EP0589462A1 - Verfahren und Gerät für Wärmetransferdruck hoher Geschwindigkeit - Google Patents

Verfahren und Gerät für Wärmetransferdruck hoher Geschwindigkeit Download PDF

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Publication number
EP0589462A1
EP0589462A1 EP93115379A EP93115379A EP0589462A1 EP 0589462 A1 EP0589462 A1 EP 0589462A1 EP 93115379 A EP93115379 A EP 93115379A EP 93115379 A EP93115379 A EP 93115379A EP 0589462 A1 EP0589462 A1 EP 0589462A1
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EP
European Patent Office
Prior art keywords
printing
film
film means
printing pattern
thermal transfer
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Withdrawn
Application number
EP93115379A
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English (en)
French (fr)
Inventor
Michiharu Tohdo
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
KEISOKU INDUSTRY Co Ltd
Original Assignee
KEISOKU INDUSTRY Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Priority claimed from JP25473192A external-priority patent/JPH06155709A/ja
Priority claimed from JP25472892A external-priority patent/JPH06115046A/ja
Priority claimed from JP04254732A external-priority patent/JP3138890B2/ja
Application filed by KEISOKU INDUSTRY Co Ltd filed Critical KEISOKU INDUSTRY Co Ltd
Publication of EP0589462A1 publication Critical patent/EP0589462A1/de
Withdrawn legal-status Critical Current

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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J2/00Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
    • B41J2/315Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by selective application of heat to a heat sensitive printing or impression-transfer material
    • B41J2/32Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by selective application of heat to a heat sensitive printing or impression-transfer material using thermal heads
    • B41J2/325Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by selective application of heat to a heat sensitive printing or impression-transfer material using thermal heads by selective transfer of ink from ink carrier, e.g. from ink ribbon or sheet
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B41PRINTING; LINING MACHINES; TYPEWRITERS; STAMPS
    • B41JTYPEWRITERS; SELECTIVE PRINTING MECHANISMS, i.e. MECHANISMS PRINTING OTHERWISE THAN FROM A FORME; CORRECTION OF TYPOGRAPHICAL ERRORS
    • B41J2/00Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed
    • B41J2/005Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material
    • B41J2/0057Typewriters or selective printing mechanisms characterised by the printing or marking process for which they are designed characterised by bringing liquid or particles selectively into contact with a printing material where an intermediate transfer member receives the ink before transferring it on the printing material

Definitions

  • the present invention relates to a method and an apparatus for a thermal transfer type printing suitable for a high speed printing.
  • thermo printer An example of a known printer apparatus of a thermal transfer type (thermal printer) is disclosed in Japanese Patent Application Laid Open No. 3-227683 (1991).
  • the thermal printer disclosed in this reference comprises a first film having a carbon (applied material) which is thermally transferrable, a second film arranged to be in contact with this first film, a printing head for thermally transferring unnecessary portion of the carbon from the first film to the second film by heating the first film so as to leave the carbon in a shape of a desired printing pattern on the first film, and a thermal transfer roller for heating the first film with the desired printing pattern formed by the carbon thereon while pressing the first film against a printing target.
  • the printing pattern is formed by means of a controllable printer head, so that the sequential printing of the constantly varying printing patterns such as the bar codes can be realized easily.
  • the unnecessary portion of the carbon is thermally transferred from the first film to the second film, but the area of the unnecessary portion is usually much larger than the area covered by the printing pattern, so that the printing head must be driven for a considerable amount of time using a considerable amount of energy for heating.
  • the portion of the first film to be heated by the printer head must be in a shape of a mirror image of the desired printing pattern in order to obtain the printing in a shape of the normal image on the printing target, so that the controlling of the printing head becomes complicated and cumbersome.
  • the printing is made by first forming the desired printing pattern on the first film, then moving a portion of the first film having the desired printing pattern thereon to a location of the printing target to carry out the thermal transfer of the printing pattern at a location of the printing target.
  • the printing head cannot be driven continuously and the formation of the next printing pattern by the printer head must be delayed until the moving of the current printing pattern to a location of the printing target object and the thermal transfer of the current printing pattern to the printing target are completed. Consequently, the interval between the successive printing operations has been considerably long, and therefore the sequential printing of a plurality of printing patterns has been time consuming.
  • It is another object of the present invention is to provide a method and an apparatus for a thermal transfer type printing, capable of realizing an accurate multi-color printing without deviated coloring at a high speed and a low cost.
  • It is another object of the present invention is to provide a method and an apparatus for a thermal transfer type printing, capable of reducing an interval between the successive printing operations such that the sequential printing of a plurality of printing patterns can be made at a high speed.
  • an apparatus for thermal transfer type printing comprising: first film means for carrying a thermally transferrable applied material; second film means for receiving the applied material thermally transferred from the first film means; printing pattern formation means for forming a desired printing pattern on the second film means by applying heat from the second printing means side to a desired part of the applied material on the first film means in a shape of the desired printing pattern; and thermal transfer means for thermally transferring the desired printing pattern formed on the second film means to a printing target.
  • an apparatus for thermal transfer type printing comprising: first film means for carrying a thermally transferrable applied material; second film means for receiving the applied material thermally transferred from the first film means; printing pattern formation means for forming a desired printing pattern on the second film means by applying heat to a desired part of the applied material on the first film means in a shape of the desired printing pattern; printing pattern pooling means for temporarily pooling a plurality of desired printing patterns sequentially formed on the second film means by the printing pattern formation means, by bending a route of the second film means passing out from a heating position of the printing pattern formation means; and thermal transfer means for thermally transferring said plurality of desired printing patterns formed on the second film means and temporarily pooled by the printing pattern pooling means to a printing target.
  • an apparatus for thermal transfer type printing comprising: a plurality of first film means for carrying thermally transferrable applied material in different colors; second film means for receiving the applied material thermally transferred from said plurality of first film means; printing pattern formation means for forming a plurality of desired printing patterns in said different colors on the second film means by applying heat to a desired part of the applied material on each first film means in a shape of the desired printing pattern; and thermal transfer means for thermally transferring said plurality of desired printing patterns formed on the second film means to a printing target.
  • a method of thermal transfer type printing comprising the steps of: providing first film means for carrying a thermally transferrable applied material; providing second film means for receiving the applied material thermally transferred from the first film means; forming a desired printing pattern on the second film means by applying heat from the second film means side to a desired part of the applied material on the first film means in a shape of the desired printing pattern by printing pattern formation means; and thermally transferring the desired printing pattern formed on the second film means to a printing target by thermal transfer means.
  • a method of thermal transfer type printing comprising the steps of: providing first film means for carrying a thermally transferrable applied material; providing second film means for receiving the applied material thermally transferred from the first film means; forming a desired printing pattern on the second film means by applying heat from the second film means side to a desired part of the applied material on the first film means in a shape of the desired printing pattern by printing pattern formation means; temporarily pooling a plurality of desired printing patterns sequentially formed on the second film means by the printing pattern formation means, by bending a route of the second film means passing out from a heating position of the printing pattern formation means; and thermally transferring the desired printing pattern formed on the second film means to a printing target by thermal transfer means.
