The present disclosure relates to yarn tubes or cores upon which yarns are wound to form yarn packages.
In the production of yarn it is frequently necessary to wind a yarn about a yarn tube to form a yarn package that can then be transported to another piece of equipment or another location at which the yarn is then unwound from the yarn package and processed in some manner. In certain segments of the yarn manufacturing industry it has been the conventional practice to use metal yarn tubes. A metal yarn tube is configured to be mounted on a drive spindle assembly that rotates the yarn tube for winding yarn onto the yarn tube to form a yarn package, or for paying yarn out from a yarn package already wound on the yarn tube.
A typical spindle assembly includes a hub that is rotatably driven by a motor and drive arrangement so as to rotate about a rotational axis, and an elongate spindle rigidly affixed to the hub and coaxial therewith. The spindle has a length that is about three-quarters or more of the length of the standard metal yarn tube. Thus, the spindle is designed to extend up within the interior of the metal yarn tube and engage a fitting disposed within the yarn tube closer to the distal end than to the proximal end of the tube, so that the yarn tube is radially centered with respect to the spindle assembly both at its proximal end that engages the hub and at a location proximate the distal end.
At one time the typical practice was to use such metal yarn tubes wholly within a single facility, and this enabled the relatively costly metal yarn tubes to be recycled for use many times, with relative ease because of the short distances the tubes had to be transported between different processes at different locations within the same facility. More recently, however, the industry has changed such that it is often necessary to ship yarn packages from one facility to another, sometimes at great distances such as from one country to another. The metal yarn tubes tend not to be returned to the point of origin in these instances, which substantially increases the yarn winder's cost of producing the yarn packages because the winder does not receive the benefit of recycling the already used yarn tubes.
The present disclosure relates to an adapter or support that enables a wound paperboard yarn core to be mounted on the spindle assembly.
In accordance with one embodiment of the invention, a support is provided for a hollow cylindrical paperboard yarn core and for engagement with a cantilevered drive spindle assembly, so that the core can be mounted on the spindle assembly. The spindle assembly has a hub and an elongate rod-shaped spindle rigidly affixed to the hub in cantilever fashion, the hub defining exterior drive surfaces, the spindle being of smaller diameter than the drive surfaces. The support comprises a proximal-end support member for supporting a proximal end of the core and engaging it in a substantially non-slip manner, and a distal-end support member for supporting a distal end of the core. The support members locate the core substantially coaxially with respect to the rotational axis of the spindle assembly.
In one embodiment as described herein, the proximal-end support member is configured to be mounted on the hub, and thus the proximal-end support member defines a through-passage for receiving the spindle therethrough, and it has interior mating surfaces configured to mate with the drive surfaces of the hub so that the proximal-end support member is constrained to rotate with the hub. The proximal-end support member is configured to be removably received into the proximal end of the paperboard core so as to locate the proximal end of the core coaxially with respect to the rotational axis of the spindle assembly. The proximal-end support member comprises core-engaging elements for engaging a cylindrical inner surface of the core so as to cause the core to rotate with the proximal-end support member, and further comprises urging elements operable to urge the core-engaging elements radially outwardly into engagement with the inner surface of the core.
The distal-end support member is configured to be removably inserted into the distal end of the core, and has a core-engaging portion configured to engage the interior surface of the core near the distal end thereof and a spindle-engaging portion rigidly affixed to the core-engaging portion. The spindle-engaging portion defines a bore configured to receive a distal end of the spindle so as to orient the distal-end support member coaxially with respect to the rotational axis. The core-engaging portion of the distal-end support member in turn locates the distal end of the core coaxially with respect to the rotational axis.
In one embodiment, the urging elements include resilient biasing members arranged to apply a radially outward force on each of the core-engaging elements.
The core-engaging elements can comprise rollers.
The proximal-end support member can include a base defining the through-passage for the spindle, and a retainer sleeved over the base and rotatable relative thereto, the retainer capturing the rollers between the retainer and the base in a manner allowing each roller to move radially to a limited radial extent and to move circumferentially to a limited circumferential extent. The biasing members bias the rollers to a radially outward extreme of the limited radial extent in the absence of any radially inward force sufficient to overcome the radially outward force exerted by the biasing members.
