a perspective view of a disc brake 1000 , The disc brake 1000 can be designed in the form of a floating caliper disc brake. The disc brake includes a caliper 100 and a brake carrier 200 , The brake carrier 200 has an outer support section 202 and an interior support section 204 on, between which one in 1 not shown brake disc can be introduced. The brake carrier 200 can be rigidly attached to a vehicle or to an axle of the vehicle (not shown). The caliper 100 is displaceable with the brake carrier 200 connected.

2 shows a view of the disc brake 1000 from underneath. In 2 are the caliper 100 , the brake carrier 200 and brake pad assemblies 300 shown. The brake pad arrangements 300 are on the brake carrier 200 arranged. Between the brake pad arrangements 300 can become an in 2 not shown brake disc extend. The caliper 100 can the brake pad assemblies 300 Apply tension forces to the brake pad assemblies 300 to shift in the direction of the brake disc. To perform a braking operation, press the brake pad assemblies 300 against the brake disc.

3 shows a side view in which a brake pad assembly 300 and the brake carrier 200 are shown. The brake carrier 200 has an outer support section 202 and an interior support section 204 on. On the outdoor support section 202 is a lead 206 formed, the sections along the brake pad assembly 300 extends. The lead 206 absorbs the high reaction forces created during a braking process, ie the projection 206 transfers these reaction forces from the brake pad assembly 300 on the brake carrier 200 , In other words, the brake pad assembly can 300 over the lead 206 on the outer support section 202 of the brake carrier 200 support. The brake carrier 200 points next to the projection 206 two tours 208 and 210 on, to guide the brake pad assembly 300 serve.

The brake pad assembly 300 has a brake pad carrier plate 302 and one in 3 not shown friction lining. On the brake pad carrier plate 302 are guiding processes 304 and 306 educated. The guide processes 304 and 306 are on opposite sides of the brake pad support plate 302 formed and thus extend laterally from the brake pad support plate 302 path. The guide processes 304 and 306 are sections in the guides 208 and 210 of the brake pad carrier 200 added. At the guides 208 and 210 of the brake carrier 200 are guide elements 400 arranged, which are used in particular for vibration damping, to avoid unwanted noise. The guide elements 400 are able to suppress acoustically perceptible, vibration-related noise, which in vehicle operation by relative movements between the brake pad assembly 300 and the brake carrier 200 in the field of guides 208 and 210 may occur.

4 shows a sectional view of the disc brake 1000 , In 4 are the caliper 100 , the brake carrier 200 with its outer support section 202 and its interior support section 204 , the brake pad assemblies 300 and the guide elements 400 shown.

The caliper 100 is with a hydraulic actuator 102 Mistake. The hydraulic actuator 102 has a recess formed in the caliper 104 and a piston 106 on, in the recess 104 slidably received. The piston 106 can be pressurized with hydraulic pressure and the Execution of a braking operation, the brake pad assemblies 300 towards an in 4 shift the brake disc, not shown.

On the outdoor support section 202 and the inner support section 204 of the brake carrier 200 are each two guide elements 400 arranged. The guide elements 400 serve to guide the brake pad assembly 300 and are engaged with the brake pad support plate 302 , The brake pad arrangements 300 each have a friction lining 308 on that with the brake pad backing plate 302 is firmly connected. The friction pads 308 when braking with the in 4 not shown brake disc ago a frictional connection.

5 shows a perspective view of a guide element 400 , The guide element 400 has a substantially U-shaped guide portion 402 in which the guide processes 304 and 306 the brake pad carrier plate 302 (please refer 3 ) can be recorded in sections. The U-shaped guide section 402 is from a floor area 404 , a back surface 406 and a roof area 408 educated. The back surface 406 connects the floor area 404 with the roof surface 408 , The back surface 406 extends substantially at a 90 ° angle to the bottom surface 404 and the roof area 408 , The floor area 404 and the roof area 408 extend substantially parallel to each other. Starting from the roof area 408 extends at an angle of substantially 90 ° to the roof surface 408 a contact surface 410 , Again, at an angle of substantially 90 °, the surface extends 412 starting from the surface 410 , The roof area 408 , the contact area 410 and the area 412 form a U-shaped receptacle.