  • a method of thermal transfer type printing comprising the steps of: providing a plurality first film means for carrying thermally transferrable applied material in different colors; providing second film means for receiving the applied material thermally transferred from the first film means; forming a plurality of desired printing patterns in said different colors on the second film means by applying heat to a desired part of the applied material on each first film means in a shape of the desired printing pattern by printing pattern formation means; and thermally transferring said plurality of desired printing patterns formed on the second film means to a printing target by thermal transfer means.
  • Fig. 1 is a schematic diagram of a first embodiment of a thermal transfer type printing apparatus according to the present invention.
  • Fig. 2 is a schematic diagram of a second embodiment of a thermal transfer type printing apparatus according to the present invention.
  • Fig. 3 is a schematic diagram of a third embodiment of a thermal transfer type printing apparatus according to the present invention.
  • Fig. 4 is a schematic diagram of a fourth embodiment of a thermal transfer type printing apparatus according to the present invention.
  • Fig. 5 is a schematic diagram of a fifth embodiment of a thermal transfer type printing apparatus according to the present invention.
  • Fig. 6 is a schematic diagram of a sixth embodiment of a thermal transfer type printing apparatus according to the present invention.
  • Fig. 7 is a schematic diagram of a modified configuration for the apparatus of the first embodiment shown in Fig. 1.
  • Fig. 8 is a schematic diagram of a modified configuration for the apparatus of the second embodiment shown in Fig. 2.
  • Fig. 9 is a schematic diagram of a modified configuration for the apparatus of the third embodiment shown in Fig. 3.
  • Fig. 10 is a schematic diagram of a modified configuration for the apparatus of the fourth embodiment shown in Fig. 4.
  • Fig. 11 is a schematic diagram of a modified configuration for the apparatus of the fifth embodiment shown in Fig. 5.
  • Fig. 12 is a schematic diagram of a modified configuration for the apparatus of the sixth embodiment shown in Fig. 6.
  • Fig. 13 is a schematic diagram of a seventh embodiment of a thermal transfer type printing apparatus according to the present invention.
  • Fig. 14 is a detailed diagram of a main portion of the apparatus of Fig. 13.
  • a first embodiment of a thermal transfer type printing apparatus according to the present invention will be described in detail.
  • This thermal printer of Fig. 1 includes a first black film member 110, a first red film member 120, and a second film member 200.
  • the first black film member 110 carries on one side a carbon black C1 as a thermally transferrable applied material for printing, while the first red film member 120 carries on one side a carbon red C2 as athermally transferrable applied material for printing.
  • the second film member 200 carries no applied material initially, and receives the carbon black C1 and the carbon red C2 thermally transferred from the first black film member 110 and the first red film member 120.
  • the first black film member 110 and the first red film member 120 are initially provided inside a printer body in a state of being rolled up on cartridge type first black roll out reel 111 and first red roll out reel 121, respectively. Then, the first black film member 110 is rolled out with the carbon black C1 facing outwards, guided to be in a close contact with the second film member 200 by being wound around a black platen roller 112, and rolled up by a first black roll up reel 113. Similarly, the first red film member 120 is rolled out with the carbon red C2 facing outwards, guided to be in a close contact with the second film member 200 by being wound around a red platen roller 122 located below the black platen roller 112, and rolled up by a first black roll up reel 123.
  • the first black roll out reel 111, the first black roll up reel 113, the first red roll out reel 121, and the first red roll up reel 123 are detachably attached to a first black roll out motor shaft 114, a first black roll up motor shaft 115, a first red roll out motor shaft 124, and a first red roll up motor shaft 125, respectively, where each of the first black roll out motor (not shown), the first black roll up motor (not shown), the first red roll out motor (not shown), and the first red roll up motor (not shown) is controlled by a motor control unit 310.
  • the black platen roller 112 and the red platen roller 122 are caused to rotate by the movements of the first black film member 110 and the first red film member 120, respectively, and positioned to be in a close proximity from each other.
  • the second film member 200 is initially provided inside a printer body in a state of being rolled up on a cartridge type second roll out reel 210. Then, the second film member 200 is rolled out from this second roll out reel 210, guided by first and second guide rollers 211 and 212 to have its one side which received the black carbon C1 and the red carbon C2 to be parallelly facing toward a surface of a printing target in a form of a cardboard A conveyed on a belt conveyer B, and rolled up by a second roll up reel 213.
  • the second roll out reel 210 and the second roll up reel 213 are detachably attached to a second roll out motor shaft 214 and a second roll up motor shaft 215, respectively, where each of the second roll out motor (not shown) and the second roll up motor (not shown) is also controlled by the motor control unit 310.
  • the motor control unit 310 controls the motors such that the roll out speed of the second film member 200 is in agreement with the roll out speed of the first black film member 110 and the first red film member 120.
  • a black printing head 410 is located at a position facing against the black platen roller 112 across the first black film member 110 and the second film member 200
  • a red printing head 420 is located at a position facing against the red platen roller 122 across the first black film member 110 and the second film member 200.
  • Each of the black printing head 410 and the red printing head 420 is equipped with a multiplicity of dot shaped heat generating resistor elements, and an amount of current flowing through each of these heat generating resistor elements is controlled by a black printing controller 411 and a red printing controller 421, respectively.
  • the black printing head 410 and the red printing head 420 are also controlled to move in a direction of moving toward or moving away from the black platen roller 112 and the red platen roller 122, respectively.
  • the black printer head 410 and the red printer head 420 are moved toward the black platen roller 112 and the red platen roller 122 to press the second film member 200 against the black platen roller 112 and the red platen roller 122, respectively, such that the heat for causing the thermal transfer generated by the heat generating resistor elements can be transmitted to the first black film member 110 and the first red film member 120 through the second film member 200.
  • the black printing head 410 and the red printing head 420 are controlled to thermally transfer the portions of the carbon black C1 and the carbon red C2 on the first black film member 110 and the first red film member 120 that are necessary for forming a desired printing pattern to be printed on the second film member 200.
  • the black printing head 410 and the red printing head 420 are moved away from the black platen roller 112 and the red platen roller 122, respectively, and while the black printing head 410 and the red printing head 420 are located away from the black platen roller 112 and the red platen roller 122, the first black film member 110 and the first red film member 120 are not rolled up.
  • the motor control unit 310, the black printing controller 411, and the red printing controller 421 are connected with a printing control unit 300 for controlling a printing operation of this thermal printer as a whole.
  • a thermal transfer roller 500 which is movable in a direction along the second film member 200 as well as in a direction of moving toward or moving away from the second film member 200.
  • the thermal transfer roller 500 is moved toward the second film member 200 to press the second film member 200 against the cardboard A while heating the second film member 200, and rolls along the second film member 200 between the first and second guide rollers 211 and 212, to print the entire desired printing pattern formed by the carbon black C1 and the carbon red C2 onto the cardboard A.
  • this thermal transfer roller 500 has its surface portion formed by a soft layer with the hardness of about 30 such that the second film member 200 can be tightly pressed against the surface of the printing target even when the surface of the printing target is not smooth as in a back side surface of a corrugated cardboard.
