Reels, or spools, of wire, cable and other material are widely used as an input to manufacturing and further processing of the cable and other materials. Reels provide a convenient method of storing the material, and, when in a vertical position, can be rolled as necessary to aid positioning of the reel on the flanged edges of the reel.
Historically, reel platforms have been used to horizontally stack one or more spools of material. The platforms rotate as material is unspooled and may be powered to assist in spinning the spools. Spools are added to the platform using forklifts, hoists or other lifting mechanisms. More recently, vertical spool unreeling devices have come into use. When it is desired to remove material from the reel, the reel is often lifted and placed on raised rollers to allow the reel to rotate freely on the flanged edges of the reel, thus allowing the material on the reel to be unwound from the reel and processed as desired.
Placing the reel on the rollers can be difficult given the size and weight of the reels, especially when loaded with material. This is especially true since the vertically-oriented reel cannot be rolled into position on the rollers since they are raised above the floor.
In the past manual labor has often been used to lift the reel onto the rollers by brute force. Clearly this is dangerous to the workers lifting the reel and prone to accidents, lack of optimal positioning and other difficulties. This process also requires multiple workers to lift the reel into place.
The lever lift assembly provides a device and process for lifting a reel onto raised rollers without the problems of the manual process described above. The lever lift assembly allows a single worker to roll the reel into position and raise the reel off the ground onto the rollers for easy rotation without assistance.
The lever lift assembly is safe, secure and positions the reel correctly on the rollers for dispensing the material from the reel, thus addressing the problems associated with the current method of raising loaded reels onto the rollers.
Referring now to
In the embodiment shown in the figures, a plurality of guide flanges 108 are attached to the base assembly 102 at various points for guiding the other members of the lever lift assembly 100 during use. Guide flanges 108 may be bolted to the base assembly 102, or formed as an integral part of base assembly 102 or base members 104 or 106. In some embodiments of the invention they may extend along a greater portion or the entire length of the base assembly 102.
In the embodiment of the base assembly 102 shown in
Optionally, the base assembly 102 further comprises a vertical element for holding the lifter assembly described hereafter and for guiding the cable or other material to be unspooled from the vertical reel. In a preferred embodiment of the lever lift assembly 100, the optional vertical element is formed from a first vertical member 112, a second vertical member 114 and a vertical cross member 116. The first vertical member 112 and the second vertical member 114 are attached to the base assembly 102 at the first end of the base members and the first end of the vertical members, and attached to each other by the vertical cross member 116 at a point between the second end of the vertical members 112 and 114 and their midpoint. This configuration of the option vertical element is not intended to be limiting of the lever lift assembly and the vertical element could also be formed in a variety of other configurations to provide support to the lifter assembly 144 and to support the feeding of cable from the vertical reel 200 when in use, as further described below.
Drive shaft assembly 118 is also attached to base assembly 102 to turn the vertical reel on its axis during use thus feeding cable from the reel to other equipment for processing. The drive shaft assembly 118 in an embodiment of the present invention comprises a base plate 120, a drive motor 122, a gear box 124, a drive shaft 126, two bearings 128, and two flanged drive wheels 130. Drive shaft assembly 118 is located along base members 104 and 106 at a position that allows a spool or vertical reel of material to be rolled between base members 104 and 106 and placed in contact with the flanged drive wheels 130.
In the embodiment shown in the figures, the drive motor 122 and gear box 124 are mounted on base plate 120. In some embodiments, base plate 120 may be an integral part of base assembly 102 or may be formed from structural members instead of sheet material. Drive shaft 126 is connected to gear box 124 so that actuation of drive motor 122 will cause the rotation of drive shaft 126. In some embodiments, drive motor 122 may directly drive the drive shaft 126 without any gear box 124.