Starting from the bottom surface 404 extends an abutment surface 414 , The stop surface 414 extends substantially at an angle of 90 ° to the bottom surface 404 , At the stop surface 414 beats the brake pad carrier plate 302 (please refer 3 ) in a braking operation to that of a frictional engagement between the friction lining 308 (please refer 4 ) and the brake disc (not shown) resulting reaction forces on the brake carrier 200 to be able to transfer. The brake pad carrier plate 302 thus hits the stop surface 414 when the brake pad support plate 302 during a braking process in the direction of one of the guides 206 and 208 the brake pad assembly is displaced.

To the stop surface 414 closes a spring arm 416 at. The spring arm 416 engages after the assembly of the brake pad assembly 300 on the brake pad carrier plate 302 and clamps them against a surface of the guides 208 and 210 on the brake carrier 200 in front. To illustrate the attack of the spring arm 416 on the brake pad carrier plate 302 became the spring arms 416 in 3 characterized. Out 3 becomes clear how the spring arms 416 on the brake pad carrier plate 302 attack and this in 3 push upwards. This will make the leadership processes 304 and 306 the brake pad carrier plate 302 against the surface 212 the leadership 210 pressed (see 6 ). By means of elastic spring arms 416 Thus, undesirable noise such as rattling while driving can be prevented.

At the guide section 402 is a reset device 418 for the brake pad assembly 300 (not shown) formed. The reset device 418 has a spring arm 420 with a nose 422 at its end and a loop-shaped spring 424 on. The feather 424 connects the spring arm 420 with the bottom surface 404 such that the spring arm 420 yourself between the floor area 404 and the roof area 408 and thus in the guide section 402 extends. The feather 424 the return device provides a restoring force for the brake pad assembly 300 (please refer 3 and 4 ) ready. The reset device 418 grips with her spring arm 420 over his nose 422 at the guide processes 304 and 308 (please refer 3 ) to the brake pad assembly 300 to return to its original position after a braking operation. This can prevent the brake lining arrangement from being prevented 300 in permanent contact with the brake disc (not shown) remains. The from a permanent system of the brake pad assembly 300 Residual grinding torques resulting on the brake disk can thus be restored by the return device 418 be prevented. Such residual grinding moments counteract the acceleration of the vehicle and thereby increase its energy consumption. To transmit the restoring force engages behind the spring arm 420 with his nose 422 the guide processes 304 and 306 on the brake pad carrier plate 302 , In 5 are the directions of movement in which the spring arm with his nose 422 can be shifted by a double arrow P shown. The restoring force acts along the arrow P in the direction of the spring 424 ,

The guide element 400 has locking elements 426 . 428 and 430 on, used to attach the guide element 400 on the brake carrier 200 serve. The locking element 426 is on the back surface 406 the leadership 402 formed and extends in a direction that the surfaces 408 and 404 is opposite. The locking element 428 is on the surface 412 trained and in the direction of the roof area 408 bent. The locking element 430 is at the stop surface 414 educated.

6 shows a partial perspective view of the brake carrier 200 , In 6 is in particular the leadership 210 for the guidance process 306 shown. The leadership 210 is from a roof area 212 , a back surface 214 and a floor area 216 educated. The floor area 216 and the roof area 212 extend substantially parallel to each other and are by means of the back surface 214 connected. The leadership 210 takes the U-shaped guide section 402 of the guide element 404 on. To the roof surface 212 the surface closes 218 at. The area 218 closes again to the surface 220 at. The roof area 212 and the area 220 are substantially parallel to each other and are by means of the surface 218 connected, which are at a 90 ° angle to the roof surface 212 and to the area 220 extends. The surfaces 212 . 218 and 220 form a projection that is in the receptacle of the guide element 400 is absorbed by the surfaces 408 . 410 and 412 is formed (see 5 ).