  • this thermal printer is capable of achieving an accurate printing even on a curved surface or a rough surface.
  • the command signal for the desired printing pattern is supplied from the printer control unit 300 to the black printing controller 411 and the red printing controller 421.
  • This command signal commands each of the black printing head 410 and the red printing head 420 to apply heat to a region in a shape of a positive normal image of the black and red portions in the desired printing pattern, respectively, just as they are expected to appear on the cardboard A when the printing is made.
  • the black printing head 410 is moved toward the black platen roller 112 to press the second film member 200 against the first black film member 110, and the currents are supplied only to those heat generating resistor elements located within a region in the shape of the positive normal image of the black portion in the desired printing pattern, so as to generate the heat in a region in the shape of the positive normal image of the black portion in the desired printing pattern.
  • the heat generated by the black printing head 410 is transmitted to the first black film member 110 through the second film member 200, and the carbon black C1 located within a region in the shape of the positive normal image of the black portion in the desired black printing pattern is thermally transferred from the first black film member 110 to the second film member 200.
  • the black printing head 410 is moved away from the second film member 200.
  • the second film member 200 is rolled to move a region having the black portion in the desired printing pattern formed therein to the position of the red platen roller 122.
  • the red printing head 420 is moved toward the red platen roller 122 to press the second film member 200 against the first red film member 120, and the currents are supplied only to those heat generating resistor elements located within a region in the shape of the positive normal image of the red portion in the desired red printing pattern, so as to generate the heat in a region in the shape of the positive normal image of the red portion in the desired printing pattern.
  • the heat generated by the red printing head 420 is transmitted to the first red film member 120 through the second film member 200, and the carbon red C2 located within a region in the shape of the positive normal image of the red portion in the desired red printing pattern is thermally transferred from the first red film member 120 to the second film member 200.
  • the red printing head 420 is moved away from the second film member 200.
  • the desired printing pattern formed on the second film member 200 by the process described so far appears as a positive mirror image of the desired printing pattern to be printed on the cardboard A.
  • the desired printing pattern is formed on the second film member 200 by the thermally transferred carbon black C1 and the carbon red C2.
  • the movements of the first black and red film members 110 and 120 and the second film member 200 are controlled such that the second film member 200 and each of the first black and red film members 110 and 120 move together through the respective one of the heating positions of the black and red printing heads 410 and 420 while the respective one of the printing heads 410 and 420 is operated to carry out the heating operation, and the movements of the first black and red film members 110 and 120 are stopped otherwise.
  • the second film member 200 with the desired printing pattern formed thereon is moved over the cardboard A until the desired printing pattern is placed at a thermal transfer printing position of the thermal transfer roller 500 provided over the cardboard A.
  • the heated thermal transfer roller 500 is moved toward the second film member 200 to press the second film member 200 against the cardboard A, and then moved along the second film member 200 from the first guide roller 211 side to the second guide roller 212 side.
  • the desired printing pattern formed on the second film member 200 is thermally transferred onto the surface of the cardboard A, such that the positive normal image of the desired printing pattern is printed on the cardboard A.
  • the thermal transfer roller 500 is moved away from the second film member 200 such that the second film member 200 is separated from the cardboard A.
  • the cardboard A with the desired printing pattern printed thereon is conveyed out from the thermal printer by the belt conveyer B, and a new cardboard A to be printed next is conveyed into a thermal transfer printing position in the thermal printer between the first and second guide rollers 211 and 212.
  • the formation of the new desired printing pattern is carried out by the black and red printing heads 410 and 420 in the manner described above.
  • the second film member 200 with the new desired printing pattern formed thereon is moved to the thermal transfer printing position over the new cardboard A, and the printing of the new desired printing pattern onto the new cardboard A is carried out in the manner described above.
  • the carbon black C1 and the carbon red C2 on the first black and red film members 110 and 120 are thermally transferred to the second film member 200 by applying heat from the second film member 200 side to the first black and red film members 110 and 120 by the black and red printing heads 410 and 420, so that the mirror image of the desired printing pattern can be formed on the second film member 200 by applying heat to a region in the shape of the normal image of the desired printing pattern by the black and red printing heads 410 and 420, such that the normal image of the desired printing pattern can be printed onto the cardboard A by thermally transferring the mirror image of the desired printing pattern on the second film member 200 at the thermal transfer roller 500. Therefore, there is no need for the black and red printing heads 410 and 420 to apply heat to a region in the shape of the mirror image of the desired printing pattern, so that the controlling of the black and red printing heads 410 and 420 can be a simple, straightforward one.
  • the black and red printing heads 410 and 420 are controlled to apply heat to a region in the shape of the positive image containing only the portion constituting the pattern itself, so that the heating area required for the black and red printing heads 410 and 420 can be small, and consequently the time required for the formation of the desired printing pattern as well as the heating energy required for operating the black and red printing heads 410 and 420 can be reduced.
  • the black and red portions in the desired printing pattern are formed on the same region of the second film member 200 by the black and red printing heads 410 and 420, and the black and red portions in the desired printing pattern formed on the second film member 200 are thermally transferred onto the cardboard A altogether at once by the thermal transfer roller 500, so that the thermal transfer type multi-color printing can be realized very easily at a high speed.
  • both of the black and red portions of the desired printing pattern can be formed in the same thermal printer, so that the problem of the deviated coloring can be prevented almost completely and therefore the highly accurate multi-color printing can be realized by using only one thermal printer, such that the cost required for the multi-color printing can also be reduced.
  • the black and red platen rollers 112 and 122 are located in a close proximity from each other, so that both of the black and red portions of the desired printing pattern can be formed on the same region of the second film member 200 easily, and the total amount of the second film member 200 required for the printing of the entire desired printing pattern can be reduced. Also, each of the first black and red film members 110 and 120 is rolled only while the heating operation by the respective one of the black and red printing heads 410 and 420 is carried out, so that the consumption of the first black and red film members 110 and 120 can be kept at the absolutely necessary minimum level.
  • Fig. 2 a second embodiment of a thermal transfer type printing apparatus according to the present invention will be described in detail.
  • those elements which are substantially identical to the corresponding elements in the first embodiment of Fig. 1 described above will be given the same reference numerals in the figure, and their description will be omitted.
  • This second embodiment of Fig. 2 differs from the first embodiment of Fig. 1 described above in that a loop shaped second film member 201 is used instead of the second film member 200.
  • the thermal printer is equipped with a driving roller 217 replacing the second guide roller 212 of the first embodiment, third and fourth guide rollers 218 and 219 replacing the second roll out reel 210 and the second roll up reel 213 of the first embodiment, and a tension roller 220 located between the driving roller 217 and the third guide roller 218 for applying a prescribed tension to the loop shaped second film member 201.
  • the loop shaped second film member 201 is guided by first guide roller 211 and the driving roller 217 to have its one side which received the black carbon C1 and the red carbon C2 to be parallelly facing toward the surface of the cardboard A, and then wound around the third and fourth guide rollers 218 and 219 to circulate through a rectangular path.
  • the driving roller 217 is attached to a driving motor (not shown) controlled by the motor control unit 310 such that the moving speed of the loop shaped second film member 201 is in agreement with the roll out speed of the first black film member 110 and the first red film member 120.
