CA1148578A - Hydraulic disc brake piston seal - Google Patents
Hydraulic disc brake piston sealInfo
- Publication number
- CA1148578A CA1148578A CA000389838A CA389838A CA1148578A CA 1148578 A CA1148578 A CA 1148578A CA 000389838 A CA000389838 A CA 000389838A CA 389838 A CA389838 A CA 389838A CA 1148578 A CA1148578 A CA 1148578A
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- CA
- Canada
- Prior art keywords
- piston
- seal
- inboard
- frusto
- cylinder
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Expired
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Abstract
ABSTRACT OF THE DISCLOSURE
A hydraulic piston activated vehicle brake system has a piston movable in a forward brake-activating direction and hydraulically sealed within a cylinder by an elastomeric annular ring seated in an annular groove within a well of the cylinder and compressed between the piston and the annular groove floor.
The annular groove floor comprises a cylindrical portion which is generally parallel to the cylinder wall and a frusto-conical rear portion sloping towards the cylinder wall.
A hydraulic piston activated vehicle brake system has a piston movable in a forward brake-activating direction and hydraulically sealed within a cylinder by an elastomeric annular ring seated in an annular groove within a well of the cylinder and compressed between the piston and the annular groove floor.
The annular groove floor comprises a cylindrical portion which is generally parallel to the cylinder wall and a frusto-conical rear portion sloping towards the cylinder wall.
Description
~48578 This is a divisional patent application based upon Canadian application Serial Number 325,584, filed April 17, 1979.
This in~ention relates to a disc brake for an auto-motive vehicle.
More specifically, the invention concerns an improved hydraulic seal for hydraulically sealing the brake actuating piston within the cylinder. Conventional sealing means of the prior art are designed to not only provide a hydraulic seal be-tween the piston and cylinder but also to exert a resisting force tending to prevent full retraction of the piston upon release of the brakes. Such a seal design is illustrated in U.S. Patent 3,998,466.
Although effective, such sealing means may at times create too much resistance thereby causing the friction pads to excessively drag.
It is therefore an object of the present invention to provide a piston seal with mitigates this disadvantage of the prior art.
It is another object of the invention to provide a piston seal arrangement whereby the force resisting piston re-tractlon may be varied or tailored to the particular brake structure.
The present invention provides a seal for a piston of a hydraulic vehicle braking system, the seal comprises an elasto-meric annular ring having a cylindrical outer peripheral surface portion and a frusto-conical outer peripheral surface portion sloping outwardly to the cylindrical outer peripheral surface portion.
The invention further provides a seal for a piston of - 1- ,,~
~48578 a hydraulic vehicle braking system, the seal comprising an elastomeric annular ring having a cylindrical outer peripheral surface portion and a frusto-conical outer peripheral surface portion sloping outwardly to the cylindrical outer peripheral surface portion.
The invention will be more readily apparent from the following description of an embodiment shown in the drawings, in which:-Figure 1 is a perspective view ofadiscbrake asviewed from the outboard side;
Figure 2 is a perspective view of the disc brake shownin Figure 1 as viewed from the inboard side;
Figure 3 is a rear elevational view of the brake shown in Figure 1 as viewed from the inboard side;
Figure 4 is a front elevational view of the disc brake shown in Figure 1 as viewed from the outboard side;
Figure 5 is a top plan view of the disc brake shown in Figure l;
Figure 6 is an exploded perspective view, partly broken away and partly in diagrammatic form, of the disc brake shown in Figure l;
Figure 7 is a longitudinal cross-sectional view taken along line 7-7 of Figure l;
Figure 7A is an enlarged view of the circled portion of Figure 7 showing details of the piston hydraulic seal con-struction;
Figure 7B is a plot of force resisting piston return versus return travel of the piston;
Figure 8 is an enlarged cross-sectional view taken along line 8-8 of Figure 5;
11~8578 Figure 9 is an exploded perspective view showing the pin bushing and sleeve assembly and details;
Figure 10 is a cross-sectional view taken along line 10-10 of Figure 5 showing the assembled position of the anti-rattle clip shown in Figures 12 and 13;
Figure 11 is a cross-sectional view taken along line 11-11 of Figure 5 showing the assembled position of the anti-rattle clip shown in Figures 12 and 13;
Figure 12 is an elevational view of an anti-rattle clip used in the disc brake as shown in Figure l;
Figure 13 is a plan view of an anti-rattle clip used in the disc brake as shown in Figure l;
Figure 14 is an enlarged cross-sectional view of the piston dust boot used in the disc brake as shown in Figure l;
Figure 15 is a cross-sectional view taken along line 15-15 of Figure 3;
Figure 16 is a front elevational view of the inboard brake shoe assembly used in the disc brake shown in Figure l;
Figure 17 is a bottom view of the brake shoe assembly shown in Figure 16;
Figure 18 is an end view of the brake shoe assembly shown in Figure 16;
Figure 19 is a cross-sectional view taken along line 19-19 of Figure 16;
Figure 20 is an elevational view looking outboard at the outboard brake shoe assembly used in the disc brake shown in Figure l;
Figure 21 is a bottom view of the brake shoe assembly shown in Figure 20; and Figure 22 is a cross-sectional view taken along line 11~8578 22-22 of Figure 20.
