[0001] . Field of the invention

[0002] . The present invention relates to a disc brake caliper and a disc brake comprising said caliper.

[0003] . Hereafter, the disc brake caliper and a disc brake assembly will be described with reference to the rotation axis of the disc itself, indicated by reference X-X, which defines an axial direction. Axial direction means any direction A-A directed parallel to the rotation axis of the brake disc. Additionally, radial direction means all directions orthogonal to rotation axis X-X and incident therewith. Furthermore, circumferential direction C-C means the circumference orthogonal to the axial direction and the radial directions .

[0004]. Otherwise, tangential direction T-T means a direction which is punctually orthogonal to an axial direction A-A and a radial direction R-R.

[0005] . Background art

[0006] . On vehicles, in particular, in a disc brake, the brake caliper is arranged straddling the outer peripheral margin of a brake disc. The brake caliper usually comprises a body having two elongated elements, referred to as side portions, which are arranged to face opposite braking surfaces of a disc. There are friction pads between each side portion of the caliper and the braking surfaces of the brake disc. At least one of the side portions of the caliper has cylinders adapted to accommodate pistons, actuated in any suitable known manner (e.g. hydraulic or electro-mechanical pistons), capable of applying a thrust action on the pads, abutting them against the braking surfaces of the disc to apply the braking action on the vehicle .

[0007] . Brake calipers are usually constrained to a supporting structure which remains fixed to the vehicle, such as, for example, a spindle of a vehicle suspension.

[0008] . In a typical arrangement, one of the two side portions has two or more attachment portions of the body of the caliper to the supporting structure, e.g. providing slots or eyelets, e.g. arranged axially, or through holes, e.g. arranged radially, adapted to receive screws for fixing the caliper which are received in threaded holes provided on the caliper support with their ends.

[0009] . Such a side portion is referred to as the attachment side portion or elongated vehicle-side element.

[0010] . The other portion is referred to as the non-attachment side portion or elongated wheel-side elements.

[0011] . In a typical caliper body construction, the side portions facing the braking surfaces of the disc are connected to each other by bridge-like elements arranged straddling the disc, referred to as bridges .

[0012] . As said, opposite pads are pressed in disc brake calipers, by virtue of the action of at least one piston, against opposite braking surfaces of a braking band of a braking band by the associable brake disc.

[0013] . This piston is usually accommodated in a cylinder in the body of the caliper and is energized by brake fluid pressurized by a brake pump, usually a pedal in cars and a lever on motorcycles.

[0014]. Brake calipers are also known in which the piston, or the pistons, is or are electro-mechanically energized, e.g. by the rotation of a worm accommodated in the piston body and turned by an electric motor, or more commonly by a ratio motor.

[0015] . Such a solution is known from US6607059B1 to SKF Engineering and Research Center B.V. In one embodiment, this document discloses a ratio motor connected to a recirculating ball worm located inside the piston body. The worm is rotationally supported by a first thrust bearing placed inside it and a transmission shaft connects it to a planet gear disc of an epicyclic gearbox placed over an electric motor. This epicyclic gearbox is supported by a second thrust bearing at the end of the drive shaft opposite to said piston.

[0016] . Therefore, this solution is highly cumbersome, especially due to the long axial extension thereof.

[0017] . A solution to this problem is disclosed in US7021415B2 to Stoneridge Control Devices, Inc. and in W02015151052 to Brembo Brakes S.p.A. These documents disclose an electrically operated brake system and actuator. The actuator comprises a motor with a motor shaft, and a gear train coupled to the motor shaft, in which the gear has at least one mechanical output from the actuator. The gear train includes a gear coupled to the drive shaft, a driven gear coupled to the driven gear and a planetary gear set coupled to the driven wheel. These documents describe configurations to arrange the gear train as wide as possible in the circumferential direction and thus reduce the axial footprint of the assembly.

[0018] . Other such solutions are known from US8051957B2, WO2011076299A1, W02015151052A1 , W02016005867A2 , US2005034936A1 , US2008271553A1.