  • the loop shaped second film member 201 is also guided by first guide roller 211 and the fourth guide roller 219 between the black and red platen rollers 112 and 122 and the black and red printing heads 410 and 420.
  • the fourth guide roller 219 is also attached to a motor (not shown) controlled by the motor control unit 310 such that the moving speed of the loop shaped second film member 201 is in agreement with the roll out speed of the first black film member 110 and the first red film member 120.
  • the thermal printer of this second embodiment should preferably be equipped with a cleaning device (not shown) either between the driving roller 217 and the third guide roller 218 or between the third and fourth guide rollers 218 and 219, for cleaning the loop shaped second film member 201 to remove the dusts from a side of the loop shaped second film member 201 for receiving the black carbon C1 and the red carbon C2.
  • a cleaning device (not shown) either between the driving roller 217 and the third guide roller 218 or between the third and fourth guide rollers 218 and 219, for cleaning the loop shaped second film member 201 to remove the dusts from a side of the loop shaped second film member 201 for receiving the black carbon C1 and the red carbon C2.
  • the loop shaped second film member 201 can be used in circulation, so that there is no need to exchange a used second film member with a new second film member as required in the first embodiment, and a cost and a time required for such an exchange operation can be saved, in addition to all the effects of the first embodiment as described above.
  • Fig. 3 a third embodiment of a thermal transfer type printing apparatus according to the present invention will be described in detail.
  • those elements which are substantially identical to the corresponding elements in the first embodiment of Fig. 1 described above will be given the same reference numerals in the figure, and their description will be omitted.
  • This third embodiment of Fig. 3 differs from the first embodiment of Fig. 1 described above in that a mechanism for temporarily pooling a plurality of desired printing patterns formed on the second printing member 200 is incorporated in a form of a movable roller 221, and a thermal transfer roller 501 replaces the thermal transfer roller 500 of the first embodiment.
  • the second film member 200 guided between the black and red platen rollers 112 and 122 and the black and red printing heads 410 and 420 from the second roll out reel 210 to the first guide roller 211 is then guided through the movable roller 221 and the thermal transfer roller 501, and then rolled up by the second roll up reel 213.
  • the movable roller 221 is movable in a direction of moving toward or moving away with respect to the cardboard A, such that a distance that the second film member 200 passes between the first guide roller 211 and the thermal transfer roller 501 can be changed.
  • This movable roller 221 is moved away from the cardboard A while the black and red printing heads 410 and 420 are carrying out the heating operations for forming the desired printing patterns on the second film member 200, so as to temporarily pool portions of the second film member 200 having a plurality of desired printing patterns formed thereon.
  • this movable roller 221 is moved toward the cardboard A such that the temporarily pooled portions of the second film member 200 having a plurality of desired printing patterns formed thereon are sequentially fed into the thermal transfer printing position of the thermal transfer roller 501 as the second film member 200 is rolled up by the second roll up reel 213.
  • the thermal transfer roller 501 is also movable in a direction of moving toward or moving away with respect to the cardboard A, and at a time of the thermal transfer of the desired printing patterns from the second film member 200 to the cardboard A, the thermal transfer roller 501 is moved toward the cardboard A to press the second film member 200 against the cardboard A while being rotated by the second film member 200 as the second film member 200 is rolled up by the second roll up reel 213.
  • the second roll up reel 213 is controlled by the motor control unit 310 to roll up the second film member 200 at the same speed as the feeding speed of the cardboard A by the belt conveyer B.
  • the command signal for the desired printing pattern is supplied from the printer control unit 300 to the black printing controller 411 and the red printing controller 421, and in response to this command signal, the black and red portions of the desired printing pattern by the carbon black C1 and the carbon red C2 are formed on the second film member 200 by the black printing head 410 and the red printing head 420, respectively, just as in the first embodiment described above.
  • the movable roller 221 is moved away from the cardboard A, so as to temporarily pool portions of the second film member 200 having a plurality of desired printing patterns formed thereon. Then, when a prescribed amount of the desired printing patterns are pooled by this movable roller 221, the heating operations by the black and red printing heads 410 and 420 are stopped and a printing start signal is issued.
  • the cardboard A to be printed is conveyed by the belt conveyer B into the thermal transfer printing position of the thermal transfer roller 501. Then, the thermal transfer roller 501 is moved toward the cardboard A to press the second film member 200 against the cardboard A and rotated by the second film member 200 as the second film member 200 is rolled up by the second roll up reel 213, while the movable roller 221 is moved toward the cardboard A such that the temporarily pooled portions of the second film member 200 having a plurality of desired printing patterns are sequentially fed into the thermal transfer printing position of the thermal transfer roller 501.
  • the belt conveyer B continues to move a number of cardboards A sequentially at the same speed as the roll up speed of the second film member 200 by the second roll up reel 213, such that the second film member 200 and each cardboard A move together to print one part of the desired printing patterns from the temporarily pooled portions of the second film member 200 onto the surface of the cardboard A sequentially.
  • the thermal transfer roller 501 is moved away from this cardboard A and the rolling up of the second film member 200 by the second roll up reel 213 is stopped while this cardboard A with the desired printing patterns printed thereon is conveyed out from the thermal printer by the belt conveyer B, and a new cardboard A to be printed next is conveyed into a thermal transfer printing position in the thermal printer. Then, the thermal transfer roller 501 is moved toward the new cardboard A gain to press the second film member 200 against the new cardboard A and rotated by the second film member 200 as the second film member 200 is rolled up by the second roll up reel 213, to print another part of the desired printing patterns from the temporarily pooled portions of the second film member 200 onto the surface of the new cardboard A sequentially.
  • the printing of a plurality of desired printing patterns from the temporarily pooled portions of the second film member 200 is carried out sequentially as the movable roller 221 is moved toward the cardboard A such that the temporarily pooled portions of the second film member 200 having a plurality of desired printing patterns are sequentially fed into the thermal transfer printing position of the thermal transfer roller 501. Also, during this printing of a plurality of desired printing patterns from the temporarily pooled portions of the second film member 200, the heating operations by the black and red printing heads 410 and 420 can be resumed for the next desired printing patterns.
  • the desired printing patterns can be pooled on the temporarily pooled portions of the second film member 200, so that the speed of the desired printing pattern formation per unit time can be increased.
  • the printing from the temporarily pooled portions of the second film member 200 can be made at the same speed as the feeding speed of the cardboard A, so that by increasing the feeding speed of the cardboard A, it also becomes possible to increase a rate of printing of the desired printing patterns per unit time, such that the interval between the successive printing operations can be reduced and therefore the sequential printing of a plurality of printing patterns can be made at a high speed, in addition to all the effects of the first embodiment as described above.
  • Fig. 4 a fourth embodiment of a thermal transfer type printing apparatus according to the present invention will be described in detail.
  • those elements which are substantially identical to the corresponding elements in the third embodiment of Fig. 3 described above will be given the same reference numerals in the figure, and their description will be omitted.
  • This fourth embodiment of Fig. 4 differs from the third embodiment of Fig. 3 described above in that a loop shaped second film member 201 is used instead of the second film member 200.
