ELECTRONIC PARKING BRAKE

Abstract

A parking brake for a wheel rotor having a brake pad associated therewith includes a housing defining first and second passages. First and second pistons are provided in the respective first and second passages. Spindles are threadably connected with each piston. An electromagnetic locking mechanism provided between the spindles having a first magnetic polarity for placing the locking mechanism in a first condition allowing relative rotation between the spindles and the pistons such that the pistons are axially movable within the passages and into engagement with the brake pad in response to hydraulic pressure applied to the pistons. The electromagnetic locking mechanism has a second magnetic polarity for placing the locking mechanism in a second condition preventing relative rotation between the spindles and the pistons such that the pistons remain engaged with the brake pad when hydraulic fluid pressure is removed from the pistons.

Description

TECHNICAL FIELD

The present invention relates to braking systems and, in particular, relates to an electronic parking brake that maintains braking force without electrical power or hydraulic assistance.

BACKGROUND

Current vehicles are equipped with hydraulic service brakes and electric parking brakes (EPB) for helping control vehicle braking depending on predetermined scenarios. The service brakes rely on one or more movable pistons that selectively apply force to brake pads in order to slow down or stop rotating wheel rotors on the vehicle. The EPB can be used to, for example, supplement the service braking and/or maintain the vehicle at a standstill on a hill.

SUMMARY

In one example, a parking brake for a wheel rotor having a brake pad associated therewith includes a housing defining first and second passages. First and second pistons are provided in the respective first and second passages. Spindles are threadably connected with each piston. An electromagnetic locking mechanism is provided between the spindles and has a first magnetic polarity for placing the locking mechanism in a first condition allowing relative rotation between the spindles and the pistons such that the pistons are axially movable within the passages and into engagement with the brake pad in response to hydraulic pressure applied to the pistons. The locking mechanism has a second magnetic polarity for placing the locking mechanism in a second condition preventing relative rotation between the spindles and the pistons such that the pistons remain engaged with the brake pad when hydraulic fluid pressure is removed from the pistons.

In another example, a parking brake for a wheel rotor having a brake pad associated therewith includes a housing defining first and second passages. First and second pistons are provided in the respective first and second passages. Spindles are threadably connected with each piston. A motor-less, electromagnetic locking mechanism is provided between the spindles and includes an electromagnet and a locking arm positioned between the spindles and rotatable relative to the electromagnet. A pair of permanent magnets is provided on the locking arm. The electromagnet is configured to have first magnetic polarity repelling the permanent magnets for rotating the locking arm to a first condition allowing relative rotation between the spindles and the pistons such that the pistons are axially movable within the passages and into engagement with the brake pad in response to hydraulic pressure applied to the pistons. The electromagnet has a second magnetic polarity attracting the permanent magnets for rotating the locking arm to a second condition preventing relative rotation between the spindles and the pistons such that the pistons remain engaged with the brake pad when hydraulic fluid pressure is removed from the pistons.

In another example, a parking brake for a wheel rotor having a brake pad associated therewith includes a housing defining a passage. A piston is provided in the passage. A spindle is threadably connected with the piston. An electromagnetic locking mechanism is provided adjacent the spindle and has a first magnetic polarity for placing the locking mechanism in a first condition allowing relative rotation between the spindle and the piston such that the piston is axially movable within the passage and into engagement with the brake pad in response to hydraulic pressure applied to the piston. The locking mechanism has a second magnetic polarity for placing the locking mechanism in a second condition preventing relative rotation between the spindle and the piston such that the piston remains engaged with the brake pad when hydraulic fluid pressure is removed from the piston.

Other objects and advantages and a fuller understanding of the invention will be had from the following detailed description and the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic illustration of a vehicle having a braking system including an example caliper assembly.

FIG. 2 is a side view of a housing of the caliper assembly.

FIG. 3 is a bottom view of the housing.

FIG. 4A is a section view taken along line 4A-4A of FIG. 2.

FIG. 4B is a section view taken along line 4B-4B of FIG. 2.

FIG. 5 is a section view taken along line 5-5 of FIG. 3.

FIG. 6 is an exploded view of a portion of the caliper assembly.

FIG. 7 is a section view of a piston assembly.

FIG. 8 is a section view of a piston of the piston assembly.

FIG. 9 is an exploded view of a spindle assembly.

FIG. 10 is an exploded view of a clutch unit of the caliper assembly.

FIG. 11 is a section view taken along line 11-11 of FIG. 10.

FIG. 12 is a bottom view of a housing of the caliper assembly.

FIG. 13A is a schematic illustration of the clutch unit in a first condition.

FIG. 13B is a schematic illustration of the clutch unit in a second condition.

FIG. 14 is a schematic illustration of another example caliper assembly.

FIG. 15 is a section view taken along line 15-15 of FIG. 14.

FIG. 16 is an exploded view of a portion of the caliper assembly of FIG. 14.

FIG. 17 is a section view of a piston of the caliper assembly of FIG. 14.

FIG. 18 is a section view of a ramp nut of the caliper assembly of FIG. 14.

FIG. 19 is a front view of a clutch unit of the caliper assembly of FIG. 14.

FIG. 20 is an exploded view of the clutch unit of FIG. 19.

FIG. 21 is a top view of a driven gear of the clutch unit of FIG. 19.

FIG. 22A is a schematic illustration of the clutch unit of FIG. 19 in a first condition.

FIG. 22B is a schematic illustration of the clutch unit of FIG. 19 in a second condition.

FIG. 23A is a schematic illustration of a single piston caliper assembly.

FIG. 23B is a section view of the caliper assembly of FIG. 23A.

FIG. 23C is another section view of the caliper assembly of FIG. 23A.

FIG. 24 is an enlarged view of a portion of FIG. 23B.

FIG. 25 is an enlarged view of another portion of FIG. 23B.

FIG. 26 is a flow chart for parking brake events when the vehicle is in a first condition.

FIG. 27 is a flow chart for parking brake events when the vehicle is in a second condition.

FIG. 28 is a schematic illustration of another example caliper assembly.

FIG. 29A is a section view of the caliper assembly of FIG. 28.

FIG. 29B is an exploded view of a portion of the caliper assembly of FIG. 28.

FIGS. 30A-30C are views of an electromagnetic locking mechanism for the caliper assembly of FIG. 28.

FIG. 31A is a front view of a portion of the locking mechanism in a first condition.

FIG. 31B is a schematic illustration of the locking mechanism in the first condition.

FIG. 32A is a front view of a portion of the locking mechanism in a second condition.

FIG. 32B is a schematic illustration of the locking mechanism in the second condition.

DETAILED DESCRIPTION

The present invention relates to braking systems and, in particular, relates to an electric parking brake that maintains braking force without electrical power or hydraulic assistance. FIG. 1 illustrates an example braking system 10 for a motor vehicle 20 in accordance with the present invention. The vehicle 20 can be an electric or hybrid vehicle.

The vehicle 20 extends from a first or front end 24 to a second or rear end 26. A pair of steerable wheels 30 is provided at the front end 24. Each wheel 30 includes a wheel rotor 36 driven and steered by a steering linkage (not shown). A pair of wheels 32 is provided at the rear end 26. Each wheel 32 includes a wheel rotor 38 driven by a steering linkage (not shown). Friction brake pads 37 are associated with each wheel rotor 36, 38 and positioned on opposite sides thereof.

A propulsion system 40 including an engine and/or electric motor supplies torque to the wheels rotors 36 and/or the wheels rotors 38. A battery 42 supplies power to the vehicle 20. A brake pedal simulator 46 or brake pedal (not shown) is provided for controlling the timing and degree of vehicle 20 braking. A sensor 48 is connected to the brake pedal simulator 46 and monitors the displacement and acceleration of the brake pedal simulator.

A caliper assembly 60 is provided on at least one of the wheel rotors 36, 38 and controls both service braking and the parking brake associated with that wheel rotor. As shown, each wheel rotor 36, 38 on the front and rear ends 24, 26 includes a caliper assembly 60. It will be appreciated, however, that only the front wheel rotors 36 or only the rear wheel rotors 38 can include a caliper assembly 60 (not shown). The caliper assemblies 60 are connected to a master cylinder 62 by hydraulic lines 64. It will be appreciated that the fluid system for the caliper assemblies 60 and master cylinder 62 has been greatly simplified for brevity.

A control system 44 is provided for helping control operation of the vehicle 20, such as operation of the propulsion system 40 and vehicle braking, including operating the caliper assemblies 60. To this end, the control system 44 can include one or more controllers, such as a transmission controller, propulsion system controller, motor controller, and/or brake controller. That said, the control system 44 is connected to and receives signals from various sensors that monitor vehicle functions and environmental conditions.

