Master processing apparatus with master engaging structure for tensioning a master

Abstract

A multi-purpose laminating and adhesive transfer apparatus having a frame supporting rotatably engaging nip rollers. A replaceable cartridge is insertable into the frame and has upper and lower feed rolls which may be a laminate, film or paper, or an adhesively coated film or a film having an affinity for adhesive. The upper and lower feed rolls containing the webs of laminating or adhesive transfer material have tensioning caps which can be adjusted to provide the proper tensioning to prevent the rollers from overrunning as they rotate. Tensioning caps and the cartridges are pre-set and provided to the user. A cutter blade is positioned at the discharge side of the nip rollers and may be actuated to sever the master at any desired location. The apparatus may be operated to apply lamination to either top or bottom surfaces of a substrate or an adhesive to the top or bottom surface of the substrate or to both surfaces.

Description

The present invention is a

DETAILED DESCRIPTION OF THE DRAWINGS

Turning now to the drawings, particularly FIGS. 1 to 11, the transfer apparatus of the present invention is generally designated by the numeral 10 and includes a housing member generally designated by the numeral 12 having a base 14, opposite side walls 16 and 18, a top 20 and a rear wall 22. The rear wall 22 of the housing is upwardly and forwardly inclined at panel 22A from the base 14 to a location where the rear wall extends vertically at panel 22B. As seen in FIG. 8, an opening 30 is defined between the panels 22A and 22B through which the substrate and processed articles are discharged.

As best seen in FIGS. 8, 9 and 10, an upper nip roller 40 extends transversely between the side walls of the frame spaced rearwardly from the edge of the side walls. The upper nip roller includes an axial shaft 42 rotatable in suitable bearings or bushings 44 at opposite ends. The shaft is covered by a cylindrical roller member 43 of resilient material such as rubber. Shaft 42 extends exteriorly of the side plate and is shown carrying a hand crank 45 for manually rotating the roller and shaft. Alternatively, the rollers may be powered by an electrical motor, not shown. A pinion gear 46 is secured to one end of the shaft adjacent the interior surfaces of the side wall.

A second nip roller 48 extends transversely between the side walls 16 and 18 positioned parallel to the upper nip roller. The lower nip roller may be vertically aligned with the upper nip roller but preferably is forwardly displaced a distance forward of the upper nip roller, as for example approximately ¼" as best seen in FIG. 8. The terms "forward" and "rearward" or "front" and "rear" as used herein, refer to the orientation of the feed path through the device. The lower nip roller has a shaft 52 which is rotatable in bearings 54 located at the interior of the opposite side walls. A pinion gear 58 is mounted at one end of the shaft 52. Pinion gear 58 engages the pinion gear 46 on the upper nip shaft so that actuation of the upper nip roller by means of the crank 45 or other power means will impart opposite rotation to both nip rollers as indicated by the arrows in FIG. 10.

The upper and lower nip rollers 40,48 comprise pressure applying and substrate advancing structures that both apply pressure to the master substrate M and unwound end portions of the stock materials wound on supply rolls 165 and 166. Broadly speaking, these nip rollers may be considered to constitute a master substrate processing assembly comprising a plurality of cooperating structures constructed and arranged to (a) advane the master substrate M and unwound portions of the stock materials on opposing sides thereof through the master substrate processing assembly and (b) apply pressure to the master substrate and the unwound portions of the stock materials to affect adhesive bonding between the master substrate M and the adhesive on the stock materials.

