BACKGROUND ART A number of systems have been developed for winding strand into a cyl indrical package and subsequently encasing the wound package in a membrane to protect the strand and to facilitate withdrawal of the strand from the package.

A number of such systems included thermally shrinking a plastic or polymeric membrane over the outer surface of the wound body of the strand. Although such systems did improve the run-out capabilities of the package, a tendency for the outermost layer of the strand to collapse in a ball or "bird's nest" still existed. That is, as a strand was withdrawn from the package working from the inside diameter of the package to the outer diameter of the package, the outermost layers exhibited a tendency to collapse and tangle and, thus, precl ude continuous operation and complete utilization of the strand. Other systems incorporated an adhesive between the membrane and the outer layer of strand to retain the strand against the membrane wall . In a number of instances, the adhesive contaminated the strand, among other probl ems .

DISCLOSURE OF THE INVENTION

A package and a ethod for producing the package are provided comprising a wound body of strand having an

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outer cylindrical portion; and an elastic membrane wound about the cyl indrical portion of said body, the membrane being wound to a sufficient thickness and stretched sufficiently to partially collapse as said strand is withdrawn from the body such that the membrane captures portions of the strand along the outer cylindrical portion of the body to retain the strand along said membrane until said strand is withdrawn from the package.

It is an object of this invention to provide an improved package system for encapsulating wound filamentary aterial .

It is another object of the present invention to provide a method for applying a membrane to a predetermined thickness in a predetermined stretched condition.

The foregoing, as well as other objects of the present invention, will become apparent to those skilled in the art in the following detailed description. BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a semi-schematic front view of a system for wrapping an elastic membrane around a package of strand .

FIG. 2 is a side view of the system shown in FIG.

FIG. 3 is a front view of the system shown in FIG. 1 at a different point during package wrap. FIG. 4 is a cross-sectional view of a package according to the principles of this invention.

FIG. 5 is a front view of the package just prior to the complete run-out of the strand from the package.

BEST MODE OF CARRYING OUT THE INVENTION As shown in FIGS. 1, 2 and 3, a cyl indricall shaped, wound package of strand 8 having an external cyl indrical portion 11 is positioned on wrapping means 30.

Elastic membrane 12 is supplied to package 8 from roll of membrane material 13. El astic membrane 12 can be of any suitable material of a suitaable thickness capable of being stretched to the proper extent. Polymeric membranes of such materials as pol vi nyl idenε chloride and

polyvinyl chloride are preferred in thickness from about .001 inch to about .003 inch.

Basically, the elastic membrane 12 is wound about the cylindrical portion 11 of wound body of strand 8, the membrane being applied to a sufficient thickness and being stretched or tensioned sufficiently to partially collapse when the strand is withdrawn from the interior of the body 8 such that the membrane 12 captures portions of the strand of the outer cylindrical portion 11 to retain such strand

10 along the membrane until the strand is withdrawn from the package at a predeter ined time.

Wrapping means 30 is comprised of a frame 32 and a rotatable member 34 associated therewith. The first collet 36 is rotatably journaled in member 34 and is I ⁵ adapted to receive body 8 thereon. Second collet 38 is rotatably journaled in member 34 and is adapted to receive roll 13 thereon. Member 34 is adapted to be rotated by motor 46. Positioning means or gear train 50, which can be attached to the housing of motor 46, is joined with shaft 20 48 of collet 36 such that as member 34 is rotated, body 8 and collet 36 maintain the same general unrotated orientation with, respect to frame 32. As can be seen by FIGS. 1 and 3, arrow A, which points vertically upward on package 8 in FIG. 1, remains pointing vertically upward 5 completely throughout the rotation of member 34.

