This application is based upon and claims the benefit of priority from Japanese Patent Application No. 2009-150042, filed Jun. 24, 2009; the entire contents of which are incorporated herein by reference.
Embodiments described herein relate generally to a booklet page turning apparatus which is mounted in, e.g., a booklet issuing machine to automatically turn the pages of a booklet, a booklet page turning method, and an ID printing apparatus.
In financial agencies and the like, automated teller machines that handle banknotes are installed, and transactions can automatically be recorded in booklets.
The booklet recording unit includes a page turning apparatus for turning pages. The page turning apparatus turns and finds a page of a booklet to be printed.
Booklets are not always inserted in a normal state with the front cover up, and may be inserted in various states. For example, a booklet may be inserted in an inverted state with its back cover up.
In this case, conventionally, the machine needs to
(1) temporarily feed the inserted booklet back to the booklet insertion unit and return it to the user so that he/she can reverse the booklet and insert it again with the front cover up, or
(2) solely repeat the operation of turning the inner sheets of the booklet until reaching the page on the front cover side.
However, the method (1) is troublesome for the user, and the method (2) requires a longer process time as the number of pages of the booklet increases.
To solve these problems, a booklet reversing apparatus is provided adjacent to the turning apparatus. The booklet is sent to the booklet reversing apparatus and reversed to make the front cover face up. The reversed booklet is sent to the turning apparatus to perform the turning operation from the front cover side.
The reversing apparatus comprises, for example, a holding plate configured to hold the fed booklet. A rotation mechanism rotates the holding plate by 180° to reverse the booklet.
However, since this method needs the extra reversing apparatus for reversing the booklet, the apparatus becomes bulky.
To solve this problem, an apparatus has been developed, which opens the back cover of a booklet inserted in a back cover face-up state, and then lifts the pages on the front cover side together with the front cover and closes them at once, thereby making the front cover side face up.
Some recent booklets have pages with high flexural rigidity as a part of adding values. For example, there are a booklet that includes an ID page with a security protection layer to prevent forgery and alteration of personal information, and a booklet that has a plastic sheet-like page incorporating an IC chip to allow high-density recording. There also exists a booklet that has a wireless IC chip so as to enable noncontact information read/write. Some of these booklets impart a radio shielding function to the front and back covers to protect recorded information against unauthorized read/write. A booklet of this type is read- and write-accessible only when the front cover is open.
In the apparatus that lifts the pages on the front cover side of a booklet together with the front cover and closes them at once, the pages to be closed at once are lifted while being sandwiched almost at the central portion by a pair of feed rollers. If the booklet is soft with low flexural rigidity, the pages can be bent and lifted. However, if the booklet is hard with high flexural rigidity, the pages cannot be lifted. If the pages are forced up, the booklet may break.
In general, according to one embodiment, a control device (40) which controls to, after the feed device (2a-2d) has fed the booklet (T) so as to bring the page on the other surface side of the booklet (T) into contact with the contact roller unit (21a) and fold the page on the other surface side, feed the booklet to the page turning position (5) again.
Hereinafter An embodiment of the present invention will now be described in detail with reference to the accompanying drawing.
Reference numeral 3 in
Contact feed mechanisms 20A and 20B are disposed above the feed rollers 2b and 2c, respectively. A page lift detection sensor 19 which optically detects a page sucked and lifted by vacuum pads 10a to be described later is provided above the page turning position 5. A page number detection sensor 24 which detects the page number of a turned page is provided near the contact feed mechanism 20B. The above-described detection sensors 4a and 4d, page lift detection sensor 19, and page number detection sensor 24 are connected to a control unit 40 serving as a control device via signal circuits, as shown in
The contact feed mechanism 20A comprises pinch rollers 21a serving as a contact roller unit. The pinch rollers 21a are attached to a shaft 6, as shown in
A support bracket 7 rotatably supports the shaft 6. One end of the shaft 6 projects outward from the support bracket 7. The projecting portion of the shaft 6 is connected to a pinch roller driving motor 9 (shown in
A guide member 20a configured to guide feed of the booklet T is integrally attached to the support bracket 7. The support bracket 7 is supported by a parallel link mechanism 23a. A parallel link driving motor 25 (shown in
Note that the contact feed mechanism 20B has the same structure as the above-described contact feed mechanism 20A. More specifically, the contact feed mechanism 20B comprises a guide member 20b, pinch rollers (contact roller units) 21b, impellers 22b, and parallel link mechanism 23b. The contact feed mechanism 20B moves the guide member 20b, pinch rollers 21b, and impellers 22b between the feed position in vicinity of the feed roller 2c and the standby position off to the upper right of the feed position.
