WO1999055531A1 - Apparatus for automated printing and assembly of passport booklets - Google Patents

Abstract

An apparatus (10) is operative for automatically producing identification booklets (300), such as passports, from a two-part thermoplastic security media. The apparatus (10) prints, die-cuts and fuses the security media to form the booklets (300). The security media consists of an opaque thermoplastic backing film (302) which is bound directly into the binder of the booklet to form a page of the booklet and a transparent thermoplastic cover film (312) which receives a thermally printed digital image including a photograph and printed identification information. The apparatus (10) consists of a thermal printing apparatus (12) for printing the digital image onto the cover film (312), a die-cutting assembly (22) for die-cutting a predetermined size patch from the cover film (312), a transport assembly (24) for transporting the patch of cover film (312) into facing relation with the backing material (302) in the booklet (300) and a fusing or laminating assembly (28) for fusing the patch of cover film (312) to the backing film (302).

Description

APPARATUS FOR AUTOMATED PRINTING AND ASSEMBLY OF PASSPORT BOOKLETS

Background of the Invention The present invention relates to automated apparatus for printing and assembling secure travel documents, such as passport booklets, and more particularly to an automated system for instant, one-up custom printing, die- cutting and fusion of security media for an identification page in a passport booklet.

Traditional identification booklets, such as passport booklets, typically comprise a number of paper pages bound inside a cover which is heavier than the inside pages. At point of issuance assembly locations, identification information is manually typed or printed onto the inside of the cover of the booklet and a photographic insert is laminated to the inside cover. The photographic insert typically comprises a die-cut sheet of photographic film bearing a photograph of the passport holder. The insert is combined with the holder's personal information typed or printed on the cover to form a means of identification. A laminate sheet is placed over the inside cover and then the whole assembly fed into a roll laminator, wherein the photographic image is sealed between the laminate and the inside cover of the booklet. In most cases, multiple photographs are exposed on a single sheet of photographic film in order to reduce waste of the expensive photographic material, and thereby reduce the per booklet cost of production. In other assembly systems, a plurality of booklet holder's photographs are taken in 35mm format, and then combined with the corresponding booklets at central issuance centers. Central issuance of identification booklets has been found to be efficient as well as cost effective.

However, both of the current systems for producing passports is still labor intensive and slow, often resulting in delays in receiving booklets, as well as the potential to incorrectly match personal information with the correct photograph. Furthermore, the central issuance system discourages the production of cards in small batches, as well as the custom production of individual booklets when replacements are necessary. While the above technologies are effective for their intended purpose, it has been found that there is an increasing need in the industry for an automated system which automatically prints and die-cuts identification materials and assembles them inside an identification booklet in an instant, one- up format, wherein a single identification booklet can be easily and inexpensively produced, with very little labor involved, in a single apparatus.

Summary of the Invention

The present invention provides a system for the automated production of identification booklets, such as passports, comprising a two-part thermoplastic security media and apparatus for printing, die-cutting and fusing of the security media into the booklets. The security media comprises an opaque thermoplastic backing film which is bound directly into the binder of the booklet. The backing film essentially forms a page in the booklet. The security media further comprises a transparent thermoplastic cover film which acts as a receptor for receiving a thermally printed digital image including a photograph and printed identification information. More specifically, the backing film preferably comprises a white amorphous copolyester film, while the cover film preferably comprises a clear polyvinyl chloride film. The apparatus consists of a thermal printing apparatus for printing the digital image onto the cover film, die-cutting means for die-cutting a predetermined size patch from the cover film, means for transporting the patch into contact with the backing film within the booklet and means for fusing the patch to the backing film. The cover film is provided in continuous roll format for printing. The thermal printing apparatus is based on a digital imaging system wherein a digital portrait of the booklet holder is combined by custom computer software with a background, booklet holder signature and alphanumeric text to produce a complete digital full-color image. A thermal web printer is operative for printing the color image onto an inner surface of the cover film adjacent a terminal end of the cover film web. The computer software automatically mirrors the card image so that it appears in its correct orientation when viewed through the top of the cover film. The thermal web printer preferably comprises a thermal dye-transfer printer apparatus having a reverse print direction for printing from a midpoint of the web toward a terminal end thereof. The printed terminal end of the cover film is advanced through a guide to a cutting station where it is clamped and the printed patch is severed from the web. The patch is die-cut to include rounded corners on one edge to match the rounded corners of the booklet into which it will be inserted. A transport assembly thereafter transports the patch into contact with the backing film of the booklet, which is held in place below the transport assembly. Once the patch is brought into contact with the backing film, the transport assembly pushes the booklet, including the patch, into a laminating station including a heated input roller pair for initial laminating of the backing film and cover film. The laminating station further includes a heated platen for heat-fusing the laminated films together and a pair of exit nips for removing the booklet from the laminating station. The end result of the process is a custom printed passport booklet which is produced in a minimal amount of time.

