This disclosure generally relates to a handling and loading system for a roll of web material. In particular, it is directed to a system and method for easy loading of a roll of web material onto axial hubs, handling the roll of web material, and easy un-loading of the roll of web material from the axial hubs.
Rolls of web material are used in a wide variety of personal, commercial and industrial applications where a web of material is to be supplied from the roll. A conventional arrangement, such as is commonly used for roll-feeding in the paper printing industry, consists of a roll of web material wound on an axle or on a hollow tube adapted with a mandrel through the tube. Due to the weight and size of the roll of web material, the roll of web material is typically lifted by a lift mechanism and placed in position with ends of the axle or the mandrel seated in opposing saddles or bearing holders. A web driving or pulling mechanism can then engage the roll of web material and feed the web material into an associated production process.
In most applications, precise care is required for placement of an axle or mandrel into the hollow tubular core of the roll of web material and lifting the roll of web material onto supporting saddles or bearing holders. Mandrels are typically quite heavy, roughly 30 to 50 pounds, can be difficult to install, and are prone to breaking during installation or use. Restricted access to the mounting position for the roll of web material also often limits utilization of conventional lifting devices such as cranes or forklifts, and therefore requires difficult manual lifting and placement, causing delay and reducing overall efficiency.
The foregoing problems with prior art roll-feeding devices are overcome by providing a system for handling and loading a roll of web material wound on a hollow tubular core onto a pair of pivotably mounted hubs, and un-loading the roll of web material from the pair of pivotably mounted hubs. The system obviates the need for an axle or mandrel to be placed in the hollow tubular core to support and handle the roll of web material.
The roll handling and loading system for a roll of web material comprises a pair of hubs positioned on opposing sides of a horizontally-oriented space in which the roll of web material is positioned. Each of the hubs comprises a hub face having an annular shape, and each of the hubs are pivotably supported on a pivot mechanism for pivoting movement between an operational position on a horizontal rotational axis and a deflected position in which the hub face of each of the hubs is deflected in an arcuate direction away from the horizontal rotational axis. The pivot mechanism is adapted to deflect each of the hubs to a deflected position above the horizontal rotational axis.
In one embodiment of the system, the pair of hubs is transitioned from the operational position to the deflected position by the roll of web material when the roll of web material is lifted from beneath the horizontal rotational axis of the pair of hubs. Subsequent lowering of the roll of web material allows the pair of hubs to transition from the deflected position to the operational position and become seated in respective ends of the hollow tubular core of the roll of web material so as to bear the weight of the roll of web material. Release of the roll of web material from the hubs only requires the roll to be lifted upwardly and beyond the reach of the pivoting hubs.
In another embodiment, a pick-up tool comprises a pair of hubs that is movable in a vertical direction. The pair of hubs is transitioned from the operational position to the deflected position by the roll of web material when the pair of hubs is lowered from a position above the roll of web material to a position where the hubs engage respective ends of the roll of web material in the horizontally-oriented space, and subsequent raising of the pair of hubs allows the pair of hubs to transition from the deflected position to the operational position and become seated in respective ends of the hollow tubular core of the roll of web material. The pick-up tool may be used to pick up the roll of web material and transport it to another location. Release of the pick-up tool from the roll of web material only requires the hubs be lowered, to cause the hubs to pivot upward and disengage from the ends of the hollow tubular core, beyond the reach of the pivoting hubs.
In both embodiments, the hubs tilt up and away from the ends of the roll of web material and then drop into position within the ends of the hollow tubular core when the hub faces become engaged therewith. The subsequent lowering of the roll of web material or the subsequent raising of the hubs with respect to the roll of web material allows the hubs to pivot back down into the ends of the hollow tubular core to become fully seated therein in the operational position.
A preferred embodiment of the system may be configured so that the hubs have hub faces with a beveled configuration for positive seating in the ends of the hollow tubular core of the roll. One of the hubs in the pair of hubs may be biased along the horizontal rotational axis of the roll of web material toward the other hub to accommodate variations in a horizontally-oriented length of the roll of web material.