Feed tray 80 has of a planar feeding surface 82 with opposite extending flanges 85 which flanges are removably insertable in horizontal recesses 84 of the cartridge 150. The feeding surface 82 may also be referred to as a master supporting surface and the feed tray may be considered to be a structure providing that master supporting surface. A master substrate engaging structure in the form of a wiper assembly 86 is mounted on the upper surface of the feed tray as seen in FIGS. 8 and 8A. The wiper has a bar 91 which extends transversely across the tray adjacent the entrance to the nip area. The bar has a master substrate engaging surface provided by a pad 87 of felt or resilient or soft material such as felt, soft plastics, fabric or rubber, which lightly engages the master as it passes between the wiper and the tray surface. The wiper serves several functions and cleans, smooths and guides the master as it enters the nip between the rollers. A particularly important function of the wiper is to tension the master substrate keeping it flat and aligned with the laminate and adhesive webs resulting in better alignment especially when feeding sheets intermittently. The wiper has an arm 89 which is upwardly biased by spring 88. Arm 89 is pivotally attached to the edge of the tray at fulcrum 93 so that the wiper is pressed into light engagement with the material passing beneath the pad 87. The wiper bar 91 may be lifted to facilitate loading a master by manually depressing the outer end of the arm 89 against the force of spring 88. Preferably the pad is replaceable as required.

Referring to FIGS. 6 and 7, a blade 90 having a cutting edge extends transversely adjacent the discharge opening. The blade is movable vertically upward from a non-actuated position to a cutting position by means of lever 95 to which the blade 90 is attached. Lever 95 is pivotally secured to the interior of the housing side wall at pivot rod 96. Downward movement of the lever at handle 97 will move the blade 90 upward into engagement with anvil bar 98 which is fixed and extends transversely. Preferably, the blade 90 is mounted on a carrier 99 by means of pins 102 having compression springs 104 thereon which bias the blade toward the cutting bar. Thus, when the cutting action occurs, the flat surface of the blade moves along the anvil which provides a self-cleaning action. The upper end of panel 22A is slightly curved at 106 as seen in FIG. 8 to facilitate smooth discharge of the item being processed. The area indicated by the numeral 106 may be coated with a suitable low-frictional material such as that sold under the trademark "Teflon".

A primary advantage of the present invention is that In the illustrated embodiment, various substrates may be provided to the user in a self-contained, ready-to-use cartridge which allows the user simply to select and insert the appropriate cartridge. As indicated above, the device of the present invention illustrated can be used for multiple purposes for adhesive transfer and lamination. Adhesive can be transferred to either surface of the master and may be a dry adhesive. The cartridge is generally designated by the numeral 150 and includes a frame having opposite side walls 152, 154, a top 156, and bottom 158. A front wall 160 defines a substantial rectangular opening 162. As shown, the cartridge includes an upper feed roll 165 and a lower feed roll 166 each containing a web of film or other flexible substrate material. A significant advantage of the present invention is that In the illustrated embodiment, the upper and lower feed rolls are provided to the user pre-wound and properly tensioned so as not to overrun during operation and to provide proper tracking. The proper tensioning of the feed rolls is accomplished by means of a tensioning device as best seen in FIGS. 3, 4 and 5.

In FIGS. 3, 4 and 5, which figures are representative of the construction of the both ends of both feed rolls, the substrate material is shown wound about the feed roll core 200. The core 200 is a cylinder of cardboard or plastic having an end face 210. Core 200 has a hollow interior 212 which receives an end cap 215. The cap may be molded of plastic or other similar material having an interior outer wall 216. A boss 220 is concentrically formed in the cap with respect to the cylinder wall 216. Boss 220 defines an axial bore 225. The cap 215 is positioned slightly inwardly of the end of the core and may be adhesively secured to the interior wall 212 of the roll core 200.

A circular end plate 230 abuts the end of the core which plate has a diameter slightly greater than the diameter of the core. The end plate has a central aperture 240 which receives the threaded shaft of bolt 246. A spring 250 is interposed between the head of the bolt and the interior face of the cap 215. Nut 252 engages the threaded end of the bolt. The head of the bolt 246 bears against the exposed surface of the end plate 230 and the position of the nut along the shaft of the bolt determines the frictional resistance that exists between the interior surface of the end plate 230 and the end face of the core of the roller. This tension is pre-adjusted by the manufacturer to provide the proper roll tension depending upon the type of material on the roll, the size of the material, the thickness of the material and other factors. Mounting tabs 260 and 260A project outwardly from the end plate and are slidingly engageable in mounting slots 270, 270A and 272, 272A provided on the interior surfaces of the cartridge side walls.

