BACKGROUND
The present invention is directed to belt conveyor pulleys and in particular to wing-type pulleys. Wing pulleys are known for supporting an endless belt of a conveyor at the feed end of the conveyor, where material such as sand, gravel, or the like is deposited on the conveyor belt. Wing pulleys comprise separate radially spaced plates emanating from a central hub that define separate contact surfaces on the pulley. The contact surfaces of a wing pulley beat the underside of the conveyor belt to remove debris and direct it as well as any other material away from the pulley to prevent wear and/or damage to the conveyor belt. There is a need to improve the effectiveness of a wing pulley in expelling debris from the belt.
SUMMARY
A wing pulley for a belt conveyor having a first end and a second end comprises a pair of spaced cylindrical hubs and a plurality of wings spaced about the hubs. Each wing of the plurality of wings has an upper edge for contacting a conveyor belt and includes a planar first wing portion having an outer end at the first end of the wing pulley. The first wing portion extends at least partway between the first end of the wing pulley and the second end of the wing pulley. A planar second wing portion has an outer end at the second end of the wing pulley. The second wing portion extends at least partway between the second end of the wing pulley and the first end of the wing pulley. Each wing of the plurality of wings is connected to a metal plate. The metal plate is spaced apart from the upper edges of said wings and extends between adjacent wings. The metal plate is at least partially supported by the hubs. The metal plate in combination with said adjacent wings defines a space to receive material below the conveyor belt. The space is unobstructed at the first and second ends of the wing pulley. Rotation of the wing pulley results in material in the space between adjacent wings being directed laterally toward the respective first and second ends of the wing pulley and discharged laterally away from the respective first and second ends of the wing pulley. The first and second wing portions define a non-zero angle therebetween. Each of the first and second wing portions are oriented at an angle C defined by the respective outer ends of the first and second wing portions relative to a respective radial of the hub. Each outer end of the first and second wing portions has a lower edge positioned on the respective radial.
The present invention is directed to a wing pulley for a belt conveyor. The pulley has a length for supporting a conveyor belt along its width. The pulley comprises spaced first and second hubs aligned along a common axis. Each of the first and second hubs has a circumferential surface. Radially spaced about and connected to the circumferential surfaces of the first and second hubs are a plurality of wings. Each wing of the plurality of wings is configured to define a contact surface radially spaced from the first and second hubs for contacting the conveyor belt. The contact surface of a first wing of the plurality of wings is configured to overlap with the contact surface of a second wing of the plurality of wings along the length of the pulley such that the width of the conveyor belt is supported by the first and second wings. A gusset is connected between a first surface of each wing and a second surface of an adjacent wing.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of a first embodiment of a wing pulley of the present invention.
FIG. 2 is a front plan view of a wing plate of the wing pulley of FIG. 1.
FIG. 3 is an end view of a hub and one wing of the wing pulley of FIG. 1.
FIG. 4 is a rear perspective view of the hung and wing of FIG. 3.
FIG. 5 is an end elevational view of the wing pulley of FIG. 1.
FIG. 6 is a diagrammatic perspective view of the wing pulley of FIG. 1 engaging a conveyor belt.
FIG. 7 is a perspective view of a second embodiment of a wing pulley of the present invention.
FIG. 8 is a perspective view of the right end of the wing pulley of FIG. 7.
DETAILED DESCRIPTION
FIG. 1 is a perspective view of a first embodiment of a wing pulley 10 of the present invention. Wing pulley 10 includes a pair of spaced hubs 12 having a common center axis A and a plurality of wings 14 that are generally equally radially spaced about hubs 12 and secured thereto. In one exemplary embodiment, each wing 14 is formed at an angle such that wing 14 includes first and second wing portions 14A and 14B. In one preferred embodiment, wing portions 14A and 14B define an angle B of about 137 degrees. In one embodiment, each wing 14 includes a contact surface 20 defined by a round metal bar secured along an upper edge of wing 14, which engages and supports a conveyor belt. Wing portions 14A, 14B define a wing apex 16 at an approximate midpoint of wing 14 relative to wing ends 18. Relative to the direction of rotation of wing pulley 10, apex 16 is oriented forward of an imaginary line I that extends between ends 18 along the contact surface 20 and is generally parallel with the center axis A of wing pulley 10. Connected between adjacent wings 14 are metal gussets 19, which extend from hubs 12 to apex 16. Gussets 19 are secured to wings 14 and hubs 12 by welding. Hubs 12 have a central opening for receiving a bushing and shaft for rotationally mounting wing pulley 10 at the feed end of a conveyor.