Brief Description of the Drawing Figures

In the drawings which illustrate the best mode presently contemplated for carrying out the present invention: Fig. 1 is a perspective view of the apparatus of the instant invention;

Fig. 2 is a cross-sectional view thereof as taken along line 2-2 of Fig. 1;

Figs. 3-7 are front views of the apparatus with selected portions removed to show operation of the apparatus;

Fig. 8 is a right side perspective view of the die- cut station of the apparatus;

Fig. 9 is a left side perspective view of the die-cut station of the apparatus;

Fig. 10 is a left front perspective view of the laminating station of the apparatus;

Fig, 11 is a right rear perspective view of the laminating station; Fig. 12 is a left front perspective view of the booklet drawer system;

Fig. 13 is a right rear perspective view of the booklet drawer system;

Fig. 14 is a right front perspective view of the transport station; and

Fig. 15 is a cross-sectional view of the die of the apparatus of the present invention, showing the type of cut made by the die. Detailed Description of the Preferred Embodiments

Referring now to the drawings, the apparatus of the present invention is illustrated and generally indicated at 10 in Figs. 1-7. As will hereinafter be more fully described, the present apparatus 10 is operative for the automated production of a passport booklet from a two-part security media. The security media preferably comprises a proprietary media developed by Minnesota Mining and Manufacturing Company of St. Paul, Minnesota, comprising a thermoplastic cover film that receives a thermally printed, computer generated digital image, and further comprising an opaque thermoplastic backing film. The specific properties of the cover film and backing film are set forth in commonly-owned U.S. Patent No.5, 637, 174, the disclosure of which is herein incorporated by reference in its entirety. In the present invention, the backing film is bound into a booklet, thereby forming one of the pages of the booklet. In the preferred embodiment as described herein, the booklet is a passport, whereby the backing film is glued or sewn into the binder of the passport booklet as the first interior page of the passport.

The printer 12 shown in Fig. 1 is a thermal web printer of the type disclosed in commonly-owned U.S. Patent No.5, 565, 902, the disclosure of which is herein incorporated by reference in its entirety. The printer 12 prints the identification information and image on the inner surface of the cover film, preferably in a reverse printing direction, i.e. the printing is done from a midpoint of the web to a terminal end. This reverse printing method ensures that little or no media is wasted at the terminal ends due to leader loss as found in conventional forward-driven printing methods. 7

Referring now to Fig. 2, the overall configuration of the apparatus will be described. For simplicity, thermal printer 12 and pedestal 14 are not shown in Fig. 2. After the cover film is printed in printer 12, the terminal end of the cover film is guided to a die-cutting station 22 by lower and upper media guides 16 and 18, wherein the printed patch of the cover film web is to be cut to a predetermined size. Die-cutting station 22 is described in detail below with reference to Figs. 8 and 9. A transport station 24 receives the terminal end of the cover film, clamps it in place for cutting in die-cutting station 22, and then transports the severed patch into a booklet drawer system 26, which holds a booklet in place with the booklet held open to allow the patch to be inserted into the booklet in contact with the backing film bound in the booklet. Transport station 26 is described in detail below with reference to Fig. 14 and drawer system 26 is described in detail below with reference to Figs. 12 and 13. Once the patch is received in the booklet, the booklet is inserted into laminating station 28, where the patch and the backing film are fused together within the booklet. Laminating station 28 is described in detail below with reference to Figs. 2, 10 and 11. After the patch is fused to the backing film in laminating station 28, the booklet is ejected from laminating station 28 and is retrieved via exit chute 30 of pedestal 14 (Fig. 1) .

