Abstract:
A card manufacturing method for manufacturing the card and a card manufacturing apparatus for manufacturing the card are provided. The card  51  includes a card base  1,  a first receptor layer  1   a  arranged on one side of the card base  1  to contain a sublimation-ink image  8,  a protecting layer OC 1  laminated on the first receptor layer  1   a  and an invisible-ink image  10  formed on the protecting layer OC 1.  Owing to the interposition of the protecting layer OC 1  between the sublimation-ink image  8  and the invisible-ink image  10,  the card  51  is capable of suppressing color fading of a sublimation ink in the image  8  in spite of a card structure where the sublimation ink and an invisible ink are printed so as to overlap each other, allowing the card  51  to be used for a long time.

Description:
BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The present invention relates to a card manufacturing method for manufacturing the card and a card manufacturing apparatus for manufacturing the card. In particular, the present invention relates to a manufacturing method of a card having information printed thereon with the use of invisible ink that is not visible by visible light but fluorescent by light having a particular wavelength in order to prevent the card from being tampered or counterfeiting, and a manufacturing apparatus of the card. 
   2. Description of Related Art 
   In order to enhance the security of a card, hitherto, a variety of techniques for preventing interpolation and counterfeit of cards have been contemplated for practical use. 
   It is desired that such technologies is on a variety of cards, for instance, credit card, ID card, certificate card, etc. 
   As for a card as a personal identifier, it is often the case that the card has a facial portrait of the owner printed thereon. In this view, there is an increasing movement of adopting sublimation ink(s) suitable for photographic printing of high grade together with to a fusible ink suitable for characters in manufacturing the card. 
   As one technique of the security of a card, there is known an art of printing information (e.g. photo and data) so as to be invisible in a normal state with the use of an invisible ink that becomes visible under light having a given range of wavelength, for example, ultraviolet light although it is invisible under visible light. 
   Japanese Patent Laid-Open Publication No. 11-321166 discloses an instance of the technique of manufacturing a card with the use of both sublimation ink and invisible ink. 
   In the above publication, there is described an identification (ID) card having its security enhanced as a result of preventing the card from being tampered or counterfeiting. In detail, the ID card includes a card area having a facial portrait (image) printed with sublimation inks and inherent information printed on the card area with a fluorescent ink visible by irradiation of ultraviolet light (black light). 
   In manufacturing the card, the above publication discloses to use a sublimation transfer ribbon where sublimation dye layers in yellow (Y), magenta (M), cyan (C) and black (B) are laid on a ribbon base in this order and further, a fluorescent ink and a protecting layer are laid in succession to these sublimation dye layers. 
   SUMMARY OF THE INVENTION 
   In general, there is room for improvement in terms of the light stability of sublimation ink in comparison with fusible ink. In detail, the sublimation ink has a tendency to be discolored by its exposure to the light. Under such a situation, it has been desired to restore the color of the sublimation ink. 
   However, in case of a card where an invisible ink is overlaid on a card area having inherent information printed with sublimation inks, which is disclosed in the above publication, the sublimation inks are directly subjected to fluorescence whenever ultraviolet light is irradiated on the card in the process of confirming card&#39;s information printed with the invisible ink. 
   Therefore, there is fear that color fading of the sublimation inks is accelerated to deteriorate the printed image (e.g. facial portrait), causing a period of effective utilization of the card to be shortened disadvantageously. 
   Under such a circumstance, an object of the present invention is to provide a card which is capable of suppressing the color fading of a sublimation ink in spite of a structure where the sublimation ink and an invisible ink are printed so as to overlap each other in the same area of the card, allowing the card to be used for a long time. Further, another object of the present invention is to provide card manufacturing method and apparatus for manufacturing such a card. 
   In order to achieve the above object, there is provided a card manufacturing method for manufacturing a card with use of an intermediate transfer film in which a protecting layer and an ink receptor layer are laminated on a strip-shaped base in this order, the intermediate transfer film having a first transcriptional region and a second transcriptional region defined in common with the protecting layer and the ink receptor layer, and an ink film having respective ink areas formed on a film base successively, the ink areas having a plurality of sublimation-ink areas in different colors and an invisible-ink area, the card manufacturing method comprising: a sublimation-ink image forming process of transferring a plurality of sublimation inks in the sublimation-ink areas of the ink film to the ink receptor layer in the first transcriptional region of the intermediate transfer film in superimposition, thereby forming a sublimation-ink image in the intermediate transfer film; an invisible-ink image forming process of transferring an invisible ink in the invisible-ink area of the ink film to the ink receptor layer in the second transcriptional region of the intermediate transfer film, thereby forming an invisible-ink image in the intermediate transfer film; a first re-transfer process of re-transferring the ink receptor layer and the protecting layer in the first transcriptional region of the intermediate transfer film to a card base of the card so that the protecting layer in the first transcriptional region is arranged on a front side of the card; and a second re-transfer process of re-transferring the ink receptor layer and the protecting layer in the second transcriptional region of the intermediate transfer film onto the protecting layer in the first transfer are so that the protecting layer in the second transcriptional region is arranged on a front side of the card. 