A turning suction mechanism 10 serving as a page turning device is provided at the above-described page turning position 5.
The turning suction mechanism 10 will be explained below with reference to
The turning suction mechanism 10 comprises upper and lower vacuum pads 10a and 10b which are arranged on the upper and lower sides of the feed path 3. The lower vacuum pads 10b are attached with the suction ports being up so as to oppose the lower surface of the booklet T fed right above. The upper vacuum pads 10a are attached to a support carriage 15.
A pump 12 is connected to the vacuum pads 10a and 10b via a negative pressure supply circuit 11. The negative pressure supply circuit 11 comprises a filter 14 which separates dust from air sucked by a negative pressure, a control valve 13 which switches the negative pressure, and branch pipes 31a to 31c.
When the control valve 13 is opened, a negative pressure is generated in the vacuum pads 10a and 10b to suck the booklet T. A suction force W [N] of the vacuum pads 10a and 10b is given by W=0.1×P×A/S
P: vacuum pressure (gauge pressure) [−kPa]
A: vacuum pad area [cm2]
S: safety factor
Bent surfaces 15A and 15B bent at a right angle are formed at the front and rear portions of the support carriage 15. Guide rings 15a and 15b are provided at the upper and lower portions of each of the bent surfaces 15A and 15B.
Guide plates 16 are disposed outside the bent surfaces 15A and 15B of the support carriage 15. Cam grooves 16a and 16b are formed at the upper and lower portions of each of the guide plates 16. The guide rings 15a and 15b of the bent surfaces 15A and 15B of the support carriage 15 fit in the cam grooves 16a and 16b of the guide plates 16, respectively.
The lower guide rings 15a of the bent surfaces 15A and 15B of the support carriage 15 fit in groove portions 17a of driving link plates 17 serving as a driving device. The driving link plates 17 are connected to a driving shaft 17c. The driving shaft 17c spans between the guide plates 16. A hand knob 26a is attached to one end of the driving shaft 17c. A driving link plate driving motor 29 is connected to the other end via a driving pulley 27 and a driving belt 28.
The shafts of the upper guide rings 15b of the bent surfaces 15A and 15B of the support carriage 15 are connected to hook portions 18a of the guide plates 16 via springs 18 to elastically bias the support carriage 15 upward.
When the driving link plate driving motor 29 is driven, the driving shaft 17c is rotated via the driving belt 28 and the driving pulley 27, and the driving link plates 17 pivot in the forward and backward directions (horizontal direction). Along with the pivotal motion, the guide rings 15a and 15b are guided via the two cam grooves 16a and 16b of each guide plate 16 so as to move the support carriage 15.
Note that in the initial state before the support carriage 15 moves, the driving link plates 17 stand at 12 o'clock, and the vacuum pads 10a supported by the support carriage 15 stand by at the upper standby position.
M1 indicates the binding position of the booklet T at the page turning start position; M2, the binding position of the booklet T at the reverse page turning start position; Pn, a central position of the guide ring 15a; and Qn, a central position of the guide ring 15b.
The position and orientation of the support carriage 15 are decided by two points corresponding to the central positions Pn and Qn of the guide rings 15a and 15b. The vacuum pads 10a move together with the support carriage 15. More specifically, the cam grooves 16a and 16b of each guide plate 16 are formed to be bilaterally symmetrical and draw arcs with M1 at the center between P1 and P2 and between Q1 and Q2, respectively. Hence, the vacuum pads 10a move about M1 between P1 and P2 and between Q1 and Q2. This movement matches a turning operation using the binding portion of the uppermost page of the booklet T at the center of rotation.
In reverse page turning, the vacuum pads 10a move about M2 in a direction reverse to that in the above-described page turning. This movement matches a reverse turning operation using the binding portion of the uppermost page of the booklet T at the center of rotation.
Note that the cam groove 16a has, between P0 and P2, an arc which smoothly connects curves formed by symmetrically extending the curve between P1 and P2. However, the cam groove 16b is formed, between Q0 and Q2, to linearly run upward in the direction of the axis of symmetry of the cam groove 16b.
Hence, the support carriage 15 decreases its tilt angle as it moves upward. When the central positions of the guide rings 15a and 15b reach P0 and Q0, the support carriage 15 returns to the upright state to locate the vacuum pads 10a at the upper standby position (initial position).