[0019] . All these solutions, however, do not allow to reduce the axial volume of the caliper mainly due to the side-by-side arrangement of the piston and worm-nut screw assembly and the gearbox .

[0020] . Therefore, the need remains strongly felt for a caliper of the type with a thrust device actuated through a screw-nut screw and which has a reduced axial dimension.

[0021] . This need is also strongly felt for motorcycles on which the axial dimensions of the caliper are a major constraint to the desired reduced width of the vehicle itself, but especially to the maneuverability thereof.

[0022] . Solution

[0023]. These and other objects are achieved by a caliper according to claim 1 and by a brake according to claim 10.

[0024]. Some advantageous embodiments are the subject of the dependent claims.

[0025] . This solution allows to significantly reduce the axial dimensions of the caliper by virtue of the integration of its components .

[0026] . By virtue of the suggested solutions, the components of the reducer or gearbox are at least partially interpenetrated with the components of the thrust device, allowing a significant reduction in the size of the assembly, particularly in the axial direction .

[0027] . The tests carried out on the solutions revealed that the achieved reduction in the axial dimension could not have been obtained in any of the previously known solutions.

[0028] . On the contrary, precisely because of the needs expressed by these previously known solutions, i.e. to suggest modular solutions in which the gearbox can be easily and simply separated from the caliper body, the known solutions suggest assemblies which are increasingly cumbersome in the axial direction, precisely because of the refined desire to separate the components of the thrust device from those of the gearbox or motor-gearbox.

[0029] . In particular, the design of the worm and the gearbox supports is exemplified, to the point of eliminating the motion transmission components from the gearbox to the worm, by directly using the worm support bearing to transmit motion from the gearbox to the worm.

[0030] . Furthermore, by virtue of the suggested solutions, it is possible to have a reduction in the number of components which form the caliper. In particular, with this suggested solution, the support bearing of the worm also incorporates the function of supporting bearing of the gearbox or a proximal part of the gearbox, further allowing to eliminate the number of components which allowed the gearbox support bearing to be fitted.

[0031] . These solutions also allow a considerable simplification of the caliper assembly step.

[0032] . Drawings

[0033] . Further features and advantages of the invention will become apparent from the description provided below of preferred embodiments thereof, given by way of non-limiting examples, with reference to the accompanying drawings, in which:

[0034]. - figure 1 shows a circumferential view of a brake caliper according to the invention;

[0035] . - figure 2 shows a section in a radial axial plane of the caliper in figure 1;

[0036] . - figure 3 shows an enlarged detail of the section in figure 2, in which the support bearing of the worm and the end part of the gearbox are highlighted;

[0037] . - figure 4 shows a section view taken along line IV-IV in figure 1 of the caliper in figure 1;

[0038] . - figure 5 shows an enlargement of a detail in Figure 4, in which the support bearing of the worm and the end part of the gearbox are highlighted.

[0039] . Description of some preferred embodiments

[0040] . According to a general embodiment, a brake caliper of a disc brake 1 comprises a caliper body 2 adapted to be arranged straddling a brake disc 3 to apply a braking action on a vehicle.

[0041] . Said brake disc 3 defining an axial direction A-A directed either along or parallel to the rotation axis X-X of said brake disc 3; a radial direction R-R orthogonal to said axial direction A-A and a circumferential direction C-C orthogonal to said axial A-A and radial R-R directions, as well as a tangential direction T-T locally orthogonal to said axial direction A-A and said radial direction R-R and tangent to said circumferential direction C-C.

[0042] . Said caliper body 2 comprising at least one thrust device housing 4 which accommodates a thrust device 5 adapted to apply a bias on at least one brake pad 6 to abut said at least one brake pad 6 against the braking surfaces 7, 8 of said brake disc 3.

[0043] . Said thrust device 5 is operatively connected to a translating screw nut 9; operatively connected to a worm 10; said translating screw nut 9 is operatively connected to a worm 10; said worm 10 is operatively connected to a reducer or gearbox 11.