  • the thermal printer is equipped with a driving roller 217 replacing the second guide roller 212 of the first embodiment, third and fourth guide rollers 218 and 219 replacing the second roll out reel 210 and the second roll up reel 213 of the first embodiment, and a tension roller 220 located between the driving roller 217 and the third guide roller 218 for applying a prescribed tension to the loop shaped second film member 201, just as in the second embodiment of Fig. 2 described above.
  • this fourth embodiment is effectively a hybrid of the second embodiment of Fig. 2 and the third embodiment of Fig. 3.
  • the loop shaped second film member 201 is guided by first guide roller 211 and the driving roller 217 to have its one side which received the black carbon C1 and the red carbon C2 to be parallelly facing toward the surface of the cardboard A, and then wound around the third and fourth guide rollers 218 and 219 to circulate through a rectangular path.
  • the driving roller 217 is attached to a driving motor (not shown) controlled by the motor control unit 310 such that the moving speed of the loop shaped second film member 201 is in agreement with the feeding speed of the cardboard A by the belt conveyer B.
  • the loop shaped second film member 201 is also guided by first guide roller 211 and the fourth guide roller 219 between the black and red platen rollers 112 and 122 and the black and red printing heads 410 and 420.
  • the fourth guide roller 219 is also attached to a motor (not shown) controlled by the motor control unit 310 such that the moving speed of the loop shaped second film member 201 is in agreement with the roll out speed of the first black film member 110 and the first red film member 120.
  • the thermal printer of this fourth embodiment should preferably be equipped with a cleaning device (not shown) either between the driving roller 217 and the third guide roller 218 or between the third and fourth guide rollers 218 and 219, for cleaning the loop shaped second film member 201 to remove the dusts from a side of the loop shaped second film member 201 for receiving the black carbon C1 and the red carbon C2.
  • a cleaning device (not shown) either between the driving roller 217 and the third guide roller 218 or between the third and fourth guide rollers 218 and 219, for cleaning the loop shaped second film member 201 to remove the dusts from a side of the loop shaped second film member 201 for receiving the black carbon C1 and the red carbon C2.
  • the tension roller 220 has a large motion stroke in order to be able to account for the motion of the movable roller 221.
  • the loop shaped second film member 201 can be used in circulation, so that there is no need to exchange a used second film member with a new second film member as required in th third embodiment, and a cost and a time required for such an exchange operation can be saved, in addition to all the effects of the third embodiment as described above.
  • Fig. 5 a fifth embodiment of a thermal transfer type printing apparatus according to the present invention will be described in detail.
  • those elements which are substantially identical to the corresponding elements in the first and third embodiments of Figs. 1 and 3 described above will be given the same reference numerals in the figure, and their description will be omitted.
  • This fifth embodiment of Fig. 5 is effectively a hybrid of the first embodiment of Fig. 1 and the third embodiment of Fig. 3.
  • a mechanism for temporarily pooling a plurality of desired printing patterns formed on the second printing member 200 is incorporated into the configuration of Fig. 1 in a form of a movable roller 221.
  • the second film member 200 rolled out from the second roll out reel 210 and guided between the black and red platen rollers 112 and 122 and the black and red printing heads 410 and 420 from the second roll out reel 210 to the first guide roller 211 is then guided through the movable roller 221.
  • the second film member 200 is guided by fifth and second guide rollers 216 and 212 to have its one side which received the black carbon C1 and the red carbon C2 to be parallelly facing toward the surface of the cardboard A conveyed on a belt conveyer B, and rolled up by the second roll up reel 213.
  • a stopper member 700 for stopping the motion of the second film member 200 through the fifth guide roller 216 by pinching the second film member 200 between this stopper member 700 and the fifth guide roller 216.
  • the motor control unit 310 controls the second roll out reel 210 such that the roll out speed of the second film member 200 is in agreement with the roll out speed of the first black film member 110 and the first red film member 120, while controlling the second roll up reel 213 to roll up the second film member 200 at a speed independent from the roll out speed of the second film member 200.
  • the thermal transfer roller 500 which is movable in a direction along the second film member 200 as well as in a direction of moving toward or moving away from the second film member 200, is provided between the fifth guide roller 216 and the second guide roller 212.
  • the movable roller 221 is moved away from the cardboard A, so as to temporarily pool portions of the second film member 200 having a plurality of desired printing patterns formed thereon.
  • the temporarily pooled portions of the second film member 200 are sequentially fed into the thermal transfer printing position of the thermal transfer roller 500 over the cardboard A as the second film member 200 is rolled up by the second roll up reel 213.
  • the roll up of the second film member 200 by the second roll up reel 213 is stopped, and the stopper member 700 is moved toward the fifth guide roller 216 to pinch the second film member 200 therebetween.
  • the second film member 200 is fixed at the fifth guide roller 216 and the appropriate part of the temporarily pooled portions of the second film member 200 is set in a state of being stretched between the fifth and second guide rollers 216 and 212.
  • the thermal transfer roller 500 is moved toward the cardboard A to press the second film member 200 against the cardboard A and then moved along the second film member 200 from the fifth guide roller 216 side to the second guide roller 212 side.
  • the appropriate part of the desired printing patterns formed on the second film member 200 is thermally transferred onto the surface of the cardboard A.
  • the thermal transfer roller 500 is moved away from the second film member 200 such that the second film member 200 is separated from the cardboard A.
  • this cardboard A with the desired printing patterns printed thereon is conveyed out from the thermal printer by the belt conveyer B, and a new cardboard A to be printed next is conveyed into a thermal transfer printing position in the thermal printer, and the thermal transfer printing operation similar to that described above is carried out for this new cardboard A.
  • the printing of a plurality of desired printing patterns from the temporarily pooled portions of the second film member 200 is carried out sequentially as the movable roller 221 is moved toward the cardboard A such that the temporarily pooled portions of the second film member 200 having a plurality of desired printing patterns are sequentially fed into the thermal transfer printing position of the thermal transfer roller 500. Also, during this printing of a plurality of desired printing patterns from the temporarily pooled portions of the second film member 200, the heating operations by the black and red printing heads 410 and 420 can be resumed for the next desired printing patterns.
  • the heating operations by the black and red printing heads 410 and 420 are stopped when an amount of the desired printing patterns pooled by this movable roller 221 reaches to a prescribed amount
  • Fig. 6 a sixth embodiment of a thermal transfer type printing apparatus according to the present invention will be described in detail.
  • those elements which are substantially identical to the corresponding elements in the fifth embodiment of Fig. 5 described above will be given the same reference numerals in the figure, and their description will be omitted.
  • This sixth embodiment of Fig. 6 differs from the fifth embodiment of Fig. 5 described above in that a loop shaped second film member 201 is used instead of the second film member 200.
  • the thermal printer is equipped with a driving roller 217 replacing the second guide roller 212 of the first embodiment, third and fourth guide rollers 218 and 219 replacing the second roll out reel 210 and the second roll up reel 213 of the first embodiment, and a tension roller 220 located between the driving roller 217 and the third guide roller 218 for applying a prescribed tension to the loop shaped second film member 201, just as in the second embodiment of Fig. 2 described above.