Related methods of making and using the roll handling and loading system are also considered to be within the scope of the present disclosure. Other objects, features, and advantages of the various embodiments in the present disclosure will be explained in the following detailed description with reference to the appended drawings.
In the following detailed description, certain preferred embodiments are described to illustrate the general principles in the present disclosure. It will be recognized by one skilled in the art that the present disclosure may be practiced in other analogous applications or environments and/or with other analogous or equivalent variations of the illustrative embodiments. For example, several pivot mechanisms are described for pivoting hubs in the roll handling and loading system, but any type of pivot mechanism may be employed in the system to provide the desired functionality. In addition, the disclosed system may be used for handling and loading any type of web material that is rolled on a hollow inner core that can support the weight of the rolled web material. It should also be noted that those methods, procedures, components, or functions which are commonly known to persons of ordinary skill in the field of the invention are not described in detail herein so as avoid unnecessarily obscuring a concise description of the preferred embodiments.
The disclosed system obviates the need for an axle, mandrel or any other device to be sleeved within the hollow tubular core 15 to support the roll 12 of web material 13, as is required by conventional roll-feeding systems. Instead, the disclosed roll handling and loading system comprises a pair of hubs 20a, 20b positioned on opposing sides 22 of a horizontally-oriented space 24 in which the roll 12 of web material 13 is positioned. The hubs 20a, 20b are seated in respective ends 15a, 15b of the hollow tubular core 15 so as to bear the weight of the roll 12 of web material 13.
In
Each of the hubs 20a, 20b is pivotably supported on a pivot mechanism 46 for pivoting movement between a load-bearing operational position OP on the horizontal rotational axis 14 (shown in
Any type of pivot mechanism 46 may be used to provide pivoting movement to the hubs 20a, 20b. One example of a suitable pivot mechanism 46 is shown in
Referring to
In
In
In
In
As set forth above, the pair of hubs 20a, 20b is transitioned from the operational position OP to the deflected position DP by the roll 12 of web material 13 when the roll 12 of web material 13 is lifted from beneath the horizontal rotational axis 14 of the hubs 20a, 20b into the horizontally-oriented space 24, and subsequent lowering of the roll 12 of web 13 material allows the hubs 20a, 20b to transition from the deflected position DP to the operational position OP and become seated in respective ends 15a, 15b of the hollow tubular core 15 of the roll 12 of web material 13 so as to bear the weight of the roll 12 of web material 13.
The pivot mechanism 46 supporting the hubs 20a, 20b may be provided with a damper mechanism to enable controlled deflection from the operational position OP to the deflected position DP and retraction from the deflected position DP to the operational position OP. A brake or clutch may also be provided to the hubs 20a, 20b to apply or release tension on the roll during roll-feeding.
One of the hubs 20a, 20b may be biased along the horizontal rotational axis 14 toward the other of the hubs 20a, 20b to accommodate variations in the horizontally-oriented length L of the roll 12 of web material 13 and/or to provide tension along the horizontal rotational axis 14 to ensure that the hubs 20a, 20b are securely seated in the hollow tubular core 15. For example, referring to
The hubs 20a, 20b may be made from any material suitable for supporting the weight of a roll 12 of web material 13. The hubs 20a, 20b may be adapted to spin and engage the roll 12, such as by including a bearing within the hubs 20a, 20b. Or, the hubs 20a, 20b may be stationary (without a bearing) and the surfaces of the hub faces 21 may be treated with a non-stick material to permit the roll 12 to rotate on the hub faces 21, such as TEFLONĀ®, a registered trademark of E.I. DuPont De Nemours and Company of Wilmington, Del.
In an alternative environment of use, referring to
Many other modifications and variations may of course be devised given the above description of preferred embodiments for implementing the principles in the present disclosure. It is intended that all such modifications and variations be considered as within the spirit and scope of this disclosure, as defined in the following claims.
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