[0044]. Said worm 10 is rotatably supported by a screw thrust bearing 12 adapted to support in a rotatable manner said worm 10 and to apply by said worm 10 an axial reaction, i.e. a direct reaction mainly along said axial direction A-A.

[0045] . At least part of said pressure gearbox 11 placed near and operatively connected to said worm 10 is rotatably supported by at least one gearbox thrust bearing 12 adapted to support in a rotatable manner said at least one part of said reduction gear 11 and apply for said at least one part of said reduction gear 11 a radial reaction, that is a direct reaction mainly along said radial direction R-R.

[0046] . Advantageously, said screw thrust bearing and said gearbox thrust bearing are the same thrust bearing 12.

[0047] . By virtue of the provision of a single thrust bearing 12 to perform both the function of a worm support bearing and a gearbox support bearing, for example, the felt need to simplify the construction of this assembly and reduce its axial dimensions is solved.

[0048] . According to a yet further general embodiment, a brake caliper of disc brake 1 comprises a caliper body 2 adapted to be arranged straddling a brake disc 3 to apply a braking action on a vehicle .

[0049] . Said brake disc 3 defining an axial direction A-A directed either along or parallel to the rotation axis X-X of said brake disc 3; a radial direction R-R orthogonal to said axial direction A-A and a circumferential direction C-C orthogonal to said axial A-A and radial R-R directions, as well as a tangential direction T-T locally orthogonal to said axial direction A-A and said radial direction R-R and tangent to said circumferential direction C-C.

[0050] . Said caliper body 2 comprising at least one thrust device housing 4 which accommodates a thrust device 5 adapted to apply a bias on at least one brake pad 6 to abut said at least one brake pad 6 against the braking surfaces 7, 8 of said brake disc 3.

[0051] . Said thrust device 5 is operatively connected to a translating screw nut 9; operatively connected to a worm 10; said translating screw nut 9 is operatively connected to a worm 10; said worm 10 is operatively connected to a gearbox 11.

[0052] . Said worm 10 is rotatably supported by a screw thrust bearing 12 adapted to support in a rotatable manner said worm 10 and to apply by said worm 10 an axial reaction, i.e. a direct reaction mainly along said axial direction A-A. [0053] . At least part of said pressure gearbox 11 placed near and operatively connected to said worm 10 is rotatably supported by at least one gearbox thrust bearing 12 adapted to support in a rotatable manner said at least one part of said reduction gear 11 and apply for said at least one part of said reduction gear 11 a radial reaction, that is a direct reaction mainly along said radial direction R-R.

[0054]. Said thrust bearing 12 comprises at least one inner bearing ring or radially inner slewing ring 14, 15.

[0055]. Said gearbox 11 comprises an epicyclic gear 20.

[0056] . Said epicyclic gear 20 comprises a fixed gear or an internally toothed body 17 which cooperates with at least one planet gear 18, and wherein said at least one planet gear 18 is rotatably supported about at least one planet gear pin 21.

[0057] . Said at least one planet gear pin 21 is operatively connected to said at least one radially inner slewing ring 15 to transmit the action of said gearbox 11 to said worm 10 by means of said at least one radially inner slewing ring 15.

[0058] . According to an embodiment, said worm 10 is rotatably supported only by said thrust bearing 12.

[0059] . According to an embodiment, said thrust bearing 12 is a bearing of the oblique type adapted to support both loads directed along the axial direction A-A and loads directed along the radial direction R-R.

[0060] . According to an embodiment, said worm 10 is a recirculating ball worm. [0061] . According to an embodiment, said thrust bearing 12 comprises at least one radially inner slewing ring 14, 15.

[0062] . According to an embodiment, said gearbox 11 comprises at least one epicyclic gear 20.

[0063] . Said epicyclic gear 20 comprises a fixed gear or an internally toothed body 17 which cooperates with at least one planet gear 18, and wherein said at least one planet gear 18 is rotatably supported about at least one planet gear pin 21.

[0064]. Said at least one planet gear pin 21 is operatively connected to said at least one radially inner slewing ring 15.