Thus, it will be seen that inserting a supply of suitable feed substrate is easily accomplished. The user simply selects the appropriate cartridge 150 and positions the cartridge in the opening at the front side of the housing. The cartridge is locked in place in the housing in a vertical position by locking detent members 280. The feed rolls may be various types of stock such as clear laminates, paper or film for removing excessive adhesive or rolls of material having a loose adhesive coating and a release coating on the opposite surface. The feed tray 80 is inserted in a generally horizontal position in the opposite slots in the cartridge.

As mentioned above, the device may be used as a lamination device or as an adhesive transfer device. In the case of use as an adhesive transfer device, the lower feed roll which consists of a film carrying an easily transferable adhesive. The upper feed roll would typically be a web of flexible carrier material having release characteristics on a lower surface and adhesive coating on the other surface. With rolls of this type in position, the end of the web of the lower feed roll is extended over the lower nip roller. The upper feed roll, in the case of adhesive transfer, will consist of a web of material such as inexpensive paper or film, having an affinity for adhesive. The end of the web is extended between the nip rollers with the end of the web adhesively secured to the web of the master in the lower roll.

Referring to FIGS. 11 to 15, the master which is designated by the numeral 300 consists of a continuous sheet of material having an upper surface and a lower surface. The upper surface carries labels 310 which have been pre-printed. Obviously, the master can be any pre-printed document or series of documents which can be generated by the user, as for example on a computer. The labels 310 can be of varying size and shape and it is understood that the term "labels" as used herein is intended to be representative of printed materials of various types arranged on a flexible substrate.

The master is aligned on the feed tray with the leading free edge of the master positioned on the exposed adhesive surface of the lower feed stock material. 166 at the nip roller interface. The slight forward protrusion of the lower nip roller 48 facilitates securing the master at this location. The web 165 of the upper feed roller is fed from the cartridge to the nip roller interface on the upper side of master 300.

The operator then actuates the machine by operating the crank which will rotate the upper nip roller and by means of the inter-engaging pinion gears, cause rotation of the lower nip roller. The rotation will also advance the upper web, the lower web and the master. The master is smoothed, guided and wiped clean as it passes between the wiper 86 and the upper surface of the tray. As the master proceeds between the nip rollers in the interface nip area, the exposed adhesive 325 from the lower web will be transferred to the lower surface of the master 300. The upper web 165 will pick up any excessive adhesive not transferred to the master, as for example adhesive in the areas outside the perimeter of the label areas 310. The upper web should be wider than the adhesive web. The master may then be easily severed into individual labels or strips of labels by operating the cutter by means of the lever as the master emerges from the discharge opening at the rear of the machine.

Note that the master can be oriented with either printing or indicia facing upwardly or downwardly depending on the user's requirements.

For example, if the user is making labels which are to be applied to the inside of a window, the master would, in most cases, be fed into the applicator with the printing disposed downwardly so adhesive would be applied over the printed area 310. The apparatus can apply lamination to either top or bottom surfaces of a substrate or adhesive to the top or bottom surfaces of a substrate or to both surfaces. The device can also perform combination operations in applying of both the laminate and an adhesive to a substrate, the operation being determined by the selection of the cartridge and feed rolls within the cartridge that are inserted into the apparatus.

The characteristics of the lower web are such that the adhesive is a nonaggression adhesive loosely adhered to the surface of the web. Thus, the lower web serves as a peelable cover which can be stripped away at the time the master is to be used by adhesively applying the master to a surface.

One significant advantage of the present invention is that In the illustrated embodiment, the upper and lower feed rolls may be provided to the user pre-wound and properly tensioned so as not to overrun during operation. The proper tensioning is pre-set by the tensioning device described above.

In FIGS. 8 and 12, a wiper assembly 86 is shown mounted at the upper surface of the feed tray which operates to clean the master and apply pressure to the master as it enters the nip area. In FIGS. 15 and 16, an alternate form of wiper assembly, the master substrate engaging structure termed a "paddle", is shown which is generally designated by the numeral 400. Referring to FIG. 16 in which the same numerals identify the same or similar elements appearing in previous drawing FIGS., the nip rollers 40 and 48 are shown and material from the upper and lower feed rolls, respectively 165 and 166, is directed across idler rollers 402 and 404 to the interface between the nip rollers.