   Further, there is also provided a card manufacturing apparatus comprising: an ink film having respective ink areas formed on a film base successively, the ink areas having a plurality of sublimation-ink areas provided with a plurality of sublimation inks in different colors and an invisible-ink area provided with an invisible ink; an intermediate transfer film in which a protecting layer and an ink receptor layer are laminated on a strip-shaped base in this order; a first detecting unit that detects the position of each of the ink areas of the ink film and outputs a first detection signal; a second detecting unit that detects a feeding position of the intermediate transfer film and outputs a second detection signal; a third detecting unit that detects a feeding position of a card base and outputs a third detection signal; a first feeding unit for feeding the ink film based on the first detection signal; a second feeding unit for feeding the intermediate transfer film based on the second detection signal; a third feeding unit for feeding the card base based on the third detection signal; a first transfer mechanism that presses the ink film against the intermediate transfer film and heats up the inks in the respective ink areas, thereby forming a transfer image in the ink receptor layer of the intermediate transfer film; second transfer mechanism that heats up the ink receptor layer having the transfer image formed therein and the protecting layer to re-transfer the ink receptor layer and the protecting layer to the card base; and a controller connected to all of the first detecting unit, the second detecting unit, the third detecting unit, the first feeding unit, the second feeding unit, the third feeding unit, the first transfer mechanism and the second transfer mechanism to control respective operations of the first transfer mechanism and the second transfer mechanism, wherein the controller controls the operation of the first transfer mechanism while controlling respective operations of the first feeding unit and the second feeding unit based on the first detection signal and the second detection signal so as to transfer the sublimation inks to the ink receptor layer in a first transcriptional region in the intermediate transfer film in superimposition thereby forming a first transfer image of the sublimation inks and further transfer the invisible ink to the ink receptor layer in a second transcriptional region in the intermediate transfer film, which is different from the first transcriptional region, thereby a second transfer image of the invisible ink; and the controller controls the operation of the second transfer mechanism while controlling respective operations of the second feeding unit and the third feeding unit based on the second detection signal and the third detection signal so as to re-transfer the ink receptor layer having the first transfer image formed therein in the first transcriptional region and the protecting layer to the card base and further re-transfer the ink receptor layer having the second transfer image formed therein in the second transcriptional region and the protecting layer onto the protecting layer in the first transcriptional region on the card base. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1A  is a schematic structural view explaining a card manufacturing apparatus in accordance with a first embodiment of the present invention; 
       FIG. 1B  is a block diagram of the card manufacturing apparatus. 
       FIG. 2  is a plan view explaining an ink film used in the card manufacturing apparatus of the first embodiment of the present invention; 
       FIG. 3  is a sectional view showing a card in accordance with the first embodiment of the present invention; 
       FIG. 4  is a sectional view showing a card of a modification of the first embodiment of the present invention; 
       FIG. 5A  is a schematic structural view explaining a card manufacturing apparatus in accordance with a second embodiment of the present invention; 
       FIG. 5B  is a block diagram of the card manufacturing apparatus. 
       FIG. 6  is a plan view explaining an ink film used in the card manufacturing apparatus of the second embodiment of the present invention; 
       FIG. 7  is a sectional view explaining an intermediate transfer film used in the card manufacturing apparatus of the second embodiment of the present invention; 
       FIG. 8  is a sectional view explaining a transfer process in the second embodiment of the present invention; 
       FIG. 9  is a sectional view showing a card in accordance with the second embodiment of the present invention; 
       FIG. 10  is a sectional view explaining a transfer process in a modification of the second embodiment of the present invention; and 
       FIG. 11  is a sectional view showing a card of the modification of the second embodiment of the present invention. 
   

   DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
   There will be below described several embodiments of the present invention with reference to  FIGS. 1A to 11 . 
   1 st . Embodiment 
   In this embodiment, using an ink film having ink layers (e.g. sublimation inks) formed in sequence, the ink is directly printed on a card base to be printed, forming a card. This printing operation is referred to as “direct printing process”. 
     FIG. 1A  is a schematic structural view of a card manufacturing apparatus  50  performing the above direct printing process.  FIG. 1B  is a schematic block diagram of the card manufacturing apparatus  50 . 
   This card manufacturing apparatus  50  comprises a card feeder (feeding unit) KH having a motor M 1  as a feeder driving source for the card base  1  and a pair of pinch rollers  2 ,  2  connected to a motor M 1  to feed the card base  1  while pinching it therebetween, a sensor (detecting unit)  7 B for detecting a feeding position of the card base  1 , an ink-film feeder (feeding unit) IFH having a pair of reels  4  for winding and rewinding a later-mentioned ink film  3  and motors M 2 , M 3  for rotating the reels  4 ,  4  respectively, a sensor (detecting unit)  7 A for detecting later-mentioned position marks PM 1  to PM 7 , which are marked on the ink film  3  in order to specify the positions of respective ink layers, in non-contact manner, a thermal head  5  for heating up the ink film  3  to sublimate the sublimation inks, a head actuator (transfer mechanism) HA for moving the thermal head  5  vertically (in  FIG. 1A ) so that the ink film  3  is pressed on the card base  1 , and a controller  6  for controlling the operation of the whole apparatus  50 . 
   In the embodiment, the card base I is provided, on one surface thereof, with a receptor layer  1   a  for receiving the sublimation inks. 
