Core with improved chuck interaction

The invention claimed is: 1. An improved core for mounting on one or more core engaging elements, the core adapted for winding and unwinding material thereon, the core being hollow and cylindrical and having an inner surface and an outer surface adapted to accommodate the material, the core having two axially opposed ends, wherein the improvement comprises: a high coefficient of friction (COF) coating disposed on all or a portion of the inner surface in one or more spiral patterns, the high COF coating adapted to increase the coefficient of friction (COF) between the inner surface of the core and the core engaging elements. 2. The core of claim 1 wherein: the high COF coating is selected from the group consisting of aqueous dispersions of anti-skid agents and silicates, latex coatings and adhesives. 3. The core of claim 1 wherein: the high COF coating comprises a high COF material; and the weight percent of high COF material in the high COF coating is between 10% and 80%. 4. The core of claim 1 wherein: the high COF coating covers at least 22% of the inner surface. 5. The core of claim 1 wherein: the high COF coating is applied to the inner surface in a pattern to achieve a predetermined level of surface area coverage. 6. The core of claim 1 wherein: the one or more core engaging elements comprise a pair of chucks. 7. An improved core for mounting on a shaft extending axially through the entire core, the core adapted for winding and unwinding material thereon, the core being hollow and cylindrical and having an inner surface and an outer surface adapted to accommodate the material, the core having two axially opposed ends, wherein the improvement comprises: a high coefficient of friction (COF) coating disposed on all or a portion of the inner surface, the high COF coating adapted to increase the coefficient of friction (COF) between the inner surface of the core and the core engaging elements, wherein: the one or more core engaging elements comprises a shaft extending axially through the entire core. 8. A method of making a hollow cylindrical core comprising the steps of: spirally winding one or more inner plies around a forming mandrel; spirally winding one or more additional plies around the forming mandrel to form a continuous core that moves axially along the mandrel before coming off the mandrel; cutting the continuous core into individual cores, each core having two axially opposed ends, an inner surface comprising one or more engaging surfaces near each end and an outer surface adapted to accommodate a material wound therein; and applying a high COF coating onto at least a portion of the inner surface in one or more spiral patterns. 9. The method of claim 8 wherein: the high COF coating is applied to each of the one or more engaging surfaces. 10. The method of claim 8 wherein: the high COF coating is applied to the inner surface by spraying. 11. The method of claim 8 wherein: the high COF coating is applied only to all or part of the engaging surfaces. 12. A method of making a hollow cylindrical core comprising the steps of: spirally winding one or more inner plies around a forming mandrel; spirally winding one or more additional plies around the forming mandrel to form a continuous core that moves axially along the mandrel before coming off the mandrel; cutting the continuous core into individual cores, each core having two axially opposed ends, an inner surface comprising one or more engaging surfaces near each end and an outer surface adapted to accommodate a material wound therein; and applying a high COF coating onto at least a portion of the inner surface, wherein: the high COF coating is applied to the inner plies before they are spirally wound around the forming mandrel. 13. A method of making a hollow cylindrical core comprising the steps of: spirally winding one or more inner plies around a forming mandrel; spirally winding one or more additional plies around the forming mandrel to form a continuous core that moves axially along the mandrel before coming off the mandrel; cutting the continuous core into individual cores, each core having two axially opposed ends, an inner surface comprising one or more engaging surfaces near each end and an outer surface adapted to accommodate a material wound therein; and applying a high COF coating onto at least a portion of the inner surface, wherein: the high COF coating is applied to the inner surface after spirally winding the inner plies around the mandrel and as the continuous core moves along the mandrel. 14. A method of making a hollow cylindrical core comprising the steps of: spirally winding one or more inner plies around a forming mandrel; spirally winding one or more additional plies around the forming mandrel to form a continuous core that moves axially along the mandrel before coming off the mandrel; cutting the continuous core into individual cores, each core having two axially opposed ends, an inner surface comprising one or more engaging surfaces near each end and an outer surface adapted to accommodate a material wound therein; and applying a high COF coating onto at least a portion of the inner surface, wherein: the high COF coating is applied only to the middle of the inner surface.