Device for roller assembly, and related systems and methods

What is claimed is: 1. A taping device for an automated taping assembly adapted for applying tape to a package, the tape having an adhesive side and an opposed non-adhesive side, the taping device comprising: a mount configured to carry a roll of the tape; a plurality of rollers configured to engage the tape so as to convey the tape from the mount to a dispensing region of the taping device, wherein at least one roller of the plurality of rollers comprises: a roller body rotatable about a central axis, the roller body including an outer roller surface, and an inner roller surface that defines a central bore that extends along the central axis; end caps positioned at opposite ends of the roller body, wherein each of the end caps defines a first portion that extends within the central bore and a second portion that defines a flange that abuts a respective one of the ends of the roller body when the at least one roller is in an assembled configuration; a shaft that is configured to extend through the central bore of the roller body and the first portions of the first and second end caps, the shaft defining an outer shaft surface, the shaft having a boss that extends radially outward from the outer shaft surface, a bushing configured to be rotationally coupled to the roller body within the central bore and received over the outer shaft surface, wherein opposed axially inward surfaces of the bushing and the boss are spaced from each other in an axial direction extending along the central axis when the at least one roller is in the assembled configuration; a coil spring configured to be received within the central bore, over the outer shaft surface, and between the opposed axially inward surfaces of the boss and the bushing, wherein the shaft, the boss, the bushing, and the coil spring are collectively configured such that opposite ends of the coil spring contact the opposed axially inward surfaces of the boss and the bushing in a manner causing an amount of resistance between the roller body and the shaft when the roller body rotates with respect to the shaft during use of the taping device to apply tape to a package. 2. The taping device of claim 1 , wherein the bushing and the boss each define an axially outward surface that abuts the first portion of an associated one of the first and second end caps when the at least one roller is in the assembled configuration. 3. The taping device of claim 1 , wherein the boss comprises another bushing, and the another bushing is welded to the shaft. 4. A roller assembly for a taping device, the roller assembly comprising: a roller body defining a central bore; a bushing configured to be received within the central bore and rotationally fixed to the roller body; a shaft configured to be disposed within the central bore, the shaft defining an outer surface that extends through the bushing; a boss extending radially outward from the outer surface of the shaft, wherein the boss is rotationally locked to the shaft; and a resistance element configured to be disposed within the central bore and to contact the bushing and the boss in a manner providing an amount of rotational resistance between the roller body and the shaft when the roller assembly is in an assembled configuration. 5. The roller assembly of claim 4 , wherein bushing and the boss each define axially inward surfaces that face one another, and the resistance element is a coil compression spring configured to be received over the outer surface of the shaft between the axially inward surfaces. 6. The roller assembly of claim 5 , wherein the axially inward surfaces are spaced from each other by a distance in the range from about 10 mm to about 30 mm along an axial direction. 7. The roller assembly of claim 6 , wherein the distance is in the range of about 16 mm to about 22 mm. 8. The roller assembly of claim 4 , further comprising a lubricant configured to be disposed between the resistance element and at least a portion of the shaft. 9. The roller assembly of claim 4 , wherein the outer surface of the shaft has a diameter of about 10 mm. 10. The roller assembly of claim 9 , wherein the bushing has an outer diameter of about 15 mm so as to provide a compression fitting between the bushing and the roller body. 11. The roller assembly of claim 9 , wherein the boss has an outer diameter of about 14 mm so as to allow the boss to rotate freely within the central bore. 12. The roller assembly of claim 4 , further comprising a pair of end caps connectable to opposite ends of the roller body, wherein each end cap defines a first portion configured for insertion within the central bore a second portion that defines a flange configured to abut a respective one of the ends of the roller body when the roller assembly is in the assembled configuration. 13. The roller assembly of claim 12 , wherein the first portion of each of the pair of end caps has an axial length in the range of about 17 mm to about 18 mm. 14. The roller assembly of claim 13 , wherein the first portion of each of the pair of end caps defines an innermost end, and the innermost ends of the pair of end caps are spaced from each other by a distance in the range of about 46 mm to about 52 mm when the flanges abut the ends of the roller body. 15. The roller assembly of claim 14 , wherein: the bushing and the boss each have 1) a first end, 2) a second end spaced from the first end so as to define an axial dimension in an axial direction, and 3) an outer surface extending between the first and second ends in the axial direction; and when the roller assembly is in the assembled configuration, the first end of the bushing abuts the innermost end of one of the end caps; the first end of the boss abuts the innermost end of the other of the end caps; the sum of the axial dimensions of the boss and bushing is about 27 to about 33 mm; and the resistance element is a coil compression spring having opposite spring ends that abut the second end of each of the bushing and the boss. 16. The roller assembly of claim 15 , wherein the coil compression spring has a spring rating in the range of about 2.00 to about 2.20 N/mm. 17. The roller assembly of claim 16 , wherein the sum of the axial dimensions of the boss and the bushing is about 30 mm, and the spring rating is about 2.11 N/mm. 18. The roller assembly of claim 4 , wherein boss is welded to the shaft. 19. The roller assembly of claim 4 , wherein the boss and the shaft are monolithic. 20. A method automatically applying tape to a package, the method comprising: engaging an adhesive side of a length of tape with a knurled outer surface of a roller body; rotating the roller body, responsive to the engaging step, about an outer surface of a shaft that extends through a central bore of the roller body and is fixed to a frame so as to prevent the shaft from rotating with respect to the frame, wherein the shaft extends through a bushing that is disposed within the central bore and is rotationally fixed to the roller body, wherein the shaft has a boss that defines a radial surface that faces an end surface of the bushing and is spaced from the end surface of the bushing, wherein a coil compression spring is received over the outer surface of the shaft and between the radial surface of the boss and the end surface of the bushing; and biasing opposite ends of the coil compression spring against the radial surface of the boss and the end surface of the bushing so as to provide a rotational resistance between the roller bod