  • this sixth embodiment is effectively a hybrid of the second embodiment of Fig. 2 and the fourth embodiment of Fig. 4.
  • the loop shaped second film member 201 is guided by fifth guide roller 216 and the driving roller 217 to have its one side which received the black carbon C1 and the red carbon C2 to be parallelly facing toward the surface of the cardboard A, and then wound around the third and fourth guide rollers 218 and 219 to circulate through a rectangular path.
  • the driving roller 217 is attached to a driving motor (not shown) controlled by the motor control unit 310 such that the moving speed of the loop shaped second film member 201 is controlled independently from the roll out speed of the first black and red film members 110 and 120.
  • Fig. 7 shows a modified configuration for the first embodiment of Fig. 1 described above, which differs from the configuration of Fig. 1 in that: each of the motor shafts 114, 124, and 214 to which the first black roll out reel 111, the first red roll out reel 121, and the second roll out reel 210 are attached, respectively, is replaced by a braking shaft not connected with a motor; the black and red platen rollers 112 and 122 are attached to black and red driving shafts 610 and 620 of stepping motors, respectively; and each of the first black roll up motor shaft 115, the first red roll up motor shaft 125, and the second roll up motor shaft 215 is driven by a torque motor.
  • the braking shafts 114, 124, and 214 provide an appropriate braking due to a prescribed torque to the first black roll out reel 111, the first red roll out reel 121, and the second roll out reel 210, respectively, such that the first black film member 110, the first red film member 120, and the second film member 200 can be rolled out smoothly at a constant tension.
  • the stepping motors connected to the black and red driving shafts 610 and 620 are controlled by the motor control unit 310 to be synchronized with each other completely, such that the first black film member 110, the first red film member 120, and the second film member 200 can be rolled out from the first black roll out reel 111, the first red roll out reel 121, and the second roll out reel 210 for the identical amount simultaneously.
  • the torque motors connected to the first black and red roll up motor shafts 115 and 125 and the second roll up motor shaft 215 are controlled by the motor control unit 310 to drive the first black roll up reel 113, the first red roll up reel 123, and the second roll up reel 213 such that the first black film member 110, the first red film member 120, and the second film member 200 can be drawn out from the black and red platen rollers 112 and 122 without any sagging.
  • Fig. 8 shows a modified configuration for the second embodiment of Fig. 2 described above, which differs from the configuration of Fig. 2 in that: each of the motor shafts 114 and 124 to which the first black roll out reel 111 and the first red roll out reel 121 are attached, respectively, is replaced by a braking shaft not connected with a motor; the black and red platen rollers 112 and 122 are attached to black and red driving shafts 610 and 620 of stepping motors, respectively; each of the first black roll up motor shaft 115 and the first red roll up motor shaft 125 is driven by a torque motor; and the driving roller 217 and the fourth guide roller 219 are made to be not connected with a motor and freely rotatable.
  • the braking shafts 114 and 124, the stepping motors connected to the black and red driving shafts 610 and 620, and the torque motors connected to the first black and red roll up motor shafts 115 and 125 are substantially similar to those in the modified configuration of Fig. 7 described above.
  • the driving roller 217 and the fourth guide roller 219 only functions to guide the loop shaped second film member 201 by freely rotating.
  • the driving roller 217 and the fourth guide roller 219 may be connected with motors as in the configuration of Fig. 2.
  • Fig. 9 shows a modified configuration for the third embodiment of Fig. 3 described above, which differs from the configuration of Fig. 3 in that: each of the motor shafts 114, 124, and 214 to which the first black roll out reel 111, the first red roll out reel 121, and the second roll out reel 210 are attached, respectively, is replaced by a braking shaft not connected with a motor; the black and red platen rollers 112 and 122 are attached to black and red driving shafts 610 and 620 of stepping motors, respectively; and each of the first black roll up motor shaft 115, the first red roll up motor shaft 125, and the second roll up motor shaft 215 is driven by a torque motor.
  • These changes are substantially similar to those in the modified configuration of Fig. 7 described above.
  • Fig. 10 shows a modified configuration for the fourth embodiment of Fig. 4 described above, which differs from the configuration of Fig. 4 in that: each of the motor shafts 114 and 124 to which the first black roll out reel 111 and the first red roll out reel 121, are attached, respectively, is replaced by a braking shaft not connected with a motor; the black and red platen rollers 112 and 122 are attached to black and red driving shafts 610 and 620 of stepping motors, respectively; each of the first black roll up motor shaft 115 and the first red roll up motor shaft 125 is driven by a torque motor; and the fourth guide roller 219 is made to be not connected with a motor and freely rotatable.
  • These changes are substantially similar to those in the modified configuration of Fig. 8 described above.
  • Fig. 11 shows a modified configuration for the fifth embodiment of Fig. 5 described above, which differs from the configuration of Fig. 5 in that: each of the motor shafts 114, 124, and 214 to which the first black roll out reel 111, the first red roll out reel 121, and the second roll out reel 210 are attached, respectively, is replaced by a braking shaft not connected with a motor; the black and red platen rollers 112 and 122 are attached to black and red driving shafts 610 and 620 of stepping motors, respectively; and each of the first black roll up motor shaft 115, the first red roll up motor shaft 125, and the second roll up motor shaft 215 is driven by a torque motor.
  • These changes are substantially similar to those in the modified configuration of Fig. 7 described above.
  • Fig. 12 shows a modified configuration for the sixth embodiment of Fig. 6 described above, which differs from the configuration of Fig. 6 in that: each of the motor shafts 114 and 124 to which the first black roll out reel 111 and the first red roll out reel 121, are attached, respectively, is replaced by a braking shaft not connected with a motor; the black and red platen rollers 112 and 122 are attached to black and red driving shafts 610 and 620 of stepping motors, respectively; each of the first black roll up motor shaft 115 and the first red roll up motor shaft 125 is driven by a torque motor; and the fourth guide roller 219 is made to be not connected with a motor and freely rotatable.
  • These changes are substantially similar to those in the modified configuration of Fig. 8 described above.
  • each of the first to six embodiments described above may be further modified to change the number of first film members to just one for the monochromatic printing, or to more than two for the multi-color printing using more than two colors. It should be obvious that, in a case of increasing the number of first film members, the corresponding platen roller and the printing head as well as elements associated with them must also be added accordingly.
  • the first to six embodiments described above are not only applicable to the printing target in a form of the cardboard A as described above, but also applicable to the other printing targets such as a box shaped cardboard, an object made of wood or iron, etc.
  • the surface of the printing target may not necessarily be a flat surface, and can be a curved surface such as that of a cylindrical printing target.
  • the thermal transfer roller 500 should preferably be moved along the second film member 200 or 201 in opposite directions in two successive thermal transfer printing operations, in such a manner that the thermal transfer roller 500 is moved alternately from the first guide roller 211 side or the fifth guide roller 216 side to the second guide roller 212 side or the driving roller 217 side for one thermal transfer printing operation, and from the second guide roller 212 side or the driving roller 217 side to the first guide roller 211 side or the fifth guide roller 216 side for next thermal transfer printing, and so on.