At this time, the driving link plates 17 stand at 12 o'clock, as shown in
Note that the binding position of the actual booklet T may sometimes shift from the position M1 or M2 because of the thickness of the booklet T, the manner the booklet T is bound, a high rigidity page arranged in the booklet T, or variations in the page turning start position caused by the feed operation. In the operation of lifting the uppermost page of the booklet T, the locus of the vacuum pads 10a is not ideal but shifted. However, this poses no serious problem because the lift angle is smaller than 45°, and a play allows to balance between the booklet T and the vacuum pads 10a and 10b. The play is ensured by elastic deformation of the vacuum pads 10a and 10b and elastic deformation of the booklet T near the binding portion.
The above-described detection sensors 4a to 4d, page lift detection sensor 19, and page number detection sensor 24 are connected to the control unit 40 serving as a control device via signal circuits. The driving motors 9, 25, 26, and 29 for the above-described pinch rollers, parallel links, feed rollers, and driving links, the control valve 13, and an arm driving motor 43 to be described later are connected to the control unit 40 via control circuits.
The control unit 40 controls driving the driving motors 9, 25, 26, and 29 and the control valve 13, thereby controlling the operations of the pinch rollers 21a and 21b, impellers 22a and 22b, parallel link mechanisms 23a and 23b, feed rollers 2a to 2d, driving link plates 17, vacuum pads 10a and 10b, and lifting arm 42 to be described later.
The page turning operation of the booklet T will be described next with reference to
As the feed roller 2a rotates in the direction of the arrow, the booklet T is fed to the right side along the feed path 3. Upon this feed, when the booklet T is fed up to the detection sensor 4b and detected, the control unit 40 rotates the pinch rollers 21a and the impellers 22a in the direction of the arrow and also operates the parallel link mechanism 23a. When the parallel link mechanism 23a operates, the movable guide 20a moves from the standby position to the feed position together with the pinch rollers 21a and the impellers 22a, as shown in
Meanwhile, the control valve 13 is operated to generate a negative pressure in the vacuum pads 10a and 10b so that the lower vacuum pads 10b suck and hold the lower surface of the booklet T. At this time, the driving link plate driving motor 29 is operated to make the driving arm plates 17 pivot clockwise so that the upper vacuum pads 10a come into contact with an uppermost page (front cover) Ta of the booklet T and suck it. After suction, the driving arm plates 17 pivot in the reverse direction (counterclockwise) and move upward along the loci of the cam grooves 16a and 16b of the guide plates 16 while the vacuum pads 10a keep sucking the uppermost page Ta. With this operation, the uppermost page Ta of the booklet T is lifted using a binding portion Tb of the booklet T as the center of rotation without changing the suction state to the vacuum pads 10a. The uppermost page Ta of the booklet T is lifted about the binding portion Tb of the booklet T without receiving any bending deformation force at all. Hence, the rigidity of the page does not influence the turning operation.
When the uppermost page Ta of the booklet T moves upward up to a predetermined position, the page lift detection sensor 19 detects it. Based on the detection, the control unit 90 moves the movable guide 20b from the standby position to the feed position together with the pinch rollers 21b and the impellers 22b, as shown in
After that, the control unit 40 closes the control valve 13 and stops suction of the vacuum pads 10a. Next, the driving link plates 17 return to 12 o'clock, and the vacuum pads 10a return to the upper standby position, as shown in
At this time, the driving link plates 17 in the initial state pivot counterclockwise to move the vacuum pads 10a so that they retreat from the turnover operation range of the uppermost page Ta of the booklet T, as shown in
Note that during the feeding, the page number detection sensor 24 scans the page number printed on the opened page Ta of the booklet T. The scan information is sent to the control unit 40. The control unit 40 determines based on the received scan information whether the turning operation has been performed as programmed. Upon determining that the turning operation has not been performed as programmed, the turning operation is redone.
Upon determining that the turning operation has been performed as programmed, the booklet T is fed to the post process and processed. After the process, the booklet T is fed backward and returned to the page turning position 5, as shown in
The booklet T is formed from, e.g., the front cover Ta, inner sheets Tc, and a back cover Td, as shown in
The above-described page turning apparatus 1 includes a lifting mechanism 41 serving as a lifting device, as shown in
The lifting mechanism 41 comprises the lifting arm 42. The proximal portion of the lifting arm 42 is connected to the arm driving motor 43 (shown in
The lifting arm 42 is designed to pivot by a predetermined angle (e.g., about 0° to 60°) in the vertical direction as the arm driving motor 43 rotates in the forward and backward directions. This pivotal motion moves the distal end portion 42a of the lifting arm 42 between the lower position (standby position) and the upper position. The distal end portion 42a can come into contact with the front cover side of the booklet T at the standby position and lift the pages at once.