To the floor surface 216 closes an area 222 at a 90 ° angle to the ground surface 216 runs. At the surface 222 can the lining carrier plate 302 by means of the stop surface 414 of the guide element 400 invest. The locking element 428 of the guide element 400 acts on the surface 220 of the brake carrier 200 one. The locking element 426 lies on the side surface 218 of the brake carrier 200 at. Also the locking element 430 lies on the side surface 218 of the brake carrier 200 at.

7 shows a front view of the brake pad assembly 300 , The brake pad assembly 300 includes the brake pad carrier plate 302 and a friction lining 308 that is on the brake pad backing plate 302 is attached. On opposite sides of the brake pad carrier plate 302 are guiding processes 304 and 306 formed and extend transversely to the axis of symmetry A of friction lining 308 , The guide processes 304 and 306 are each with a Einführfase 310 and 312 provided the insertion of the guide extensions 304 and 306 in the guides 208 and 210 of the brake carrier 200 facilitate. The introduction chamfers 310 and 312 extend from a surface 314 the brake carrier plate 302 , At the surface 314 is the friction lining 308 appropriate. The introduction chamfers 310 thus extend between the surface 314 and a contour surface 316 . 318 at the guide processes 304 . 306 the brake pad carrier plate 302 , The introduction chamfers 310 . 312 further extend along the guide extensions 304 . 306 transverse to the axis of symmetry A of the friction lining 308 , The introduction chamfers 310 and 312 extend at a predetermined angle between the surfaces 314 . 316 and 318 , The introduction chamfers 310 . 312 further have a predetermined length, with which they are between the surfaces 314 . 316 and 318 extend.

In addition to the introduction chamfers 310 and 312 are on the brake pad carrier plate 302 furthermore compensation chamfers 320 and 322 educated. One each of the compensation chamfers 320 . 322 is an introductory phase 310 . 312 assigned. The compensation chamfers 320 and 322 extend between the surface 314 the brake pad carrier plate 302 and a contour surface 324 , The compensation chamfers 320 and 322 are in the direction of the axis of symmetry A of friction lining 308 below the guide processes 304 and 306 educated. The compensation chamfers 320 . 322 are on a wavy or curved lower contour edge 324 educated. The compensation chamfers 320 . 322 are at a section of the lower contour edge 324 formed in the direction of the guide extensions 304 . 306 is executed swinging. The compensation chamfers 320 and 322 extend between points a and b on the surface 314 and the contour surface 324 , In the area of the contour surface 324 between the points a and b engages the spring arm 416 on the contour surface 324 the brake pad carrier plate 302 on (see 3 ).

8th shows a partial perspective view of the brake pad carrier plate 302 , On the brake pad carrier plate 302 is the leadership process 304 educated. The guiding process 304 has a Einführfase 310 on that between the surface 314 and the contour surface 316 the brake pad carrier plate 302 is trained. On the brake pad carrier plate 302 is also a compensation phase 320 formed, extending between the surface 314 and the contour surface 324 the brake pad carrier plate 302 extends. The contour surface 324 extends substantially perpendicular to the surface 314 at the friction lining 308 is attached.

9 shows a view in which the brake carrier 200 cut and the brake pad assembly 300 is shown as a solid body. Next to the brake carrier 200 and the brake pad assembly 300 is in 9 also the guide element 400 to see. From the guide element 400 is in 9 the reset device 418 with her pen 424 recognizable. Starting from the spring 424 extends the spring arm 420 with his nose 422 , The surfaces 404 and 408 of the guide element attach to the surfaces 212 and 216 the leadership 210 of the brake carrier 200 at.