   As shown in  FIG. 2 , the ink film  3  has a strip-shaped base sheet  3   a,  sublimation-ink layers, a fusible-ink layer, protecting-ink layers and an ultraviolet-emitting-ink (invisible ink) layer all formed on one of the base sheet  3   a,  in sequence. 
   Hereinafter, these layers of the ink film  3  might be referred to as “sublimation-ink areas”, “fusible-ink area”, “first protecting-ink area” “sublimation ultraviolet-emitting-ink (invisible-ink) area” and “second protecting-ink area”, respectively. 
   In detail, a plurality of groups of layers (KM) are formed in the longitudinal direction of the ink film  3  successively. Each group of layers (KM) comprises respective sublimation-ink layers Y, M, C in yellow (Y), magenta (M) and cyan (C), a fusible-ink layer K in black, a first protecting-ink layer OC 1 , a sublimation ultraviolet-emitting-ink layer UVS and a second protecting-ink layer OC 2 , in sequence in the longitudinal direction of the ink film  3   
   The first protecting-ink layer OC 1  and the second protecting-ink layer OC 2  may be made of acrylate resin, polyester resin, polyurethane resin or the like. Further, as ultraviolet absorbents for the protecting-ink layers, there may be added organic absorbent, for example, benzophenone compound, benzotriazole compound and anilide-oxalate compound, or inorganic absorbent of metal oxide. 
   For the purpose of allowing the sensor  7 A to detect the positions of respective ink layers, the ink film  3  is also provided with a plurality of positioning marks PM 1  to PM 7  corresponding to the ink layers respectively. 
   In operation, the controller  6  controls the operation of the card feeder KH to feed the card base  1  so that a print starting position designated on the card base  1  is aligned with the thermal head  5  (cueing of the card base  1 ). 
   Based on detection signals from the sensor  7 A detecting the positioning marks PM 1  to PM 7 , the controller  6  further controls the operation of the ink-film feeder IFH so that an ink layer corresponding to a certain color to be printed in accordance with a required printing content (e.g. yellow as the first printed color) is aligned with the thermal head  5  (i.e. cueing operation of the ink layer). 
   Corresponding to the above positioning of the card base  1  and the ink film  3 , additionally, the controller  6  drives the head actuator HA to feed the card base  1  and the ink film  3  while allowing the thermal head  5  to pushing the ink film  3  onto the card base  1 . Simultaneously, the controller  6  drives the head actuator HA to heat up the thermal head  5  for sublimating or melting respective inks on the ink layers, so that a designated print image is printed on the card base  1 . 
   After that, the cueing operations of the card base  1  and an ink layer of color to be next-printed in the ink film  3  are repeated. In this way, the inks in several colors, the protecting inks and the ultraviolet emitting inks are successively printed on the card base  1 , in lamination. 
   Next, this lamination-printing (referred to as “trapping”) will be described with reference to  FIG. 3 , in detail.  FIG. 3  is a schematic sectional view showing a printing area on a card  51  of the first embodiment. 
   First, using the sublimation-ink layers Y, M, C, the printing of respective colors is applied on the card base  1 . Consequently, a sublimation-ink image  8  is formed in the receptor layer  1   a.  This image is suitable for a facial portrait since the image could be printed in full-color printing with high quality. 
   Next, the printing operation using the fusible-ink layer K in black is performed. Thus, a fusible-ink image  9  is formed on the surface of the receptor layer  1   a.  This image is suitable for characters and marks since the image could be printed in black remarkably clearly. 
   Next, the printing operation of the first protecting-ink layer OC 1  is carried out against the whole surface of the printing area including the fusible-ink image  9 . In this way, the entire printing area including the fusible-ink image  9  is covered with the first protecting-ink layer OC 1 . 
   Next, the printing operation using the ultraviolet-emitting-ink layer UVS is carried out. Thus, a designated invisible-ink image (ultraviolet emitting ink image)  10  is printed on the first protecting-ink layer OC 1 . This image is suitable for personal data (name, birthday, finger print, etc.). 
   Next, the printing operation of the second protecting-ink layer OC 2  is carried out against the whole surface of the printing area including the invisible-ink image (ultraviolet emitting ink image)  10 . 
   In this way, the card  51  is completed through the above-mentioned printing processes. 
   In the shown embodiment, an invisible-ink layer  10   s  (as one layer of the invisible-ink image  10 ) is arranged apart from the card base  1  in comparison with the receptor layer  1   a  including the sublimation-ink image  8  and additionally, the first protecting-ink layer OC 1  as one protecting layer is interposed between the sublimation-ink image  8  and the invisible-ink layer  10   s.    
   Accordingly, as the sublimation-ink image  8  does not abut on the invisible-ink image  10  (image of ultraviolet emitting ink) directly, the light intensity of fluorescence, which is radiated from the invisible-ink image  10  onto the sublimation-ink image  8  in irradiating ultraviolet light in order to make the invisible-ink image  10  visible, is reduced in diffusion by the fluorescence&#39;s transmitting through the first protecting-ink layer OC 1 , so that the color of the sublimation ink is restored to maintain the sublimation-ink image  8  in a good condition for a long period. 