  • the movable roller 221 may be made to be movable in any direction other than a direction perpendicular to the cardboard A as shown in Figs. 3 and 4, so long as it is possible to temporarily pool some portions of the second film member 200 or 201.
  • a seventh embodiment of a thermal transfer type printing apparatus will be described in detail.
  • This thermal printer of Fig. 13 includes a first black film member 710, a first red film member 720, and a second film member 800.
  • the first black film member 710 carries on one side a carbon black C1 as a thermally transferrable applied material for printing, while the first red film member 720 carries on one side a carbon red C2 as a thermally transferrable applied material for printing.
  • the second film member 800 carries no applied material initially, and receives the carbon black C1 and the carbon red C2 thermally transferred from the first black film member 710 and the first red film member 720.
  • the first black film member 710 and the first red film member 720 are initially provided inside a printer body in a state of being rolled up on cartridge type first black roll out reel 711 and first red roll out reel 721, respectively. Then, the first black film member 710 is rolled out with the carbon black C1 facing inwards, guided into a vicinity of a platen roller 900 by a plurality of guide rollers 712 and a black printing head 713 located around the platen roller 900, and rolled up by a first black roll up reel 714.
  • the first red film member 720 is rolled out with the carbon red C2 facing inwards, guided into a vicinity of the platen roller 900 by a plurality of guide rollers 722 and a red printing head 723 located around the platen roller 900, and rolled up by a first black roll up reel 724.
  • the first black roll out reel 711 and the first red roll out reel 721 are detachably attached to a first black roll out motor shaft 715 and a first red roll out motor shaft 725, respectively, each of which is connected with a braking motor (not shown) for generating a prescribed braking torque to provide a constant tension to the respective one of the first black film member 710 and the first red film member 720.
  • the first black roll up reel 714 and the first red roll up reel 724 are detachably attached to a first black roll up motor shaft 716 and a first red roll up motor shaft 726, respectively, each of which is connected with a torque motor (not shown) for rolling up the respective one of the first black film member 710 and the first red film member 720 at a constant tension.
  • the second film member 800 is initially provided inside a printer body in a state of being rolled up on a cartridge type second roll out reel 810. Then, the second film member 800 is rolled out from this second roll out reel 810, guided by a plurality of guide rollers 811 and a feed forward roller 812 to the platen roller 900 around which it is wound, guided by printing guide rollers 813 to have its one side which received the black carbon C1 and the red carbon C2 to be parallelly facing toward a surface of a printing target in a form of a cardboard A, and rolled up by a second roll up reel 214.
  • the second roll out reel 810 is detachably attached to a second roll out motor shaft 815 connected with a braking motor (not shown) for generating a prescribed braking torque to provide a constant tension to the second film member 800.
  • the feed forward roller 812 operates to feed the second film member 800 at a high speed.
  • the second roll up reel 816 is detachably attached to a second roll up motor shaft 816 connected with a torque motor (not shown) for rolling up the second film member 800 at a constant tension.
  • the platen roller 900 is attached to a stepping motor 901 as shown in Fig. 14, and controls the motion of the second film member 900 around this platen roller 900 accurately.
  • Each of the black printing head 713 and the red printing head 723 is equipped with a multiplicity of dot shaped heat generating resistor elements, and an amount of current flowing through each of these heat generating resistor elements is controlled by a black printing controller (not shown) and a red printing controller (not shown), respectively.
  • the black printing head 713 is located around the platen roller 900 at an upper stream side of the second film member 800, while the red printing head 723 is located around the platen roller 900 at a lower stream side of the second film member 800.
  • Each of the black and red printing heads 713 and 723 is made to be pivotable about a fixed end by means of a spring 920 and an air cylinder 940, such that a free end can be moved toward or away from the platen roller 900 by this pivotal motion.
  • the spring 920 draws the free end of the respective one of the black and red printing heads 713 and 723 toward the platen roller 900 such that the respective one of the first black and red film members 710 and 720 is pressed against the second film member 800 wound around the platen roller 900 by a constant force.
  • the drawing force exerted by the spring 920 can be adjusted by means of an adjustment bolt 930 attached to the spring 920.
  • the air cylinder 940 pulls the free end of the respective one of the black and red printing heads 713 and 723 away from the platen roller 900.
  • the black printing head 713 and the red printing head 723 are controlled to thermally transfer the portions of the carbon black C1 and the carbon red C2 on the first black film member 710 and the first red film member 720 that are necessary for forming a desired printing pattern to be printed on the second film member 800.
  • the black printing head 713 and the red printing head 723 are moved away from the platen roller 900, and while the black printing head 713 and the red printing head 723 are located away from the platen roller 900, the first black film member 710 and the first red film member 720 are not rolled up.
  • a thermal transfer roller 910 which is movable in a direction along the second film member 800 as well as in a direction of moving toward or moving away from the second film member 800.
  • the thermal transfer roller 910 is moved toward the second film member 800 to press the second film member 800 against the cardboard A while heating the second film member 800, and rolls along the second film member 800 between the printing guide rollers 813, to print the entire desired printing pattern formed by the carbon black C1 and the carbon red C2 onto the cardboard A.
  • this thermal transfer roller 910 has its surface portion formed by a soft layer with the hardness of about 30 such that the second film member 800 can be tightly pressed against the surface of the printing target even when the surface of the printing target is not smooth as in a back side surface of a corrugated cardboard.
  • this thermal printer is capable of achieving an accurate printing even on a curved surface or a rough surface.
  • the cardboard A is automatically conveyed into the thermal transfer printing position between the printing guide rollers 813 by means of a belt conveyer (not shown ).
  • the command signal for the desired printing pattern is supplied from a printer control unit (not shown) of the thermal printer to the black printing controller (not shown) and the red printing controller (not shown), where this command signal commands each of the black printing head 713 and the red printing head 723 to apply heat to a region in a shape of a positive mirror image of the black and red portions in the desired printing pattern, respectively, just as they are expected to appear on the cardboard A when the printing is made.
  • the black printing head 713 is moved toward the platen roller 900 to press the second film member 800 against the first black film member 710, and the currents are supplied only to those heat generating resistor elements located within a region in the shape of the positive mirror image of the black portion in the desired printing pattern, so as to generate the heat in a region in the shape of the positive mirror image of the black portion in the desired printing pattern.
  • the platen roller 900 is accurately rotated by means of the stepping motor 901 to place the appropriate portion of the second film member 800 at the heating position of the black printing head 713.
  • the heat generated by the black printing head 713 is transmitted to the first black film member 710, and the carbon black C1 located within a region in the shape of the positive mirror image of the black portion in the desired black printing pattern is thermally transferred from the first black film member 710 to the second film member 800.
  • the black printing head 713 is moved away from the second film member 800 and the rolling out of the first black film member 710 is stopped.
  • the second film member 800 is rolled by the platen roller 900 to move a region having the black portion in the desired printing pattern formed therein to the heating position of the red printing head 723.
  • the red printing head 723 is moved toward the platen roller 900 to press the second film member 800 against the first red film member 720, and the currents are supplied only to those heat generating resistor elements located within a region in the shape of the positive mirror image of the red portion in the desired red printing pattern, so as to generate the heat in a region in the shape of the positive mirror image of the red portion in the desired printing pattern.