For example, a vehicle speed/acceleration sensor 50 monitors the vehicle speed and acceleration and generates signals indicative thereof. A road grade sensor 52 can detect or calculate the slope of the road on which the vehicle 20 is driving and generate signals indicative thereof. An ignition sensor 54 generates signals indicative of when the ignition is turned on. The control system 44 can receive and interpret these signals and perform vehicle functions, e.g., braking, in response thereto. The control system 44 can also be connected to an alert 56 for notifying the driver/operator of the vehicle 20 of vehicle conditions, vehicle status, and/or environmental conditions.

Referring to FIGS. 2, 3, 4A and 4B, the caliper assembly 60 includes a housing 70 and a clutch unit 240 connected to the housing. The housing 70 extends generally along a centerline 72 from a first end 74 to a second end 76. First and second bores or passages 80, 82 (see FIGS. 4A-4B) extend into the housing 70 and parallel to the centerline 72. A passage 84 fluidly connects the first and second passages 80, 82. An inlet opening 85 extends into the housing 70 to the connecting passage 84. The inlet opening 85 is configured to receive hydraulic fluid from the hydraulic lines 64. An annular recess or seal groove 86 is provided in each passage 80, 82. A cover or end cap 87 on the first end 74 extends over and obstructs the passages 80, 82. The end cap 87 can be integrally formed with or a separate component connected to the first end 74. Openings 88, 90 extend through the end cap 87 and to the respective passages 80, 82.

A bridge 92 extends from the second end 74 of the housing 70 and along/parallel to the centerline 72. A projection 94 extends from the bridge 92 and transverse to the centerline 72. The bridge 92 and projection 94 cooperate to define a channel 96 for receiving the rotor 36 or 38 of one of the wheels 30 or 32.

Referring to FIGS. 5-8, a piston assembly 100 is provided in each passage 80, 82 in the housing 70. The piston assembly 100 includes a piston 102 extending along a centerline 104 from a first end 106 to a second end 108 (see FIG. 8). A first cavity 110 extends from the first end 104 towards the second end 108 and terminates at an axial end surface 112. The end surface 112 can be angled (as shown) or flat (not shown) relative to the centerline 104.

A second passage extends 114 from the end surface 110 towards the second end 108 and terminates at an axial end surface 116. A first annular recess 120 is provided in the first cavity 110 and encircles the centerline 104. A second annular recess 122 is provided on the exterior of the piston 102 at the second end 108 thereof. The piston 102 is formed from a material that is durable in both compression and tension, such as steel, aluminum or the like.

A nut 130 (FIG. 7) is provided in the first cavity 110 of the piston 102. The nut 130 includes a base 132 and a flange 134 extending radially outward from the base 132. The flange 134 includes a first axial end surface 136 and a second axial end surface 138. The second axial surface 138 abuts the axial end surface 112 of the piston 102 and has the same shape/contour thereof. A central passage 140 extends the entire length of the nut 130 through the base 132 and the flange 134. Threads 142 are provided along a portion of the central passage 140.

A volume reducer 150 is also provided in the first cavity 110 of the piston 102. The reducer 150 includes first and second axial end surfaces 152, 154. An inner surface 156 defines a central passage 158 (see FIG. 6) extending the entire length of the reducer 150 from the axial end surface 152 to the axial end surface 154. The reducer 150 also includes an outer surface 160. The reducer 150 can be formed from an incompressible material, such as aluminum or phenolic.

The base 132 of the nut 130 is received by the central passage 158 of the reducer 150 such that the axial end surface 154 of the reducer abuts the axial end surface 136 on the flange 134 of the nut 130. The inner surface 156 is adjacent to or abutting the base 130. The outer surface 158 is adjacent to or abutting the piston 102. The reducer 150 is securely fixed to the nut 130 along the surfaces 154, 156. In any case, the outer surface of the reducer 150 is positioned adjacent to or in engagement with the inner surface of the piston 102.

It will be appreciated that although the piston 102, nut 130 and reducer 150 are shown and described as separate components, the piston, nut, and reducer could likewise be formed integrally with one another. In any case, the nut 130 and reducer 150 are securely fixed or connected to the piston 102. That said, the nut 130 and reducer 150 (whether integrally formed with the piston 102 or securely fastened thereto) can be considered part of the piston.

A clip 170 forms a snap-fit with the annular recess 120 of the piston 102. The clip 170 abuts the base 132 of the nut 130 and the axial end surface 152 of the reducer 150 and maintains the nut and reducer within the first cavity 110 of the piston 102. The clip 170 also prevents relative movement between the piston 102, the nut 130, and the reducer 150.

A seal 172 extends around the exterior of the second end 108 of the piston 102. A piston boot excluder 180 is provided in the outer recess 122 and cooperates with the housing 70 to help prevent dirt and debris from entering the passages 80, 82.

As shown in FIGS. 7 and 9, a spindle assembly 190 extends through each piston assembly 100. The spindle assembly 190 includes a spindle 192 extending along an axis 194 from a first end 196 to a second end 198. A projection or flange 200 extends radially from the spindle 192 between the first and second ends 196, 198. External threads 202 are provided from the flange 200 to the extent of the second end 198. An unthreaded portion 204 extends from the projection 200 towards the first end 196 and terminates at an annular recess 208. A splined portion 210 extends from the annular recess 208 to the extent of the first end 196. A thrust bearing 214 is received by the unthreaded portion 204 and abuts the flange 200. A retaining ring 218 is configured to snap into the recess 208 on the first end 196 of the spindle 192.

The spindle assemblies 190 are connected to each respective piston assembly 100 as shown in FIG. 7. More specifically, the spindle 192 extends through the clip 170 and the passage 140 in the nut 130. The second end 198 of the spindle 192 abuts the axial end surface 116 of the piston 102. The threads 202 on the spindle 192 are threadably engaged with the threads 142 on the nut 130. As noted, the nut 130 can be integrally formed with or securely fastened to the piston 102. Consequently, the mating threads 142, 202 established a threaded connection between each spindle 190 and corresponding piston 102.

In any case, it will be appreciated that the mating threads 142, 202 can be configured to be “fast lead” threads. That is to say, the threads 142, 202 can be configured to have mating fast-pitch constructions that facilitate relative rotational and translational movement between the nut 130 and the spindle 192, which facilitates relative movement between the piston 102 and the spindle.

A piston assembly 100 and respective spindle 190 are provided in each of the passages 80, 82 in the housing 70. In particular, and referring back to FIG. 5, the first ends 106 of the pistons 102 are positioned closer to the first side 74 of the housing 70 while the second ends 106 are positioned closer to the second side 76. The seals 172 are positioned in the seal grooves 86 in the first and second passages 80, 82 and is configured to cooperate with the seal grooves (FIG. 5) to seal the piston 102 within the respective passage.

The unthreaded portion 204 of one spindle 192 extends through the passage 80 and the associated opening 88 to the exterior of the housing 70. The unthreaded portion 204 of another spindle 192 extends through the passage 82 and the associated opening 90 to the exterior of the housing 70. The thrust bearing 214 is provided on the unthreaded portion 204 and prevents axial movement of the spindle 190. The retaining rings 218 are positioned in the annular recesses 208 and outside the end cap 87 of the housing 70 to prevent the spindle 192 from moving axially towards the second end 76 of the housing 70.

The clutch unit 240 is connected to the first end 74 of the housing 70 and the exposed ends 196 of the spindles 192. Referring to FIG. 10, the clutch unit 240 includes a housing 250 having a first side 252 and a second side 254. As will be described, an actuating arm 330, solenoid 350, and cap 360 are received in the first side 252. A wedge ring 280, roller bearings 290, roller cage 300, hub 310, and cap 320 (collectively a “clutch subassembly”) are received in the second side 254 of the housing 250. The number of clutch subassemblies corresponds with the number of piston assemblies 100 provided in the housing 70. That said, although a pair of clutch assemblies are shown in FIG. 10, it will be appreciated that more or fewer clutch subassemblies can be provided in the clutch unit 240.

Referring to FIGS. 11-12, a first passage 260 extends from the first side 252 of the housing 250 towards the second side 254. A pair of second passages 262 extends from the second side 254 towards the first side 252 and intersect the first passage 260. A circular recess 264 is provided in each second passage 260 and is centered therewith. A pocket 266 extends around each recess 264 and is sized/shaped to receive one of the wedge rings 280.

Referring back to FIG. 10, the wedge ring 280 has a polygonal, e.g., triangular shape. Projections 282 extend outward from the wedge ring 280. An inner surface defines an opening 284 that extends through the center of the wedge ring 280. The inner surface includes angled or ramped portions 288. In particular, the surfaces 288 are angled relative to the center of the opening 284 such that one end of each surface is closer to the center than the other end. As shown, three surfaces 288 are symmetrically arranged about the opening 284, with each surface angling towards the center of the opening in a direction extending clockwise. It will be appreciated, however, that any number of surfaces 288 can be provided symmetrically about the opening 284.