   It is noted that if the ultraviolet emitting ink (fluorescent ink) makes contact with the sublimation ink, there is a possibility that the color degradation of the sublimation ink is promoted due to the cross-reaction of both inks. However, according to the embodiment, both of the ultraviolet emitting ink and the sublimation ink are separated from each other through the first protecting-ink layer OC 1 , so that the color degradation of the sublimation ink can be prevented to maintain the sublimation-ink image  8  in a good condition for a long period. 
   Moreover, if the first protecting-ink layer OC 1  is mixed with either known ultraviolet absorbent or known ultraviolet diffusing agent, it is also possible to suppress an influence of ultraviolet rays on the sublimation-ink image  8 . 
   Further, as the invisible-ink image  10  is arranged closer to the surface of the card  51  in comparison with the sublimation-ink image  8  and the fusible-ink image  9 , it is possible to make the fluorescence of the invisible-ink image  10  visible more clearly. 
   Modification of 1 st . Embodiment 
     FIG. 4  shows a card  51 A in one modification of the first embodiment. The modification differs from the first embodiment in the position of the fusible-ink image  9 . 
   We now describe the printing process for the card  51 A in detail. 
   With the use of the sublimation-ink layers Y, M, C, it is firstly performed to print respective colors of Y, M, C on the card base  1 . Consequently, a sublimation-ink image  8  is formed in the receptor layer  1   a.    
   Next, the printing operation of the first protecting-ink layer OC 1  is applied on the whole surface of the printing area including the sublimation-ink image  8 . As a result, the sublimation-ink image  8  is covered with the first protecting-ink layer OC 1 . 
   Successively, the printing operation in black is performed with the use of the fusible-ink layer K. Thus, a fusible-ink image  9  is formed on the surface of the first protecting-ink layer OC 1 . 
   Next, the printing operation is performed with the use of the ultraviolet-emitting-ink layer UVS. Thus, a designated invisible-ink image (ultraviolet emitting ink image)  10  is printed on the fusible-ink image  9  and the first protecting-ink layer OC 1  except its portions having no fusible-ink image. 
   Next, the printing operation of the second protecting-ink layer OC 2  is applied on the whole surface of the printing area including the fusible-ink image  9  covered with no invisible-ink image, the invisible-ink image (ultraviolet-emitting-ink image)  10  and the remaining the first protecting-ink layer OC 1 . 
   In this way, the card  51 A is completed through the above-mentioned printing processes. 
   In this modification also, the receptor layer  1   a  including the sublimation-ink image  8  is arranged close to the card base  1  in comparison with the layer including the invisible-ink image  10  and additionally, the first protecting-ink layer OC 1  as one protecting layer is interposed between the receptor layer  1   a  and the above layer including the invisible-ink image  10 . 
   Accordingly, as the sublimation-ink image  8  does not abut on the invisible-ink image  10  (image of ultraviolet emitting ink) directly, the light intensity of fluorescence, which is radiated from the invisible-ink image  10  onto the sublimation-ink image  8  in irradiating ultraviolet light in order to make the invisible-ink image  10  visible, is reduced in diffusion by the fluorescence&#39;s transmitting through the first protecting-ink layer OC 1 , so that the color of the sublimation ink is restored to maintain the sublimation-ink image  8  in a good condition for a long period. 
   It is noted that if the ultraviolet emitting ink (fluorescent ink) makes contact with the sublimation ink, there is a possibility that the color degradation of the sublimation ink is promoted due to the cross-reaction of both inks. However, according to the embodiment, both of the ultraviolet emitting ink and the sublimation ink are separated from each other through the first protecting-ink layer OC 1 , so that the color degradation of the sublimation ink can be prevented to maintain the sublimation-ink image  8  in a good condition for a long period. 
   Moreover, if the first protecting-ink layer OC 1  is mixed with either known ultraviolet absorbent or known ultraviolet diffusing agent, it is also possible to suppress an influence of ultraviolet rays on the sublimation-ink image  8 . 
   Further, as the invisible-ink image is arranged closer to the surface of the card in comparison with the sublimation-ink image  8  and the fusible-ink image  9 , it is possible to make the fluorescence of the invisible-ink image  10  visible more clearly. 
   2 nd . Embodiment 
   In this embodiment, using an ink film having ink layers (e.g. sublimation ink) formed in sequence, the ink in the form of an image is transferred to an intermediate transfer film having an ink receptor layer and subsequently, the so-transferred image is further transferred onto a card base to be printed, forming a card. This printing operation is called to as “re-transfer printing process”. 
   As shown in  FIGS. 5A and 5B , a card manufacturing apparatus  60  comprises a card feeder KH (as the third feeding mechanism of the invention) having a motor M 3  as a feeder driving source for a card base  1 AA and a pair of pinch rollers  2 ,  2  connected to the motor M 3  to feed the card base  1 AA while pinching it therebetween, a sensor  7 B (as the third detecting unit of the invention) for detecting a feeding position of the card base  1 AA, an ink-film feeder IFH (as the first feeding mechanism of the invention) having a pair of reels  4 ,  4  for winding and rewinding a later-mentioned ink film  33  and motors M 1 , M 2  for rotating the reels  4 ,  4  respectively, a sensor  7 A (as the first detecting unit of the invention) for detecting later-mentioned position marks PM 11  to PM 15 , which are marked on the ink film  33  in order to specify the positions of respective ink layers, in non-contact manner, a thermal head  5  for heating up the ink film  33  to sublimate the sublimation ink or melt the fusible ink, a head actuator HA (as the first transfer mechanism of the invention) for moving the thermal head  5  horizontally (in  FIG. 5A ) so that the ink film  33  is pressed on an intermediate transfer film  11  (mentioned later) between a roller  5 B and the thermal head  5 , and a controller  6  for controlling the operation of the whole apparatus  60 . 
