FR2548312A1 - DISC BRAKE - Google Patents

Abstract

THIS DISC BRAKE INCLUDES A CALIPER 12 OVERLAPING A PART OF THE EXTERNAL CIRCUMFERENCE OF A ROTARY DISC 10 AND ADAPTED TO BE ABLE TO MOVE PARALLEL WITH THE AXIS OF THE LATTER, THE CALIPER HAVING TWO FINGERS 13A, 13B WHICH ARE SPACED L ' ONE OF THE OTHER IN THE CIRCUMFERENTIAL DIRECTION OF THE DISC AND ARE SUITABLE TO COME IN CONTACT WITH A BACKING PLATE 15 OF A FRICTION PAD 14 TO PUSH THE LATTER AGAINST A SURFACE OF THE DISC. THE FACE D OF THE BACKING PLATE 15 OF THE FRICTION PAD WITH WHICH THE FINGERS 13A, 13B OF THE CALIPER 12 COME IN CONTACT IS INCLINED WITH THE SURFACE OF THE DISC 10 IN THE CIRCUMFERENTIAL DIRECTION, THUS PREVENT THE PHENOMENON OF WHISPING .

Description

The present invention relates to a disc brake and it relates

  more particularly an improvement to pocket the squeak phenomenon in

the disc brake.

  When the brakes are applied this often causes the so-called squeak phenomenon. This phenomenon is attributed to vibrations due to friction in the bodies coming into mutual contact with friction such as a brake disc and the friction pads which enter into vibration 10 in a self-excitation mode and the vibrations are transmitted to the associated members such as a stirrup and a support, thus generating very loud noisy sounds usually designated by brake squeaks. This creaking phenomenon is caused by a complex vibration system and It is very difficult to find a solution to it. Various proposals have been made with regard to the individual constituent members of the disc brake to experimentally suppress the squeak phenomenon. The present invention aims to achieve a disc brake comprising a pad. improved friction. There is known a disc brake of the type comprising a support which is adapted to be adjusted on a non-rotating part of a vehicle, a caliper which is mounted on the support so as to be able to move in the direction of the axis d '' a rotating disc which overlaps part of its outer circumference, two friction pads arranged on opposite surfaces of the disc, a pushing mechanism such as a hydraulic cylinder and piston mechanism incorporated in the caliper to directly push one of the friction pads (internal pad) against a surface of the disc The caliper has two fingers which are spaced in the direction of the circumference of the disc and are in contact with a 35 l support plate another friction pad (outer pad) to apply the latter against the other surface of the disc when

  the caliper is moved by the reaction force of the pushing mechanism.

  In the disc brake of the above type, the external shoe being pushed by the fingers of the caliper is supposed to undergo a primary mode of vibrations as shown in broken lines and in broken lines in Fig ll with nodes located at the points of contact between the pad support plate and the caliper fingers 1 and 1

  and a belly located in the intermediate position, circumferentially, between the fingers.

  In this regard, the faces B and B of the pad support plate with which the fingers come into contact are parallel to a surface A of the disc. Consequently, the force F of thrust which is transmitted by the fingers to the plate. support is perpendicular to side A of the disc and no transverse force is generated,

  therefore it is not useful to dampen vibrations.

  The invention was carried out following the study of the thrust force transmitted by the fingers to the pad 20 from the dynamic point of view relative to the face of the pad support plate, and a goal of the invention is to provide a disc brake which makes it possible to prevent or dampen the vibrations of the friction pad by using force

  thrust transmitted by the fingers, thus limiting or em25 fishing the squeak phenomenon.

  The construction of the disc brake according to the invention is characterized in that the face of the friction pad support plate with which the fingers of the caliper come into contact is inclined with respect to

  on the surface of the disc, in the circumferential direction.

  Thanks to this construction characteristic, the thrust force F is counteracted by a reaction force R which is perpendicular to the inclined face of the support plate and by a component f which acts along the inclined face of the support plate. Component f acts generally in the direction of the wavelength of the vibrations of the support plate and resists the relative displacement between the fingers and the support plate as

  that frictional force between these parts.

  In other words, the component f which acts in the direction of the wavelength of the vibrations of the support plate and in a circumferential direction acts as a friction force in a positive and negative manner repeatedly. dynamic is thus caused between the fingers and the support plate in the direction of the wavelength of the latter's vibrations, which improves the damping characteristics

  vibrations and prevents or reduces the squeak phenomenon.

  Other characteristics and advantages of the invention will emerge during the description which follows, made with reference to the appended drawings given.

  only by way of examples and in which: FIG. 1 is an end view of a dis20 brake according to the invention; Figures 2 to 8 are partial sectional views showing discs, caliper fingers and friction pads having inclined bearing plates according to the preferred embodiments of the invention; Figures 9 and 10 are partial sectional views showing other variants of the invention; Fig ll is a sectional view similar to that of Fig 2 to 8 but showing the vibrations of a pad

  disc brake friction according to the prior art 30 re.