[0065] . According to an embodiment, said at least one radially inner slewing ring 15 comprises at least onepin housing 23 and said at least one pin housing 23 receives said at least one planet gear pin 21.

[0066] . According to an embodiment, said at least one radially inner slewing ring 14, 15 is connected to said worm 10.

[0067] . According to an embodiment, said worm 10 comprises a screw shank 22; said at least one radially inner slewing ring 14, 15 is connected to said screw shank 22 to transmit the action of said gearbox 11 to said worm 10 by means of said at least one radially inner slewing ring 14, 15.

[0068] . According to an embodiment, said worm 10 comprises a screw shank 22; said at least one radially inner slewing ring 14, 15 is keyed to said screw shank 22 to transmit the action of said gearbox 11 to said worm 10 through said at least one radially inner slewing ring 14, 15. [0069] . According to an embodiment, said gearbox 11 comprises at least one epicyclic gear 20.

[0070] . Said epicyclic gear 20 comprises a fixed gear or an internally toothed body 17 which cooperates with at least one planet gear 18, and said at least one planet gear 18 is rotatably supported about at least one planet gear pin 21.

[0071] . Said at least one planet gear pin 21 is supported by a planet carrier disc.

[0072] . Said at least one radially inner slewing ring 15 is in one piece with said planet carrier disc.

[0073] . According to an embodiment, said thrust bearing 12 comprises at least one outer bearing ring or radially outer slewing ring 13.

[0074]. According to an embodiment, said radially outer slewing ring 13 is connected to a first outer slewing ring housing 16 provided at least partly in said caliper body 2.

[0075] . According to an embodiment, said gearbox 11 comprises a fixed gear or an internally toothed body 17 which cooperates with rotating or planet gears 18; said fixed gear or internally toothed body 17 is connected to said caliper body 2; said radially outer slewing ring 13 is connected to a second outer slewing ring housing 19 at least partly provided in said fixed gear or internally toothed body 17.

[0076] . According to an embodiment, thrust bearing 12 comprises at least one radially inner slewing ring 14, 15.

[0077] . At least one radially inner slewing ring 14, 15 is in one piece with said worm 10.

[0078] . According to an embodiment, said worm 10 comprises a screw shank 22; said at least one radially inner slewing ring 14, 15 is in one piece with said screw shank 22 to transmit the action of said gearbox 11 to said worm 10 through said at least one radially inner slewing ring 14, 15.

[0079] . According to an embodiment, said at least one radially inner slewing ring 14, 15 is a first inner slewing ring 14 and a second inner slewing ring 15 mutually side-by-side.

[0080] . According to an embodiment, said second inner slewing ring 15 is operatively connected to said gearbox 11.

[0081] . According to an embodiment, said gearbox 11 comprises at least one epicyclic gear 20.

[0082] . Said second inner slewing ring 15 comprises at least one pin housing 23 and said at least one pin housing 23 receives at least one planet gear pin 21 which rotatably supports at least one planet gear 18 of said epicyclic gear 20.

[0083] . According to an embodiment, said gearbox 11 is a part of a ratio motor 24 which comprises an electric motor 25 operatively connected to said gearbox 11.

[0084]. According to an embodiment, said brake caliper 1 is an electrically actuated caliper.

[0085] . According to an embodiment, said thrust device housing 4 has an insertion opening 26, said insertion opening 26 opens towards said gearbox 11 and allows the insertion in said pin device housing 4 of said thrust device 5 and/or of said translating screw nut 9 and said worm 10.

[0086] . According to an embodiment, said thrust device 5 comprises an inner thrust device chamber 28.

[0087] . Said inner thrust device chamber 28 accommodates said translation screw 9 and said worm 10.

[0088] . According to an embodiment, a support ring 29 is interposed between said thrust device 5 and said translation screw 9; and wherein said translating screw nut 9 rests on said resting ring 29, so as to contain the clearance of said thrust device 5 and of said translation screw nut 9.

[0089] . According to an embodiment, said translating screw nut 9 comprises at least one snap coupling device 30.

[0090] . According to an embodiment, said snap coupling device 30 snap-connects said translation nut screw 9 to said thrust device 5.