A detection target piece 42b projects from the proximal portion of the lifting arm 42. First and second arm position detection sensors 45a and 45b are disposed near the detection target piece 42b along the pivoting direction. The first and second arm position detection sensors 45a and 45b are connected to the control unit 40, as shown in
When the distal end portion 42a of the lifting arm 42 reaches the lower position (standby position), the first arm position detection sensor 45a detects the detection target piece 42b, and the driving of the arm driving motor 43 stops. When the distal end portion 42a of the lifting arm 42 reaches the upper position, the second arm position detection sensor 45b detects the detection target piece 42b, and the driving of the arm driving motor 43 stops.
The contact feed mechanism 20A includes a first guide plate 46a serving as a first guide unit configured to receive the pages on the front cover side of the booklet T which are lifted by the lifting arm 42 and then drop off from the lifting arm 42, as will be described later. The support carriage 15 of the vacuum pads 10a includes a second guide plate 47a serving as a second guide unit configured to receive the pages on the front cover side of the booklet T which are folded, as will be described later. The first and second guide plates 46a and 47a are made of a metal or resin material not to damage the pages of the booklet T.
The booklet T is inserted and fed to the page turning position 5 in various states.
For example, the booklet T is inserted in a state (normal state) with the binding portion Tb facing left and the front cover Ta facing up, as shown in
When the booklet T is inserted, as shown in
The booklet T is inserted and fed in a closed state, as shown in
The plurality of vacuum pads 10a and 10b hold a relation given by
Σspfp<ΣSqFq
s and S: the distances between the axis of the lifting operation and the vacuum pads
f and F: the suction forces of the vacuum pads Note that the lowercase letters indicate upper vacuum pads, and the uppercase letters indicate lower vacuum pads.
The upper vacuum pads exist from 1 to p, and the lower vacuum pads exist from 1 to q.
With this relation, when the upper vacuum pads 10a and the lower vacuum pads 10b pull against each other, the upper vacuum pads 10a always release the booklet T.
In this case, the control unit 40 determines that the binding portion Tb of the inserted booklet T is located on the right side. Hence, a right turning operation is performed, as shown in
After the reading, the booklet T is fed to locate the pages on the side of the front cover Ta at the page turning position 5, as shown in
Upon this feed, the binding portion Tb of the booklet T passes between the feed roller 2c and the pinch rollers 21b, and the pages on the side of the front cover Ta of the booklet T are lifted upward at once about the binding portion Tb, as shown in
Upon the release, the pages on the side of the front cover Ta of the booklet T lose the support and drop, come into contact with the first guide plate 46a so as to be held by it. At this time, the second arm position detection sensor 45b detects the detection target piece 42b of the lifting arm 42, and the upward pivotal motion of the lifting arm 42 stops.
From this state, the booklet T is further fed to the left side, as indicated by the arrow in
The folded booklet T is further fed in the direction of the arrow, as shown in
The booklet T thus folded has the same state as the normally inserted state shown in
As described above, according to the first embodiment, if the booklet T is inserted and fed to the page turning position 5 in the back cover face-up state, the back cover Td of the booklet T is opened. After that, the lifting arm 42 lifts the pages on the side of the front cover Ta at once about the binding portion Tb and folds the pages.
It is therefore possible to lift and fold the pages at once even in a booklet having a page with high flexural rigidity as a part of adding values, for example, a booklet that includes an ID page with a security protection layer to prevent forgery and alteration of personal information, a booklet that has a plastic sheet-like page incorporating an IC chip to allow high-density recording, or a booklet that has a wireless IC chip so as to enable noncontact information read/write, not to mention a soft booklet T.
Note that the same reference numerals as in the above-described first embodiment denote the same parts, and a detailed description thereof will not be repeated.
In the above-described first embodiment, only one lifting arm 42 is provided. In the second embodiment, in addition to a first lifting arm 42, a second lifting arm 52 is disposed to be symmetric with respect to the first lifting arm 42 about a page turning position 5. The second lifting arm 52 has the same structure as the first lifting arm 42, and a detailed description thereof will not be repeated.