The disc brake shown in Figures 1 to 7 comprise a generally C-shaped caliper 10 slidably supported on pins 15L
and 15R secured to anchor plate 11 which is secured to a fixed part of the vehicle. Caliper 10 has a front or outboard leg 13 and a rear or inboard leg 12 interconnected by a bridge por-tion 14. The inboard caliper leg 12 contains the hydraulic actuation means comprising a piston 16 slidable in cylinder 17 and engaging back plate 18 of the inboard friction pad 20. An indirectly actuated outboard friction pad 21 has its back plate 22 engaged by the outboard caliper leg 13. When hydraulic fluid is forced into the actuator cylinder through inlet port 23, inboard pad 20 is urged into frictional engagement with the inboard side of rotor 24 whereupon caliper 10 is caused to slide on pins 15L and 15R thereby applying an inwardly directed force to outboard backing plate 22 causing frictional engage-ment of outboard friction pad 21 with the outboard surface of rotor 24.
Anchor plate 11 has two axially and outward extending arms 26L and 26R which extend over the periphery of the rotor and slidably support both the inboard friction pad backing plate 18 and the outboard friction pad backing plate 22 upon rail guides 30L and 30R by engagement of inboard backing plate guide grooves 32L and 32R and ou~board backing plate guide grooves 33L and 33R. By this construction all braking friction torque is transferred directly to anchor plate support 11 and hence to the vehicle frame (not shown). The caliper 10 serves primarily as means for applying the necessary clamping forces to the brake shoe assemblies without having im~arted thereto the braking torque.
~1~8578 Pins 15L and 15R are secured to anchor plate 11 by threaded engagement and are each received in a bushing assembly, as shown in Figure 9, which extends through bores appropriately positioned and configured in the caliper inboard leg 12.
Referring now to Figures 8 and 9, in which reference numeral 15 is used to indicate either of pins 15L and 15R, bush-ing 40 is made of an elastomeric material, such as rubber, and comprises two zones. Zone A, extending between outboard flange 45 and inboard flange 46 extends through bore 34 in the caliper inboard leg 12 as shown in Figure 8. Flanges 45 and 46 posi-tion, lock and retain bushing 40 within bore 34 and prevent axial movement of the bushing with respect to the caliper in-board leg. Positioned inside zone A of bushing 40 is sleeve 50, made of any suitable plastic or other low friction material such as "Teflon"*. Sleeve 50 functions as a low friction bear-ing within bushing 40 and is retained axially between radially extending portion 49 of Flange 45 and annular recess 43. The inside cylindrical surface of zone A of bushing 40 may be pro-vided with annular grooves 42 to allow for radial displacement of material upon insertion of pin 15 into sleeve 50. Sleeve 50 is preferably provided with a longitudinal gap 51 permitting ease of insertion into bushing 40. Zone B of bushing 40, ex-tending inboard of caliper leg 12, is provided with a multiple number of annular ribs 41 generally having a circular cross-section; a preferable number being three as shown in Figures 8 and 9.
During assembly of the caliper brake, pin 15 is in-serted into bushing 40 from the inboard side, first passing through zone B, then through sleeve 50 and threaded into or otherwise fastened to anchor plate 11. Annular recess 43 is * Registered Trade Mark ~8578 thus provided to permit radial deflection of sleeve 50 into recess 43 thereby allowing passage of the pin leading edge through sleeve 50 without pushing the sleeve through the bush-ing ahead of the pin thusly dislodging sleeve 50 from its desired position within zone A. Further, upon insertion of pin 15 into bushing 40 ribs 41 in zone B slidingly engage pin 15, and are slightly compressed or deformed as shown in Figure 8.
