Abstract:
In a thermal transfer recording apparatus comprising an ink film coated with a heat-fusion type ink, an ink film supplying roller rotatably mounted at a first support member, an ink film winding roller rotatably mounted at a second support member, and a recording station wherein a recording material contacts with the ink film to be recorded an image information by a heat transfer, the first and second support members are rotatable respectively around a first axis and a second axis provided at ends of a rotating member which connects the first and second support members, so that the first and second support members integrally rotate around a third axis provided substantially at a center of the rotating member.

Description:
BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to a thermal transfer printer for transferring images to a recording sheet using a ink film coated with a heat-fusion type ink. 
     2. Description of the Related Arts 
     Conventional thermal transfer printers have a platen roller 1 and a retractable thermal head 2 or the like capable of making and breaking contact with said platen roller 1, as shown in FIG. 4. Recording sheet 3 is transported, by a transport means, between platen roller 1 and thermal head 2 so as to wrap around the outer surface of said platen roller 1. 
     An ink film 4, which is coated on one side with a heat-fusion ink, is fed so as to pass medially between the aforesaid recording sheet 3 and thermal head 3. The ink film 4 is fed from an ink film roll 5, guided by guide rollers 7 and 8, and rerolled onto ink film reel 6. 
     Because the ink film 4 used in the aforesaid conventional thermal transfer printer is an extremely thin film having a thickness of about 3 to 10 μm to improve transfer efficiency, it is transported at an incline with unequal tension on the upstream and downstream side of the platen roller in the film transport direction when the ink film is fed, which at times produces a twist in the film and causes poor ink transfer to the recording sheet. Further, wrinkles are at times produced in the film during the ink film 4 transporting process. These wrinkles are thought to be caused by dislocation of ink film roll 5 and ink film reel 6 respectively used to feed the ink film to thermal head 2 and rewind the film thereafter, and by stretching the film 4 with different tension on the upstream and downstream side of the platen roller in the film transport direction due to the peeling process. 
     The latter case results in a great discrepancy in the quantity of ink transferred to recording sheet 3 in the width direction of film 4, because as ink film 4 is peeled from recording sheet 3 after the transfer, the peeling force causes a large disparity in the tension on ink film 4 on the upstream and downstream side of the platen roller in the film transport direction, such that when the ink transfer occurs after wrinkles are produced in the ink film, poor ink transfer will result. 
     In U.S. Pat. application Nos. 4,425,568 and 4,463,360, the inside of the ink film makes touching contact with a stress-absorbing roller disposed between the platen and the supply roller, the center of rotation of said stress-absorbing roller being inclined in a perpendicular direction relative to the surface of the ink film. By inclining the stress-absorbing roller, tension is equalized in the width direction of the ink film. However, the degree of parallelism between the film supply roller and the rerolling roller cannot be maintained, and the ink film cannot be transported with uniform tension. 
     SUMMARY OF THE INVENTION 
     A main object of the present invention is to provide a thermal transfer printer capable of accomplishing suitable transfers. 
     A further object of the present invention is to provide a thermal transfer printer capable of transporting ink film without twisting or wrinkling said film. 
     These and other objects of the present invention are accomplished by providing a thermal transfer printer having a platen roller and a retractable thermal head capable of making and breaking contact with said platen roller, and which transports the aforesaid recording sheet between the platen roller and the thermal head, and transports an ink film between the recording sheet and the thermal head so as to transfer images to the recording sheet, said thermal transfer printer being characterized by having a first cradle which supports the ink film supply roller around which the ink film is wound, and which is mounted so as to be capable of bidirectional oscillation in parallel and perpendicular directions relative to the ink film transport direction; and 
     a second cradle which supports the ink film receiving roller around which the film is rewound, and which is mounted so as to be capable of bidirectional oscillation in parallel and perpendicular directions relative to the ink film transport direction. 
     These and other objects, advantages and features of the invention will become apparent from the following description thereof taken in conjunction with the accompanying drawings which illustrate specific embodiments of the invention. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     In the following description, like parts are designated by like reference numbers throughout the several drawings. 
     FIG. 1 is a cross section view along line I--I shown in FIG. 2 which illustrates an embodiment of the thermal transfer printer of the present invention; 
     FIG. 2 is a top plan view of the thermal transfer printer shown in FIG. 1; 
     FIG. 3A shows an embodiment of the thermal transfer printer of the present invention wherein the ink film transport direction is not perpendicular relative to the center shaft of the platen roller; 
     FIG. 3B shows an embodiment of the thermal printer of the present invention wherein the ink film mounting error shown in FIG. 3A is corrected, and the ink film transport direction is perpendicular to relative to the center shaft of the platen roller; 
     FIG. 4 is an elevation view showing the basic construction of a conventional thermal transfer printer. 
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     FIGS. 1 and 2 show the essential portions of an embodiment of the present invention. 
     The thermal transfer printer shown in FIG. 1 has a recording sheet 3 interposed between a platen roller 1 and a thermal head 2. 
