Rotary tensioner

Abstract

A tensioner comprising a base having a base aperture, the base aperture having an axis A-A and capable of receiving a driven component, a rotary arm rotatably engaged with the base and encircling the base aperture, a swing arm pivotally engaged with the rotary arm, a first torsion spring biasing the swing arm, a first pulley journalled to the swing arm, a rotary ring rotatably encircling the base aperture and disposed between the rotary arm and the base, a second pulley journalled to the rotary ring, a second torsion spring engaged between the rotary ring and the rotary arm for biasing the rotary ring, and a wave spring in pressing engagement between the base and the rotary ring.

Claims

1. A tensioner comprising: a base having a base aperture, the base aperture having an axis A-A and capable of receiving a driven component; a rotary arm rotatably engaged with the base and encircling the base aperture; a swing arm pivotally engaged with the rotary arm and having a pivot axis B-B, a first torsion spring biasing the swing arm, a first pulley journalled to the swing arm; a rotary ring rotatably encircling the base aperture and disposed between the rotary arm and the base, a second pulley journalled to the rotary ring; a second torsion spring engaged between the rotary ring and the rotary arm for biasing the rotary ring; and a wave spring in pressing engagement between the base and the rotary ring.

2. The tensioner as in claim 1, wherein the rotary arm and the rotary ring coaxially rotate about the axis A-A.

3. The tensioner as in claim 1, wherein the driven component rotates on the axis A-A.

4. The tensioner as in claim 1, wherein the first torsion spring is loaded in an unwinding direction to bias the swing arm towards the second pulley.

5. The tensioner as in claim 1, wherein the second torsion spring is loaded in an unwinding direction to bias the second pulley towards the first pulley.

6. The tensioner as in claim 1 further comprising a damping member in frictional engagement with the rotary arm and the rotary ring.

7. The tensioner as in claim 1, wherein the base is fixedly attachable to a driven component.

8. The tensioner as in claim 1, wherein the pivot axis B-B of the swing arm is disposed radially from the axis A-A.

9. The tensioner as in claim 1, wherein the pivot axis B-B is disposed outside of the base aperture.

10. The tensioner as in claim 1, wherein the rotary arm is retained by a retaining member attached to the base.

11. The tensioner as in claim 1, wherein the first torsion spring is loaded in a winding direction to bias the swing arm towards the second pulley.

12. The tensioner as in claim 1, wherein the second torsion spring is loaded in a winding direction to bias the second pulley towards the first pulley.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The accompanying drawings, which are incorporated in and form a part of the specification, illustrate preferred embodiments of the present invention, and together with a description, serve to explain the principles of the invention.

(2) FIG. 1 is a top perspective view.

(3) FIG. 2 is a cross sectional view.

(4) FIG. 3 is a cross sectional detail of FIG. 2.

(5) FIG. 4 is an exploded view.

(6) FIG. 5 is a cross section of the swing arm tensioner.

(7) FIG. 6 is a perspective view of the device on a driven machine.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

(8) FIG. 1 is a top perspective view. Rotary tensioner 1000 comprises a base 100, rotary arm 200, rotary ring 400 and a swing arm tensioner 300. Rotary tensioner 1000 has a generally circular form to accommodate installation on a belt driven machine (BDM). Base 100 is used to mount the inventive device to a belt driven machine such as an alternator, starter generator or motor generator unit. Such units are typically used in so-called engine start-stop applications. A driven shaft pulley P of the BDM projects through base aperture 103. Mounting portions 102 receive fasteners such as bolts or screws to attach the tensioner 1000 to the BDM.

(9) Rotary arm 200 is rotatably engaged with base 100. Retaining ring 101 retains rotary arm 200 on base 100. Retaining ring 101 may be press fit or clamped to base 100. Rotary arm 200 is rotatable about base aperture 103 on axis A-A.

(10) Tensioner swing arm 300 is pivotally mounted to rotary arm 200 on an axis B-B. Pulley 301 is journalled to pivot arm 300. Torsion spring 600 biases pivot arm 300 toward pulley 401 and into engagement with a drive belt (not shown), thereby applying a belt load. Torsion spring 600 is loaded in the unwinding direction.