In one embodiment, the base defines a wedge surface corresponding to each roller, and each roller is captive between the retainer and the corresponding wedge surface. The wedge surfaces are configured such that any tangential movement of the rollers away from a neutral position thereof with respect to the corresponding wedge surfaces causes the rollers to be moved radially outwardly relative to the neutral position.
In one embodiment, the retainer defines a window for each roller, each window having a circumferential width that becomes narrower in a radially outward direction and reaches a minimum width, each roller having a diameter larger than said minimum width. This allows the rollers to partly protrude out from the windows to engage the ID of the core, but the rollers are prevented from escaping through the windows.
The biasing members can comprise sheet-metal springs.
Having thus described the disclosure in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein:
The present invention now will be described more fully hereinafter with reference to the accompanying drawings in which some but not all embodiments of the inventions are shown. Indeed, these inventions may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will satisfy applicable legal requirements. Like numbers refer to like elements throughout.
A support 20 for allowing a paperboard yarn core C to be mounted on a cantilevered drive spindle assembly SA is depicted in
With initial reference to
With reference to
The base 32 defines an outer skirt 36 having a sloped or generally conical upper surface that acts as a guide surface for yarn being wound onto the paperboard core. The skirt can assume any of various configurations to accommodate different winding spindles. The base further defines a generally cylindrical portion 37 extending upwardly from a transverse wall 38 that connects the skirt 36 to the cylindrical portion 37. The OD of the cylindrical portion 37 is sized to fit closely within the ID of the core C. The skirt 36 includes an ID sized to closely receive the OD of the core C, as best seen in
With primary reference to
The generally cylindrical portion 39 of the base 32 is not fully cylindrical, but rather has a plurality of (three, in the illustrated embodiment, although a different number of them is possible) wedge surfaces 43 circumferentially spaced apart about the circumference of the portion 39. As shown, the wedge surfaces can be flat or planar surfaces, although that is not essential. The wedge surfaces 43 lie at a smaller radius than that of the ID of the retainer 40, and hence there is a space between the ID of the retainer and each wedge surface. The retainer 40 defines a number (i.e., the same number as there are wedge surfaces) of cutouts or windows 44. As best seen in
Interposed between each core-engaging element 45 and the wedge surface 43 is an urging element 46 whose function is to urge or bias the core-engaging element radially outwardly into the position shown in
The proximal-end support member 30 further comprises a spring retainer 47. The spring retainer is a ring-shaped member having an ID sized larger than the OD of the cylindrical portion 39 of the base 32 by an amount that accommodates the thickness of the urging elements 46. The spring retainer is sleeved over the cylindrical portion 39, above the retainer 40. The urging elements 46 thus are clamped or captured between the spring retainer 47 and the cylindrical portion 39. The uppermost ends of the urging elements 46 can be bent in an “L” shape to form radially outwardly extending leg portions that sit atop the upper surface of the spring retainer 47 so as to prevent the urging elements from shifting axially downward. A split snap ring 48 is also sleeved over the upper end of the cylindrical portion 39 and engages a circumferential groove 49 in the cylindrical portion 39 to fix the snap ring in place, so as to capture the leg portions of the urging elements 46 between the snap ring 48 and the spring retainer 47. The urging elements are thus substantially prevented from moving axially and radially, and the urging elements are wide enough circumferentially that the ID of the retainer 40 substantially prevents them from moving circumferentially, as can be appreciated from
Thus far, the proximal-end support member 30 has been described in detail. The distal-end support member 50 (
When it is desired to install a paperboard core C on the spindle assembly SA having the proximal-end support member 30 mounted on the hub H in the manner already described, the paperboard core is sleeved down over the proximal-end support member until the lower end of the core abuts the transverse wall 38 (
The proximal-end support member 30 operates in the following manner to substantially prevent slippage between the support member 30 and the core C. With reference particularly to
Once a yarn-winding operation is completed to produce a yarn package on the core C, the spindle is brought to rest and the yarn package is removed from the spindle by grasping the yarn package and pulling straight upward to disengage the core from the proximal-end support member 30 and distal-end support member 50. The proximal-end support member remains attached to the hub of the spindle assembly, but the distal-end support member remains engaged in the core. The user can then grasp the distal-end support member 50 and pull it out of the core. The yarn package is then ready to be transported to a further location for processing.
As best seen in
Many modifications and other embodiments of the inventions set forth herein will come to mind to one skilled in the art to which these inventions pertain having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is to be understood that the inventions are not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the appended claims. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.