The roller cage 300 includes a tubular base 302. Openings 304 extend radially outward through the base 302 and are configured to receive the roller bearings 290. As shown, three roller bearings 290 are received in three radial openings 304 arranged symmetrically about the base 302. The roller bearings 290 are shown as cylindrical but could have alternative configurations, e.g., frustoconical or spherical. More or fewer roller bearings 290 and corresponding openings 304 can be provided in each clutch subassembly. An arm 306 extends radially outward from the base 302. A pin or projection 308 is formed on the arm 306 and extends substantially perpendicular to the arm. Other angles are contemplated.

The hub 310 is cylindrical and includes an outer surface 312 and an inner surface 314 defining an axially extending passage 316. The inner surface 314 is splined or otherwise configured to mate with the splined portion 210 of the spindle 192.

The actuating arm 330 is elongated and includes a base 332 and an opening 334 extending therethrough. Arms 340 extend in opposite directions from the base 332. A notch 342 is formed at the end/axial extent of each arm 340 for receiving the projection 308 of the roller cage 300.

When each clutch subassembly is assembled, the wedge ring 280 is positioned within the pocket 266 in the second passage 262. The projections 282 on the wedge ring 280 prevent relative rotation between the wedge ring and the housing 250. The base 302 of the roller cage 300 is positioned in the recess 264, which positions the base within the opening 284 of the wedge ring 280. The arm 306 on the roller cage 300 extends under (as shown) wedge ring 280 and into the first passage 260.

The roller bearings 290 are positioned in the openings 304 in the roller cage 300 and abut the angled surfaces 288 of the wedge ring 280. The number of roller bearings 290 in each clutch subassembly corresponds with the number of angled surfaces 288 on the associated wedge ring 280. In any case, the hub 310 is positioned within the tubular base 302 of the roller cage 300 and is concentric therewith. The inner surface 314 of the hub 310 receives the splined portion 210 of the spindle assembly 190 to rotatably couple the hub and spindle assembly together.

The actuating arm 330 is positioned in the recess 270 in the first passage 260 of the housing 250 such that the notches 342 on the arms 340 at least partially receive the projections 308 on the arms 306 of the roller cage 300. The solenoid 350 extends into the opening 334 of the actuating arm 330 such that the solenoid is capable of rotating the actuating arm about an axis 352. The solenoid 350 can be, for example, a bistable solenoid having a positive voltage polarity position and a negative voltage polarity position. That said, the clutch unit 240 is motor-less, gear-less, and does not require a constant voltage application to maintain any one position.

The clutch unit 240 is positioned over the exposed, splined portions 210 of the spindles 192 such that the splined inner surfaces 314 of the hubs 310 mesh with the splined portions. This positions the first ends 196 of the spindles 192 within the bases 302 of the hollow cages 300.

The clutch unit 240 has a first condition/position (FIG. 13A) that allows the hubs 310 and, thus, allows the spindles 192 secured thereto to rotate in the manner indicated at R₁ (and the direction opposite R₁). In the first condition the solenoid 350 is rotated such that the notches 342 in the arms 340 partially receive the projections 308 on the roller cage 300. As a result, each roller cage 300 is oriented in a first rotational position relative to the respective axis 194 that places the roller bearings 290 at a first location along the angled surfaces 288 of the wedge ring 280. In this location, the roller bearings 290 are radially spaced from the outer surfaces 312 of the hubs 310. This allows the hubs 310/spindles 192 to rotate freely relative to the respective roller cages 300.

The clutch unit 240 has a second condition/position (FIG. 13B) that prevents the hubs 310 and spindles 192 secured thereto from rotating. To this end, the solenoid 350 can be actuated to rotate in the direction R₂ (CCW as shown), which rotates the arms 340 in the direction R₂. The rotating arms 340 move the projections 308 engaged therewith in the direction R₃ (CW as shown).

As a result, the roller cages 300 are rotated in the direction R₃ to a second rotational position relative to the axes 194, which moves the roller bearings 290 along and “up” the angled surfaces 288. By rolling up the surfaces 288, the roller bearings 290 are moved radially towards the hubs 310 until engaging the outer surfaces 312 thereof. More specifically, the roller bearings 290 become wedged or locked between the surfaces 288 and the outer surface 312 sufficient to prevent rotation of the hubs 310 and thereby prevent rotation of the spindles 192 connected thereto in the direction R₁. This, in turn, prevents back-drive of the pistons 102. Rotation of the spindles 192 in the direction opposite the direction R₁, however, is still permitted.

It will be appreciated that the solenoid 350 and actuating arms 330 can alternatively be configured such that the solenoid imparts linear motion on the actuating arms (not shown) which, in turn, impart rotational movement on the roller cages 300 to lock the roller bearings 290 in the manner described. In such a construction, the spindles 192 would still operate in the same manners when the clutch unit 240 is in the respective first and second conditions.

Returning to FIG. 5, during operation of the braking system 10, a service brake demand initiated by the system and/or vehicle operator causes hydraulic fluid to be delivered via the hydraulic line 64 to the inlet opening 85 of the housing 70 of at least one caliper assembly 60. In this example, service braking is shown for a single, rear end 26 wheel rotor 38.

The hydraulic fluid passes through the inlet opening 85, into the connecting passage 84, and subsequently into both the first and second passages 80, 82. The hydraulic fluid pressure builds within the passages 80, 82 and behind/upstream of the clips 170 in the passages 110 of the piston assemblies 100 until the fluid pressure is sufficient to urge the pistons 102 in the direction D towards the wheel rotor. More specifically, the pistons 102 are urged to move axially in the direction D but initially encounter the connection between the threaded components 142, 202.

At this time, the clutch unit 240 is in the first condition allowing free rotation of the spindles 192 about their respective axes 194. That said, urging the pistons 102 to move in the direction D causes the spindles 192 connected thereto to rotate in the direction opposite the direction R₁ (see FIG. 13A) relative to the pistons due to the threaded connection 142, 202. In other words, the position of the roller bearings 290 at the first location on the angled surfaces 288 allows the spindles 192 to rotate to accommodate axial movement of the pistons 102 towards and into engagement with the brake pad 37 on the wheel rotor 38. Consequently, the service brake is applied and the bridge 92 of the housing 70 elastically deforms in a known manner.

Advantageously, the pistons 102 can move in the direction D independent from one another when the clutch unit 240 is in the first condition as each spindle 192 is free to rotate independent of the other. As a result, the pistons 102 can move different distances in the direction D to account for pad and/or rotor wear. For example, the piston 102 in the first passage 80 can move a first distance in the direction D before engaging the brake pad 37. If the brake pad 37 is worn, however, the piston 102 in the second passage 82 may be required to move a second, greater distance in the direction D before engaging the brake pad. In each case, the fast lead connection 142, 202 facilitates rapid piston 102 movement in the direction D with little frictional resistance between the moving threads. Consequently, both pistons 102 will reach the brake pad 37 at substantially the same time regardless of any disparity in the degree of movement needed.

In any case, if the demand for service brakes is stopped, hydraulic fluid is no longer supplied to the inlet openings 85 and, thus, the pistons 102 are no longer urged in the direction D towards the brake pad 37. This allows the elastically deformed bridge 92, housing 70, and pads 37 to automatically relax and push the pistons 102 back towards the respective passages 80, 82 in the direction opposite the direction D. The clutch unit 240 remains in the first condition during this return and, thus, the spindles 102 are free to rotate in the direction R₁ to accommodate the axial return movement of the pistons. The fast lead threaded connection 142, 202 facilitates a rapid, reduced stress retreat of the pistons 102 away from the brake pad 37.

On the other hand, if the parking brake is demanded during application of the service brake, the clutch unit 240 is actuated to the second condition to lock the pistons 102 against the brake pad 37. More specifically, the solenoid 350 is actuated (FIG. 13B) to lock the roller bearings 290 against the hubs 310 and thereby lock the spindles 192 in place. To this end, rotation of the spindles 192 in the direction R₁ (back-drive) is prevented, whereas rotation of the spindles in the direction opposite the direction R₁ is permitted to permit the pistons 102 to advance further in the direction D where the application of additional hydraulic pressure is desired.

That said, when the clutch unit 240 is in the second condition and hydraulic pressure is released/removed, the pistons 102 cannot translate along/relative to the spindles 192 due to the threaded connection 142, 202 therebetween. The pistons 102 are therefore locked in place so long as the solenoid 350 is in the second condition.

Advantageously, this allows the brake system to remove the hydraulic pressure from the caliper 60. In other words, the hydraulic fluid can be removed from the passages 80, 82 since the clutch unit 240 maintains the braking pressure between the pistons 102 and brake pad 37. The braking system 10 therefore does not rely on hydraulic fluid/pressure in order to hold the parking brake and is capable of maintaining substantially the same braking clamp force as the hydraulic system.