Referring now to Figs. 8 and 9, the die-cutting station 22 will be described. Die-cutting station 22 includes lower media guide 16 and upper media guide 18. A splice sensor 32 optically determines when a splice in the cover film web is present, as when two rolls of cover film have been spliced together. When a splice is present, the spliced portion of the cover film is advanced by the printer 12 through die-cutting station 22, 50 that the splice can be cut out by the die 62, described below, and ejected from the apparatus. Die-cutting station 22 includes brackets 34a and 34b which are mounted together by a beam 36. Brackets 34a and 34b mount the die-cutting station 22 to the apparatus 10 through bolt opening 35 in bracket 34a and a similar bolt opening (not shown) in bracket 34b. A DC motor 38 is mounted to bracket 34a by bolts 40a and 40b. DC motor 38 includes a drive shaft 42 on which a drive gear 44 is mounted and held in place by locking device 46. Drive gear 44 meshes with and drives a secondary gear 48 which is mounted on a camshaft 50. Secondary gear 48 is cooperatively mounted to a two position cam 52, including detents 54a and 54b. Also mounted on camshaft 50 are die-actuating cams 60a and 60b. Die 62 is mounted in a die holder 64, which rides on columns 65a and 65b, which are mounted on brace 66, having a slot 66a, through which die 62 passes and through which scrap pieces punched from the cover film by die 62 also pass. Brace 66 is mounted between brackets 34a and 34b. Die holder 64 is biased in an upward position against stops 70a and 70b, which are mounted to beam 36 by springs which are in turn mounted around each of columns 65a and 65b between die holder 64 and brace 66. One of the springs is indicated by reference numeral 68 in Fig. 2. Die holder 64 includes cam followers 72a and 72b, which are in direct contact with die-actuating cams 60a and 60b. A die position sensor 56 includes a mechanical sensor 58 which rides along the outer surface of two position cam 52 and mechanically senses the position of the die 62 by engaging detents 54a and 54b. A clamp-actuating bar 74, including fingers 76a and 76b is mounted to die holder 64. The operation of two position cam 52, die position sensor 56 and clamp-actuating bar 74 is described below.

Transport station 24 will now be described with reference to Figs. 2 and 14. Transport station 24 includes a vertical slide carriage 78 having bores 80a and 80b for receiving vertical slide rails 82a and 82b. Vertical slide rails 82a and 82b are mounted between a base 84 and a truss 86. A DC motor 88 is mounted to truss 86 via a plate 90. Motor 88 drives includes a drive shaft (not shown) on which a one stop cam 92 including a detent 92a is mounted. A vertical slide carriage position switch 93 is mounted to plate 90 and includes a mechanical sensor 95 which is biased to maintain contact with the outer surface of one- stop cam 92 and to engage detent 92a. Mechanical sensor 95 is in an open position when engaged with detent 92a and is in a closed position when the transport is moving and mechanical sensor 95 is biased against the outer surface of one-stop cam 92. Linkage system 94 comprises a primary link 96 which is mounted at one end 96a on the drive shaft of motor 88 and which is rotatably mounted at a distal end 96b to a secondary link 98 at one end 98a thereof by a mounting device 102a. Distal end 98b of secondary link 98 is rotatably mounted to vertical slide carriage 78 at a center bore 100 thereof by a mounting device 102b. Ends 98a and 98b of link 98 may be mounted to link 96 and carriage 78 with any of a number of mounting devices known in the art, which will allow the ends 98a and 98b to rotate about the mounting devices 102a and 102b. Transport station 24 further includes a tilt tray 104 which is rotatably mounted on a shaft 106 which in turn is mounted to vertical slide carriage 78. Tilt tray 104 is 10