A second collet 38, which is rotatably journaled in member 34, is attached to adjustable braking means 40 to apply a predetermined amount of drag to second collet 38 such that membrane 12 is wrapped about body 8 under a 0 predeter ined amount of tension to stretch membrane 12. Brake means 40 can be of any suitable type such as a pneumatic or el ectrodynamic brake as is known in the art. Brake means 40 is adjustably controlled by control means 41 via connection 42 as is known in the art. 5 Alternatively, wound body 8 can be mounted on a driven rotatable collet. Membrane 12 can be pulled from a roll mounted on another collet as the body 8 is rotated.

Also, the roll and the collet associated therewith could have a brake means to apply sufficient amount of tension to membrane 12 as it is being wound around the cylindrical portion 11 of body 8.

As shown in FIG. 4, one end 16 of package 6 is substantially open with the opposite end 17 being substanti lly closed. It is believed that membrane 12 should project no further than approximately 1/2 inch radially inward from the cyl indrical shell 15 at the open end of the package to facilitate complete, continuous run-out of the strand. Preferably, first strand end 9 positioned in the hollow core of body 8 is adapted to be pulled out through the open end 16 of the package 6. Second strand end 10 can be located along the external cyl indrical portion 11 of body 8. For continuous operation, end 10 can be tied to another end of a second package to permit continuous operation.

FIG. 4 is drawn in a slightly exploded view; the cyl indrical shell 15 formed by membrane 12 according to the principles of this invention is in intimate compressive contact with the external cyl indrical portion 11 of body 8.

Closed end 17 can be formed by supplying a sheet of membrane 12 substantially longer than the length of body 8, as shown in FIG. 2, and folding the excess membrane over the end to form closed end 17. Open end 16 is formed by positioning one end of body 8 and one end of rol l 13 in a common vertical plane and maintaining this relationship during wrapping, as can be seen in FIG. 2.

As shown in FIG. 5, cyl indrical shell 15 develops a plurality of undulations or crinkled sections or ridges due to the relaxation of the tension on membrane 12 as well as the weight of the shel l 15 and unsupported outer layers of strand as the strand is almost completely withdrawn from package 6. The crinkles or corrugations 20 have been found to mechanically grasp or crimp portions of the strand at the outer cylindrical portion of body 3 to retain such portions of the strand along the shell 15 of membrane 12

until the strand is withdrawn from the package in a predetermined manner.

It has been found that shell 15 collapses along its axial length in an amount within the range from about 10% to about 50% of the original package height or length. A partial collapse within a range from about 20% to 40% is preferred. The amount of radial contraction of shell 15 is substantially less.

It has been found that a tensile force within the range from about 2 to about 4 pounds applied to membrane 12 as it is being wound around body 8 for a pl urality of convolutions within the range from about 2 to about 4 convolutions employing a membrane having a width within the range from about 17 to 24 inches and having a thickness within the range from about .001 inch to about .003 inch applied to a package of wound glass strand approximately 11 inches long and 12 inches in diameter provides a package having improved strand run-out characteristics.

As such, the tension applied to membrane 12 during winding should be within a range from about .08 pounds per inch of width of membrane to about .24 pounds per inch of width of membrane for acceptable results, wherein from 2 to 4 convolutions of membrane are wound about body 8. The number of wraps of membrane is dependent upon the characteristics of the particular membrane and body of strand.

If the shell 15 were wound too thick, the tendency for the shell to collapse along its length would be substantially reduced. Therefore, it is necessary that the number of convolutions of membrane not be excessive.

Package 6 produced according to the instant invention provides improved strand run-out characteristics, in the absence of "heat-shrinking" the membrane 12 as is known in the art. It has been found that "heat-shrinking" a polymeric membrane generally provides a shell or membrane not having the proper collapse characteristics to sufficiently capture the strand between the folds to retain

the strand along the membrane.

Al so, the membrane 12 should be of the type having a static electrical charge adapted to attract the strand to help retain the strand along membrane 12.

It is apparent that within the scope of the invention, modifications and different arrangements can be made other than as herein disclosed. The present disclosure is merely illustrative with the invention comprehending all variations thereof.

INDUSTRIAL APPLICABILITY

This invention is applicable to the textile i ndust r .