When the parking brake is no longer needed, e.g., drive-away release (DAR) or parking release event, the solenoid 350 is actuated to the first condition to move the roller bearings 290 along the angled surfaces 288 and out of engagement with the hubs 310. At the same time, hydraulic fluid is returned to the passages 80, 82 via the inlet opening 85 at an increased level, e.g., a 5% or 10% increase, relative to the hydraulic pressure previously applied at the time the parking brake was engaged (solenoid moved to second condition). As noted, the clutch unit 240 allows for additional rotation of the spindles 192 in the direction opposite the direction R₁ to enable the pistons to provide this additional/elevated clamping force. The increased hydraulic pressure on the pistons 102 helps to relieve the torque experienced by the hubs 310, thereby helping the solenoid 350 to move the roller bearings 290 off the surfaces 288, and complete the transition to the first condition position.

In other words, the increased hydraulic pressure facilitates movement of the solenoid 250 to the first condition. That said, moving the roller bearings 290 out of engagement with the hubs 310 and subsequent hydraulic pressure release enables rotation of the spindles 192, which allows the pistons 102 to move axially along and relative to the spindles back to their initial condition under the influence of the relaxing bridge 92 of the housing 70.

FIGS. 14-22B illustrate another example caliper assembly 390 in accordance with the present invention. Components in the caliper assembly 390 that are similarly or identically constructed to components in the caliper assembly 60 are given the same reference number. That said, the specific discussion of those components is reduced or omitted in the interest of brevity.

The piston assembly 400 includes a piston 402 extending along a centerline 404 from a first end 406 to a second end 408 (see FIGS. 16-17). A first passage 410 extends from the first end 404 towards the second end 408 and terminates at an axial end surface 412. A second passage extends 414 from the end surface 410 towards the second end 408 and terminates at an axial end surface 416. A first annular recess 420 is provided in the first passage 410 and encircles the centerline 404. A second annular recess 422 is provided on the exterior of the piston 402 at the second end 408 thereof.

The piston assembly 400 further includes an annular, stationary ramp 430. A central passage 432 extends through the ramp 430. An annular track 434 encircles the central passage 432 and includes a series of ramps symmetrically arranged about the central passage. A bearing cage 450 (FIG. 16) is aligned with the annular track 434 and includes a central passage 452 and pockets 454 arranged around the central passage for receiving roller bearings 440. In this example, the roller bearings 440 are spherical and extend to both sides of the bearing cage 450.

A ramp nut 460 (FIG. 18) is provided in the first passage 410 of the piston 402. The nut 460 includes a base 462 and a flange 464 extending radially outward from the base. The flange 464 includes a first axial end surface 466 and a second axial end surface 468. A central passage 472 extends the entire length of the ramp nut 460 through the base 462 and the flange 464. An annular track 470 is formed in the second axial end surface 468 and includes a series of ramps 471 symmetrically arranged about the central passage 472. Threads 474 are provided along a portion of the central passage 472. A cage 476 extends over the base 460 and engages the spring 480 at end surface 484 (see also FIGS. 15-16). The cage 476 encloses a thrust bearing 478 and presses the thrust bearing against the axial end of the base 462.

A spring 480 (FIG. 16) is also provided in the first passage 410 of the piston 402. The spring 480 includes first and second axial end surfaces 482, 484. An inner surface defines a central passage 488 extending the entire length of the spring 480 from the axial end surface 482 to the axial end surface 484.

Referring to FIG. 15, the stationary ramp 430 abuts the end surface 412 in the piston 402. The roller bearings 440 are positioned in the annular track 434 of the stationary ramp 430. The ramp nut 460 is positioned in the first passage 410 The roller bearings 440 are received in the annular track 470 such that the roller bearings are movable along and relative to both the annular recess in the ramp nut 460 and the annular track 434 in the stationary ramp 430.

The base 462 of the ramp nut 460 extends through the central passage 488 in the spring 480 such that the end surface 484 of the spring is adjacent the end surface 466 of the flange 464 of the ramp nut.

A clip 490 forms a snap-fit with the annular recess 420 of the piston 402. The clip 490 abuts the spring 480 on the end 482 and the spring 480 axial end surface 484 abuts the cage 476. Due to the presence of the thrust bearing 478, the spring 480 urges or presses the ramp nut 460 against the roller bearings 440. Since the roller bearings 440 press against the stationary ramp 430, which presses against the piston 102, the roller bearings are held in place in the tracks 430, 470 and loaded up to a force equal to the pre-loaded (or compressed) spring 480.

The seal 172 extends around the exterior of the second end 408 of the piston 402. The piston boot excluder 180 is provided in the outer recess 422 and helps prevent dirt and debris from entering the passages 80, 82. The spindle 192 extends through the passages 432, 452, 472, 488 and is threadably engaged with the threads 474 on the ramp nut 460.

As shown in FIGS. 19-20, the clutch unit 500 is connected to an motor assembly 600. The clutch unit 500 and motor assembly 600 can be separate components coupled together (as shown) or integrally formed together in a single assembly (not shown). In any case. The clutch unit 500 is connected to the first end 74 of the housing 70 and includes a housing 510 having a first side 512 and a second side 514. A first passage 520 extends from the first side 512 towards the second side 514 and terminates at an axial end surface 524. An opening 526 extends into the end surface 524. A pair of second passages 522 extends entirely through the housing 510 and intersect the first passage 520. A cap 523 closes the passages 522.

A plate 530 is provided in each second passage 522. The plate 530 includes a central opening 532 and an annular recess 534 encircling the opening. Roller bearings 540 are provided in the annular recess 534. The roller bearings 540 can be cylindrical and symmetrically arranged about the opening 532.

A hub 550 is provided in the opening 532 in the plate 530. The hub 550 is cylindrical and includes an outer surface 552 and an inner surface 554 defining an axially extending passage 556. The inner surface 554 is splined or otherwise configured to mate with the splined portion 210 of the spindle 192.

The clutch unit 500 further includes a drive gear 560 and a pair of driven gears 580. Teeth 562 extend radially outward from the drive gear 560 and mesh with similarly shaped teeth 582 on the driven gears 580. An inner surface 564 extends into through the drive gear 560 and defines a splined passage 566. An opening (not shown) extends from the passage 566 through the end of the drive gear 560. An axle 570 is received in the opening in the drive gear 560 and the opening 526 in the housing 510.

Referring to FIG. 21, each driven gear 580 includes an inner surface 584 defining a central passage 586 and pockets 588 arranged circumferentially about the central passage. Each pocket 588 is defined by a first, curved surface 590 and a second, angled surface 592. To this end, the surface 592 is angled such that the distance d between the surface and the central passage 586 decreases in a direction extending away from the first surface 590 (CW as shown). The roller bearings 540 are positioned within the pockets 588 when the clutch unit 500 is assembled.

The clutch unit 500 is positioned over the exposed, splined portions 210 of the spindles 192 such that the splined inner surfaces 554 of the hubs 550 mesh with the splined portions of the spindles (FIG. 22A). This positions the first ends 196 of the spindles 192 within the bases 302 of the hollow cages 300.

The motor assembly 600 is coupled to the splined passage 566 of the drive gear 560 for rotating the same. The motor assembly 600 includes a motor, a gear stage assembly that can be adjusted depending on the application, and solenoid brake, e.g., normally locked, spring loaded brake for selectively allowing and preventing rotation of the motor and gear stage assembly (not shown).

The clutch unit 500 has a first condition (FIG. 22A) that allows the hubs 550 and. thus, allows the spindles 192 secured thereto to rotate in the manner indicated at R₄. In particular, in the first condition the motor assembly 600 is unactuated, which places/maintains the roller bearings 540 against the first surfaces 590 of the pockets 588. In this location, the roller bearings 540 are radially spaced from the outer surfaces 552 of the hubs 550. This allows the hubs 550/spindles 192 to rotate freely in the direction R₄ (and the direction opposite the direction R₄) relative to the respective driven gears 580.

The clutch unit 500 has a second condition (FIG. 22B) that prevents the hubs 550 and spindles 192 secured thereto from rotating. In particular, the motor assembly 600 is actuated to rotate the drive gear 560 in the direction R₅ (CW as shown), which rotates the driven gears 580 in the direction R₆ (CCW as shown). The driven gears 580 rotate relative to the roller bearings 540 and, thus, rotating the driven gears in the direction R₆ moves the pockets 588 circumferentially relative to the stationary roller bearings 540. Consequently, each roller bearing 540 becomes spaced from the first surface 590 of the respective pocket 588 and ultimately wedged between the angled surface 592 and the outer surface 552 of the hub 550 sufficient to prevent rotation of the hubs and thereby prevent rotation of the spindles 192 connected thereto.

At the same time, the spindles 192 are also rotated in the direction R₆. When this occurs, only the spindles 192 initially rotate to move the pistons 402 and ball ramp assembly (including both stationary ramps 430, ramp nuts 460, roller bearings 440, spring 480, thrust bearings 478, clips 490) connected thereto toward the brake pad 37 at low load. When the pistons 402 contact the brake pad 37 and develop some small level of clamp force, the spindles 192 and ramp nuts 460 rotate together due to the threaded connection 202, 474 therebetween. The ramp 430, however, remains stationary.