  Fig 1 schematically shows a disc brake of the aforementioned type, which comprises a support 11 adapted to be fixed on a non-rotating part of a vehicle (not shown) using two screws (not shown) 35 which extend respectively in threaded holes shown in Fig l, and a bracket 12 which is mounted on the support 11 so as to slide by sliding in the direction parallel to the axis of a rotary disc 10 in

  a direction perpendicular to the drawing sheet.

  The stirrup 12 overlaps a part of the dull outer circumference of the disc 10 and has two fingers 13 a and 13 b which are spaced in the circumferential direction of the disc 10 Usually the stirrup 12 is slidably mounted on two pins (not shown) which are fixed on the support 11 Two friction pads are arranged on the 10 opposite surfaces of the disc 10 although a single pad 14 is shown in Fig l The bracket 12 includes, incorporated, a pushing mechanism such as a device hydraulic cylinder and piston to push one of the pads towards the disc 10 The reaction force moves the caliper 12 15 in the opposite direction so that the pad 14 is

  pushed against the adjacent surface of the disc 10 by means of the fingers 13 a and 13 b.

  Fig 2 shows a first embodiment of the invention in which the shoe 14 has a rigid support plate 20 which is curved in a middle part c, in the circumferential direction considering the direction of a radius of the disc 10 Surface portions 15 a and 15 b which are symmetrically inclined as a whole are thus formed, to come into contact with the fingers 13 a and 13 b of the stirrup 12 respectively The surface portions 15 a and 15 b of the support plate 15 which come into contact with the fingers 13 a and 13 b are thus inclined with respect to the surface A of the disc 10 in the circumferential direction of the latter. According to this embodiment, the faces of the fingers 13 a and 13 b coming into contact with the surface parts 15 a and 15 b

  are tilted correspondingly as shown clearly in Fig 2.

  The thrust force which is applied by the stirrup 12 to the shoe 14 is perpendicular to the face A of the disc 10 as shown in the form of forces F which induce reaction forces R which are perpendicular to the surfaces mutually in contact between the fingers 13 a and 13 b and parts 15 a and 15 b, and of components f acting along mutually contacting surfaces The components f act generally in circumferentially opposite directions The frictional force acting between the disc and the pad 14 when the brake is applied tends to induce vibrations in a self-excitation mode in the support plate 15, the direction of the wavelength of which follows the circumference

  of the disc 10 and the direction of the amplitude follows vertical directions at F Ig 2 These vibrations, which excite themselves, generate relative forces of displacement between the support plate 15 and the fingers 13 a and 135 b 15 in the transverse directions considering Fig 2.

  The components f act effectively on these relative displacement forces in a positive and negative manner repeatedly, thus generating a dynamic imbalance in the direction of the wavelength of the vibrations of the support plate 15 between the latter and the fingers 13 a and 13 b The

  vibrations of the support plate 15 can thus be effectively limited and the phenomenon of cobuinemnent is significantly reduced.

  Fig 3 shows a second embodiment in which a support plate 16 of the friction pad 14 is curved in the opposite direction with respect to the plate

  Support 15 of Fig 2 The components f in Fig 3 act as a whole in opposite directions to each other The function and operation of the second embodiment 30 are similar to those of the first.

  FIG. 4 shows a fourth embodiment in which a support plate 17 of the friction pad 14 is shaped so as to present a configuration similar to the support plate 16 of the second embodiment, however the surfaces in contact B of fingers 13 a and 13 b

  are not tilted correspondingly and are

  overall wind parallel to the surface A of the disc

  These fingers 13 a and 13 b are thus in contact by their internal ends in the circumferential direction with the support plate 17 The directions of the reaction forces 5 R and of the components F are as a whole similar to those shown in FIG. 3 .

  By comparison with FIG. 3, the points of application of the pressure forces F and of the reaction forces R are displaced circumferentially in close directions in order to delimit a distance 4 as shown in F Ig 4, and the amplitude of the vibrations can 8 be reduced, which is effective in reducing the squeaking noise. Furthermore, by bringing the thrust forces together in the circumferential direction, it is possible to achieve a relatively uniform distribution of the surface pressure on the shoe. friction and thereby improve braking performance such as for example resistance & loss of efficiency,

  resistance to partial wear and others.

  FIG. 5 shows a fourth embodiment in which a support plate 18 of the shoe 14 is constituted by two wedge-shaped plates which are linked to each other The thickness of the plates varies in the circumferential direction of the disc 10 The relationship between 25 the support plate 18 and the fingers 13 a and 13 b is in its

  assembly similar to that of the first embodiment.

  Fig 6 shows a fifth embodiment which as a whole is similar to that of Fig 3 but which includes a support plate 19 made up of two wedge shaped plates which are linked to each other with interposition between them of a material 20 thermally

  insulating or of a material 21 absorbing vibrations.