  • the platen roller 900 is accurately rotated by means of the stepping motor 901 to place the appropriate portion of the second film member 800 at the heating position of the red printing head 723.
  • the heat generated by the red printing head 723 is transmitted to the first red film member 720, and the carbon red C2 located within a region in the shape of the positive mirror image of the red portion in the desired red printing pattern is thermally transferred from the first red film member 720 to the second film member 800.
  • the red printing head 723 is moved away from the second film member 800 and the rolling of the first red film member 720 is stopped.
  • the second film member 800 with the desired printing pattern formed thereon is moved by the platen roller 900 over the cardboard A until the desired printing pattern is placed at the thermal transfer printing position of the thermal transfer roller 910 provided over the cardboard A.
  • the heated thermal transfer roller 910 is moved toward the second film member 800 to press the second film member 800 against the cardboard A, and then rolled along the second film member 800 between the printing guide rollers 813, from the platen roller 900 side to the second roll up reel 814 side.
  • the desired printing pattern formed on the second film member 800 is thermally transferred onto the surface of the cardboard A, such that the positive normal image of the desired printing pattern is printed on the cardboard A.
  • the thermal transfer roller 910 is moved away from the second film member 800 such that the second film member 800 is separated from the cardboard A.
  • the thermal transfer roller 910 returns back to its initial position at the platen roller 900 side, and the second film member 800 is fedforward for a prescribed amount by the feed forward roller 812 while the prescribed amount of the second film member 800 is rolled up by the second roll up reel 814.
  • the cardboard A with the desired printing pattern printed thereon is conveyed out from the thermal printer by the belt conveyer (not shown), and a new cardboard A to be printed next is conveyed into a thermal transfer printing position in the thermal printer between the printing guide rollers 813.
  • the formation of the new desired printing pattern is carried out by the black and red printing heads 713 and 723 in the manner described above.
  • the second film member 800 with the new desired printing pattern formed thereon is moved to the thermal transfer printing position over the new cardboard A, and the printing of the new desired printing pattern onto the new cardboard A is carried out in the manner described above.
  • the black and red printing heads 713 and 723 are located around the single common platen roller 900, so that the region of the second film member 800 on which the black portion of the desired printing pattern is thermally transferred by the black printing head 713 can be moved accurately to the heating position of the red printing head 723 by the rotation of the platen roller 900 caused by the stepping motor 901, so that the problem of the deviated coloring can be prevented almost completely.
  • the controlling in the thermal printer can be simplified and the size of the thermal printer can be reduced.
  • the distance for which the second film member 800 is moved from the heating position of the black printing head 713 to the heating position of the red printing head 723 can be very short, and the wasteful moving of the second film member 800 becomes unnecessary and the total amount of the second film member 800 required for the printing of the entire desired printing pattern can be reduced.
  • the black and red portions in the desired printing pattern are formed on the same region of the second film member 800 by the black and red printing heads 713 and 723, and the black and red portions in the desired printing pattern formed on the second film member 800 are thermally transferred onto the cardboard A altogether at once by the thermal transfer roller 910, so that the thermal transfer type multi-color printing can be realized very easily at a high speed.
  • both of the black and red portions of the desired printing pattern can be formed in the same thermal printer, so that there is no need for the alignment of the different color portions, and therefore the highly accurate multi-color printing can be realized, by using only one thermal printer such that the cost required for the multi-color printing can also be reduced.
  • each of the first black and red film members 710 and 720 is rolled only while the heating operation by the respective one of the black and red printing heads 713 and 723 is carried out, so that the consumption of the first black and red film members 710 and 720 can be kept at the absolutely necessary minimum level.
  • this seventh embodiment may be further modified to change the number of first film members and the number of the printing heads provided around the platen roller 900 to more than two for the multi-color printing using more than two colors. It is also possible to provide more than one of the platen rollers similar to the platen roller 900 described above around which more than one printing heads are located.
  • the seventh embodiment described above are not only applicable to the printing target in a form of the cardboard A as described above, but also applicable to the other printing targets such as a box shaped cardboard, an object made of wood or iron, etc.
  • the surface of the printing target may not necessarily be a flat surface, and can be a curved surface such as that of a cylindrical printing target.
  • the thermal transfer roller 910 can be moved along the second film member 800 in opposite directions in two successive thermal transfer printing operations, in such a manner that the thermal transfer roller 910 is moved alternately from the platen roller 900 side to the second roll up reel 814 side for one thermal transfer printing operation, and from the second roll up reel 814 side to the platen roller 900 side for next thermal transfer printing, and so on.

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EP93115379A 1992-09-24 1993-09-23 Verfahren und Gerät für Wärmetransferdruck hoher Geschwindigkeit Withdrawn EP0589462A1 (de)

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JP25473192A JPH06155709A (ja) 1992-09-24 1992-09-24 印刷機
JP254732/92 1992-09-24
JP25472892A JPH06115046A (ja) 1992-09-24 1992-09-24 印刷機
JP254728/92 1992-09-24
JP254731/92 1992-09-24
JP04254732A JP3138890B2 (ja) 1992-09-24 1992-09-24 印刷機

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EP0680835A2 (de) * 1994-04-05 1995-11-08 Michiharu Tohdo Wärmetransferdruckverfahren und Vorrichtung
US6639618B2 (en) * 2001-05-14 2003-10-28 Alps Electric Co., Ltd. Thermal transfer line printer properly used for forming intermediate transfer type image
WO2003091030A1 (en) * 2002-04-24 2003-11-06 Eidos S.P.A. A machine for printing images on articles
WO2016075446A1 (en) * 2014-11-10 2016-05-19 David Hitch Apparatus for printing onto objects
US20220105740A1 (en) * 2020-10-02 2022-04-07 Illinois Tool Works Inc. Multi-Color Retransfer Single Stamping System And Method

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US5005028A (en) * 1985-06-03 1991-04-02 Canon Kabushiki Kaisha Image forming method and transfer recording medium therefor
EP0262595A2 (de) * 1986-09-29 1988-04-06 Hitachi, Ltd. Verfahren und Vorrichtung zur thermischen Aufzeichnung durch Übertragung
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Publication number Priority date Publication date Assignee Title
EP0680835A2 (de) * 1994-04-05 1995-11-08 Michiharu Tohdo Wärmetransferdruckverfahren und Vorrichtung
EP0680835A3 (de) * 1994-04-05 1997-04-23 Michiharu Tohdo Wärmetransferdruckverfahren und Vorrichtung.
US6639618B2 (en) * 2001-05-14 2003-10-28 Alps Electric Co., Ltd. Thermal transfer line printer properly used for forming intermediate transfer type image
WO2003091030A1 (en) * 2002-04-24 2003-11-06 Eidos S.P.A. A machine for printing images on articles
WO2016075446A1 (en) * 2014-11-10 2016-05-19 David Hitch Apparatus for printing onto objects
US20220105740A1 (en) * 2020-10-02 2022-04-07 Illinois Tool Works Inc. Multi-Color Retransfer Single Stamping System And Method

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