A master "M" to which a laminating or adhesive transfer operation is to be applied is fed along the tray 80 as indicated by the arrows in FIGS. 16 and 17. The paddle 400 is associated with tray 80 spaced from the rollers 40 and 48. The tray 80, as has been explained previously, has a generally planar master substrate supporting surface 82 on which a master "M" to be processed is placed. The surface 80 of the tray is disposed a slight vertical distance, about {fraction (1/16)}", above the plane of the material 166 as it enters into the area between the feed rollers. This is illustrated by the space "S" in FIG. 16. This space allows the master "M" to be properly oriented and aligned before it is picked up by the material 166 from feed roll 166.

The paddle 400 is disposed above the tray and serves to flatten and attach the master to the material 166 and also cleans the master prior to processing such as an application of laminates. The paddle has a generally planar platen 410 which is formed having a vertical wall 412 and opposite side walls 416 and 418. The paddle may be any suitable size, and typically may be approximately 25" in width. The opposite side walls 416 and 418 are each provided with openings 420 and 422. The openings each extend vertically at 424 and 425 and have a rearwardly inclined upper cam surface 426. A generally lower arcuate region 430 is provided at the forward end of the cam surface at an arcuate surface 432 at the rearward end of the cam surface. The upper surface forms a cam surface which rides on detent members 440 and 442 which are pins or rollers that are fixed to the opposite side walls 452 and 454 of the tray 80.

Thus, it will be seen that by manually moving the paddle 400 forward toward the nip rollers, the paddle will be displaced downwardly as the cam surfaces 426 move along the associated detents 440 and 442. In the forward position, the paddle rests on the master "M" which is positioned on the surface 82 of the tray 80. The paddle applies a gentle downward pressure and/or applies a predetermined resistance or tension to the master as it passes beneath the paddle. Typically, for a paddle having a width of about 25", the weight of the paddle will be between 1 and 4 pounds.

By manually moving the paddle in the direction away from the nip rollers, the paddle will be elevated away from the surface of the master. FIG. 16 shows the paddle in the position in which it engages the master.

As indicated above, the purpose of the paddle is to apply light pressure to flatten the master and attach the master to the web and also to clean the master. The paddle also applies a controlled back tension to avoid wrinkling. Accordingly, the lower master substrate engaging surface of the platen 410 is specially fabricated to have characteristics to best perform these operations. As seen in FIG. 18, the leading position of the platen in the area generally designated by the numeral 460 is treated with an elastomer which has non-stick characteristics. A typical material would be silicon rubber. Thus, when the bottom surface of the platen 460 is in contact with the master, this area of the base plate will tend to force the master into contact with the web from the feed roll 166 and against roller 404. Again, it is noted that the surface of tray 82 is slightly above the plane of the material 166 as it passes over the idler roller and into the nip area.

The portion of the surface of the base plate indicated by the numeral 462 has characteristics to provide a slight resistance to the master as it moves or is advanced towards the nip area. The purpose of the resistance is to slightly flatten and tension the material to overcome any curl. Also, this area provides a cleaning and wiping action to the master removing lint, dust and particulates. The slight tension also helps to flatten materials that may have a slight curl remaining due to be provided in a rolled condition. Accordingly, the surface of the paddle in this area is treated with a suitable material such as the material manufactured and sold under the trademark Ultrawipe™. The areas 460 and 462 preferably extend the entire width of the platen.

While the paddle has been described with respect to the adhesive transfer apparatus of the present invention, such as that designated by the numeral 10, the paddle 400 has wide application to various apparatus and methods for processing substrates in which the substrate is required to be properly oriented, flat and clean at the time of processing.

While the principles of the invention have been made clear in the illustrative embodiments set forth above, it will be obvious to those skilled in the art to make various modifications to the structure, arrangement, proportion, elements, materials and components used in the practice of the invention. To the extent these various modifications do not depart from the spirit and scope of the appended claims, they are intended to be encompassed therein.