Once assembled and during brake actuation the caliper is free to slide axially upon pins 15L and 15R. Lip 44 of flange 45 acts as a seal preventing entrance of dirt or other contaminants into the bushing assembly of each pin. Annular ribs 48, because of their seal like engagement of the pin, form annular contamination chambers 4 7 and 4 8 thereby preventing dirt or other contaminants from entering the bushing from the inboard side. Thus a reasonably dirt free environment is assured between each pin and its sleeve 50.
Caliper 10, supported upon pins 15L and 15R extending inboard from anchor plate 11 has no other principal means of support. Outboard leg 13 extends laterally between and abut-tingly engages anchor plate rails 30L and 30R through verticalabutment surfaces 35 and 36 respectively. Caliper 10 is principally restrained from circumferential movement resulting from any possible brake shoe frictional drag forces, which may be imparted to caliper 10, by the interaction of abutment sur-faces 35 and 36 with anchor plate rails 30L and 30R respect-fully. The caliper is further restrained from possible radial or vertical movement by the interference of horizontal abut-ment surface 37 with anchor plate rail 30R.
Thus caliper 10 is supported and free to move in an 30 axial direction upon pins 15L and 15R passing through the ~148578 caliper inboard leg 12 and restrained from circumferential or vertical movement through interference abutments on the outboard leg. Movements of or forces imparted to caliper 10 as a result of brake activation are transmitted directly to anchor plate 11 without passing through supporting pins 15L and 15R.
Figure 15 presents a cross-sectional view taken along line 15-15 of Figure 3 showing details of the rear portion of the hydraulic cylinder in claiper inboard leg 12. The cylinder rear wall 52 is provided with boss-like port 23 protruding there-from and allows for cavity 53 to the rear of cylinder wall 17.Thus, the cylinder inlet 54 may be bored directly into cavity 53 requiring no interior machining of the cylinder rear wall 52.
Figures 16 to 19 show the preferred structure of the inboard brake shoe assembly 19. Friction pad 20 is bonded, using any suitable bonding technique known to the industry, or may be integrally molded upon backing plate 18 using readily known methods. Backing plate 18 has a multiplicity of recesses or apertures such as the double step bore 27 shown in Figure 19 extending through the backing plate. During molding of friction pad 20 upon backing plate 18, friction material is forced into and through the apertures and after curing serves to resist shear forces be~ween the pad 20 and backing plate 18 during brake application.
Friction pad 20 is further provided with double cham-fered leading and trailing edges 28 and 29, respectively. When new, or so long as the frictional surface of pad 20 wears evenly, the centroid thereof will coincide with the center of pressure P, which is fixed by the hydraulic piston geometry. Thus a uniform loading is applied to the rotor by pad 20 cver its friction surface. Should, for example, the leading portion of 11~8578 pad 20 wear unevenly or at a faster rate than the trailing por-tion, the frictional surface area increases by reason of cham-fer 28 thus causing the centroid of the friction surface area to translate to C' or C", depending upon the particular wear pattern experienced. However, the center of pressure P remains fixed and coincident with the piston axial center-line, causing an increased surface pressure loading over the trailing portion of the pad friction surface and a decrease in surface loading over the leading portion of pad 20. Thus the pad tends to cor-rect its wear pattern and return the centroid to the center ofpressure P thereby restoring uniform loading and pad wear. By reason of the double chamfer, friction pad 20 will tend to cor-rect for uneven wear in both the circumferential and radial directions.
Figures 20 to 22 show the preferred configuration of the outboard brake shoe assembly 25. Similar to the inboard brake shoe assembly 19 described above, friction pad 21 is molded onto backing plate 22 which also has double step bore apertures therein receiving friction material therein to resist shear forces between pad 21 and backing plate 22. Although the outboard friction pad 21 may be provided with double chamfered leading and trailing edges, it is not believed necessary be-cause of the uniform force applied to backing plate 22 by the caliper outboard leg 13.
As an alternative and upon reuse of backing plates 18 and 22, the double step bore apertures 27 may serve to accommo-date the application of riveted frictional material thereto.
One merely applies the friction pad to the reverse side of the backing plate and the double step bore 27 accommodates the rivet fastener therein.