   Further, the card manufacturing apparatus  60  includes an intermediate-transfer-film feeder TFH (as the second feeding mechanism of the invention) having a pair of reels  12 ,  12  for winding and rewinding the intermediate transfer film  11  and motors M 4 , M 5  for rotating the reels  12 ,  12 , a sensor  7 C (as the second detecting unit of the invention) for detecting positioning marks that are marked on the intermediate transfer film  11  in order to specify its transfer position, in non-contact manner, a thermal head  13  for heating up the intermediate transfer film  11  to sublimate the sublimation ink or melt the fusible ink, a head actuator HA 2  (as the second transfer mechanism of the invention) for moving the thermal head  13  vertically (in  FIG. 5A ) so that the intermediate transfer film  11  is pressed on the card  1 AA. 
   As shown in  FIG. 6  (partial plan view), the ink film  33  has a strip-shaped base sheet  33   a,  sublimation-ink layers Y, M, C, an ultraviolet-emitting-ink layer UV and a fusible-ink layer K all formed on one surface of the base sheet  33   a  in sequence. 
   Hereinafter, these layers on the ink film  33  might be referred to as “fusible-ink areas”, “sublimation ultraviolet-emitting-ink (invisible-ink) area” and “fusible-ink area”, respectively. 
   In detail, a plurality of groups (KM 2 ) of various layers are formed in the longitudinal direction of the ink film  33  repeatedly. Each of the groups (KM 2 ) comprises respective sublimation-ink layers Y, M, C in yellow (Y), magenta (M) and cyan (C), a sublimation ultraviolet-emitting-ink layer UVS and a fusible-ink layer K in black, all of which successively arranged in the longitudinal direction of the ink film  33 , in this order. 
   For the purpose of allowing the sensor  7 A to detect the positions of respective ink layers, the ink film  33  further includes positioning marks PM 11  to PM 15  corresponding to the ink layers respectively. 
   While, as shown in  FIG. 7 , the intermediate transfer film  11  includes a strip-shaped base  11   a,  a release layer  11   b  laminated on the base  11   a,  a protecting layer  11   c  on the release layer  11   b  and an ink receptor layer  11   d  on the protecting layer  11   c.    
   In these laminated layers, both the protecting layer  11   c  and the ink receptor layer  11   d  on the front side constitute a transfer layer  11   cd  of the intermediate transfer film  11 . The above release layer  11   b  is provided to facilitate a peeling of the transfer layer  11   cd.    
   For instance, the protecting layer  11   c  is made of polyurethane resin, acrylate resin, polyethylene resin or the like. 
   Based on output signals from the sensors  7 A,  7 C, the controller  6  carries out the cueing operation of the intermediate transfer film  11  (i.e. cueing of a film&#39;s unused area on which an ink is to be transferred) and the cueing operation of the ink film  33 , in detail, the cueing of a film&#39;s first ink layer (e.g. yellow) of an image to be transferred on the unused area. That is, the controller  6  drives the ink-film feeder IFH and the intermediate-transfer-film feeder TFH so that respective cueing positions of the films  11 ,  33  are aligned with the thermal head  5 . 
   In association with the positioning of the films  11 ,  33 , the controller  6  drives the head actuator HA to transfer these films  11 ,  33  while pinching them between the thermal head  5  and the roller  5 B. Simultaneously, the controller  6  heats up the thermal head  5  to sublimate inks in order to transfer a designated image on the intermediate transfer film  11 . 
   Then, this transfer operation is completed since the sublimated inks are retained in the ink receptor layer  11   d  of the intermediate transfer film  11 . 
     FIG. 8  is a schematic sectional view of the intermediate transfer film  11  after the inks have been transferred. In transferring the inks to the intermediate transfer film  11 , respective sublimation colors Y, M, C are transferred into the first transcriptional region  21  of the same area, in piles. 
   On the other hand, respective inks of both the sublimation ultraviolet-emitting-ink layer UVS and the fusible-ink layer K are transferred into a second transcriptional region  22  abutting on the first transcriptional region  21  through a regular interval, in piles. 
   Thus, as for the sublimation inks, the cueing operation of the first transcriptional region  21  and respective colors in the ink film  33  is repeated, so that respective inks in plural colors Y, M, C are transferred into the ink receptor layer  11   d  ( 11   d   1 ) of the first transcriptional region  21 . As a result, the sublimation-ink image  18  is formed in the ink receptor layer  11   d  ( 11   d   1 ). (i.e. the sublimation-ink image forming process of the invention) This image is suitable for a facial portrait since the image could be printed in full-color printing with high quality. 