biased in the horizontal position shown in Fig. 14 by a spring 108. A blade 110 is adjustably mounted to the top surface of tilt tray 104 via bolts Ilia and 111b, and includes a main body portion 110a and two extensions 110b and 110c disposed at either end of main body portion 110a. A clamping device 112 is mounted on tilt tray 104 and includes a pair of mounting shafts 113a and 113b, which hold clamp bar 114 in place. Springs 116a and 116b, which are mounted on shafts 112a and 112b, respectively, bias clamp bar 114 downwardly, against blade 110. A tilt tray actuator shaft 118, having a beveled top end 118a, is mounted to base 84 in such a way to enable the shaft 118 to be adjusted vertically. Preferably, shaft 118 includes a threaded end (not shown) which is threaded into base 84. The vertical positioning of shaft 118 is adjusted by threading the shaft 118 into base 84 to lower shaft 118 and by threading shaft 118 out from base 84 to raise shaft 118. Once the shaft 118 is at the desired height, a lock nut 120 is tightened against base 84 to prevent shaft 118 from turning. The adjustability of the height of shaft 118 enables the tilt tray 104 and blade 110 to be adjusted in order to keep blade 110 horizontal. A set screw 122 is threaded into tilt tray 104, which enables the tilt tray 104 to be adjusted in order to keep tilt tray 104 perpendicular with respect to vertical slide carriage 78. A bottom portion 122a of set screw 122 abuts with the top end 118a of shaft 118, 50 that when set screw 122 is threaded into tilt tray 104, tilt tray 104 is pivotally raised, and when set screw 122 is threaded out of tilt tray 104, tilt tray 104 is pivotally lowered.

Drawer system 26 will now be described with reference to Figs. 2, 12 and 13. Drawer system 26 includes a drawer 11

130 and a drawer retaining device 132. Drawer 130 includes a front plate 134 having a handle 136, left drawer rail 138 and right drawer rail 140. Front plate 134 is attached to left drawer rail 138 and right drawer rail 140 by bolts 142a and 142b. Left booklet slide 144 is mounted to left drawer rail 138 and includes a clip 146 which is slidably attached thereto. Right booklet slide 148 is mounted to right drawer rail 140 and includes a clip 150 slidably attached thereto. Drawer retaining device 132 includes left rail retainer 152, including left runner 152a, and right rail retainer 154, including right runner 154a. Left drawer rail 138 is received by left runner 152a and right drawer rail 140 is received by right runner 154a. Left rail retainer 152 includes mounting holes 139a and 139b for mounting left rail retainer 152 to wall 200 of apparatus 10 and right rail retainer 154 includes mounting holes 141a and 141b for mounting right rail retainer 154 to wall 200 of apparatus 10. Left rail retainer 152 and right rail retainer 154 are each coupled to frame 156. A top booklet guide 158 is coupled to frame 156 by bolts

162a and 162b, and includes a magnetic lock device 160 for maintaining drawer 130 in the closed position by magnetically engaging front plate 134, a left top booklet guide 164 and a right top booklet guide 166. Left top booklet guide 164 includes a tab 165 which is inserted into a slot 167 in left rail retainer 152. A scrap slide 170 is coupled to right rail retainer 154 and includes a shelf 172 which holds scrap tray 174. An adjustable backstop 176 is slidably mounted to left rail retainer 152 by bolts 178a and 178b, which mount adjustable backstop 176 to left rail retainer 152 via slots 180a and 180b, respectively. Bolts 178a and 178b may be slid back and 12

forth in slots 180a and 180b to adjust the depth of the drawer retaining device 132, thereby allowing different size booklets to be used. A booklet position sensor 182 is mounted on adjustable backstop 176 and includes a mechanical sensor which determines whether a booklet is fully inserted in drawer retainer 132 against adjustable backstop 176.

Laminating station 28 will now be described with reference to Figs. 2, 10 and 11. Laminating station 28 includes a series of nips and rollers that advance the booklet and identification card into a heat source and then out from the heat source. A first roller stage comprises nips 220a and 220b which are mounted on rollers 222a and 222b, respectively, and each include a one-way clutch mechanism which only allows the nips to rotate toward the center of the laminating station in order to pull the booklet from the drawer system 26 and into a second roller stage, which comprises a heated roller 224a and a cooperating guide roller 224b. A third roller stage comprises exit rollers 226a and 226b. Laminating station also includes heating plate 228a and a cooperating guide plate 228b and exit guides 230a and 230b for guiding the finished product from laminating station 28 via exit slot 232. In a preferred embodiment, heating plate 228a is coated with a non-stick material, to prevent the cover or backing films from sticking to it as the booklets are heated. Rollers 222a, 224a and 226a and heating plate 228a are fixedly mounted within laminating station 28, while rollers 222b, 224b and 226b are rotatably mounted within laminating station 28 by a floating linkage which will be described in detail below. Guide plate 228b is also floatably. mounted within laminating station 28 and is 13

biased against heating plate 228a by spring 234 which is mounted to wall 236 of laminating station 28.