  The support plates 18 and 19 of Examples 5 and 6 act in a similar manner to that of the support plates 35 and 16 of Figs 2 and 3 with respect to the circumferentially inclined surfaces In addition, it is possible to modify the stiffness or mass of the parts of the support plate in contact with the respective parts of the fingers 13 a and 13 b

  one with respect to the other, which is effective in reducing or damping vibrations. It is understood that such ef5 fets can be reinforced by a modification of the dimension or of the material of these two plates, one with respect to the other.

  In addition, since the two plates are bonded together along a surface which is inclined with respect to the perpendicular to the direction of transmission of the vibrations, it is still possible to decrease the transmission of the vibrations and to obtain additional effects d 'amortization. FIG. 7 shows a sixth embodiment 15 in which a support plate 22 of the friction pad 14 decreases in the direction of the circumference of the disc 10 and has a thickness t 1 at a circumferential end which differs from the thickness t 2 from the other end in the circumferential direction as shown in Fig 7 The difference in thickness of the support plate in the circumferential direction or in the direction of the amplitude of the vibrations of the support plate is effective to generate a damping function In this example it is preferable to modify the thickness of a plate 25 than of support 23 of another friction pad 14 ′ in the circumferential direction as shown in FIG. 7 On this subject the friction material of the outer shoe 14 usually wears more on the downstream side or on the outlet side by considering the direction of rotation of the disc by comparison 30 with the upstream or inlet side, and the friction material of the inner shoe 14 ' s' use more on the upstream or input side of the direction of rotation, consequently the pads 14 and 14 'in Fig 7 are preferably arranged as shown in

  drawing where it can be seen that the direction of rotation of the disk 10 35 is assumed to be oriented to the right.

  FIG. 8 shows a friction pad 14 comprising a support plate which is essentially analogous to the support plate 15 of the example in FIG. 3 However, the support plate of this external friction pad 14 has a thickness t 3 which is different from the thickness t 4 of a support plate 24 of the internal shoe 14 ′ As a result, in addition to the effect of the surface of the support plate of the external shoe 14 which is inclined in the circumferential direction, the difference in thickness t 3 and t 4 of the bearing plates of the pads 14 and 14 'causes unbalanced vibrations on the pads 14 and 14', thus ensuring a new damping force. Figs 9 and 10 show modified finger shapes which can be applied respectively to the embodiments of Figs 2, 5 and 7 and to those of Figs 3, 6 and 15 8 so as to obtain effects similar to those obtained

in the example of F Ig 4.

  As described above in detail, the invention can induce components f which act to prevent or reduce the vibrations of the friction pad and to improve the damping characteristics, thanks to

  to which the squeak phenomenon is limited or prevented.

Claims (7)

  1 Disc brake comprising a caliper overlapping a part of the outer circumference of a rotating disc and adapted to be able to move in a direction parallel to the axis of the disc, this caliper comprising two fingers which are spaced apart from one other in the direction of the circumference of the disc and adapted to come into contact with a support plate of a friction pad for pushing this pad against a surface of the disc, brake characterized in that the face (15 a, 15 b , 17 a, 17 b) of said ap10 plate then (15, 16, 22) with which the finger (13 a, 13 b) of the stirrup (112 ") comes into contact is inclined relative to said surface of the disc (10), in the circumferential direction of the latter.  2 Disc brake according to claim 1, ca15 characterized in that a part (15a, 17a) of the face of said support plate (15, 17) with which one of the fingers (13 a) is inclined relative to another part (15b, 17b) of the face of said support plate (15,   17) with which the other finger comes into contact (13b).   3 Disc brake according to claim 2, characterized in that said parts of the face of the support plate (15, 16, 17) are inclined symmetrically one by compared to each other.   4 Disc brake according to claim 1, ca25 characterized in that the support plate (15, 18, 22) as a whole has a V shape in cross section,   the middle part of which in the circumferential direction is brought closer to the disc (10).   Disc brake according to claim 1, ca30 characterized in that the support plate (16, 17, 20) as a whole has a V shape in cross section   inverted whose ends opposite in the circumferential direction are brought closer to the disc (10).   6 Disc brake according to claim 1, ca35 characterized in that the surface (B) of the fingers (13 a, 13 b) coming into contact with the support plate (15, 16, 18, 20, 22) is inclined correspondingly to the support plate. 7 Disc brake according to claim 5, ca5 characterized in that the surface (B) of the fingers (13 a, 13 b) in contact with the support plate (17) is parallel to the disc surface (10).   8 Disc brake according to claim 1, characterized in that the support plate consists of two or more plates (18, 20) or overlapping each other,   the thickness of these plates varying in the circumferential direction of the disc.   9 Disc brake according to claim 1, characterized in that the thickness of the support plate (18, 15 20) varies in the direction of the circumference of the disc (10). I -