Outboard brake shoe assembly 25 is configured so as to prevent its inadvertent installation on the inboard side of rotor 24. Therefore the width W of friction pad 21 is such that pad 21 interferes with anchor plate arms 26L and 26R pre-venting insertion of brake pad assembly 25 on the inboard side of the rotor. As a further prevention against installing the outboard brake shoe upon the inboard side of the rotor when the pad 21 is worn thin the backing plate width is such that it abuts against anchor plate ledges 38L and 38R (Figure 6), thus preventing sliding of guide grooves 33L and 33R along guide rails 30L and 30R.
Figures 12 and 13 show anit-rattle clip 60 which is preferably constructed of spring steel wire comprising two longitudinally extending segments 61 and 62 (see also Figure 5) projecting oppositely away from looped hook 63. Inboard seg-ment 61 terminates in looped projection 64 which serves as a finger hold for insertion or removal of clip 60. Clip 60 is positioned as shown in Figures 5, 10 and 11 such that inboard segment 61 and outboard segment 62 lie axially along rail guide 30R and are respectively disposed within notches 31 and 39 of inboard backing plate 18 and outboard backing plate 22. Looped hook 63 extends under and engages the bottom surface of caliper bridge 14 thereby providing a torsional spring force in clip segments 61 and 62 tending to force backing plates 18 and 22 into frictional engagement with rail guides 30L and 30R thereby preventing rattling of the backing plates upon rail guides 30L
and 3OR.
To further assist in applying a positive force upon backing plates 18 and 22, it is preferred to preload the spring clip legs 61 and 62 as shown by the broken line extensions of ~8578 Figure 13. Alternatively the legs 61 and 62 may be preloaded as shown by the broken line extensions shown in Figure 12 or preloaded in both directions. However it has been found that preloading as shown in Figure 13 alone proves satisfactory.
Figure 14 presents an enlarged cross-sectional view of piston dust boot 70. Dust boot 70 comprises an integral one piece molding of an elastomeric material, such as rubber, having an annular bead 71 suitably received in annular groove 38 of piston 17, and flexible bellows portion 72, which radially extends to and terminates at annular flange 73. Annular flange 73 has molded therein a rigid annular ring 74 and is fixedly received in annular groove 75 cut into caliper inboard leg 12 about the hydraulic cylinder bore 17.
By encapsulating ring 74 within elastomeric material, a compression fit is thereby obtained within groove 75 assuring retention of dust boot 70. Further, ring 74 and groove 75 are sealed from moisture and other contaminants which would tend to cause corrosion making it difficult to remove boot 70, and to require groove maintenance prior to replacing boot 70 upon brake servicing.
Sealing piston 16 hydraulically within cylinder 17 is accomplished by use of annular seal means 55 in the form of an elastomeric ring positioned within annular groove 56 in the wall of cylinder 17 as shown in Figure 7A. The floor of groove 56 has a cylindrical portion thereof 57 axially paralleling cylinder 17 and a frusto-conical portion 58 sloped at angle x of 7 to 2~. Preferably angle x is fifteen degrees (15) and the ratio of portion 57 to portion 58 is within the range of 1:1 and 4:1 and preferably three to one (3:1).
Seal means 55 has cylindrical and frusto-conical outer ~8578 surface portions corresponding in orientation and axial length to groove portions 57 and 58.
It has been common practice in the industry to pro-vide a groove floor sloped at approximately 7 so as to cause the seal to compressingly grip the piston thereby resisting in-board movement of the piston upon deactivation of the brake.
However, it has been noticed that many times too much resistance is experienced causing the brake shoe assemblies to slightly drag. By varying the ratio of floor portion 57 to portion 58 various piston resistance forces may be obtained thereby per-mitting one to tailor such resistance to the particular brake assembly without need for specially engineered elastomeric seals. In addition to varying the ratio of floor portion 57 to 58 the slope or angle x may also be varied, thus adding another variable to consider. The seal 55 may be either of rectangular cross-section or may be shaped to conform to the floor con-figuration.
Figure 7B presents a typical plot of seal compressive force against piston ~ravel. The curve identified as "Standard Groove" represents the force distribution for a groove floor sloped at a constant 7 as known in the prior art. The curve identified as "Improved Groove" represents the force distri-bution for a groove floor as shown in Figure 7A having a ratio of portion 57 to portion 58 of 3:1 and x being 15.
The foregoing description presents the preferred em-bodiment of this invention. Modifications and alterations may occur to those skilled in the art which will come within the scope of the following claims.
This in~ention relates to a disc brake for an auto-motive vehicle.