According to the second embodiment, a booklet T inserted in the back cover face-up state is lifted and closed by the first lifting arm 42a so that page turning processing can be performed from the front cover side, as in the first embodiment. In addition, when the booklet T is inserted in the normal state, the pages on the side of a back cover Td are lifted and folded at once to enable page turning from the back cover side.
The operation of folding the pages on the side of the back cover Td of the booklet T inserted in the normal state will be explained next.
When the booklet T is closed, inserted, and fed in the normal state, as shown in
From this state, the booklet T is further fed to the right side, as indicated by the arrow in
The booklet T is then further fed to the right side as indicated by the arrow in
The folded booklet T is further fed to the right side, as shown in
The booklet T thus folded has the same state as that of the booklet T inserted in the back cover face-up state shown in
In the second embodiment as well, it is possible to lift and fold the pages at once even in a hard booklet, not to mention a soft booklet, as in the first embodiment.
Note that
More specifically, when the booklet T is inserted, as shown in
More specifically, when the booklet T is inserted, as shown in
According to the above-described method, normal turning processing can automatically end regardless of the inserted state of the booklet T.
Note that the same reference numerals as in the above-described second embodiment denote the same parts, and a detailed description thereof will not be repeated.
In the above-described second embodiment, the first and second lifting arms 42 and 52 are provided. In the third embodiment, a lifting cam 62 serving as a lifting device is provided between feed rollers 2b and 2c in place of the lifting arms 42 and 52. The lifting cam 62 is made to pivot about a rotating shaft 62a in the forward and backward directions by a pulse motor. Its rotation amount can arbitrarily be changed by pulse control of the pulse motor.
As the lifting cam 62, a metal or resin member that produces little friction and reduces the contact resistance is adopted to prevent damage to a booklet T. A pair of sensors 63a and 63b configured to detect the position of the lifting cam 62 is disposed near the lifting cam 62. The pair of sensors 63a and 63b detect the pivot amount of the lifting cam 62 for positioning control.
A case will be described next with reference to
After the lifting, pinch rollers 21a and a guide plate 67a move under the lifted pages on the front cover side, as shown in
A case will be described next with reference to
The ID printing apparatus 101 comprises a booklet insertion unit 104. A plurality of closed booklets T are stacked and set in the booklet insertion unit 104 and inserted one by one. The inserted booklet T is fed along a feed path 3 by a plurality of pairs of feed rollers 2. A first wireless IC R/W (Reader/Writer) unit 105, page turning apparatus 1, direct printing unit 107, intermediate transfer printing unit 108, OCR reading unit 109, booklet folding unit 114, and second wireless IC R/W unit 110 are disposed in the feed path 3 along the feed direction of the booklet T.
A discharge gate 111 configured to switch the discharge direction of the booklet T between a first direction and a second direction is provided on the discharge end side of the feed path 3. A normal booklet collection unit 112 which collects normal booklets T is arranged in the first direction. A defective booklet collection unit 113 which collects defective booklets is arranged in the second direction.
The above-described booklet insertion unit 104 can insert a plurality of booklets T in the stacked state. In accordance with an instruction from the control unit, a picker (not shown) extracts only the lowermost booklet and inserts it toward the first wireless IC R/W unit 105.
The first wireless IC R/W unit 105 reads, by wireless communication, booklet-specific ID information and control information which are recorded in the wireless IC incorporated in the booklet T.
The page turning apparatus 1 has a function of turning the front cover of the booklet T inserted from the booklet insertion unit 104 and also turning the inner sheets, as described above. A turned page is recognized by causing a bar mark reader to read a bar mark printed on the booklet T from the first.
The direct printing unit 107 presses an ink ribbon 107b and a thermal head 107a in this order against a print page surface of the booklet T to print. The thermal head 107a generates heat to print an image or characters. In this embodiment, the direct printing unit 107 prints information of lower security level than that of information to be printed by the intermediate transfer printing unit 108.
Note that not all pages of the booklet T are printed by the direct printing unit 107. In addition, the pages to be printed by the direct printing unit 107 are different from those to be printed by the intermediate transfer printing unit 108. For this reason, when printing of the direct printing unit 107 has occurred, the page turning apparatus 1 turns the page to be printed, and direct printing is performed first. Then, the booklet T is fed to the page turning apparatus 1 again to turn the page to be subjected to intermediate transfer printing. If there exists no information to be printed by the direct printing unit 107, the booklet T passes through the direct printing unit 107.