That said, rotating the ramp nuts 460 relative to the stationary ramps 430 causes the roller bearings 440 to roll “up” the ramps 436, 471 in the respective tracks 434, 470. As a result, the ramp nut 460 in effect pushes the stationary nut 430 in the direction D through the roller bearings 440. This, in turn, applies sufficient clamp force to the brake pads 37 to park the vehicle without the need of assistance from the hydraulic brake system.

The clutch unit 500 operates in cooperation with the service brake in the same manner as the clutch unit 240 described above. That said, when the pistons 402 are fully retracted into the passages 80, 82 and the motor assembly 600 is powered off, the clutch unit 500 is disengaged from the hubs 550 so the spindles 192 can freely rotate, thereby allowing normal service braking to take place. Hydraulic pressure supplied to the passages 80, 82 urges the pistons 402 to come into contact with pad 37; as the pistons move, the corresponding spindles 192 rotate in response.

The clutch unit 500 is disengaged from the spindles 192/hubs 550 when the pistons 402 are under hydraulic pressure and, thus, the pistons are allowed to move axially in the direction D independent from one another when the clutch unit is unactuated. As a result, the pistons 402 can move different distances in the direction D to account for wear on the brake pad 37.

When it is desirable to apply and maintain a parking brake on the wheel rotor 38 without hydraulic assistance, an ECU 601 (see FIG. 14) directs electrical power of polarity A to be applied to the motor assembly 600. This causes the solenoid brake therein to unlock so the gears, including the driven gears 580, rotate in the direction R₆. As the driven gears 580 move in the apply direction R₆, the clutch unit 500 engages the hubs 550, thereby rotating the spindles 192 and thereafter causing the roller bearings 440 to roll “up” the ramps 436, 471 to clamp the rotor 38. When the ECU 601 detects sufficient current draw from the motor assembly 600, the ECU shuts off power to the motor assembly 600 which causes the solenoid brake therein to automatically lock, which locks the motor and gear train assembly connected thereto to prevent rotation of the spindles 192.

When it is desirable to release the parking brake, thereby allowing wheel rotor 38 to be able to rotate without frictional drag, electrical power of polarity opposite A is applied to motor assembly 600 causing the driven gears 580 to rotate in an opposite direction of direction R₆. This reduces the clamp force up to zero and with continued electrical power the clutch unit 500 disengages the hubs 550. Electrical power is then turned off, which causes the solenoid brake to automatically lock. Thereafter, the spindles 192 may rotate freely so service brake events can take place normally.

It will be appreciated that although the caliper assemblies 60, 390 are shown and described as dual piston assemblies one a single side of the rotor, each respective caliper assembly can alternatively be configured as a single piston assembly. In such constructions, the clutch unit 240, 500 would be modified accordingly, e.g., reducing the number of hubs, wedge rings, driven gears, etc.

Moreover, one or more pistons can be provided on the inboard side of the rotor (as shown in FIGS. 5 and 15), the outboard side of the rotor, or both sides of the rotor. A caliper assembly can be associated with any number of these pistons. For example, caliper assemblies can be provided on both sides of the rotor 38 of FIG. 5 and secured to one another such that the piston(s) on opposite sides of the rotor oppose one another. That said, one or more pistons can be provided on one or both sides of the rotor and operate with an associated clutch unit as previously discussed.

With this in mind, FIGS. 23A-25 illustrate another example caliper assembly 650 configured as a single piston assembly. Components in the caliper assembly 650 that are similarly or identically constructed to components in the caliper assembly 390 are given the same reference number. Components in the assembly 650 that are different than their corresponding component in the assembly 390 are given the suffix “a”.

In the construction of FIGS. 23A-25, the components of the clutch unit 500a are provided within the housing 70 and a gear unit 502 connects the clutch unit to the motor assembly 600. Referring to FIG. 23B, the spindle 192a extends from the first end 196a to the second end 198a. The first end 196a, however, does not extend out of the passage 80 in the housing 70, but instead terminates therein. Consequently, an adapter 660 extends over the first end 196a and selectively couples the spindle 192a to a gear (not shown) of the gear unit 500a.

More specifically, the adapter 660 extends along the centerline 194a from a first end 662 to a second end 664. The adapter includes a base 670 and a projection 672 extending from the base to the first end 662. The projection 672 extends out of the housing 70 and is received by the gear (not shown) of the gear unit 502. The base 670 extends to the second end 664 and includes a pocket or recess 674 for receiving the first end 196a of the spindle 192a.

Both the rollers 540 and the gear 580a as positioned around the first end 196a of the spindle 192a (FIG. 23C). In particular, the rollers 540 are positioned radially between the base 670 and the pockets 588 of the gear 580a. The adaptor 660 can be rotated by the motor assembly 600 to selectively move the rollers 540 into and out of engagement with the first surfaces 590 of the pockets 588 to thereby selectively allow (in the former case) and prevent (in the latter case) rotation of the spindle 192a.

With this in mind, the parking brake is thereby applied and released by the motor assembly 600 in the same manner as described above. To this end, the base 670 can include projections or fingers (not shown) for moving the rollers 540 within and relative to the pockets 588 in response to rotation of the adaptor 660 by the motor assembly 600. In any case, when the parking brake is applied, all the clamp force loads experienced by the spindle 192a are transferred to the base 670 which, in turn, transfers the clamp forces loads into the thrust bearing 214 and ultimately into the housing 70.

Additionally, and referring to FIG. 24, the base 462a of the ramp nut 460a includes a stepped recess adjacent the cage 476. The recess includes a first portion 463 for receiving the thrust bearing 478 and a second portion 465 for receiving a resilient member, such as a wireform 467. The wireform 467 is a contoured wire that can extend partially or entirely around the spindle 192a and engages the threads 202a thereof. In one example, the threads 202a of the spindle 192a adjacent the wireform 467 can include surfaces 201, 203 extending at multiple flank angles on the downward side, i.e., in a direction facing towards the second end 198a of the spindle.

Providing multiple downward flank angles is advantageous in that, since the flank surface 201 immediately adjacent the thread 202a root contacts the wireform 467, the wireform deflects when clamp force is generated such that the second flank surface 203 contacts the thread of the ramp nut 460a. That said, the wireform 467 acts to bias the spindle 192a in a direction towards the piston 402 and help to prevent axial movement of the piston 192a and, thus, axial movement of the piston connected thereto, during application of the parking brake.

The caliper assemblies 60, 390, 650 shown and described herein can be used in different configurations within the vehicle 20 depending on several factors, including the type of vehicle in which braking is desired. For example, and referring back to FIG. 1, current, motor-driven EPB systems (not shown) might be used solely with the rear wheels 32 or on at least one front wheel 30. In accordance with the present invention, any of the caliper assemblies 60, 390, 650 can be provided for all four wheels 30, 32 in the case of light duty vehicles. Alternatively, any of the caliper assemblies 60, 390, 650 can be provided on the front wheels 30 to supplement motor-driven EPB systems provided on the rear wheels 32 in the case of medium duty or heavy duty vehicles.

In the present example, the motor-less caliper assembly 60 is shown on all four wheels 30, 32. With this in mind, the braking system 10 of the present invention can rely on sensed vehicle conditions to determine when service brake and/or parking brake actuation is desired. To this end, the control system 44 continuously monitors signals received from the sensors 48, 50, 52, 54 and controls the service brake and/or parking brake accordingly. More specifically, the control system 44 can rely on a series of sequential steps illustrated in FIG. 26.

In FIG. 26, the integrated brake control (IBC) system of the vehicle 20 is operational/available. The control system 44 continuously scans for parking brake related events. With this in mind, at step 700, the control system 44 determines that a parking brake apply event is detected. At step 702 the control system 44 checks whether the vehicle speed is below a predetermined threshold value, e.g., less than about 5 km/h. To this end, the control system 44 evaluates the signals received from the vehicle speed sensor 50.

If the vehicle speed is below the threshold value, at step 704, the control system 44 determines whether the vehicle 20 is stationary based on the vehicle speed sensor 50. If “no”, at step 706 the control system 44 evaluates the signals from the road grade sensor 52 and applies the service brake accordingly until the control system 44 determines the vehicle 20 is stationary.

On the other hand, if the detected vehicle speed is not below the threshold value at step 702, at step 708 the control system 44 alerts the vehicle 20 driver, e.g., informs the driver via the alert 56 that services brakes will be applied, and automatically applies the service brake. In one example, the control system 44 applies hydraulic pressure to the caliper assemblies to decelerate the vehicle 20 at 0.3 g (or current OEM requirement) or, if the brake pedal is applied by the driver, at a deceleration corresponding to the brake pedal position from the sensor 48. In any case, the service brake is applied and the control system 44 checks whether the vehicle is stationary at step 710 until the inquiry is answered in the affirmative.