In 9 is the brake pad assembly 300 shown inclined or tilted. The guiding process 300 was with the spring arm 420 of the guide element 400 brought into contact. Through the introduction phase 310 can the brake pad assembly 300 with her leadership extension 304 in the lead 210 of the brake carrier 200 in the tilted state of the brake pad assembly 300 inserted and then erected in their vertical operating position. In the operating position of the brake lining arrangement 300 extends the brake pad assembly 300 with her friction lining 308 essentially parallel to the brake disc 500 , In the tilted state, the brake pad assembly 300 past the outer support section 202 of the brake carrier 200 in the guides 208 and 210 (in 9 only the lead 210 shown) and with the guide element 400 be engaged.

10 shows another view in which the brake carrier 200 cut and the brake pad assembly 300 are shown as solid body. 10 shows the brake pad assembly 300 in the finished imported state and thus in its erect, vertical operating position. The introduction chamfers 310 . 312 at the guide processes 304 . 306 allow a transfer of the brake pad assembly 300 from the tilted position according to 9 in the erected operating position according to 10 , The introduction phase 310 has a predetermined angle α ₁ and a predetermined length ₁ on, with which they are between the surfaces 314 and 316 extends. The length ₁ is starting from the surface 314 determined or determined.

In the operating position of the brake pad assembly, the guide element engages behind 400 with the spring arm 420 the return device 418 the guiding process 304 the brake pad carrier plate 302 , The nose 422 is in contact with the surface 314 the brake pad assembly 300 , The feather 424 provides a restoring force that the brake pad assembly 300 biased into its unconfirmed position.

The spring arm 416 is part of the guide element 400 , engages the contour surface 324 the brake pad carrier plate 302 and holds the brake pad assembly 300 in contact with the surface 408 of the guide element 400 or with the surface 212 the leadership 210 of the brake carrier 200 , At the point where the spring arm 416 on the brake pad carrier plate 302 attacks, is the compensation phase 320 educated. The compensation phase 320 has a predetermined angle α ₂ and a predetermined length l ₂ on. The length l ₂ is starting from the surface 314 determined or determined. The compensation phase 320 serves to the force application point of the force of the spring arm 416 on the contour surface 324 the brake pad carrier plate 302 and to the force application point of the reaction force on the surface 212 align. The force application point of the force of the spring arm is in 10 through an arrow FS shown schematically. The point of application of the reaction force is schematically indicated by an arrow FR shown. Both arrows or both force application points FR and FS lie in a plane, the plane e , This can prevent that due to the Einführfase 310 the spring force of the spring arm 416 a torque on the brake pad assembly 300 can exercise. Such unwanted torque could tilt the brake pad assembly 300 and undesirable, abrasive contact between a portion of the friction lining 308 (please refer 9 ) and the brake disc (see 9 ) to lead. In other words, the compensation phase becomes 320 or their length l ₂ on the length ₁ the introduction phase 310 tuned to prevent from the spring arm 416 a torque is applied to the brake pad assembly. Because the contour edge 316 of the insertion process 304 through the introduction phase 310 is shortened, the compensation bevel 320 be provided to the contour surface 324 to shorten so that the force application points FR and FS again lie in a plane.

Due to the introduction chamfers 310 . 312 at the guide processes 304 . 306 can the brake pad assembly 300 in an inclined or tilted state in the corresponding guides 208 . 210 on a brake carrier 200 be used. In the tilted position, the brake pad assembly requires 300 less room to go in the guides 208 . 210 on the brake carrier 200 to be used. After insertion in the guides 208 . 210 of the brake carrier 200 in the tilted position, the brake pad assembly due to the Einführfasen 310 . 312 be erected on the guide extensions in their vertical operating position.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2006/141135 [0003]

Claims (15)