     In the drawings, the item labeled 40 is a sheet supply tray which accommodates recording sheets of uniform length. The sheets accommodated in the tray are fed to the nip section of the platen roller and the thermal head via first guide roller 41, whereupon the ink transfer occurs. After the ink transfer, the recording sheet is accommodated in output tray 44 via a second guide roller 42 and output rollers 43. 
     On the other hand, the surface of ink film 4 is coated with a heat-fusion type ink. The unused portion of ink film 4 is wound around a cylindrical core 5a of ink film roll 5, while the used portion of ink film 4 is rewound around a cylindrical core 6a of ink film reel 6. Ink film roll 5 is mounted on a first cradle 10, while ink film reel 6 is mounted on a second cradle 11. First cradle 10 and second cradle 11 are mounted via pins 25 and 26 respectively so as to be movable on rotatable plate 23. 
     Support pin 22 attached to the main base plate 21 fits in the center portion of rotatable plate 23. Rotatable plate 23 is movable about the center shaft of the aforesaid support pin 22. Rotatable plate 23 is separated from base plate 21 by means of a spacer 24 fit onto support pin 22, so that the aforesaid movement of plate 23 about the center shaft of support pin 22 is smooth. Support pin 22 is disposed at a fixed position on base plate 21, so as to position the rotational center shaft of platen roller 1 above or near the extension of the center shaft of support pin 22. 
     The construction of the first and second cradles are hereinafter described in more detail with reference to FIG. 2. 
     Two facing brackets 10a and 10b used to support ink film roll 5 are connected to a base 10c; brackets 10a and 10b and base 10c comprise the first cradle 10 for supporting ink film roll 5. Similarly, two facing brackets 11a and 11b used to support ink film reel 6 are connected to a base 11c; brackets 11a and 11b and base 11c comprise the second cradle 11 for supporting ink film reel 6. 
     First cradle 10 is mounted so as to be oscillatable and rotatable on a center shaft formed by pin 25, which is arranged at one end of rotatable plate 23 on base 10c so as to be perpendicular relative to the ink film 4 transport direction, and second cradle 11 is mounted so as to be freely oscillatable and rotatable on a center shaft formed by pin 26, which is arranged at the opposite end of the aforesaid rotatable plate 23 on base 11c so as to be perpendicular relative to the ink film 4 transport direction. To assure the smooth movement of the aforesaid cradles 10 and 11, the respective pins 25 and 26 are fitted with spacers 27 and 28. 
     Further, a support shaft 12 is provided a flange 12b and a fitting 12a that fits into the end of ink film roll 5, said support shaft 12 being fixedly attached to the aforesaid bracket 10a. In addition, an oscillating shaft 13 that is freely oscillatable in the axial direction is provided a flange 13b and a fitting 13a that fits into the other end of ink film roll 5, said oscillating shaft 13 being mounted to the previously described bracket 10b. A spring force in the ink film transport direction is applied to the aforesaid oscillating shaft 13 via a coil compression spring 14. 
     An ink film winding motor 15 is connected to the outer side of the previously described bracket 11a, and the tip of drive shaft 17, which is connected via a clutch 16 to the main shaft of said motor 15, is provided a flange 17b and fitting 17a that fits in ink film reel 6. The tip of oscillating shaft 18 has a flange 18b and a fitting 18a which fits in ink film reel 6 attached thereto, said oscillating shaft 18 is attached to the previously described bracket 11b so as to be oscillatable in the axial direction. A spring force in the ink film transport direction is applied to the aforesaid oscillating shaft 18 via a coil compression spring 19. 
     The weights of flange 11a attached to motor 15 and clutch 16 and the opposite flange 11b are balanced, and a weight 29 is provided on flange 11b of second cradle 11 so as to assure said second cradle 11 will move smoothly with a rotational center about pin 26. 
     A pair of stoppers 31 are fixedly attached to base plate 21 with specific spacing therebetween to regulate the movement of the previously described moveable plate 23 within a certain specified range of movement, and similarly, two pairs of stoppers 32 and 33 are fixedly attached to base plate 21 to regulate the range of movement of the two cradles 10 and 11 respectively within a specified range. 
     With ink film 4 installed in the ink film transport portion of the thermal transfer printer shown in FIGS. 1 and 2 and oscillating shaft 13 in the state wherein said shaft 13 is retracted in the direction of arrow A against the force exerted by spring 14, said oscillating shaft 13 is returned to its former position after fitting 12a fits into the core 5a of the ink film roll 5 until flange 12b makes contact with the end face of ink film roll 5. The result of the aforesaid operation is that fitting 13a is fitted into core 5a until flange 13b on the other side of ink film roll 5 makes contact with the end face of said film roll 5. Accordingly, the loading of ink film roll 5 is completed, and ink film reel 6 is loaded in an identical sequence of procedures to complete the loading operation for ink film 4. The respective ink film roll 5 and reel 6 are pressed in the axial direction by springs 14 and 19. 