That said, once the vehicle 20 is stationary, at step 720 the control system 44 increases the hydraulic pressure at the caliper assemblies based on the both the road grade as well as the expected clamp drop-off. By “expected clamp drop-off”, it is to be understood to mean the amount of clamping force expected to be lost in the transition between service braking and applying the parking brake. At step 722, the control system 44 actuates the clutch unit(s) to the second condition, thereby applying and maintaining the parking brakes. The program ends at step 724.

When a parking brake release event is detected at step 730, the control system 44 increases the hydraulic service brake pressure to, for example, 10% greater than the last-applied service brake hydraulic pressure. At step 734, the control system 44 actuates the clutch unit(s) to the first condition, thereby releasing the parking brakes. At step 736, the program ends. It will be appreciated that the parking brake release event could be, for example, sensing that the accelerator pedal is depressed greater than about 5% of its maximum stroke, i.e., a drive-away release (DAR).

In another example flow chart illustration in FIG. 27, the IBC system of the vehicle 20 is inoperable/unavailable. With this in mind, at step 750 the control system 44 detects a parking brake apply event. At step 752, the control system 44 alerts/instructs the operator of the vehicle 20 to apply the brake pedal until the determining the vehicle is stationary at step 754.

Once the vehicle 20 is stationary, at step 756 the control system 44 determines whether the ignition is off based on the ignition sensor 54. If “yes”, at step 758 the control system 44 alerts/instructs the driver to apply a maximum brake pedal force. The driver maintains the maximum brake pedal force until a until the control system 44 actuates the clutch units to the second condition to apply the parking brakes at step 760. The program ends at step 762.

On the other hand, the control system 44 can detect a parking brake release event at step 770. When this occurs, the control system 44 displays a diagnostic trouble code (DTC) to the driver and/or alerts the driver that the IBC is not available. At the same time, the control system 44 disables vehicle movement entirely.

At step 774, the control system 44 actuates the clutch units to the first condition to release the parking brakes. If the parking brake release event is a DAR, the control system 44 releases the hydraulic pressure at step 778 at a first rate based on the accelerator pedal position and in a manner that helps to prevent vehicle rollback. If the parking brake release event is not a DAR, the control system 44 releases the hydraulic pressure at a second rate based on the brake pedal actuation. In both release events scenarios, the program ends at step 784.

FIGS. 28-32B illustrate another example caliper assembly 800 in accordance with the present invention. Components in the caliper assembly 800 that are similarly or identically constructed to components in the caliper assembly 60 are given the same reference number. That said, the specific discussion of those components is reduced or omitted in the interest of brevity.

As shown in FIG. 29A, a locking mechanism 860 is provided for selectively allowing for or preventing rotation of the spindles 810. In one example, the locking mechanism 860 is magnetic, e.g., electromagnetic. The locking mechanism 860 is motor-less and gear-less and is located partially on the atmospheric side of the caliper assembly 800 and partially on the hydraulic side.

Turning to FIG. 29B, the spindle 810 in the caliper assembly 800 includes a head 812 having a polygonal, e.g., hexagonal, shape. A flange 814 connects to the head 812 with a similarly shaped opening and extends radially from the head. Consequently, the head 812 and flange 814 rotate together. It will be appreciated that the flange 814 could alternatively be formed integrally as one piece with the head 812 (not shown). In any case, the flange 814 can be considered part of the spindle 810. The nut 820 (FIG. 29A) has a fast lead connection, e.g., at least 75% efficiency, with the spindle 810 for axially moving the piston 102 towards and away from the brake pad 37. Not sure it's discussed anywhere below, but the unlabeled part that's partially shown in FIG. 29B located under 814 is a sort of a clip that engages a groove in the housing 70. Therefore, during assembly, the flange 814 will be located at the bottom of the bore and trapped between thrust plug 816 and this unlabeled clip.

Referring to FIGS. 30A-30C, the locking mechanism 860 extends generally along an axis 862 and includes a housing 870. A recess 872 extends into a top side (as shown) of the housing 870. A series of openings extends into the other side (the bottom as shown) of the housing 870. In one example, a blind opening 874 extends towards the top of the housing 870 along the axis 862. A pair of openings 876 are positioned diametrically opposed from one another about the axis 862 and also extend towards the top of the housing 870. Both openings 876 extend all the way to the recess 872.

A pair of ramp-shaped projections 880 is provided along the bottom side of the housing 870. As shown, each projection 880 extends generally circumferentially about the axis 862. The ramps defining the projections 880 incline away from one another in the circumferential direction. The projections 880 do not intersect one another and are symmetrically arranged about the blind opening 874. The projections 880 are stops to define the rotation range of the locking arm 910.

An electromagnet 890 is provided in the recess 872 of the housing 870. The electromagnet 890 includes a ferritic core 892 and a coil 894 wrapped around the core. A cap 896 is secured to the housing 872 to enclose the electromagnet 890 within the recess 872. Ferritic pins 900 extend through the openings 876 and into contact with the core 892. Consequently, the pins 900 effectively extend from and contact the core 892 and, thus, can be considered part of the electromagnet 890 and/or part of the overall locking mechanism 860. With that in mind, it will be appreciated that the core 892 could be formed in a substantially U-shaped contour (not shown) such that the pins 900 are integrally formed with the core 892 and therefore contact the core.

Regardless, each pin 900 includes a frustoconical or tapered head 902 exposed at the bottom of the housing 870 (see FIG. 30B). Each pin 900 is sealed to openings 876 to prevent brake fluid leakage— the sealing method is not shown, but a rubber o-ring on each pin 900 is contemplated. Each pin 900 acts to extend the magnetic poles of the electromagnet 890 in a desired direction.

A power source 940 is connected to the coil 894 of the electromagnet 890 for selectively supplying power thereto. The power source 940 can be, for example, the vehicle battery 42 and/or a separate, on-board battery (not shown). In any case, the power source 940 can supply a voltage to the electromagnet 890 having either an electrical polarity A or an opposite electrical polarity B, thereby generating magnetic fields in the electromagnet having magnetic polarity NS or SN. The connector between the coil 894 in the locking mechanism 860 is not shown.

The electromagnet 890 does not generate a magnetic field until/unless electrical current is supplied to the coil 894. Furthermore, the magnetic field polarity can be switched depending on the electrical voltage polarity used to power the electromagnet 890. A controller or control system, e.g., the control system 44, can be responsible for selectively supplying power from the power source 940 to the electromagnet 890 and dictating the polarity A or B of said power.

A lock arm assembly 906 is also connected to the housing 870. The lock arm assembly 906 include a locking arm 910 having a central passage 912 extending along the axis 962. The locking arm 910 has a generally oblong, elliptical, or bi-lobal shape and includes a pair of opposing projections or lobes 911a, 911b. Pockets 914 are formed in one side (the top side as shown) of the locking arm 910 on opposite sides of the central passage 912.

Permanent magnets PM1, PM2 are provided in the pockets 914 and rigidly fixed to the locking arm 910. The permanent magnets PM1, PM2 are fixed to the locking arm 910 with opposite magnetic orientation from one another. In this example, the permanent magnet PM1 has a N/S (above/below) orientation and the permanent magnet PM2 has a S/N (above/below) orientation. The reverse configurations for the permanent magnets PM1, PM2 are contemplated. It will also be appreciated that the locking arm 910 can be provided with only a single permanent magnet, in which case only a single corresponding pin 900 extends from the electromagnet 890 (not shown).

An elongated rod or axle 920 extends along the axis 862 through the central passage 912 and into the blind opening 874 of the housing 870. A cylindrical spacer 922 is provided over the portion of the axle 920 extending out of the locking arm 910 away from the housing 870. A portion of the axle 920 is exposed through the end of the spacer 922.

A washer 930 (illustrated transparently in FIG. 31A for added clarity) is provided between the locking arm 910 and the housing 870. The washer includes a central passage 932 for receiving the axle 920. A pair of pockets or recesses 934 is provided on opposing sides of the central passage 932. The pockets 934 are generally aligned with the pockets 914 in the locking arm 910. The heads 902 of the pins 900 extend through the pockets 934 to the vicinity of the pockets 914 and, thus, extend to the vicinity of the permanent magnets PM1, PM2.

When the caliper assembly 800 is assembled (FIG. 29A), the axle 920 extends into a recess (not shown) in the housing 70. Thrust load plugs 816 are positioned axially between the heads 812 of the spindles 810 and the housing 70. The locking mechanism 860 is positioned between the spindles 810 such that the locking arm 910 is located between and in the same plane as the flanges 814. The locking mechanism 960 extends from outside the hydraulic side of the caliper assembly 800 (the atmospheric side) into the hydraulic side at the terminal end of the axle 920.

The axle 920 supports the locking arm 910, which is rotatable about the axis 862 in both the CW and CCW direction until the lobes 911a, 911b engage the projections 880 on the housing 970. The housing 870 is fixed to the housing 70 and, thus, the housing 870, electromagnet 890, and pins 900 have a fixed position during operation of the vehicle 20.