Claims

1. A paddle for a master substrate processing apparatus in which for processing a master substrate is fed into a nip roll area to be processed , said paddle comprising:

(a) a tray disposed adjacent said nip area having a generally planar tray surface for receiving a master;

(b) a paddle having a platen surface disposed above said tray;

(c) means for moving said paddle between a first position elevated above said tray and a second position disposed against said tray; and

(d) said platen surface having a first area having characteristics of non-stick and a second area for applying a predetermined resistance to a master in contact with the platen surface

a first supply roll comprising a wound supply of a first stock material carrying a layer of adhesive;

a second supply roll comprising a wound supply of a second stock material;

a master substrate processing assembly having structure constructed and arranged to process said master substrate and said unwound portions of said stock materials during advancement thereof in a feeding direction through said processing assembly to affect adhesive bonding between said master substrate and said adhesive;

structure providing a master substrate supporting surface adjacent a feed site of said master processing assembly to support the master substrate thereon as the master substrate is being fed into said master substrate processing assembly; and

a master substrate engaging structure extending generally transversely across said master substrate supporting surface, said master substrate engaging structure having a master substrate engaging surface that engages the master substrate while supported on said master substrate supporting surface so as to apply frictional resistance to advancement of the master substrate in said feeding direction thereby tension the master substrate.

2. The paddle of A master substrate processing apparatus according to claim 1 12, wherein said tray master substrate supporting surface is disposed a predetermined distance above the interface of the nip roll area rollers.

3. The paddle of A master substrate processing apparatus according to claim 1 31, further comprising a frame and wherein said structure providing said master substrate supporting surface is a feed tray mounted to said frame and said tray has opposite side walls defining a cam surface which surfaces are in engagement with fixed detents whereby the tray may be manually moved between said first and second positions providing said camming members.

4. The paddle of The master substrate processing apparatus according to claim 1 35, wherein said first area is treated with an elastomeric material and said second area is treated with a nonwoven fabric material.

5. The paddle of A master substrate processing apparatus according to claim 1 in which , wherein said master substrate processing apparatus is an adhesive transfer apparatus.

6. The paddle of A master substrate processing apparatus according to claim 1 in which , wherein said master substrate processing apparatus is a laminating apparatus.

7. The paddle of A master substrate processing apparatus according to claim 4 wherein said elastomeric material is silicon rubber.

8. A master substrate processing apparatus according to claim 1, wherein said structure of said master substrate processing assembly comprises a plurality of cooperating structures constructed and arranged to (a) advance said master substrate with unwound portions of said first and second stock materials on opposing sides thereof in a feeding direction through said master substrate processing assembly and (b) apply pressure to said master substrate and said unwound portions of said stock materials to affect said adhesive bonding between said master substrate and said adhesive.

9. A master substrate processing according to claim 8, wherein said master substrate engaging structure is movable between (a) a first position wherein said master engaging surface engages the master substrate while supported on said master substrate supporting surface so as to apply said frictional resistance to advancement of the master substrate and (b) a second position wherein said master substrate engaging surface is moved away from said master supporting surface so as to be disengaged from the master substrate.

10. A master substrate processing apparatus according to claim 9, wherein said cooperating structures include a pair of pressure applying and substrate advancing structures constructed and arranged to both (a) apply said pressure to the master substrate and the unwound portions of the stock materials and (b) advance the master substrate and the stock materials through said master processing assembly.

11. A master substrate processing apparatus according to claim 10, wherein said pressure applying and advancing structures include a rotatable nip roller.

12. A master substrate processing apparatus according to claim 10, wherein said pressure applying and advancing structures include a pair of rotatable nip rollers.

13. A master substrate processing apparatus according to claim 12, further comprising an actuator constructed and arranged such that operation thereof affects nip roller rotation.

14. A master substrate processing apparatus according to claim 13, wherein said actuator is a manually operated crank.

15. A master substrate processing apparatus according to claim 13, wherein said actuator is an electrically powered motor.

16. A master substrate processing apparatus according to claim 1, wherein said adhesive is a pressure-sensitive adhesive and wherein said master substrate processing assembly affects said adhesive bonding without the use of heat transfer.