More specifically, the invention concerns an improved hydraulic seal for hydraulically sealing the brake actuating piston within the cylinder. Conventional sealing means of the prior art are designed to not only provide a hydraulic seal be-tween the piston and cylinder but also to exert a resisting force tending to prevent full retraction of the piston upon release of the brakes. Such a seal design is illustrated in U.S. Patent 3,998,466.
Although effective, such sealing means may at times create too much resistance thereby causing the friction pads to excessively drag.
It is therefore an object of the present invention to provide a piston seal with mitigates this disadvantage of the prior art.
It is another object of the invention to provide a piston seal arrangement whereby the force resisting piston re-tractlon may be varied or tailored to the particular brake structure.
The present invention provides a seal for a piston of a hydraulic vehicle braking system, the seal comprises an elasto-meric annular ring having a cylindrical outer peripheral surface portion and a frusto-conical outer peripheral surface portion sloping outwardly to the cylindrical outer peripheral surface portion.
The invention further provides a seal for a piston of - 1- ,,~
~48578 a hydraulic vehicle braking system, the seal comprising an elastomeric annular ring having a cylindrical outer peripheral surface portion and a frusto-conical outer peripheral surface portion sloping outwardly to the cylindrical outer peripheral surface portion.
The invention will be more readily apparent from the following description of an embodiment shown in the drawings, in which:-Figure 1 is a perspective view ofadiscbrake asviewed from the outboard side;
Figure 2 is a perspective view of the disc brake shownin Figure 1 as viewed from the inboard side;
Figure 3 is a rear elevational view of the brake shown in Figure 1 as viewed from the inboard side;
Figure 4 is a front elevational view of the disc brake shown in Figure 1 as viewed from the outboard side;
Figure 5 is a top plan view of the disc brake shown in Figure l;
Figure 6 is an exploded perspective view, partly broken away and partly in diagrammatic form, of the disc brake shown in Figure l;
Figure 7 is a longitudinal cross-sectional view taken along line 7-7 of Figure l;
Figure 7A is an enlarged view of the circled portion of Figure 7 showing details of the piston hydraulic seal con-struction;
Figure 7B is a plot of force resisting piston return versus return travel of the piston;
Figure 8 is an enlarged cross-sectional view taken along line 8-8 of Figure 5;
11~8578 Figure 9 is an exploded perspective view showing the pin bushing and sleeve assembly and details;
Figure 10 is a cross-sectional view taken along line 10-10 of Figure 5 showing the assembled position of the anti-rattle clip shown in Figures 12 and 13;
Figure 11 is a cross-sectional view taken along line 11-11 of Figure 5 showing the assembled position of the anti-rattle clip shown in Figures 12 and 13;
Figure 12 is an elevational view of an anti-rattle clip used in the disc brake as shown in Figure l;
Figure 13 is a plan view of an anti-rattle clip used in the disc brake as shown in Figure l;
Figure 14 is an enlarged cross-sectional view of the piston dust boot used in the disc brake as shown in Figure l;
Figure 15 is a cross-sectional view taken along line 15-15 of Figure 3;
Figure 16 is a front elevational view of the inboard brake shoe assembly used in the disc brake shown in Figure l;
Figure 17 is a bottom view of the brake shoe assembly shown in Figure 16;
Figure 18 is an end view of the brake shoe assembly shown in Figure 16;
Figure 19 is a cross-sectional view taken along line 19-19 of Figure 16;
Figure 20 is an elevational view looking outboard at the outboard brake shoe assembly used in the disc brake shown in Figure l;
Figure 21 is a bottom view of the brake shoe assembly shown in Figure 20; and Figure 22 is a cross-sectional view taken along line 11~8578 22-22 of Figure 20.
The disc brake shown in Figures 1 to 7 comprise a generally C-shaped caliper 10 slidably supported on pins 15L
and 15R secured to anchor plate 11 which is secured to a fixed part of the vehicle. Caliper 10 has a front or outboard leg 13 and a rear or inboard leg 12 interconnected by a bridge por-tion 14. The inboard caliper leg 12 contains the hydraulic actuation means comprising a piston 16 slidable in cylinder 17 and engaging back plate 18 of the inboard friction pad 20. An indirectly actuated outboard friction pad 21 has its back plate 22 engaged by the outboard caliper leg 13. When hydraulic fluid is forced into the actuator cylinder through inlet port 23, inboard pad 20 is urged into frictional engagement with the inboard side of rotor 24 whereupon caliper 10 is caused to slide on pins 15L and 15R thereby applying an inwardly directed force to outboard backing plate 22 causing frictional engage-ment of outboard friction pad 21 with the outboard surface of rotor 24.