Referring to
The printing apparatus 101 includes an apparatus control unit 158. A direct print image processing unit 167, intermediate transfer image processing unit 168, heater temperature control unit 160, booklet feed control unit 161, image formation control unit 162, and wireless IC control units 169 and 173 are connected to the apparatus control unit 158 via control circuits.
A head control unit 163 configured to control the print operation of the thermal head 107a is connected to the above-described direct print image processing unit 167. A head control unit 164 configured to control the print operation of a thermal head 119 is connected to the intermediate transfer image processing unit 168.
A heater 165 of a heat roller 135 shown in
A transfer ribbon feed mechanism 132a, a backup roller elevating mechanism 119a which elevates a backup roller 136 shown in
The wireless IC R/W units 105 and 110 are connected to the wireless IC control units 169 and 173, respectively.
The print operation of the ID printing apparatus 101 having the above-described arrangement will be explained next.
The booklets T are extracted from the booklet insertion unit 104 shown in
The printing apparatus control unit 158 also receives holder's color face image data acquired by the image input unit 156 and holder's security character information input via the operation panel 155. Print data is generated based on the holder's color face image data, holder's security character information, booklet-specific information, and control information data sent to the printing apparatus control unit 158. The intermediate transfer image processing unit 168 operates the thermal head 119 to print the holder's face image on the surface of an intermediate transfer film 121 by color printing based on the print data by overprinting four color inks, i.e., three primary color inks of Y (yellow), M (magenta), and C (cyan) and black ink. The overprinting of the plurality of color inks is done by reciprocally moving the thermal head 119 on the intermediate transfer film 121 as many times as the number of color inks. The information to be printed is an inverted image. Note that the print color inks may include a functional ink such as an ink containing a fluorescent pigment in addition to the above-described four color inks.
After the color printing of the holder's face image, the thermal head 119 prints the security information added with the booklet-specific information on the surface of the intermediate transfer film 121.
The intermediate transfer film 121 on which the color face image and the security information added with the booklet-specific information are thus printed is wound in the forward direction (the direction of the heat roller 135).
At this time, the booklet T is inserted with the transfer page open and fed to a predetermined position with respect to the heat roller 135. The transfer page can be either the front cover flyleaf or any, other inner page.
The intermediate transfer film 121 and the page of interest of the booklet T, which are positioned to each other in the above-described way, are overlaid and fed as the metal heat roller 135 with a partially cutout circumference rotates, and simultaneously pressed and heated. After that, the transfer film base is pulled up at an angle of 60° to 110° with respect to the booklet T. Transfer of the specific print information, image receiving and adhesion layer, and hologram layer is completed so that the security information containing the transferred specific information and formed from numbers, characters, symbols, barcode, and the like and the holder's color face image area are transferred. The booklet T that has undergone the transfer is fed to the OCR reading unit 109 while keeping the page open.
The OCR reading unit 109 reads the booklet-specific information and security information. The read booklet-specific information and security information are recognized, and the recognition result is sent to the printing apparatus control unit 158. The printing apparatus control unit 158 collates the data and sends the determination result to the booklet feed control unit 161.
Upon determining based on the data collation result that the booklet is defective, the printing apparatus control unit 158 notifies the data input control unit 151 and the wireless IC control unit 173 that the created booklet is defective.
Upon receiving the notification representing that the created booklet is defective, the data input control unit 151 sends the same print processing instruction to the printing apparatus control unit 158 again to automatically re-create the booklet.
The booklet T which has passed through the OCR reading unit 109 is fed to the booklet folding unit 114, folded, and then fed to the wireless IC R/W unit 110. If the booklet is defective, the wireless IC R/W unit 110 records, on the wireless IC of the booklet T, data representing that the booklet is defective.
On the other hand, if the collation result of the data read by the OCR reading unit 109 is correct, data to be recorded on the wireless IC is generated based on the print data generated by the printing apparatus control unit 158, and sent to the wireless IC control unit 173. Based on this sending, the wireless IC R/W unit 110 records (writes) the security information added with the booklet-specific information on the wireless IC of the booklet T.
The discharge gate 111 operates to discharge normal booklets T for which the wireless IC R/W unit 110 has recorded the information on the wireless IC to the normal booklet collection unit 112, and defective booklets to the defective booklet collection unit 113 so as to collect the booklets.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel methods and systems described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the methods and systems described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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2009-150042 | Jun 2009 | JP | national |