The invention relates to a motor vehicle disc brake.
The invention relates more particularly to a motor vehicle disc brake including:
In this design, the guiding section of each pin is slidably mounted in the first section of the associated bore which is blind or closed, for the purposes of tightness and protection of this sliding guiding zone, and a quantity of air is thus trapped between the free end of the guiding section of the pin and the base of the first section of the associated bore.
During the axial insertion of the pin into the associated bore on the fitting and assembly line, or during the so-called “de-braking” phase when the disc pushes back the brake pad and the caliper, this volume is reduced by progressive forward motion of the free end of the guiding section of the pin towards the base of the first section of the bore.
So that the volume of air trapped does not impede, or abut against, this forward motion, it is necessary to provide means enabling the progressive evaluation of the trapped air.
The prior art particularly includes a series of solutions requiring modifications, that are complex to carry out, of the tiered bore which further affect the sliding guiding capabilities of the associated pin.
In order to remedy these drawbacks, and solve the problem of air evacuation, the invention proposes a motor vehicle disc brake including:
According to further features of the invention:
Further features and advantages of the invention will emerge on reading the detailed description hereinafter for the comprehension whereof, reference will be made to the appended figures wherein:
In the description and claims hereinafter, expressions such as “longitudinal orientation”, “transversal”, etc. will be used in a non-restrictive manner with reference to the dihedron (L, T) represented in the figures and the definitions given in the description.
In the description hereinafter, identical reference numbers denote identical or equivalent parts or parts having similar functions.
The brake also includes a caliper 10 which is axially slidably mounted, along a longitudinal direction parallel with the axes A and B, with respect to the fixed cover 12. The caliper 10 is slidably mounted with respect to the cover 12 by means of two parallel pins 16, 18 of axes A, B, each whereof includes a first axial end 20, 22 which is attached to the caliper 10, and includes at least one section, blind or sealed, 24, 26 for guiding the axial sliding of the caliper 10 with respect to the cover 12 which is slidably mounted, with a radial clearance, in the first section 28, 30 of the associated tiered bore 29, 31 of the cover 12.
The outer cylindrical guiding surface of the section 24, 26 for guiding each pin 16, 18 includes herein, by way of non-limiting example, and as can be seen in
To embody the portions 64, each portion 64 is for example defined by a pair of flat sections 66 of axial orientation.
Each section 24, 26 of each pin 16, 18 is thus obtained herein using a section of cylindrical cross-section wherein four flat sections 66 are formed.
Each axial portion 64, extends herein along the same axial length.
Each guiding section 24, 26 extends from a free end 25, 27 of the associated pin 16, 18 which is facing the base 33, 35 of the associated first section 28, 30.
As such, each guiding section offers a maximum length for the axial guiding of the caliper.
To particularly enable the evacuation, or “decompression”, of the air contained in the blind tiered bores 29 and 30, at least one flat section 66 of each pin 16, 18 extends from the free end 25, 27 of the pin along a length greater than that of the guiding section 24, 26.
Due to the presence of at least one flat section 66, each pin, engaging with the wall of the blind bore 29, 31, defines at least one axial channel 65 which extends from the free end 25, 27 of the pin and communicates with the space defined by the base 33, 35, by the concave lateral wall of the bore 29, 30 and by the transverse face of the free end 25, 27 of the associated pin 16, 18.
Each associated tiered bore 29, 31 of the cover 12 includes, on the side of the end 20, 22 for attaching the pin 16, 18 to the caliper 10, a second so-called “entry” section 46, 48, and each pin 16, 18 receives a tubular cap 32, 34 made of elastomer material an axial section whereof is inserted radially between the associated pin 16, 18 and the second entry section 46, 48.
The caps 32, 34 ensure the tightness of the tiered bores 29, 31 to dust.
Each cap 32, 34 includes an end 36, 38 which is fitted onto a collar 40, 41 of the end 20, 22 for attaching each pin 16, 18, and it includes an opposite section 42, 44 which is inserted radially between each pin 16, 18 and the second entry section 46, 48 of the associated tiered bore 29, 31 of the cover 12.
To enable the decompression of the air contained in the tiered bores 29 and 30, the caps 32, 34 are associated with the flat sections (66) mentioned above by proposing, for each pin, at least one channel 65 allowing air to flow outside.
For this purpose, one wall of the internal bore 70 of each tubular cap 32, 34 includes at least one internal radial groove 72.
In this embodiment, the internal radial groove 72 “intersects” with at least one axial channel 65, defined by a flat section 66 of the pin in question and by the wall of the bore 29, 31.
The fluidic communication between the axial channel 65 and the groove 72 is ensured continuously, and as such the circulation and progressive evacuation of the air contained in the space defined at the blind front end of the bore 29, 31 (wherein the channel 65 opens) to the outside environment, i.e. to the bellows-shaped end parts.
According to a first embodiment of the caps 32, 34 according to the invention, which is represented in
Alternatively, according to a second embodiment (not shown), the inner wall 70 of the cap 32, 34 includes a single helicoidal groove, of determined pitch, extending along the entire axial length of the cap 32, 34 and which, for this reason, “intersects” with said axial channels at a plurality of points.
In the example of an embodiment of pins described above, each pin defined, in a non-limiting manner, four axial channels 65, each whereof is continuously in communication with at least one radial groove 72 for evacuation of air to the “outside”.
The non-axial orientation of the grooves further makes it possible not to penalise the other functions such as the guiding for sliding.
The invention is not limited to the principle design described above. According to one conventional “mechanical inversion” in the field, the pins can be attached to the caliper and the associated bores can be formed in the cover.
The invention is likewise not limited to the proposed design of one or a plurality of axial channel(s) 65 obtained using one or a plurality of flat section(s) 66. Alternatively, at least one channel connecting the blind end of the bore with a groove or channel of the associated cap can be embodied in any suitable form.
Number | Date | Country | Kind |
---|---|---|---|
13 61310 | Nov 2013 | FR | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2014/074375 | 11/12/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/071309 | 5/21/2015 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4049086 | Rath | Sep 1977 | A |
4311219 | Watanabe | Jan 1982 | A |
4401194 | Klassen | Aug 1983 | A |
4427096 | Stoka | Jan 1984 | A |
4491205 | Rath | Jan 1985 | A |
5069313 | Kato | Dec 1991 | A |
20060049008 | Kinoshita | Mar 2006 | A1 |
20130161134 | Kobayashi | Jun 2013 | A1 |
20140116817 | Morais | May 2014 | A1 |
Number | Date | Country |
---|---|---|
202349032 | Jul 2012 | CN |
103062262 | Apr 2013 | CN |
203082090 | Jul 2013 | CN |
202006006142 | Jul 2006 | DE |
Entry |
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International Search Report PCT/EP2014/074375 dated Aug. 11, 2015. |
Number | Date | Country | |
---|---|---|---|
20160273596 A1 | Sep 2016 | US |