(11) Rotary ring 400 is rotatably engaged between rotary arm 200 and base 100. Rotary ring 400 is rotatable about axis A-A and base aperture 103. Pulley 401 is journalled to rotary ring 400.

(12) Torsion spring 500 is engaged between the rotary arm 200 and rotary ring 400. Torsion spring 500 is loaded in the unwinding direction. Torsion spring 500 causes pulley 401 to resist the force exerted by torsion spring 600 through pulley 301. Torsion spring 500 is enclosed in part within rotary arm 200 and rotary ring 400.

(13) The use of two torsion springs (500, 600) divides the significant rotational requirements and torque requirements of this tensioner in its intended service, thereby ensuring proper performance. The intended service can include use in the accessory belt drive for a start-stop engine configuration.

(14) FIG. 2 is a cross sectional view. A shaft pulley P of the BDM extends through base aperture 103 along axis A-A such that a drive belt B will engage pulley P on a BDM shaft as well as pulley 301 and pulley 401.

(15) Pivot axis B-B of swing arm 300 is disposed radially from and is not coaxial with axis A-A. Pivot axis B-B is disposed outside the base aperture 103.

(16) FIG. 3 is a cross sectional detail of FIG. 2. Damping band 402 and damping band 403 frictionally engage with and damp oscillatory movements of rotary arm 200 and rotary ring 400. Damping band 402 and 403 comprise frictional materials known in the tensioner damping arts. A wave style spring 404 presses the stack comprising damping band 403, rotary ring 400, damping band 402, rotary arm 200 and bushing 201 into contact with retaining ring 101, thereby providing a normal force necessary to generate frictional damping forces. Spring 404 bears upon base 100. Low-friction bushing 201 facilitates relative movement of rotary arm 200 with respect to base 100. Bushing 201 locates rotary arm 200 and rotary ring 400 with respect to base aperture 103.

(17) FIG. 4 is an exploded view. Pulley 301 is fastened to swing arm 300 by a bolt 302. Pulley 401 is fastened to rotary ring 400 by a bolt 406. Dust cover 407 and dust cover 408 prevent debris from entering a pulley bearing. Dust cover 303 prevents debris from entering a pulley bearing.

(18) Two springs are depicted in FIG. 4 wherein the tensioner can be made to operate in either a spring unwinding under load or spring winding under load. In the spring unwinding to load mode, spring 500 and spring 600 is used. Each spring 500 and spring 600 is loaded in a spring unwinding direction. Spring 500 engages rotary ring 400 and rotary arm 200. Spring 600 engages rotary arm 200 and swing arm 300.

(19) In an alternate embodiment spring 500 and 600 can be loaded in a winding direction. In the winding direction embodiment spring 500a and spring 600a each replace spring 500 and spring 600 respectively.

(20) Spring 500a comprises a tab 500b and 500c extending therefrom. Tab 500b engages rotary ring 400 and tab 500c engages rotary arm slot 200c. Spring 600 comprises a tab 600b and 600c extending therefrom. Tab 600b engages rotary arm 200 and tab 600c engages swing arm 300.

(21) In yet another embodiment, an unwinding spring 500 or 600 may be used with a winding spring 500a or 600a. For example, spring 500 with spring 600a, or spring 500a with spring 600 depending on the needs of a user.

(22) FIG. 5 is a cross section of the swing arm tensioner. Swing arm 300 pivots about shaft 304. Shaft 304 is fixed to rotary arm 200. Low-friction bushing 305 facilitates movement of swing arm 300 on shaft 304. Pulley 301 is journalled on a bearing 306 to shaft 304.

(23) FIG. 6 is a perspective view of the device on a driven machine. The driven pulley P of the BDM projects into and through base aperture 103. The BDM is typically mounted to a vehicle engine and is driven by a drive belt B. Belt B engages pulley P, pulley 301 and pulley 401.

(24) Although a form of the invention has been described herein, it will be obvious to those skilled in the art that variations may be made in the construction and relation of parts and method without departing from the spirit and scope of the invention described herein.