Anchor plate 11 has two axially and outward extending arms 26L and 26R which extend over the periphery of the rotor and slidably support both the inboard friction pad backing plate 18 and the outboard friction pad backing plate 22 upon rail guides 30L and 30R by engagement of inboard backing plate guide grooves 32L and 32R and ou~board backing plate guide grooves 33L and 33R. By this construction all braking friction torque is transferred directly to anchor plate support 11 and hence to the vehicle frame (not shown). The caliper 10 serves primarily as means for applying the necessary clamping forces to the brake shoe assemblies without having im~arted thereto the braking torque.
~1~8578 Pins 15L and 15R are secured to anchor plate 11 by threaded engagement and are each received in a bushing assembly, as shown in Figure 9, which extends through bores appropriately positioned and configured in the caliper inboard leg 12.
Referring now to Figures 8 and 9, in which reference numeral 15 is used to indicate either of pins 15L and 15R, bush-ing 40 is made of an elastomeric material, such as rubber, and comprises two zones. Zone A, extending between outboard flange 45 and inboard flange 46 extends through bore 34 in the caliper inboard leg 12 as shown in Figure 8. Flanges 45 and 46 posi-tion, lock and retain bushing 40 within bore 34 and prevent axial movement of the bushing with respect to the caliper in-board leg. Positioned inside zone A of bushing 40 is sleeve 50, made of any suitable plastic or other low friction material such as "Teflon"*. Sleeve 50 functions as a low friction bear-ing within bushing 40 and is retained axially between radially extending portion 49 of Flange 45 and annular recess 43. The inside cylindrical surface of zone A of bushing 40 may be pro-vided with annular grooves 42 to allow for radial displacement of material upon insertion of pin 15 into sleeve 50. Sleeve 50 is preferably provided with a longitudinal gap 51 permitting ease of insertion into bushing 40. Zone B of bushing 40, ex-tending inboard of caliper leg 12, is provided with a multiple number of annular ribs 41 generally having a circular cross-section; a preferable number being three as shown in Figures 8 and 9.
During assembly of the caliper brake, pin 15 is in-serted into bushing 40 from the inboard side, first passing through zone B, then through sleeve 50 and threaded into or otherwise fastened to anchor plate 11. Annular recess 43 is * Registered Trade Mark ~8578 thus provided to permit radial deflection of sleeve 50 into recess 43 thereby allowing passage of the pin leading edge through sleeve 50 without pushing the sleeve through the bush-ing ahead of the pin thusly dislodging sleeve 50 from its desired position within zone A. Further, upon insertion of pin 15 into bushing 40 ribs 41 in zone B slidingly engage pin 15, and are slightly compressed or deformed as shown in Figure 8.
Once assembled and during brake actuation the caliper is free to slide axially upon pins 15L and 15R. Lip 44 of flange 45 acts as a seal preventing entrance of dirt or other contaminants into the bushing assembly of each pin. Annular ribs 48, because of their seal like engagement of the pin, form annular contamination chambers 4 7 and 4 8 thereby preventing dirt or other contaminants from entering the bushing from the inboard side. Thus a reasonably dirt free environment is assured between each pin and its sleeve 50.
Caliper 10, supported upon pins 15L and 15R extending inboard from anchor plate 11 has no other principal means of support. Outboard leg 13 extends laterally between and abut-tingly engages anchor plate rails 30L and 30R through verticalabutment surfaces 35 and 36 respectively. Caliper 10 is principally restrained from circumferential movement resulting from any possible brake shoe frictional drag forces, which may be imparted to caliper 10, by the interaction of abutment sur-faces 35 and 36 with anchor plate rails 30L and 30R respect-fully. The caliper is further restrained from possible radial or vertical movement by the interference of horizontal abut-ment surface 37 with anchor plate rail 30R.
Thus caliper 10 is supported and free to move in an 30 axial direction upon pins 15L and 15R passing through the ~148578 caliper inboard leg 12 and restrained from circumferential or vertical movement through interference abutments on the outboard leg. Movements of or forces imparted to caliper 10 as a result of brake activation are transmitted directly to anchor plate 11 without passing through supporting pins 15L and 15R.
Figure 15 presents a cross-sectional view taken along line 15-15 of Figure 3 showing details of the rear portion of the hydraulic cylinder in claiper inboard leg 12. The cylinder rear wall 52 is provided with boss-like port 23 protruding there-from and allows for cavity 53 to the rear of cylinder wall 17.Thus, the cylinder inlet 54 may be bored directly into cavity 53 requiring no interior machining of the cylinder rear wall 52.