[0091] . According to an embodiment, said worm 10 comprises a screw thrust head 27 adapted to cooperate either directly or indirectly with said thrust device 5.

[0092] . According to an embodiment, a limit stop disc 31 is provided interposed between said thrust device 5 and said screw thrust head 27.

[0093] . According to an embodiment, said limit stop disc 31 is shaped as a spherical cap 32.

[0094]. The present invention further relates to a disc brake 33 comprising a caliper according to any one of the embodiments described above and associated with a brake disc 3.

[0095] . Those skilled in the art may make many changes and adaptations to the embodiments described above or may replace elements with others which are functionally equivalent in order to meet contingent needs without however departing from the scope of the appended claims.

[0096] . According to an embodiment, the thrust device 5 comprises a retaining device 34 which can prevent the rotation of the thrust device 5 in thrust device housing 4.

[0097] . According to an embodiment, a brake caliper 1 comprises a caliper body 2 adapted to straddle the disc 3, wherein said caliper body 2 comprises:

[0098] . - a first elongated portion 105 adapted to face a first braking surface 106 of the brake disc 3, and

[0099] . - a second elongated portion 107, opposite to said first elongated portion 105 and adapted to face a second braking surface 108 of the brake disc 3 opposite to said first braking surface 106, and

[00100] . - at least one bridge 109 which connects said first elongated portion 105 and said second elongated portion 107 to each other arranged straddling the disc 3.

[00101] . Said brake caliper 1 further comprises at least one pair of opposite brake pads, comprising a first brake pad 110 and a second brake pad 120.

[00102] . Each brake pad 110, 120 of said at least one pair of opposite brake pads comprises:

[00103] . friction material 111, 121, and

[00104] . a support plate 112, 122, which supports said friction material 111, 121.

[00105]. Each support plate 112, 122 of each brake pad 110, 120 comprises a plate back 113, 123 facing a respective elongated portion of said elongated portions 105, 107 of the caliper body 2.

[00106]. Said brake caliper 1 further comprises:

[00107] . - at least one thrust device 5, adapted to apply a thrust action on said plate back 113 to abut said first brake pad 110 of said pair of brake pads against a braking surface 106 of said facing braking surfaces 106, 108 of the disc 3;

[00108] . - at least one detecting device 115, adapted to detect a biasing force directed in axial direction X-X .

[00109] . Said detecting device 115 of the brake caliper 1 is interposed either directly or indirectly between said plate back 123 of said second brake pad 120 of said pair of brake pads and an elongated portion 107 of the caliper body 2, thus avoiding the provision of a thrust device 5 interposed between said detecting device 115 and said plate back 123 of said second brake pad 120 of said pair of brake pads.

LIST OF REFERENCE SYMBOLS

brake caliper of a disc brake

caliper body

brake disc

thrust device housing

thrust device, e.g. a piston

brake pad

braking surface

braking surface

translating nut screw

endless screw or worm, e.g. with recirculating ball screw reducer or gearbox

thrust bearing

radial outer slewing ring or outer bearing ring

first radially inner slewing ring or first inner bearing ring

second radially inner slewing ring which supports planet gear pins or second inner bearing ring

first outer slewing ring housing

fixed gear or an internally toothed body or ring gear planet gears

second outer slewing ring housing

epicyclic gear

planet gear pin

screw shank pin housings

ratio motor

electric motor

insertion opening

screw thrust head

inner thrust device chamber

X-X support ring brake disc rotation axis snap engagement device

limit stop disc

spherical cap

disc brake

retaining device, e.g. anti-rotation device first elongated portion

first braking surface

second elongated portion

second braking surface

at least one bridge

first brake pad

second brake pad

friction material

friction material

support plate

support plate

plate back

plate back 115 axial bias sensing device

A-A axial direction parallel to rotation axis

R-R radial direction orthogonal to rotation axis

C-C circumferential direction orthogonal to an axial direction and radial directions

T-T tangential direction punctually orthogonal to a radial direction and axial direction