Positive Locking Roller Stop Device

Abstract

The present invention relates to a positive locking roller stop device having a rotational mechanism attached to a shaft that allows rotational motion to be transmitted to a work piece, such as a flywheel, in one direction at high rotational speeds but allowing for free-wheeling with minimal friction wheeling of a work piece such as a flywheel with minimal friction when the power source is reduced, preventing the slower shaft speed from reducing the speed of the work piece.

Description

TECHNICAL FIELD

The present invention relates to a device having a rotational mechanism attached to a shaft that allows rotational motion to be transmitted in one direction at high rotational speeds, but allowing for free-wheeling of a work piece such as a flywheel with minimal friction when the power source is reduced, preventing the slower shaft speed from reducing the speed of the work piece.

BACKGROUND OF THE INVENTION

The most common type of apparatus that operates in a similar way is a ratchet with a gear and pawl. A ratchet typically is used to transmit torque in one direction to a work piece but is not practical for high speed applications. In contrast to the conventional ratchet, the present invention allows for the transmission of rotational energy at high rotational speeds while allowing free-wheeling with minimal friction, and without hindering the rotation of a work piece such as a flywheel when the energy supplied to the shaft decreases. As energy is supplied to the shaft and the rotational speed increases the roller stop is engaged to add rotation to the work piece. As the energy supplied to the shaft decreases, the positive locking roller stop allows the work piece to continue to rotate unhindered until additional energy again is supplied to the shaft by the power source and the rotational speed of the shaft increases again.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a lateral view of the positive locking roller stop device of the present invention showing an embodiment of the present invention with a shaft 8 through the center of disks 1 and 5 with the spring arm/rollers 2, which are attached to disk 1, operating on a plane perpendicular to the axis of the shaft 8. Disk 1 is attached to shaft 8 through bearing 3. Fasteners 4 are used for attaching the positive locking roller stop device of the present invention to a work piece, such as a flywheel.

FIG. 2 and FIG. 3 are cross-sectional views of the positive locking roller stop device of the present invention showing disk 1 mounted on a bearing 3 allowing rotation independent of the shaft 8, and disk 5 mounted on the shaft 8 and held in a fixed position by collar 6. FIG. 1 and FIG. 3 also show the inclined notches 7 or inclined ramps 9 which are inscribed into or raised above the surface of disk 5, and engage the spring arm/rollers 2 attached to disk 1.

FIG. 4 a is a detail of the spring arm/roller 2 showing the spring arm 11, spring 12, bracket 13 for attaching the spring arm 11 to the surface of disk 1, roller 14, and pins 15 for attaching the roller 14 to the roller arm 11 and attaching roller arm 11 to bracket 13 attached to disk 1. FIG. 4b is a lateral view of the two positions of the spring arm/roller 2 with respect to the surfaces of disk 1, disk 5 and inclined notch 7 cut in disk 5. FIG. 4c is a lateral view of the two positions of the spring arm/roller 2 with respect to the surfaces of disk 1, disk 5, and inclined ramp 9 positioned above the surface of disk 5, as an alternative to the inclined notch 7 shown in FIG. 4b.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

As shown in the figures, the positive locking roller stop device of the present invention is a very simple device with few moving parts.

The positive locking roller stop device configuration shown in FIG. 1, FIG. 2 and FIG. 3 is comprised of disk 1 and disk 5 of any convenient size and thickness aligned on a shaft 8 with the sufficient space between the two disks to allow the spring arm/rollers 2 room for proper travel. As shown in FIG. 1, disk 5, which includes the inclined notches 7 or inclined ramps 9, is attached to shaft 8 in a fixed position by collar 6, so that shaft 8 and disk 5 rotate together. Disk 1, to which the spring arm/rollers 2 are attached, is attached to bearing 3 and rotates independently of shaft 8 and disk 5, if disk 1's rotation is faster than shaft 8 and disk 5. The orientation of the disks 1 and 5 as being attached to shaft 8 in a fixed position or rotating freely on a bearing may be reversed. Fasteners 4 in disk 1 provide a means of attaching a work piece such as a flywheel.

The size, configuration and number of spring arm/rollers 2 used can vary. The orientation of the spring arm rollers 2 on disk 1 and the inclined notches 7 or inclined ramps 9 on disk 5 to the axis of shaft 8 also may vary from a plane perpendicular to the axis of shaft 8 as shown in FIG. 1 to a plane parallel to the axis of shaft 8. The spring arm/roller 2 is comprised of the arm 11, spring 12, bracket 13, roller 14 and pins 15 as shown in FIG. 4.

When the rotational speed of shaft 8 and disk 5 is equal to that of disk 1, the inclined notches 7 cut in disk 5 or inclined ramps 9 positioned above the surface of disk 5, engage with the spring arm/rollers 2 attached to disk 1, and the rotational speed of disk 1 remains the same as shaft 8 and disk 5. When the rotational speed of shaft 8 and disk 5 decreases, the spring arm/rollers 2 attached to disk 1 roll freely over disk 5 unaffected by the slowing of shaft 8 and disk 5.

Claims

1. A positive locking roller stop device comprising: a. two parallel disks mounted on a shaft 8, wherein a first disk 1 is mounted on shaft 8 through bearing 3 allowing rotation of the first disk 1 independent of the rotation of shaft 8; and wherein first disk 1 also has a plurality of spring arm/rollers 2 attached to the surface of disk 1 facing second disk 5; andsecond disk 5 also is mounted on shaft 8 and is held in a fixed position by collar 6; and wherein second disk 5 has a plurality of inclined notches 7 cut in the surface facing the first disk 1, or inclined ramps 9 positioned above the surface of second disk 5 facing the first disk 1; and there being sufficient space between the first disk 1 and second disk 5 to allow the spring arm/rollers 2 mounted on disk 1 sufficient room for proper travel to engage the inclined notches 7 in the surface of the second disk 5, or the inclined ramps 9 positioned above the surface of the second disk 5; andb. a power source connected to the shaft 8 to turn the shaft and provide rotational movement to the shaft 8, and to the parallel disks 1 and 5 mounted on the shaft 8.

2. The device of claim 1 wherein the first disk 1 is connected by fasteners 4 to a work piece such as a flywheel.

3. Means for transmitting rotational energy at high rotational speeds, while allowing free-wheeling with minimal friction and without hindering the rotation of the work piece when the energy supplied to the shaft 8 decreases, comprising: a positive locking roller stop device which is engaged to add rotation to the work piece such as a flywheel as energy is supplied to shaft 8, and which allows rotation of the work piece to continue unhindered until additional energy is again supplied to the shaft 8 by the power source and the rotational speed of the shaft again increases.

4. A method for transmitting rotational energy at high rotational speeds, while allowing free-wheeling with minimal friction and without hindering the rotation of the device when the energy supplied to the shaft 8 decreases; wherein a) two concentric disks are aligned on a shaft 8 with sufficient space between the disks to allow a plurality of spring arm/rollers 2 permanently attached to the first disk 1 to freely travel across the second disk 5 and engage inclined notches 7 cut in the surface of second disk 5, or inclined ramps 9 attached to the surface of the second disk 5 facing the spring arm and rollers 2 on the first disk 1; andb) the second disk 5 is attached to the shaft 8 in a fixed position by collar 6, and the first disk 1 is attached to a bearing 3 and rotates independently of the shaft 8 and the second disk 5 if the rotation of the first disk 1 is faster than that of the shaft 8 and the second disk 5.