Figures 16 to 19 show the preferred structure of the inboard brake shoe assembly 19. Friction pad 20 is bonded, using any suitable bonding technique known to the industry, or may be integrally molded upon backing plate 18 using readily known methods. Backing plate 18 has a multiplicity of recesses or apertures such as the double step bore 27 shown in Figure 19 extending through the backing plate. During molding of friction pad 20 upon backing plate 18, friction material is forced into and through the apertures and after curing serves to resist shear forces be~ween the pad 20 and backing plate 18 during brake application.
Friction pad 20 is further provided with double cham-fered leading and trailing edges 28 and 29, respectively. When new, or so long as the frictional surface of pad 20 wears evenly, the centroid thereof will coincide with the center of pressure P, which is fixed by the hydraulic piston geometry. Thus a uniform loading is applied to the rotor by pad 20 cver its friction surface. Should, for example, the leading portion of 11~8578 pad 20 wear unevenly or at a faster rate than the trailing por-tion, the frictional surface area increases by reason of cham-fer 28 thus causing the centroid of the friction surface area to translate to C' or C", depending upon the particular wear pattern experienced. However, the center of pressure P remains fixed and coincident with the piston axial center-line, causing an increased surface pressure loading over the trailing portion of the pad friction surface and a decrease in surface loading over the leading portion of pad 20. Thus the pad tends to cor-rect its wear pattern and return the centroid to the center ofpressure P thereby restoring uniform loading and pad wear. By reason of the double chamfer, friction pad 20 will tend to cor-rect for uneven wear in both the circumferential and radial directions.
Figures 20 to 22 show the preferred configuration of the outboard brake shoe assembly 25. Similar to the inboard brake shoe assembly 19 described above, friction pad 21 is molded onto backing plate 22 which also has double step bore apertures therein receiving friction material therein to resist shear forces between pad 21 and backing plate 22. Although the outboard friction pad 21 may be provided with double chamfered leading and trailing edges, it is not believed necessary be-cause of the uniform force applied to backing plate 22 by the caliper outboard leg 13.
As an alternative and upon reuse of backing plates 18 and 22, the double step bore apertures 27 may serve to accommo-date the application of riveted frictional material thereto.
One merely applies the friction pad to the reverse side of the backing plate and the double step bore 27 accommodates the rivet fastener therein.
Outboard brake shoe assembly 25 is configured so as to prevent its inadvertent installation on the inboard side of rotor 24. Therefore the width W of friction pad 21 is such that pad 21 interferes with anchor plate arms 26L and 26R pre-venting insertion of brake pad assembly 25 on the inboard side of the rotor. As a further prevention against installing the outboard brake shoe upon the inboard side of the rotor when the pad 21 is worn thin the backing plate width is such that it abuts against anchor plate ledges 38L and 38R (Figure 6), thus preventing sliding of guide grooves 33L and 33R along guide rails 30L and 30R.
Figures 12 and 13 show anit-rattle clip 60 which is preferably constructed of spring steel wire comprising two longitudinally extending segments 61 and 62 (see also Figure 5) projecting oppositely away from looped hook 63. Inboard seg-ment 61 terminates in looped projection 64 which serves as a finger hold for insertion or removal of clip 60. Clip 60 is positioned as shown in Figures 5, 10 and 11 such that inboard segment 61 and outboard segment 62 lie axially along rail guide 30R and are respectively disposed within notches 31 and 39 of inboard backing plate 18 and outboard backing plate 22. Looped hook 63 extends under and engages the bottom surface of caliper bridge 14 thereby providing a torsional spring force in clip segments 61 and 62 tending to force backing plates 18 and 22 into frictional engagement with rail guides 30L and 30R thereby preventing rattling of the backing plates upon rail guides 30L
and 3OR.
To further assist in applying a positive force upon backing plates 18 and 22, it is preferred to preload the spring clip legs 61 and 62 as shown by the broken line extensions of ~8578 Figure 13. Alternatively the legs 61 and 62 may be preloaded as shown by the broken line extensions shown in Figure 12 or preloaded in both directions. However it has been found that preloading as shown in Figure 13 alone proves satisfactory.