17. A master substrate processing apparatus according to claim 1, wherein said second stock material carries a layer of adhesive.

18. A master substrate processing apparatus according to claim 1, wherein said first and second stock materials are laminating films.

19. A master substrate processing apparatus according to claim 18, wherein said laminating films are transparent.

20. A master substrate processing apparatus according to claim 9, further comprising a biasing element biasing said master substrate engaging structure to said first position thereof.

21. A master substrate processing apparatus according to claim 20, wherein said biasing element is a spring.

22. A master substrate processing apparatus according to claim 21, wherein said spring is a coil spring.

23. A master substrate processing apparatus according to claim 9, wherein said master substrate engaging structure is pivotally movable between said first and second positions thereof.

24. A master substrate processing apparatus according to claim 23, further comprising a biasing element biasing said master substrate engaging structure to said first position thereof.

25. A master substrate processing apparatus according to claim 24, wherein said biasing element is a spring.

26. A master substrate processing apparatus according to claim 25, wherein said spring is a coil spring.

27. A master substrate processing apparatus according to claim 9, further comprising a frame and wherein said structure providing said master substrate supporting surface is a feed tray mounted to said frame.

28. A master substrate processing apparatus according to claim 27, wherein said feed tray is removably mounted to said frame.

29. A master substrate processing apparatus according to claim 27, wherein said master substrate engaging structure is movably mounted to said tray for movement between said first and second positions thereof.

30. A master substrate processing apparatus according to claim 29, wherein said master substrate engaging structure is pivotally mounted to said tray for movement between said first and second positions thereof.

31. A master substrate processing apparatus according to claim 9, wherein said master substrate engaging structure has a pad formed from a material selected from the group consisting of felt, soft plastic, fabric, and rubber, said pad providing said master substrate engaging surface.

32. A master substrate processing apparatus according to claim 9, wherein manual movement of said master substrate engaging structure in said feeding direction and opposite said feeding direction causes said master substrate engaging structure to move between said first and second positions thereof.

33. A master substrate processing apparatus according to claim 32, further comprising a frame and wherein said master substrate engaging structure provides camming surfaces and wherein said frame has camming members engaging said camming surfaces, said camming members and said camming surfaces being configured such that during movement of said master substrate engaging structure opposite the feeding direction said camming members cam against said camming surfaces to move said master substrate engaging structure upwardly away from said master substrate supporting surface to said second position thereof.

34. A master substrate processing apparatus according to claim 33, wherein said camming surfaces provide first and second detents in which said camming members are received when said master substrate engaging structure is in said first and second positions thereof, respectively.

35. A master substrate processing apparatus according to claim 32, wherein said master substrate engaging surface has first area of non-stick material and a second area for providing resistance to movement of the master.

36. A master substrate processing apparatus according to claim 9, further comprising a frame and wherein said first and second supply rolls are each removably mounted to said frame for removal and replacement thereof.

37. A master substrate processing apparatus according to claim 36, further comprising a cartridge having a cartridge body structure removably mounted to said frame, said first and second supply rolls being mounted to said cartridge body structure such that said cartridge body structure removably mounts both said first and second supply rolls to said frame for removal and replacement thereof.

38. A master substrate processing apparatus for processing a master substrate, said apparatus comprising:

a first supply roll comprising a wound supply of a first stock material carrying a layer of adhesive;

a second supply roll comprising a wound supply of a second stock material;

a pair of nip rollers constructed and arranged to advance the master substrate and unwound portions of the first and second stock materials in a feeding direction and apply pressure to the master and first and second stock materials to affect adhesive bonding between said master substrate and said adhesive;

structure providing a master substrate supporting surface positioned to support the master substrate thereon as the master substrate is being advanced into said nip rollers; and

a master substrate engaging structure extending generally traversely across said master substrate supporting surface, said master substrate engaging structure having a master substrate engaging surface that engages the master substrate while supported on said master supporting surface so as to apply frictional resistance to advancement of the master substrate in said feeding direction to thereby tension the master substrate.