A brake pad assembly (300) for a vehicle brake, comprising: at least one friction pad (308) and a brake pad carrier (302) to which the at least one friction pad (308) is attached, the pad carrier (302) having at least two guide extensions (304, 306) which are formed on opposite sides of the brake pad carrier (302), wherein each of the guide extensions (304, 306) has at least one Einführfase (310, 312) extending between two angled mutually extending surfaces (314, 316, 318) of the respective Guide extension (304, 306), wherein the at least one Einführfase (310, 312) has a predetermined length (l ₁ ) and at least one predetermined angle (α ₁ ) to at least one of the two angled mutually extending surfaces (314, 316, 318) having. Brake arrangement after Claim 1 in that one of the two angled surfaces (314, 316, 318) is the surface (314) of the brake pad carrier (302) to which the friction pad (308) is attached or a surface on the guide extensions (304, 306) that is substantially parallel to the surface (314) of the brake pad carrier (302) to which the friction pad (308) is attached. Brake pad arrangement after Claim 1 or 2 in which one of the two angled surfaces (314, 316, 318) is a contour surface (316, 318) on the guide extension (304, 306). Brake pad assembly according to one of Claims 1 to 3 in that the contour surface (316, 318) of the guide extension (304, 306) extends substantially at a 90 ° angle to the surface (314) of the brake pad carrier (302) to which the friction pad (308) is attached. Brake pad assembly according to one of Claims 1 to 4 in that the insertion chamfer (310, 312) extends along the guide extensions (304, 306) transversely to the axis of symmetry (A) of the friction lining (308). Brake pad assembly according to one of Claims 1 to 5 in that at least one compensation land (320, 322) is formed on the brake pad carrier (302), the compensation land (320, 322) being located between the surface (314) of the brake pad carrier (302) to which the friction pad (308) is attached , and a contour surface (324) of the brake pad carrier (302), the compensation bevel (320, 322) having a predetermined length (l ₂ ) and at least a predetermined angle to the surface of the brake pad carrier (302) against which the friction pad (308 ) is attached. Brake pad arrangement after Claim 6 in which each introduction chamfer (310, 312) is assigned at least one compensation chamfer (320, 322). Brake pad arrangement after Claim 6 or 7 wherein the length (l ₁ ) of the Einführfase (310, 312) and the length (l ₂ ) of Kompensationsfase (320, 322) are coordinated so that the contour surface (316, 318) of the guide extension (304, 306) and the contour surface (324) of the brake pad carrier (302) in the region of the compensation bevel (320, 322) are substantially of the same length. Brake pad assembly according to one of Claims 6 to 8th wherein the position of the compensation bevel (320, 322) on the brake pad carrier (302) is set to a predetermined position in response to a force application point (FS) of a biasing force for biasing the brake pad assembly (300). A disc brake (1000) having a caliper (100), a brake carrier (200) to which the caliper (100) is attached, and at least two brake pad assemblies (300) according to any one of Claims 1 to 9 , wherein the brake pad assemblies (300) by means of guide extensions (304, 306) in the brake carrier (200) formed guides (208, 210) are received displaceably. Disc brake after Claim 10 in that the brake carrier (200) has a projection (206) on which at least one of the two brake pad arrangements (300) is supported. Disc brake according to one of the Claims 10 or 11 in which guide elements (400) are provided, which guide the brake pad arrangements (300) in the guides (208, 210) of the brake carrier (200), wherein the guide elements (400) each have at least one spring arm (416) which holds the brake pad arrangement (400). 300) is biased to a predetermined position. Disc brake after Claim 11 in that the at least one spring arm (416) biases the contour surface (316, 318) of one of the guide extensions (304, 306) against a surface (212) of the guide (208, 210) of the brake carrier (200). Disc brake after Claim 12 or 13 in that the compensation bevel (320, 322) is formed in a region of the brake lining carrier (302) in which the spring arm (416) acts on the brake lining carrier (302). Disc brake after Claim 14 in which the length of the insertion chamfer (310, 312) and the length of the Kompensationsfase (320, 322) are coordinated so that the point (FS) of the spring force of the spring arm (416) and the point (FR) of the reaction force on the surface (212) of the guide (208, 210) of the brake carrier (200) lying in a plane (E).

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