Figure 14 presents an enlarged cross-sectional view of piston dust boot 70. Dust boot 70 comprises an integral one piece molding of an elastomeric material, such as rubber, having an annular bead 71 suitably received in annular groove 38 of piston 17, and flexible bellows portion 72, which radially extends to and terminates at annular flange 73. Annular flange 73 has molded therein a rigid annular ring 74 and is fixedly received in annular groove 75 cut into caliper inboard leg 12 about the hydraulic cylinder bore 17.
By encapsulating ring 74 within elastomeric material, a compression fit is thereby obtained within groove 75 assuring retention of dust boot 70. Further, ring 74 and groove 75 are sealed from moisture and other contaminants which would tend to cause corrosion making it difficult to remove boot 70, and to require groove maintenance prior to replacing boot 70 upon brake servicing.
Sealing piston 16 hydraulically within cylinder 17 is accomplished by use of annular seal means 55 in the form of an elastomeric ring positioned within annular groove 56 in the wall of cylinder 17 as shown in Figure 7A. The floor of groove 56 has a cylindrical portion thereof 57 axially paralleling cylinder 17 and a frusto-conical portion 58 sloped at angle x of 7 to 2~. Preferably angle x is fifteen degrees (15) and the ratio of portion 57 to portion 58 is within the range of 1:1 and 4:1 and preferably three to one (3:1).
Seal means 55 has cylindrical and frusto-conical outer ~8578 surface portions corresponding in orientation and axial length to groove portions 57 and 58.
It has been common practice in the industry to pro-vide a groove floor sloped at approximately 7 so as to cause the seal to compressingly grip the piston thereby resisting in-board movement of the piston upon deactivation of the brake.
However, it has been noticed that many times too much resistance is experienced causing the brake shoe assemblies to slightly drag. By varying the ratio of floor portion 57 to portion 58 various piston resistance forces may be obtained thereby per-mitting one to tailor such resistance to the particular brake assembly without need for specially engineered elastomeric seals. In addition to varying the ratio of floor portion 57 to 58 the slope or angle x may also be varied, thus adding another variable to consider. The seal 55 may be either of rectangular cross-section or may be shaped to conform to the floor con-figuration.
Figure 7B presents a typical plot of seal compressive force against piston ~ravel. The curve identified as "Standard Groove" represents the force distribution for a groove floor sloped at a constant 7 as known in the prior art. The curve identified as "Improved Groove" represents the force distri-bution for a groove floor as shown in Figure 7A having a ratio of portion 57 to portion 58 of 3:1 and x being 15.
The foregoing description presents the preferred em-bodiment of this invention. Modifications and alterations may occur to those skilled in the art which will come within the scope of the following claims.
Claims (4)
1. A seal for a piston of a hydraulic vehicle braking system, said seal comprising an elastomeric annular ring having a cylindrical outer peripheral surface portion and a frusto-conical outer peripheral surface portion sloping outwardly to said cylindrical outer peripheral surface portion, wherein the ratio of axial length of said cylindrical portion to said frusto-conical portion lies within the range of 1 to 1 to 4 to 1.
2. A seal as claimed in claim 1, wherein the ratio of axial length of said cylindrical portion to said frusto-conical portion is 3 to 1.
3. A seal as claimed in claim 1, wherein the angle of inclination of said frusto-conical portion is within the range of 7° to 20°.
4. A seal as claimed in claim 3, wherein the angle of inclination of said frusto-conical portion is 15°.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CA000389838A CA1148578A (en) | 1978-08-01 | 1981-11-10 | Hydraulic disc brake piston seal |
Applications Claiming Priority (4)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| US05/928,474 US4228726A (en) | 1978-08-01 | 1978-08-01 | Hydraulic disc brake piston seal |
| US928,474 | 1978-08-01 | ||
| CA325,584A CA1128089A (en) | 1978-08-01 | 1979-04-17 | Hydraulic disc brake piston seal |
| CA000389838A CA1148578A (en) | 1978-08-01 | 1981-11-10 | Hydraulic disc brake piston seal |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CA1148578A true CA1148578A (en) | 1983-06-21 |
Family
ID=27166184
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CA000389838A Expired CA1148578A (en) | 1978-08-01 | 1981-11-10 | Hydraulic disc brake piston seal |
Country Status (1)
| Country | Link |
|---|---|
| CA (1) | CA1148578A (en) |
-
1981
- 1981-11-10 CA CA000389838A patent/CA1148578A/en not_active Expired
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Legal Events
| Date | Code | Title | Description |
|---|---|---|---|
| MKEX | Expiry |