     When an image is formed on recording sheet 3, ink film 4 is fed from ink film roll 5 by means of the operation of motor 15, and wound onto ink film reel 6 Although the driving force of motor 15 is transmitted to ink film reel 6 via clutch 16, said clutch 16 functions as a torque limiter so that when platen roller 1 is enjoined with the thermal head 2 during the copy operation, the torque transmitted to the ink film 4 is not greater than the moving force of the transported recording sheet 3. Thus, reeling of excess ink film 4 during the transfer process is preventing, and the speed differential between the transport speed of the recording sheet 3 and the transport speed of ink film 4 is absorbed. 
     To assure a suitable transfer operation, it is desirable to load the ink film 4 in the film transport portion of the thermal transfer printer so that the film transport direction is perpendicular relative to the axis of rotation of platen roller 1. Accordingly, the ink film roll 5 and reel 6 must be installed with great precision in conventional thermal transfer printers so as to have the rotational axes of said roll 5 and reel 6 coincide with the rotational axis of platen roller 1, while such consideration is unnecessary in the printer of the present invention. Therefore, a situation may be hypothesized, for example, wherein the actual transport direction of ink film 4 is inclined an angle Θ relative to the appropriate transport direction P that is perpendicular to the rotational axis 0 of platen roller 1, as shown in FIG. 3A. When this positional dislocation is viewed using platen roller 1 as a base, the position O 1  of platen roller 1, which is required for proper transfer of ink film 4, is inclined at an angle Θ from the 0 position relative to ink film 4 transport direction P 1 . At this time, one side of the section wherein the inside of ink film 4 has passed platen roller 1 and thermal head 2 is designated section D, the opposite side of the film is designated section E, and the upstream inside prior to aforesaid passage is designated section F, and the opposite side is designated section G. 
     When the previously described installation error occurs and motor 15 is operated to wind ink film 4 on film reel 6, the actual ink film 4 transport direction P 1  is inclined an angle Θ relative to direction P that is perpendicular to the center of rotation axis 0 of platen roller 1, therefore the aforesaid sections D and G have a higher tension than sections E and F. This situation results in counterclockwise rotational forces centered at pins 22, 25 and 26 being applied to rotatable plate 23, and first and second cradles 10 and 11, as shown in FIG. 3A. More specifically, a rotational force acts on ink film 4 and, in turn, first and second cradles 10 and 11 due to the tension applied to ink film 4 while said film is wound, said rotational force occurring in the actual film 4 transport direction P which is virtually perpendicular to the rotational center axis 0 of platen roller 1. 
     The result of the action of the aforesaid tension and rotational force is that first and second cradles 10 and 11 move while maintaining parallel positions, such that rotatable plate 23 and first and second cradles 10 and 11 change attitude, as shown in FIG. 3B. In the aforesaid state, the rotational center axes of both ink film roll 5 and ink film reel 6 are parallel to the rotational center axis of platen roller 1, that is, in a state wherein suitable transfer operation may be accomplished Accordingly, even if the ink film 4 is installed in the thermal transfer printer imprecisely so as to produce a mounting error relative to the rotational center axis of platen roller 1, the ink film 4 is automatically adjusted so as to assume the proper attitude at the start of the printing operation, thereby eliminating twisting of said ink film 4 when the film 4 separates from the recording sheet 3, which is the major cause of wrinkles forming in the film. 
     Even when ink film 4 has been properly loaded in the printer, a disparity may occur in the quantity of ink transferred from ink film 4 to the recording sheet 3 in the width direction of said recording sheet 3, that is, when ink film 4 separates from the recording sheet 3 after passing between thermal head 2 and platen roller 1, disparate separation force is produced in the width direction of ink film 4 causing disparate tension to be applied to said ink film 4 in the width direction. In such a case, both ink film roll 5 and ink film reel 6 are synchronized and have rotational axes at pins 25 and 26 respectively, and automatically oscillate while maintaining a parallel positional relationship in a plane parallel to the transport plane of ink film 4, so that the tension is equalized on all along ink film 4. Twisting, and particularly wrinkling of ink film 4 can thereby prevented, and proper ink transfer can be accomplished. 
     If both ink film roll 5 and ink film reel 6 only oscillate as previously described, rotatable plate 23 becomes unnecessary, and first and second cradles 10 and 11 may be mounted so as to be directly rotatable on base plate 21 via pins 25 and 26 without using rotatable plate 23. 
     A further application of the construction shown in the drawings is possible wherein the ink film roll 5 and ink film reel 6 are housed within a casing so that ink film 4 may be accommodated in a cassette. In such a case, the casing of the cassette itself fulfills the function of base plate 21. Further, using ink films coated with yellow, magenta, cyan and other color ink is also possible. 
     In addition, the present invention may also be used in either of thermal transfer printers employing sequential methods and multihead type thermal transfer printers, and recording sheet 3 may be either cut sheets, continuous sheets, or various other types. 
     Although the present invention has been fully described by way of examples with reference to the accompanying drawings, it is to be noted that various changes and modifications will be apparent to those skilled in the art. Therefore, unless otherwise such changes and modifications depart from the scope of the present invention, they should be construed as being included therein.