DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0012] Referring now to the drawings, a protective garment 10 provides protection to participants of indoor athletic events, especially competitive events such as volleyball and the like which are typically played on gymnasium floors of hard wood or other composition. In competitive volleyball matches and other athletic events a wearer frequently contacts the playing floor in maneuvers which include some form of sliding motion in which the participant experiences frictional engagement with the playing floor. Accordingly, a need has arisen for protective garments which are toughened to provide extended wear and to reduce premature failure caused, for example by melting when subjected to frictional heating. However, it is important that protective devices, avoid hindering the participants playing ability if they are to receive substantial commercial acceptance. For example, it is important that knee pads and elbow pads employed for protection while sliding across a playing floor do not abruptly stop a player's motion. Accordingly, the contact surface portion of the protective garment must offer a sufficiently low frictional resistance while remaining tough enough to withstand the riggers of enthusiastic athletic activities.

[0013] A protective garment 10 includes a body 12 , preferably in the form of a cylinder, and a compressive cuff portion 14 disposed at one end, or optionally both ends. Cuff portion 14 is preferably made of elastic material of a type known in the art to maintain the position of garment 10 about a wearer's leg or arm, so as to locate protective device at the wearer's knee or elbow. The cylindrical body 12 is preferably provided with a conventional padding or cushioning material disposed within an outer shell 20 , and fastening straps 21 (see FIG. 2 ).

[0014] Outer shell 20 is preferably comprised of nylon and most preferably comprised of 8 ounce nylon material, type 6-6 having the following percentage stretch characteristics: length (warp) of 45%, and variance or range between 30 and 65%. The stretch percentage of the material width (side or weft) of approximately 65% and a variance range between 45 and 85%. An example of such material is a type 6-6, 100% nylon, Product No. 1700 “Swiss Pique” commercially available from Adele Knits, Inc. of Winston-Salem, N.C.

[0015] The patch 30 preferably comprises a solid film of Teflon powders combined with plastisol inks to initially form a liquid coating. The coating is applied via a conventional silk screen process onto a paper release liner 90 (see FIG. 3 ), coated with a release agent such as silicone. Preferably, the coating mixture comprises hot split PVC plastisol ink with 25% by-volume Teflon additive polyamide. After application to the paper release liner, the coating is allowed to harden to form a solid film which is accumulated for subsequent delivery to a manufacturing site.

[0016] Upon arrival at the manufacturing site, the nylon shell 20 is prepared to receive the film coating. The transfer material, as mentioned, is provided in the form of a release liner, preferably a coated paper. The film coating is laid against the nylon shell (see FIG. 3 ) and heat is applied to the release liner. Optionally, heat may also be applied to the backside of the nylon shell. Simultaneous with the application of heat, pressure is applied to the release liner, pressing the heated coating against the nylon shell as schematically indicated in FIG. 4 .

[0017] With the application of heat and pressure, the ink component of the film coating is dispersed into the fabric of the nylon shell while the Teflon component of the film coating is bonded to the cloth fibers of the nylon shell. It is believed that there is substantial penetration of the Teflon powders into the nylon fabric, in addition to a surface adhesion. Accordingly, any interposition of release agents or protective liners between the coating mixture and the nylon shell is avoided since this would retard or prohibit dispersion of the ink, as well as adhesion of the Teflon powder component. The transfer operation of the preferred embodiment was carried out at a temperature of approximately 400° F., a pressure of approximately 80 lbs. and a dwell time of approximately 6 seconds, to achieve desired bonding, adhesion strength and color value. The ink component of the coating undergoes a substantial change of color value during the heat transfer process.

[0018] During application of the film coating the nylon shell undergoes substantial shrinking, that is, the surface area of the nylon material is noticeably reduced by the heat transfer process.

[0019] In order to produce a toughening patch using low cost fabrication techniques, it is preferred that the film coating mixture be compatible with conventional silk screen techniques. However, the amount of Teflon material need in an optimally efficient coating rendered the coating relatively thick or viscous. In order to prepare the coating for reliable silk screen printing using conventional techniques, an additional amount of ink was introduced into the mixture to acta as a solvent or flowing medium, sufficient to allow the Teflon component to flow or permeate through the silk screen in a conventional manner. In the preferred embodiment the amount of ink was in excess of an amount needed to adequately color the film coating. This excess amount of ink remains with the coating after the silk screen application to the paper release liner, and thereafter during the heat transfer process. It has been found preferable in order to achieve a reliable cost effective commercial process, that the excess ink remain in the composition and be transferred to the outer surface of the nylon shell 20 .

[0020] The excess ink raises the coefficient of friction of the applied coating to a level unacceptable for certain activities such as athletic competition. Accordingly, after the heat transfer is applied to the nylon shell and the liner 90 removed (see FIG. 5 ), one or more clean sheets of blotting or transfer paper 96 are pressed against the applied film of transfer material, preferably in the presence of heating, in order to fix a certain portion of the excess ink to the transfer paper (see FIGS. 6 and 7 ). In this manner, a certain portion of the excess ink 98 is extracted from the film coating as the paper 96 is removed (see FIG. 8 ). Depending upon the characteristics of the transfer paper used in the “blotting” operation two or more blotting operations are carried out subsequent to the initial heat transfer application. However, additional blotting operations may be unnecessary if a suitable paper having receptive characteristics is selected for the blotting operation. After the blotting operation, the applied coating is allowed to cool to form a rugged, low friction patch 30 which is aggressively bonded to the nylon shell so as to prevent edge separation or other defects.

[0021] The drawings and the foregoing descriptions are not intended to represent the only forms of the invention in regard to the details of its construction and manner of operation. Changes in form and in the proportion of parts, as well as the substitution of equivalents, are contemplated as circumstances may suggest or render expedient; and although specific terms have been employed, they are intended in a generic and descriptive sense only and not for the purposes of limitation, the scope of the invention being delineated by the following claims.