39. A master substrate processing apparatus according to claim 38, wherein said master substrate engaging structure is movable between (a) a first position wherein said master engaging surface engages the master substrate while supported on said master substrate supporting surface so as to apply said frictional resistance to advancement of the master substrate and (b) a second position wherein said master substrate engaging surface is moved away from said master supporting surface so as to be disengaged from the master substrate.

40. A master substrate processing apparatus according to claim 38, further comprising an actuator constructed and arranged such that operation thereof affects nip roller rotation.

41. A master substrate processing apparatus according to claim 40, wherein said actuator is a manually operated crank.

42. A master substrate processing apparatus according to claim 40, wherein said actuator is an electrically powered motor.

43. A master substrate processing apparatus according to claim 38, wherein said adhesive is a pressure-sensitive adhesive and wherein said nip rollers apply pressure to affect said adhesive bonding without the use of heat transfer.

44. A master substrate processing apparatus according to claim 38, wherein said second stock material carries a layer of adhesive.

45. A master substrate processing apparatus according to claim 38, wherein said first and second stock materials are laminating films.

46. A master substrate processing apparatus according to claim 45, wherein said laminating films are transparent.

47. A master substrate processing apparatus according to claim 39, further comprising a biasing element biasing said master substrate engaging structure to said first position thereof.

48. A master substrate processing apparatus according to claim 47, wherein said biasing element is a spring.

49. A master substrate processing apparatus according to claim 45, wherein said spring is a coil spring.

50. A master substrate processing apparatus according to claim 39, wherein said master substrate engaging structure is pivotally movable between said first and second positions thereof.

51. A master substrate processing apparatus according to claim 50, further comprising a biasing element biasing said master substrate engaging structure to said first position thereof.

52. A master substrate processing apparatus according to claim 51, wherein said biasing element is a spring.

53. A master substrate processing apparatus according to claim 52, wherein said spring is a coil spring.

54. A master substrate processing apparatus according to claim 39, further comprising a frame and wherein said structure providing said master substrate supporting surface is a feed tray mounted to said frame.

55. A master substrate processing apparatus according to claim 54, wherein said feed tray is removably mounted to said frame.

56. A master substrate processing apparatus according to claim 54, wherein said master substrate engaging structure is movably mounted to said tray for movement between said first and second positions thereof.

57. A master substrate processing apparatus according to claim 56, wherein said master substrate engaging structure is pivotally mounted to said tray for movement between said first and second positions thereof.

58. A master substrate processing apparatus, according to claim 39, wherein said master substrate engaging structure has a pad formed from a material selected from the group consisting of felt, soft plastic, fabric, and rubber, said pad providing said master substrate engaging surface.

59. A master substrate processing apparatus according to claim 39, wherein manual movement of said master substrate engaging structure in said feeding direction and opposite said feeding direction causes said master substrate engaging structure to move between said first and second positions thereof.

60. A master substrate processing apparatus according to claim 59, further comprising a frame and wherein said master substrate engaging structure provides camming surfaces and wherein said frame has camming members engaging said camming surfaces, said camming members and said camming surfaces being configured such that during movement of said master substrate engaging structure opposite the feeding direction said camming members cam against said camming surfaces to move said master substrate engaging structure upwardly away from said master substrate supporting surface to said second position thereof.

61. A master substrate processing apparatus according to claim 60, wherein said camming surfaces provide first and second detents in which said camming members are received when said master substrate engaging structure is in said first and second positions thereof, respectively.

62. A master substrate processing apparatus according to claim 59, wherein said master substrate engaging surface has first area of non-stick material and a second area for providing resistance to movement of the master.

63. A master substrate processing apparatus according to claim 39, further comprising a frame and wherein said first and second supply rolls are each removably mounted to said frame for removal and replacement thereof.

64. A master substrate processing apparatus according to claim 63, further comprising a cartridge having a cartridge body structure removably mounted to said frame, said first and second supply rolls being mounted to said cartridge body structure such that said cartridge body structure removably mounts both said first and second supply rolls to said frame for removal and replacement thereof.