An AC gear motor 202 drives driveshaft 204 having a pulley 206 mounted thereon. A belt 208 is mounted between pulley 206 and a drive gear 210. Drive gear 210 directly drives exit roller 226a and includes an internal gear (not shown) which drives idler gear 212. Idler gear 212 drives second roller stage gear 214, which directly drives heated roller 224a. Second roller stage gear 214 also drives primary drive transfer gear 216a, which drives drive transfer shaft 238, which drives secondary drive transfer gear 216b on the front of laminating station 28. Primary drive transfer gear 216a also drives first roller stage gear 218, which drives roller 222a, and consequently, nip 220a. Secondary drive transfer gear 216b drives idler gear 240, which drives first stage roller gear 242, which drives roller 222b, and consequently, nip 220b. Idler gear 240 also drives second stage roller gear 244, which drives guide roller 224b. Second stage roller gear 244 drives idler gear 246, which drives third stage roller gear 248, which drives exit roller 226b.

As discussed above, rollers 222b, 224b and 226b are mounted within laminating station 28 by means of a floating linkage. The floating linkage comprises link 250 which connects the non-geared ends of rollers 222b and

224b, and a link 252 which connects the non-geared ends of rollers 224b and 226b. Rollers 222b, 224b and 226b are mounted in slots 254a, 254b and 254c, respectively, which allow rollers 222b, 224b and 226b to float toward and away from fixed rollers 222a, 224a and 226a, respectively. In a similar manner, the geared ends of rollers 222b, 224b and 226b are mounted through slots in the front wall 259 of 14

laminating station 28 and are interconnected by means of a floating linkage. The geared ends of rollers 222b and 224b are interconnected by a link 260a, and the geared ends of rollers 224b and 226b are interconnected by a link 261. Furthermore, the end of drive transfer shaft 238 on which drive transfer gear 216b is mounted is interconnected to the shaft (not shown) on which idler gear 240 is mounted by a link 260b, which is formed integrally with link 260a. Pressure adjustment spring systems 262a and 262b comprise rods 264a and 264b and springs 268a and 268b, respectively. Rods 264a and 264b are coupled to link 250 through slots 266a and 266b, respectively.

Pressure adjustment spring systems 269a and 269b comprise rods 270a and 270b and springs 272a and 272b, respectively. Rods 270a and 270b are coupled to link 252 through slots 274a and a second slot in link 252 (not shown) , respectively. Likewise, pressure adjustment spring systems 276a, 276b, which comprise rods 278a and 278b and springs 280a and 280b, respectively, and pressure adjustment spring systems 282a and 282b, which comprise rods 284a and 284b and springs 286a and 286b, respectively, are coupled to links 260a and 261. Pressure adjustment spring systems 262a, 262b, 269a, 269b, 276a, 276b, 282a and 282b operate to bias rollers 222b, 224b and 226b against rollers 222a, 224a and 226a, respectively.

The amount of pressure between the rollers can be adjusted by the pressure adjustment spring systems, in order to allow booklet of varying thicknesses to be used with the present invention. Laminating station 28 also comprises a switch 288 having a mechanical sensor 290 which contacts roller 222b and determines when a booklet has passed through nips 220a and 220b, by the movement of roller 222b 15

as the booklet passes through nips 220a and 220b.