Referring to FIGS. 31A-31B, the locking mechanism 860 has a first condition/position that allows the flanges 814 and, thus, allows the spindles 810 secured thereto to rotate in the manner indicated at R₇ (and the direction opposite R₇). In the first condition the electromagnet 890 is powered to have an electrical polarity A that is attracted by both permanent magnets PM1, PM2. In particular, a magnetic field having the electrical polarity A is generated in the coil 894, which is imparted to/through the core 892 and ultimately to the pins 900 engaging the core. Since the heads 902 of the pins 900 are in close proximity to the permanent magnets PM1, PM2 the magnetic fields of the pins 900 interact with the respective magnetic fields of the permanent magnets.

The permanent magnets PM1, PM2 are fixed to the locking arm 910 and, thus, repelling the permanent magnets with the pins 900 causes the locking arm to rotate in the manner indicated at R₈ about the axis 862 (CCW as shown) to a position in which the pawls 911a, 911b are spaced from the respective flanges 814. This allows the flanges 814/spindles 810 to rotate freely relative to the respective lobes 911a, 911b. The locking arm 910 rotates in the direction R₈ until the lobes 911a, 911b engage the projections 880 on the housing 870. The projections 880 therefore act as a hard stop to limit clockwise rotation of the lobes 911a, 911b. In this condition, the permanent magnets PM1, PM2 are at least partially aligned with the respective pins 900 (see FIG. 31A). In other words, in this condition the axes of the permanent magnets PM1, PM2 are offset with respect to the axes of the corresponding pins 900. The offset defines the direction of rotation of the lock arm 910 during a parking event.

The locking mechanism 860 can be moved to a second condition/position (FIGS. 32A-32B) that prevents the flanges 814 and spindles 810 secured thereto from rotating. In particular, the electromagnet 890 can be powered to have the electrical polarity B such that the heads 902 of the pins 900 repel the respective permanent magnets PM1, PM2. When this occurs, the locking arm 910 will rotate in the manner indicated at Ry about the axis 862 (CW as shown) to a position in which the lobes 911a. 911b engage the respective flanges 814.

More specifically, the lobes 911a, 911b become wedged or locked between and with the flanges 814 sufficient to prevent rotation of the spindles 810 connected thereto. This, in turn, prevents back-drive of the pistons 102 once hydraulic fluid pressure is removed from the pistons 102. In this condition, the pins 900 are offset a second circumferential distance from the permanent magnets PM1, PM2 that is less than the first circumferential distance. Consequently, the pins 900 and respective permanent magnets PM1, PM2 are offset or misaligned from one another. In other words, in this condition the permanent magnets PM1, PM2 have different circumferential positions from the corresponding pins 900 relative to the axis 862.

It will be appreciated that the locking mechanism 860 can instead be configured such that repelling the permanent magnets PM1, PM2 places the locking mechanism in the first condition and attracting the permanent magnets PM1, PM2 places the locking mechanism in the second condition. In each instance, the electrical polarity A, B of the power delivered to the electromagnet 890 causes the electromagnet to interact with the permanent magnets PM1, PM2 to thereby rotate the locking arm 910 either into or out of engagement with the flanges 814 of the spindles 810.

In another configuration (not shown), the locking mechanism 860 is configured to be bi-stable. To this end, the locking mechanism 860 in such a design would include the first pair of permanent magnets PM1, PM2 (shown in FIG. 32A) as well as a second pair of permanent magnets (designated PM3, PM4 for clarity). The second pair of permanent magnets PM3, PM4 would be provided on the locking arm 910 circumferentially offset around axis 862 from the first pair of permanent magnets PM1, PM2 and have the same polarity orientation. The order of polarity for permanent magnets PM1, PM3, PM2 and PM4 would be, for example, NS, SN, SN, NS respectively. That said, the locking arm 910 operates in the same manner to rotate and selectively engage (FIG. 31B) or disengage (FIG. 32B) the flanges 814. In this bi-stable design, however, the pins 900 are always at least partially aligned with or in closer proximity of one of the pairs of permanent magnets PM1, PM2 or PM3, PM4.

In particular, the pins 900 are partially aligned with the permanent magnets PM1. PM2 when the electromagnet 890 is powered to have the electrical polarity A. The pins 900 are partially aligned with the permanent magnets PM3, PM4 when the electromagnet is powered to have the electrical polarity B. Since both pairs of permanent magnets PM1, PM2 and PM3, PM4 have the same polarity, it will be appreciated that the strength of the electrical polarity A or B provided to the electromagnet 890 is sufficient to rotate the locking arm 910 in the desired manner.

With that in mind, once power is removed from the electromagnet the locking arm 910 remains in the same rotational position as it was before power was removed. Consequently, the locking arm 910 is actively held in either the first position (FIG. 31B) by the pins 910/permanent magnets PM1, PM2 or actively held in the second position (FIG. 32B) by the pins 910/permanent magnets PM3, PM4 regardless of whether the electromagnet 890 is powered due to the closer proximity of each permanent magnet pair to the pins 900. This configuration allows the locking mechanism 860 to be stable in both rotational positions of the locking arm 910, i.e., bi-stable, even if there is a malfunction of the electromagnet 890. The locking arm 910 will simply be held in place by being magnetically attracted to the pair of permanent magnets PM1, PM2 or PM3, PM4 circumferentially closer thereto. Conversely, the locking mechanism 860 shown in FIGS. 31A-32B is mono-stable because the locking arm 910 is only actively attracted to/held by the permanent magnets PM1, PM2 when in the first position.

Regardless, the locking mechanism 860 operates in cooperation with the service brake in the same manner as the clutch unit 240 described above. That said, when the pistons 102 are fully retracted into the passages 80, 82 and the electrical polarity A is delivered to the electromagnet 890, the locking arm 910 is disengaged from the flanges 814 to allow the spindles 810 to rotate freely. Consequently, normal service braking can take place. To this end, hydraulic pressure supplied to the passages 80, 82 urges the pistons 102 to come into contact with pad 37. As the pistons 102 move, the corresponding spindles 810 rotate about their respective axes 194. The locking arm 910 with PM1, PM2 are inertially stable and thus are inert to vibrations generated while driving the vehicle.

The locking arm 910 is disengaged from the flanges 814 when the pistons 102 are under hydraulic pressure and, thus, the pistons are allowed to move axially in the direction D (see FIG. 29A) independent from one another when the locking mechanism 860 is in the first condition. As a result, the pistons 102 can move different distances in the direction D to account for wear on the brake pad 37.

When it is desirable to apply and maintain a parking brake on the wheel rotor 38 without hydraulic assistance, the control system/controller directs power having electrical polarity B to the electromagnet 890. This causes the locking arm 910 to rotate in the direction R₉ to the second condition (FIG. 32B) engaging the flanges 814 and thereby locking the spindles 810 against rotation to prevent back-drive thereof.

When it is desirable to release the parking brake, thereby allowing wheel rotor 38 to be able to rotate without frictional drag, power of electrical polarity A is re-applied to the electromagnet 890 causing the locking arm 910 to rotate in the direction R₈ until the lobes 911a, 911b are disengaged from the flanges 814 (FIG. 31B). Thereafter, the spindles 810 may rotate freely so service brake events can take place normally.

By using a magnetic-driven locking mechanism 860 in lieu of a mechanical one, the present invention advantageously alleviates the need to have a locking mechanism shaft extending from the atmospheric side of the caliper assembly 800 to the pressure side. Instead, the magnetic fields generated by the electromagnet 890 and permanent magnet PM1, PM2 passes between the atmospheric side and the hydraulic side. With this in mind, the magnetic field is capable of passing through a seal, e.g., part of the housing or an additional membrane, sealing off the atmospheric side from the hydraulic side. Consequently, the locking mechanism 860 and hydraulic service braking operate wholly independent from one another and, thus, the torque needed to rotate the locking arm 910 is independent from any fluid pressure already present in the caliper assembly 800 at the time the parking brake is applied. Using a magnetic field instead of a shaft to operate the locking mechanism 860 advantageously facilitates rotating the fast lead spindles 192 at pressure and rotating the locking arm 910 independent of the applied hydraulic pressure.

It will be appreciated that although the locking mechanism 860 is shown and described for use with a caliper assembly 800 having two pistons 102 (and therefore two associated spindles 810), the locking mechanism 860 can also be adapted to function in a similar manner with a caliper assembly having a single piston and spindle. In such a configuration, the locking arm 910 would rotate between a first position/condition engaging the flange 814 on the lone spindle 812 as well as a projection, surface, feature of or provided on the housing 70 and a second position/condition spaced from the flange 814 and said projection, surface, feature, etc.

In other words, the projection, surface, feature, etc. would be formed to interface with (or mate with) the flange 814 normally present in the two piston 102 construction in order to allow the locking arm 810 to become wedged or locked in a similar manner in the single piston construction. The configuration of the locking mechanism 860 would otherwise be the same in either the single or dual piston 102 construction and the locking mechanism could be mono-stable or bi-stable in either construction. Regardless of the configuration, the magnetic field generated by the electromagnet 890 causes the locking arm 910 to rotate to either prevent or allow rotation of the spindle(s) 812.