   At each of the second transcriptional regions  22 , the ink in the sublimation ultraviolet-emitting-ink layer UVS is firstly transferred into the ink receptor layer  11   d  ( 11   d   2 ), forming the invisible-ink image  20  (i.e. the invisible-ink image forming process of the invention). In succession, the ink in the fusible-ink layer K is transferred onto the invisible-ink image  20 , so that the fusible-ink image  19  is laminated on the invisible-ink image  20 , in piles. 
   Accordingly, the later-transferred fusible-ink image  19  is formed on the front side of the ink receptor layer  11   d  in each second transcriptional region  22 . 
   Hereinafter, the ink receptor layer (portion)  11   d  in the first transcriptional region  21  and the ink receptor layer (portion)  11   d  in the second transcriptional region  22  are indicated with reference signs  11   d   1 ,  11   d   2 , respectively. Similarly, the protecting layer (portion)  11   c  in the first transcriptional region  21  and the protecting layer (portion)  11   c  in the second transcriptional region  22  are indicated with signs  11   c   1 ,  11   c   2 , respectively. 
   In this way, respective positions for the first and second transcriptional regions  21 ,  22  containing the ink images  18 ˜ 20  are established in the intermediate transfer film  11  previously. Further, the intermediate transfer film  11  is provided, between each first transcriptional region  21  and each second transcriptional region  22  (and between the second transcriptional region  22  and the first transcriptional region  21 ), with positioning marks PM 16 , PM  17  for specifying the transcriptional regions  21 ,  22 . These positioning marks are detected by the sensor  7 C, while the controller  6  judges the positions of the marks on the basis of the detection signals from the sensor  7 C. 
   The ink images  18 ˜ 20  transferred to the intermediate transfer film  11  in the above way are re-transferred to a card base  1 AA. 
   Based on the positional information of the card base  1 AA detected by the sensor  7 B, the controller  6  controls the operation of the card feeder KH so as to cue the re-transfer area on the card base  1 AA. 
   This cueing operation is performed so as to align a re-transfer starting position defined on the card base  1 AA with the thermal head  13  (see  FIG. 5A ). 
   Based on the detection signal from the sensor  7 C, the controller  6  further controls the operation of the intermediate-transfer-film feeder TFH so that, as a film&#39;s area to be re-transferred preferentially, the first transcriptional region  21  is selected from the first and second transcriptional regions  21 ,  22  of the intermediate transfer film  11  and additionally, the re-transfer starting position of the first transcriptional region  21  is aligned with the thermal head  13 . 
   Corresponding to the alignment of the intermediate transfer film  11  with the card base  1 AA, the controller  6  drives the head actuator HA 2  to transfer both of the intermediate transfer film  11  and the card base  1 AA while allowing the thermal head  13  to press the intermediate transfer film  11  on the card base  1 AA. Additionally, the controller  6  operates to heat up the thermal head  13  to peel the ink receptor layer  11   d   1  and the protecting layer  11   c   1  (i.e. the transfer layer  11   cd ) in the first transcriptional region  21  from the release layer  11   b  and successively transfer (re-transfer) these layers  11   d   1 ,  11   c   1  to the card base  1 AA (i.e. the first re-transfer process of the invention). 
   Consequently, the card  52  has the transfer layer  11   cd  in the first transcriptional region  21  re-transferred on the card base  1 AA while positioning the ink receptor layer  11   d   1  inside the card  52  and the protecting later  11   c   1  on the front side of the card  52 . 
   Next, it is performed to re-cue the re-transfer area on the card base  1 AA and further cue the second transcriptional region  22  of the intermediate transfer film  11 . Thereafter, as similar to the re-transferring of the first transcriptional region  21 , it is performed to peel the ink receptor layer  11   d   2  and the protecting layer  11   c   2  (i.e. the transfer layer  11   cd ) in the second transcriptional region  22  from the release layer  11   b  and successively transfer (re-transfer) these layers  11   d   2 ,  11   c   2  onto the transfer layer  11   cd  in the first transcriptional region  21  previously transferred onto the card base  1 AA (i.e. the second re-transfer process of the invention). 
   Referring to  FIG. 9 , we now describe this re-transferring operation in superimposition although there are redelivered explanations.  FIG. 9  is a schematic sectional view of the card  52  in accordance with the second embodiment of the present invention, showing the re-transfer areas transferred on the card base  1 AA that correspond to the first and second transcriptional regions  21 ,  22 . 
   First, the transfer layer  11   cd  (containing the sublimation-ink image  18 ) in the first transcriptional region  21  of the intermediate transfer film  11  is re-transferred to a designated re-transfer area on the card base  1 AA. As a result, the ink receptor layer  11   d   1  and the protecting layer  11   c   1  both forming the transfer layer  11   cd  are laminated on the card base  1 AA, in this order. 
   Next, the second transcriptional region  22  having the fusible-ink image  19  and the invisible-ink image  20  is re-transferred so as to overlap a card&#39;s portion to which the first transcriptional region  21  has been transferred previously. 
   The card  52  of the second embodiment is completed by the above-mentioned re-transfer processes. 