FIG. 2 is a front plan view of a wing plate 22 which forms each wing 14 of wing pulley 10. Wing plate 22 includes a lower edge 24 and an upper edge 26, which extend between opposing ends 18. The lower edge 24 and the upper edge 26 define a height H of wing plate 22. In one embodiment, lower edge 24 is configured with a notch 28 adjacent to ends 18 for connection of wing plate 22 to each hub 12. Upper edge 26 defines the length L of wing plate 22, which is greater than the length of lower edge 24. Upper edge 26 travels in an arc from midpoint M of wing plate 22 to each end 18, such that wing plate 22 has bi-lateral symmetry relative to midpoint M. The radius of curvature of upper edge 26 is selected to define a radius R of wing 14 as measured from axis A (FIG. 1) that is generally the same at all points along the length L of upper edge 26 and contact surface 20 (not shown). The radius of curvature of upper edge 26 will vary according to the particular length and radius selected for wing pulley 10 and may be calculated using any suitable mechanical design software. Wing plate 22 is formed by cutting a plate of steel having a thickness of between about 3/16 inch to about 5/16 inch, such as with a plasma cutter. In one embodiment, wing plate 22 has a length of about 40.50 inches and a midpoint of about 20.25 inches.
FIG. 3 is an end view of hub 12 and one wing 14 representative of the orientation of each wing 14 relative to hub 12. As shown in FIG. 3, in one embodiment, lower edge 24 of wing portion 14A is positioned on a radial B of axis A of hub 12A at end 18 of wing 14. Wing portion 14B is similarly positioned relative to the opposite hub. Each wing 14 is set at an angle C such that each wing portion 14A, 14B lies in a plane that is between about 0 degrees and 30 degrees forward of radial B in the direction of intended rotation of wing pulley 10, as indicated by arrow D. In one preferred embodiment, each wing portion 14A, 14B is set at an angle of about 30 degrees relative to radial B. As further shown in FIG. 3, attached to upper edge 26 of wing plate 22 is a metal contact bar 30, which in the embodiment shown has a generally circular cross section. In one exemplary embodiment, contact bar 30 has a diameter of about 0.984 inches. Other shapes and dimensions of contact bar 30 may be employed with the present invention.
FIG. 4 is a rear perspective view of the hub and wing shown in FIG. 3. As shown in FIG. 4, each hub 12A, 12B is provided with a stepped circumferential outer surface 32, with the inward facing portions of hubs 12A, 12B having a slightly smaller outer diameter than the adjacent outward facing portion of hubs 12A, 12B. The notch 28 of each wing portion 14A, 14B includes a lower edge which lies at an angle relative to lower edge 24 of wing plate 22. The angle of the lower edge of notch 28 is selected to maximize the lower edge contact of wing plate 22 with the outer surface 32 of hubs 12A, 12B. Wing plate 22 is connected to hubs 12A, 12B by welding along the lower edge of notch 28 on opposite sides of wing plate 22.
Adjacent wings 14 are connected together via gussets 19, which are shown in phantom in FIG. 4. Each gusset 19 is comprised of two elongated metal plates 19A, 19B that extend from hubs 12 to apex 16 and is configured to contact the facing surfaces of adjacent wing plates. Each end 34 of gusset plates 19A, 19B are secured to the hub outer surface 32 by welding. Plates 19A, 19B are secured to one wing plate 22 along edge 36 by welding, while the adjacent wing plate (not shown) is secured to edge 38 by welding. Plates 19A and 19B are also welded together at the interface of the two plates at the apex 16. Plates 19A, 19B extend from the lower edge of notch 28 and hubs 12 at an angle toward the upper edge 26 of wing plate 22, which results in each gusset 19 having a radius at the apex 16 of wing 14 relative to hub axes A that is greater than the radius of ends 34 of gusset 19. Gussets 19 thus slope away from the midpoint of wings 14 to the hubs 12, which aids in the ability of wing pulley 10 to direct debris in a direction towards hubs 12.