Drive shaft 126 is supported by two bearings 128 which support the weight of the drive shaft 126, and also the weight of the vertical reel, when the assembly is in use, while still allowing the drive shaft 126 to rotate as driven by the drive motor 122. The bearings 128 are mounted on the base assembly 102 to mounting brackets affixed to the base assembly 102. In the embodiment shown in
Two flanged drive wheels 130 are mounted on drive shaft 126. The flanged drive wheels are positioned on the drive shaft 126 so that they can accept the vertically-positioned reel of cable between the flanges of the drive wheels 130. Each flanged drive wheel 130 comprises a drum and the raised flange around the outer edge of the wheel 130.
The lever lift assembly 100 further comprises a lever assembly 132. The embodiment of the lever assembly 132 shown in
The first and second lever members 134 and 136, respectively, are attached at a second end of each member to the lever cross member 138. Lever cross member 138 maintains the appropriate separation between the first and second lever members 134 and 136, and provides a place for the user of the lever lift assembly 100 to apply pressure to the lever assembly 132 during use of the device.
The second lever shaft 142 is attached at each end to the first and second lever members 134 and 136, respectively, at lifter pivot points 146 located along length of the members 134 and 136. The lifter pivot points may be located at any point along the length of members 134 and 136, however, the lifter pivot points 146 are generally located between the midpoint and the second end of the members 134 and 136. The second lever shaft 142 may be reconfigured to different lifter pivot points 146 as necessary to accommodate varying sizes of reels.
The lever lift assembly 100 further comprises a lifter assembly 148. In one embodiment, the lifter assembly 148 comprises a first lifter member 150 and a second lifter member 152. The first lifter member 150 and second lifter member 152 are pivotally attached at a first end of each member to the second lever shaft 142, and thereby pivotally attached to the first and second lever members 134 and 136 at lifter pivot points 146.
The lever lift assembly 100 may be reconfigured to accommodate various sizes or diameters of vertical reels by relocating the second lever shaft 142 to the various lever pivot points 146 located on the first and second lever members 134 and 136. Reels with shorter diameters may be accommodated by moving the second lever shaft 142 and the lifter members 150 and 152 to a lifter pivot point 146 located closer to the second end of lever members 134 and 136. Similarly, reels with a longer diameter may be accommodated by moving the second lever shaft 142 and the lifter members 150 and 152 to a lifter pivot point 146 located closer to the first end of lever members 134 and 136.
The first and second lifter members 150 and 152, respectively, are attached a second end of each member to lifter shaft 154. Lifter shaft 154 maintains the appropriate separation between the first and second lifter members 150 and 152, and supports flanged wheels 156. Bearings 158 allow flanged wheels 156 to rotate freely around the lifter shaft 154.
Referring now to
In preparation for unrolling the material from the reel 200, the reel 200 is rolled in between the second ends of base members 104 and 106 until spool flanges 202 come in contact with the flanged drive wheels 130. When properly contacted, the edges of flanges 202 are in contact with the drum of the flanged drive wheels 130, and the outer surface 204 of reel 200 is adjacent to the inner surface of the flange of flanged drive wheel 130.
In
Referring now to
Referring now to
Referring now to
When the reel 200 is no longer needed for processing, the process of loading the spool into the lever lift assembly 100 is reversed. The lever assembly 132 is pivoted upward, forcing lifter assembly 148 away from the base assembly 102, and lowering reel 200 onto the floor. Further lifting of lever assembly 132 forces lifter assembly 148 farther from reel 200, causing the flanged wheels 156 to lose contact with reel 200 and extending the lifter members 150 and 152 sufficiently to allow the flanged wheels 156 to be lifted up and over the reel 200. Once the lifter assembly 148 is lifted off the reel 200, it can be rolled away and replaced with another spool.
It is understood that the embodiments described herein and shown in the figures are not the only embodiments of the lever lift assembly, and that other embodiments of the lever lift assembly that operate in the general manner described herein are contemplated by this disclosure and the claims provided herein.
Number | Date | Country | |
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Parent | 12148694 | Apr 2008 | US |
Child | 12503633 | US |