The operation of the apparatus 10 will now be described with reference to Figs. 3-7 and 15. For simplicity, the top booklet guide 158, drawer front plate 134 and pedestal 14 are not shown in Figs. 3-7. As shown in Fig. 3, drawer 130 is removed from drawer retainer device 132, and a booklet 300 is inserted into drawer 130 and held against left and right booklet slides 144 and 148 by clips 146 and 150, respectively. As described above, booklet 300 includes a cover and a backing film 302 bound into the binder of booklet 300 to form a page therein. Booklet 300 also includes a plurality of paper pages 304 bound therein. Booklet 300 is inserted into drawer 130 such that backing film 302 is exposed and clipped under clip 146 of left booklet slide 144. Drawer 130 is then inserted into drawer retaining device 132, such that booklet 300 rests against backstop 176 and booklet position sensor 182. The cover film, after being printed on as described above, is advanced in the direction of arrow 310 between lower media guide 16 and upper media guide 18 into die-cutting station 22. The terminal end of the cover film is advanced to the distal edge of blade 110 of transport station 24. Motor 38 then rotates drive gear 44 which rotates secondary gear 48, turning two position cam 52, and consequently, cam shaft 50 in the counterclockwise direction, Fig. 4. Cams 60a and 60b depress cam followers 72a and 72b, driving die 62 into the cover film, thereby cutting the cover film and severing the printed patch from the cover film roll. Fig. 15 shows the type of cut performed by die 62. In Fig. 15, a cross-section of die 62 is shown, and also shows the resulting severed patch 312.- As is shown in Fig. 15, die 62 severs the 1 6

terminal end of the cover film to form a patch 312 having rounded corners on one edge 314 thereof. Patch 312 is approximately the same width and length as a page of booklet 300. Opposite edge 314, a straight edge 316 is formed on the new terminal end of the cover film. The scrap piece of cover film which is punched out by die 62 falls through slot 66a in beam 66 into scrap tray 174 via scrap slide 170. As shown in the figure, patch 312 also includes a flat edge 316. As die 62 is driven downwardly into the cover film, die holder 64 also is driven down, causing clamp-actuating bar 74 to also be driven downwardly. Consequently, fingers 76a and 76b release clamp bar 114, thereby clamping patch 312 to blade 110 of transport station 24. Mechanical sensor 58 stops motor 38 from rotating camshaft 50 when it is received in detent 54a of two position cam 52.

Motor 88 of transport station 24 then rotates cam 92 in the direction indicated by arrow 320, Fig. 5, causing link 96 to turn in the same direction, thereby pushing link 98 and, consequently vertical slide carriage 78 downward. Tilt tray actuator 118 causes tilt tray 104 to rotate 90° downward about shaft 106, as vertical slide carriage 78 and tilt tray 104 are pushed downward by link 98. Tilt tray 104 and blade 110 are held in place in the vertical orientation by maintaining contact with tilt tray actuator 118 while tilt tray 104 is driven downward. Blade 110, with patch 312 clamped thereto, is driven into the binder of booklet 300, bringing identification card 312 into contact with backing film 302 with straight edge 316 of Patch 312 being adjacent to the binder, and edge 314, with the rounded corners, being located opposite the binder. The side edges of the patch 312 are aligned with 17

the side edges of the backing film 302. Blade 110 pushes booklet along drawer booklet slides 144 and 148 into nips 220a and 220b of laminating station 28. Driven by motor 202, nips 220a and 220b receive booklet 300 from blade 110 in the area between extensions 110b and 110c, so that only booklet 300, including identification card 312, and not blade 110 is received between nips 220a and 220b. Motor 88 continues to rotate cam 92 until it makes a complete revolution and links 96 and 98 have pulled tilt tray 104 back to the horizontal position shown in Fig. 6. Motor 88 stops rotating cam 92 when sensor 93 is received in detent 92a and tilt tray 104 has returned to the horizontal position.

Booklet 300, having patch 312 in contact with backing film 302, is passed from nips 220a and 220b to heated roller 224a and roller 224b, which passes booklet 300 between heating plate 228a and guide plate 228b. Roller 224a is heated to a temperature of about 200°C, and performs an initial lamination of the patch 312 to the backing film 302, while removing air from between patch 312 and backing film 302. Heating plate 228a is heated to a temperature of about 160°C to define a full laminating stage. As the booklet is passes between rollers 224a and 224b, air bubbles are squeezed from between the patch 312 and the backing film 302 as they are initially heated by roller 224a. After the initial lamination, booklet 300 is passed between heated plate 228a and guide plate 228b, and patch 312 and backing film 302 are heated for a longer duration and are fully fused together. Rollers 226a and 226b remove booklet 300, with patch 312 and backing film 302 completely fused together, from between heated and guide plates 228a and 228b, and pass the finished product through exit slot 232, guided by exit guides 230a and 230b, Fig. 7. While booklet 300 is being laminated in laminating station 28, motor 38 of die-cutting station 22 rotates camshaft 50 in the counterclockwise direction to raise die 62, and consequently, clamp-actuating bar 74. Two position cam 52 rotates until mechanical sensor is received by detent 54b, which signals motor 38 to cease rotating camshaft 50. The cover film is then retracted by the printer 12, and the patch is printed, as described above.