FIG. 5 is an end view of wing pulley 10 of FIG. 1. As shown in FIG. 5, in one embodiment, wing pulley 10 is comprised of ten generally equally radially spaced wings 14, each of which is mounted to hubs 12 in the manner previously described. Collectively, the metal contact bars 30 define a generally cylindrical contact surface of wing pulley 10 for supporting a conveyor belt. As shown in FIG. 5, the contact bar 30 of each wing 14 substantially overlaps the contact bar 30 of an adjacent wing 14. As a result, a conveyor belt is able to be substantially supported along the length of wing pulley 10 by at least two wings 14. The overlap of contact bars 30 of adjacent wings 14 provides a smooth transition for belt contact from one contact bar to the next adjacent contact bar, which minimizes the amount of vibration transmitted to the conveyor belt and decreases the rate of wear on the belt.
FIG. 6 is a diagrammatic perspective view of wing pulley 10 shown engaging a conveyor belt 40 at the feed end of a conveyor. The upper belt surface 42 is shown traveling away from wing pulley 10, while the lower belt surface 44 is shown traveling toward wing pulley 10, with wing pulley 10 rotating counterclockwise. Material deposited on the upper belt surface 42 invariably results in some material migrating to the lower belt surface 44 facing wing pulley 10. Material 46 that falls on the lower belt surface 44 is carried to wing pulley 10 until it engages wings 14. The angular shape of wings 14 relative to apex 16 and the rotation of wing pulley 10 result in the material 46 being quickly and efficiently directed laterally toward ends 18 of wings 14 and away from wing pulley 10. The V-shaped configuration of wings 14 further aid in keeping belt 40 centered on wing pulley 10.
FIG. 7 is a front perspective view of a second embodiment of the present invention. FIG. 7 shows a wing pulley 50 having eight generally equally radially spaced wings 52, each of which is formed in a V-shape substantially as described relative to wings 14 of the first embodiment (FIG. 1). Each wing 52 is secured to hubs 54 by welding in the manner previously described. Also adjacent wings 52 are connected to gussets 56 by welding in the manner previously described. Wing pulley 50 differs from wing pulley 10 in that contact bars 58 are formed from metal bars 58A, 58B having a rectangular cross-sectional shape. Metal bars 58A, 58B have mitered ends that abut one another and are welded together to conform to the angle of wings 52. As a result of wing pulley 50 having eight wings, there is less overlap between the contact bars 58 of adjacent wings 52, yet wings 52 provide sufficient belt support. As shown in FIG. 8, which is an end perspective view of one wing 52 mounted to hubs 54, each wing 52 is oriented on a radial R′ in a plane that is substantially parallel to radial R′. Unlike wings 14 of wing pulley 10, the lower edge 56 of wings 52 of wing pulley 50 lack a notch at the ends 58 of wings 52.
The V-shaped wing configuration of the wing pulley of the present invention deflects material away from the wing pulley and conveyor belt more efficiently and effectively than standard wing pulleys. As a result, material is less apt to get wedged between adjacent wings and the conveyor belt and belt damage is minimized. The V-shaped wing configuration also results in wing overlap along the length of the wing pulley to permit a conveyor belt to be supported by multiple wings along the belt width and ease the transition of belt contact from one wing to the next. This in turn minimizes vibration to the belt, extends belt life and reduces the amount of noise generated from the wings contacting the belt.
Although specific embodiments have been illustrated and described herein, it will be appreciated by those of ordinary skill in the art that a variety of alternate and/or equivalent implementations may be substituted for the specific embodiments shown and described without departing from the scope of the present invention. This application is intended to cover any adaptations or variations of the specific embodiments discussed herein. Therefore, it is intended that this invention be limited only by the claims and the equivalents thereof.