   According to the second embodiment of the present invention, the layer including the sublimation-ink image  18  is arranged close to the card base  1 AA in comparison with the layer including the invisible-ink image  20  and additionally, the protecting layer  11   c   1  is interposed between the former layer and the latter layer. 
   Accordingly, as the sublimation-ink image  18  does not abut on the invisible-ink image  20  (image of ultraviolet emitting ink) directly, the light intensity of fluorescence, which is radiated from the invisible-ink image  20  onto the sublimation-ink image  18  in irradiating ultraviolet light in order to make the invisible-ink image  20  visible, is reduced in diffusion since the fluorescence is transmitted through the protecting layer  11   c   1 , so that the color of the sublimation ink is restored to maintain the sublimation-ink image  18  in a good condition for a long period. 
   It is noted that if the ultraviolet emitting ink (fluorescent ink) makes contact with the sublimation ink, there is a possibility that the color degradation of the sublimation ink is accelerated due to the cross-reaction of both inks. However, according to the second embodiment, both of the ultraviolet emitting ink and the sublimation ink are separated from each other through the protecting layer  11   c   1 , so that the color degradation of the sublimation ink can be prevented to maintain the sublimation-ink image  18  in a good condition for a long period. 
   Moreover, if the protecting layer  11   c   1  is mixed with either known ultraviolet absorbent or known ultraviolet diffusing agent, it is also possible to suppress an influence of ultraviolet rays on the sublimation-ink image  18 . 
   Further, as the invisible-ink image  20  is arranged closer to the surface of the card  52  in comparison with the sublimation-ink image  18  and the fusible ink image  19 , it is possible to make the fluorescence of the invisible-ink image  20  visible more clearly. 
   Modification of 2 nd . Embodiment 
     FIG. 11  shows a card  52 A in accordance with one modification of the second embodiment. The modification differs from the second embodiment in the re-transfer position of the fusible-ink image  19  in lamination. 
   We first describe the re-transfer process for the card  52 A with reference to  FIGS. 10 and 11 . 
   First, respective ink images in the sublimation-ink layers Y, M, C are transferred from the ink film  33  ( FIG. 6 ) to a designated first transcriptional region  21  of the intermediate transfer film  11 , in piles. Consequently, as shown in  FIG. 10 , the sublimation-ink image  18  is formed in the ink receptor layer  11   d  in the first transcriptional region  21  of the intermediate transfer film  11 . 
   Similarly, an ink of the fusible-ink layer K is transferred from the ink film  33  to the first transcriptional region  21  of the intermediate transfer film  11 . As a result, the fusible-ink image  19  is formed on the front side of the ink receptor layer  11   d  in the first transcriptional region  21  of the intermediate transfer film  11 . 
   On the other hand, an ink of the ultraviolet-emitting-ink layer UVS is transferred from the ink film  33  to the ink receptor layer  11   d  in the second transcriptional region  22  adjoining the first transcriptional region  21  of the intermediate transfer film  11  through a predetermined interval. As a result, the invisible-ink image  20  is formed on the front side of the ink receptor layer  11   d  in the second transcriptional region  22 . 
   In this case also, respective positions for the first and second transcriptional regions  21 ,  22  containing the ink images  18 ˜ 20  are established in the intermediate transfer film  11  previously. Further, the intermediate transfer film  11  is provided, between the first transcriptional region  21  and the second transcriptional region  22 , with either the positioning mark PM 16  or the positioning mark PM  17  for specifying the transcriptional regions  21 ,  22 . These positioning marks PM 16 , PM 17  are detected by the sensor  7 C, while the controller  6  judges the positions of the marks on the basis of the detection signals from the sensor  7 C. 
   The ink images  18 ˜ 20  transferred to the intermediate transfer film  11  in the above way are transferred to the card base  1 AA again (i.e. re-transfer operation). 
   This re-transfer operation will be described with reference to  FIGS. 10 and 11 .  FIG. 11  is a schematic sectional view of the card  52 A in accordance with the modification of the second embodiment, showing the re-transfer areas transferred on the card base  1 AA that correspond to the first and second transcriptional regions  21 ,  22  substantially. 
   First, the transfer area  11   cd  in the first transcriptional region  21  of the intermediate transfer film  11  (containing the sublimation-ink image  18  and the fusible-ink image  19 ) is transferred to a designated re-transfer area of the card base  1 AA, as shown in  FIG. 11 . As a result, the card base  1 AA has the ink receptor layer  11   d   1  and the protecting layer  11   c   1  formed thereon and laminated in this order. 
   Here, it should be noted that the intermediate transfer film  11  had the fusible-ink images  19  positioned on the front side of the ink receptor layer  11   d   1 . Therefore, in the card  52 A, the fusible-ink images  19  are positioned on one side of the ink receptor layer  11   d   1  close to the card base  1 AA. 
   Next, the transfer layer  11   cd  in the second transcriptional region  22  containing the invisible-ink image  20  is re-transferred from the intermediate transfer film  11  to the card base  1 AA so as to overlap the previously-transferred first transcriptional region  21 . Consequently, the ink receptor layer  11   d   2  containing the invisible-ink image  20  is interposed between the protecting layer  11   c   1  and the protecting layer  11   c   2  on the front side of the card  52 A. In this way, the card  52 A in the modification of the second embodiment is completed through the re-transfer process mentioned above. 