Mechanical sensor 290 of switch 288 senses the movement of booklet 300 through nips 220a and 220b and notifies the operator when booklet 300 has passed through nips 220a and 220b, so that another booklet can be loaded into drawer system 26, while the next patch is printed. The above-described process is then repeated to form another passport booklet in accordance with the invention.

It can therefore be seen that the present invention provides a novel apparatus for instant, one-up printing, die-cutting and laminating of passport booklets from two- part security media. The apparatus 10 provides a thermal web printing device 12, for thermally printing a digital image onto the security media, die-cutting apparatus 22 for die-cutting a predetermined sized patch from the web, drawer apparatus 26 for holding the booklet in place, transport apparatus 24 for transporting the patch into the booklet, laminating apparatus 28 for fusing the security media together and the appropriate guide and advancing mechanisms for guiding and advancing the security media and booklet through the die-cutting, transport and laminating apparatus. The apparatus 10 is quick and efficient and therefore it provides a convenient and cost- 19

effective means for instant custom production of passport booklets. For these reasons, the present invention is believed to represent a significant advancement in the art which has substantial commercial merit. While there is shown and described herein certain specific structure embodying the invention, it will be manifest to those skilled in the art that various modifications and rearrangements of the parts may be made without departing from the spirit and scope of the underlying inventive concept. For example, while the invention is disclosed as being for producing passport booklets, any type of booklets may be produced by the present invention, including bank account booklets, visas and novelty booklets. Therefore, the underlying inventive concept is not limited to the particular forms herein shown and described except insofar as indicated by the scope of the appended claims.

Claims

20Claims

1. An apparatus for the automated assembly of an identification booklet from a two part security media comprising a backing material and a cover film, said booklet having said backing attached therein, said cover film receiving a printed image thereon, the apparatus comprising: a printer for printing indicia on said cover film; a cutting device for cutting a patch of said cover film to be attached to said backing; a transport assembly for inserting said patch into said booklet in facing relation with said backing; and a laminating assembly, said booklet passing through said laminating assembly wherein said patch and said backing are permanently fused together by heat.

2. The apparatus of claim 1 wherein said cover film comprises a continuous web of cover film, said printer printing said indicia on a terminal end portion of said continuous web of cover film, said cutting device severing said terminal end portion of said cover film to form said patch to be assembled with said booklet.

3. The apparatus of claim 2 wherein said patch is cut with a straight edge for alignment with an inner binding of the booklet, and an opposing edge with rounded corners.

4. The apparatus of claim 1 further comprising a booklet holding device for holding said booklet in an open position for receiving said patch of cover film. 21

5. The apparatus of claim 4 wherein said booklet holding apparatus holds said booklet in an open position with the backing material exposed for alignment with said cover film.

6. A method for the automated assembly of an identification booklet from a two part security media comprising a backing material and a cover film, said booklet having said backing material permanently attached therein, said cover film receiving printed indicia thereon, the method comprising the steps of: printing indicia on a terminal end portion of a continuous web of said cover film; severing the printed terminal end portion of said cover film to form a patch for assembly with said booklet; holding said booklet in an open position with said backing material exposed; inserting said patch into said booklet in facing relation with said backing material; and applying heat to said booklet with said booklet in a closed position to fuse said patch and said backing together within said booklet.

7. The method of claim 6 wherein said indicia is printed in reverse image on the side of the patch to be mated with the backing material, said indicia being visible in the correct orientation when viewed through the opposing side of the cover film. 22

8. The method of claim 6 wherein said patch is cut with a straight edge for alignment with an inner binding of the booklet, and an opposing edge with rounded corners.

9. The method of claim 6 wherein said step of inserting said patch into said booklet is accomplished using a booklet holding device to hold said booklet in an open position for receiving said patch of cover film.