It will also be appreciated that although the caliper assembly 800 is shown and described as a dual piston assembly on a single side of the rotor, the caliper assembly can alternatively be configured as a single piston assembly. In such constructions, the locking mechanism 860 would be modified accordingly, e.g., reducing the number of hubs, wedge rings, driven gears, etc.

The caliper assemblies of the present invention are advantageous for several reasons. First, utilizing an electromagnet to actuate the parking brake advantageously reduces the size of the locking mechanism and allows the locking mechanism to operate with reduced power. More specifically, the current/power draw for the electromagnet can be fulfilled with a small, on-board battery as opposed to relying on the vehicle battery. Using a motor-less locking mechanism can also allow for the removal of other traditional caliper assembly components such as parking pawls. The locking mechanism also advantageously operates outside of and independent from the hydraulic fluid pressure in the caliper assembly, thereby making the design simpler and facilitates rotation of not only the locking arm but also between the fast lead connection.

Second, the locking mechanisms described herein allow the caliper assemblies to maintain their clamping force, e.g., up to and exceeding about 90 kN, even when the hydraulic pressure is removed. This provides redundant braking control in the event of hydraulic system failure during parking brake application and/or a service brake mechanical push-through situation. Furthermore, the fast lead connection between the nut and spindle provides rapid clamping apply and release times, e.g., less than about 1.2 s in each direction, less than about 0.8 s in each direction, or less than about 0.3 s in each direction, with minimal resistive load on the piston and/or spindle. The fast lead also enables the locking mechanism to operate with minimal current draw.

Third, the caliper assemblies may also be used on the front wheels of a vehicle because they are very compact in size. Additionally, the motor-less caliper assembly described herein can supplement the total vehicle parking capacity of motor-driven EPB systems. Consequently, the size of the motor-driven EPB systems can be advantageously reduced, with a reduced braking force requirement needed at each vehicle corner. Moreover, the motor-less caliper assemblies can be readily implemented in any hydraulic-based service braking system—including opposed piston constructions—with a simple connection at the inlet opening of the caliper housing.

What have been described above are examples of the present invention. It is, of course, not possible to describe every conceivable combination of components or methodologies for purposes of describing the present invention, but one of ordinary skill in the art will recognize that many further combinations and permutations of the present invention are possible. Accordingly, the present invention is intended to embrace all such alterations, modifications and variations that fall within the spirit and scope of the appended claims.

Claims

1. A parking brake for a wheel rotor having a brake pad associated therewith, comprising: a housing defining first and second passages;first and second pistons provided in the respective first and second passages;spindles threadably connected with each piston; andan electromagnetic locking mechanism provided between the spindles and having a first magnetic polarity for placing the locking mechanism in a first condition allowing relative rotation between the spindles and the pistons such that the pistons are axially movable within the passages and into engagement with the brake pad in response to hydraulic pressure applied to the pistons, the locking mechanism having a second magnetic polarity for placing the locking mechanism in a second condition preventing relative rotation between the spindles and the pistons such that the pistons remain engaged with the brake pad when hydraulic fluid pressure is removed from the pistons.

2. The parking brake of claim 1, wherein the locking mechanism comprises: an electromagnet;a locking arm positioned between the spindles and rotatable relative to the electromagnet; andat least one permanent magnet provided on the locking arm, wherein the electromagnet is configured to have the first magnetic polarity for rotating the locking arm to the first condition and configured to have the second magnetic polarity for rotating the locking arm to the second condition.

3. The parking brake of claim 2, wherein the electromagnet attracts the at least one permanent magnet when having the first magnetic polarity and repels the at least one permanent magnet when having the second magnetic polarity.

4. The parking brake of claim 2, wherein the electromagnet repels the at least one permanent magnet when having the first magnetic polarity and attracts the at least one permanent magnet when having the second magnetic polarity.

5. The parking brake of claim 2, wherein the locking arm includes opposing lobes spaced from the spindles when the locking mechanism is in the first condition and engaging the spindles when the locking mechanism is in the second condition.

6. The parking brake of claim 2, wherein the at least one permanent magnet comprises a pair of permanent magnets diametrically opposed from one another about a rotation axis of the locking arm.

7. The parking brake of claim 2, wherein the locking arm is rotatable in a first direction to place the locking mechanism in the first condition and rotatable in a second direction opposite the first direction to place the locking mechanism in the second condition.

8. The parking brake of claim 7, wherein the locking mechanism includes at least one hard stop for limiting rotation of the locking arm in at least one of the first direction and the second direction.

9. The parking brake of claim 2, wherein the locking mechanism further includes at least one pin in contact with the electromagnet to extend a magnetic pole thereof for cooperating with the at least one permanent magnet to place the locking mechanism in the first condition or the second condition.

10. The parking brake of claim 2, wherein the at least one permanent magnet comprises a pair of permanent magnets and the locking mechanism further includes a pair of pins in contact with the electromagnet to extend magnetic poles thereof for cooperating with the respective permanent magnets to place the locking mechanism in the first condition or the second condition.

11. The parking brake of claim 10, wherein the permanent magnets and the pins are at least partially aligned with one another when the locking mechanism is in the first condition and offset from one another when the locking mechanism is in the second condition.

12. The parking brake of claim 10, wherein the permanent magnets and the pins are offset from one another when the locking mechanism is in the first condition and at least partially aligned with one another when the locking mechanism is in the second condition.

13. The parking brake of claim 1, wherein the locking mechanism comprises: an electromagnet;a locking arm positioned between the spindles and rotatable relative to the electromagnet; andtwo pairs of permanent magnets provided on the locking arm, wherein the electromagnet is configured to have the first magnetic polarity for rotating the locking arm to the first condition and at least partially aligned with the first pair of permanent magnets and configured to have the second magnetic polarity for rotating the locking arm to the second condition and at least partially aligned with the second pair of permanent magnets.

14. The parking brake of claim 1, wherein the spindles have a fast lead threaded connection with each piston.

15. The parking brake of claim 1, wherein the locking mechanism is motor-less.

16. The parking brake of claim 1, wherein the locking mechanism and the housing cooperate to define a hydraulic side of the parking brake and an atmospheric side, and wherein the locking mechanism generates a magnetic field that passes between the atmospheric and hydraulic sides for controlling the positions of the pistons relative to the brake pad.

17. A parking brake for a wheel rotor having a brake pad associated therewith, comprising: a housing defining first and second passages;first and second pistons provided in the respective first and second passages;spindles threadably connected with each piston; anda motor-less, electromagnetic locking mechanism provided between the spindles and comprising: an electromagnet;a locking arm positioned between the spindles and rotatable relative to the electromagnet; anda pair of permanent magnets provided on the locking arm, wherein the electromagnet has a first magnetic polarity repelling the permanent magnets for rotating the locking arm to a first condition allowing relative rotation between the spindles and the pistons such that the pistons are axially movable within the passages and into engagement with the brake pad in response to hydraulic pressure applied to the pistons, the electromagnet having a second magnetic polarity attracting the permanent magnets for rotating the locking arm to a second condition preventing relative rotation between the spindles and the pistons such that the pistons remain engaged with the brake pad when hydraulic fluid pressure is removed from the pistons.

18. The parking brake of claim 17, wherein the locking arm includes opposing lobes spaced from the spindles when the locking mechanism is in the first condition and engaging the spindles when the locking mechanism is in the second condition.

19. The parking brake of claim 17, wherein the permanent magnets are diametrically opposed from one another about a rotation axis of the locking arm.

20. The parking brake of claim 17, wherein the locking arm is rotatable in a first direction to place the locking mechanism in the first condition and rotatable in a second direction opposite the first direction to place the locking mechanism in the second condition.

21. The parking brake of claim 20, wherein the locking mechanism includes at least one hard stop for limiting rotation of the locking arm in the first direction.

22. The parking brake of claim 17, wherein a pair of pins contact the electromagnet to extend magnetic poles thereof, and wherein the permanent magnets and the pins are at least partially aligned with one another when the locking mechanism is in the first condition and offset from one another when the locking mechanism is in the second condition.

23. The parking brake of claim 17, wherein a pair of pins contact the electromagnet to extend magnetic poles thereof, and wherein the permanent magnets and the pins are offset from one another when the locking mechanism is in the first condition and at least partially aligned with one another when the locking mechanism is in the second condition.

24. The parking brake of claim 17, wherein the locking mechanism and the housing cooperate to define a hydraulic side of the parking brake and an atmospheric side, and wherein the locking mechanism generates a magnetic field that passes between the atmospheric and hydraulic sides for controlling the positions of the pistons relative to the brake pad.

25. A parking brake for a wheel rotor having a brake pad associated therewith, comprising: a housing defining a passage;a piston provided in the passage;a spindle threadably connected with the piston; and