   According to the modification of the second embodiment, the layer including the sublimation-ink image  18  is arranged close to the card base  1 AA in comparison with the layer including the invisible-ink image  20  and additionally, the protecting layer  11   c   1  is interposed between the former layer and the latter layer. 
   Accordingly, as the sublimation-ink image  18  does not come in direct contact with the invisible-ink image  20  (an image of ultraviolet emitting ink), the light intensity of fluorescence, which is radiated from the invisible-ink image  20  onto the sublimation-ink image  18  in irradiating ultraviolet light in order to make the invisible-ink image  20  visible, is reduced in diffusion since the fluorescence is transmitted through the protecting layer  11   c   1 , so that the color of the sublimation ink is restored to maintain the sublimation-ink image  18  in a good condition for a long period. 
   It is noted that if the ultraviolet emitting ink (fluorescent ink) makes contact with the sublimation ink, there is a possibility that the color degradation of the sublimation ink is accelerated due to the cross-reaction of both inks. However, according to the second embodiment, both of the ultraviolet emitting ink and the sublimation ink are separated from each other through the protecting layer  11   c   1 , so that the color degradation of the sublimation ink can be prevented to maintain the sublimation-ink image  18  in a good condition for a long period. 
   Moreover, if the protecting layer  11   c  ( 11   c   1 ,  11   c   2 ) is mixed with either known ultraviolet absorbent or known ultraviolet diffusing agent, it is also possible to suppress an influence of ultraviolet rays on the sublimation-ink image  18 . Particularly, if the protecting layer  11   c   1  is mixed with either known ultraviolet absorbent or known ultraviolet diffusing agent, the above suppression can be effected with high efficiency. 
   Further, as the invisible-ink image  20  is arranged closer to the surface of the card  52 A in comparison with the sublimation-ink image  18  and the fusible ink image  19 , it is possible to make the fluorescence of the invisible-ink image  20  visible more clearly. 
   As for the above-mentioned embodiments and the modifications, we now exhibit materials available for respective inks and films, as follows.
         base sheet ( 3   a,    33   a ) for ink films ( 3 ,  33 ): plastics (e.g. polyester, polypropylene, polyethylene) or condenser paper (thickness: 0.003 mm˜0.010 mm)   sublimation-ink layer: forming of disperse dyes in respective colors with resinous binder applied on base sheet ( 33   a )   fusible-ink layer: forming of carbon black (as color fixing agent) with resinous binder applied on base sheet ( 33   a )   first and second protecting inks OC 1 , OC 2 : acrylate resin, polyester resin, polyurethane resin, etc.   invisible ink UVS: pigment (major components: crystal of metal oxides or sulfides) or organic compound as invisible (colorless) fluorescent material, and ultraviolet-fluorescent ink or infrared-fluorescent ink as invisible ink       

   Note: In each case, preferably, the protecting layers OC 1 ,  11   c  are made of material exhibiting low transmissivity against the wavelength range of fluorescence of the invisible ink.
         base ( 11   a ) of intermediate transfer film ( 11 ): plastics (e.g. polyester, polypropylene, polyethylene) or condenser paper (thickness: 0.01 mm˜0.05 mm)   release layer ( 11   b ): forming of thermoplastic resin (e.g. acrylate resin, polyester resin, polyurethane resin) plus mold-releasing material (as additive)   ink receptor layer ( 11   d ): polyester resin, polyvinyl resin, cellulosic resin, etc.   protecting layer ( 11   c ): polyurethane resin, acrylate resin, polyethylene resin, etc.       

   It will be understood by those skilled in the art that the foregoing descriptions are nothing but two embodiments and their modifications of the disclosed card, its manufacturing method and apparatus and therefore, various changes and modifications may be made within the contents of the present invention. 
   For instance, the fusible-ink images  9 ,  19  are not necessarily formed in the cards  51 ,  51 A,  52  and  52 A. Even if forming the fusible-ink image, there is no need to arrange the fusible-ink image and the sublimation-ink image (or the invisible-ink image) so as to overlap each other. Thus, the fusible-ink image may be arranged in an area different from the area containing the sublimation-ink image (or the invisible-ink image), out of the superimposition. 
   Further, as for the ink film  3  of the first embodiment (including the modification), the array of respective ink areas is not limited to the illustrated array only. Irrespective of any array of ink areas, the controller  6  of the card manufacturing apparatus  50  judges the sort of each ink area. Thereupon, the controller  6  controls the entire operation of the apparatus  50  so as to perform, at least in principle, the printing operation using the protecting ink after completing the printing operation using the sublimation inks and subsequently perform the printing operation using the invisible ink. 
   Similarly to the ink film  33  of the second embodiment (including the modification), the array of respective ink areas is not limited to the illustrated array only. Irrespective of any array of ink areas, the controller  6  of the card manufacturing apparatus  60  judges the sort of each ink area. Thereupon, the controller  6  controls the operation of the apparatus  60  so as to form, at least in principle, the sublimation-ink image  18  by superimposing sublimation inks on a designated area (the first transcriptional region) in the intermediate transfer film  11  and the invisible-ink image  20  in a different area (the second transcriptional region) from the above designated area (the first transcriptional region).