JP2014184582A - Thermal printer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a thermal printer capable of selectively transferring multiple types of protective layer while suppressing increase in cost.SOLUTION: In an ink ribbon 3, a protective layer 16 is provided to overlap with a protective layer 17. The protective layer 17 is transferred to paper 4 by giving heat of a quantity of heat P to a protective layer 11d. The protective layer 16 is transferred to the paper 4 by giving heat of a quantity of heat Pa greater than the quantity of heat P to the protective layer 11d. A control unit 9 controls a thermal head 1 to generate one of the heat of the quantity of heat P and the heat of the quantity of heat Pa.

Description

  The present invention relates to a thermal printer using an ink ribbon having a plurality of types of protective layers.

  In recent years, thermal printers have been widely used in the photographic field. Further, in the photographic field, the thermal printer is often required to switch the glossiness (glossiness) of the paper surface by a simple operation according to the user's preference. For this reason, various inventions have been made for thermal printers.

  For example, Patent Document 1 discloses a technique for reducing the gloss of the surface of a protective layer (overcoat layer) (hereinafter also referred to as related technique A). Specifically, in Related Art A, the heating temperature of the thermal head is increased during transfer of the protective layer (overcoat layer). Thereby, the gloss of the surface of a protective layer is made small.

  Patent Document 2 discloses a technique (hereinafter also referred to as related technique B) in which two types of protective layers (overcoat layers) are provided on an ink ribbon and a protective layer to be transferred is switched according to preference. .

Japanese Patent No. 4457452 (paragraphs 0015 to 0024) JP 2007-001129 A (paragraphs 0024 to 0034)

  In Related Art B, two types of protective layers (overcoat layers) are provided on the ink ribbon so as not to overlap. Hereinafter, a conventional ink ribbon provided with one type of protective layer is also referred to as an ink ribbon J. For this reason, the length of the ink ribbon in the related art B is longer than the length of the ink ribbon J. As a result, the number of sheets of paper that can be printed on the roll-shaped ink ribbon in the related art B is smaller than that of the roll-shaped ink ribbon J having the same diameter as that of the roll-shaped ink ribbon.

  Therefore, in the related art B, the length of the ink ribbon required for printing on a predetermined number of sheets is increased as compared with the conventional technique using the ink ribbon J. As a result, the related technique B has a problem that the cost for printing increases.

  The present invention has been made to solve such problems, and an object thereof is to provide a thermal printer capable of selectively transferring a plurality of types of protective layers while suppressing an increase in cost. And

  In order to achieve the above object, a thermal printer according to one embodiment of the present invention includes a plurality of types of color regions indicating colors to be transferred to an object, and transferred to the object by being transferred to the object. Printing is performed using an ink ribbon having a protective layer for protecting the printed color. The protective layer of the ink ribbon is provided so as to overlap the first protective layer and the first protective layer transferred to the object when the first heat amount is applied to the protective layer. A second protective layer that is transferred to the object when heat having a second heat amount greater than the first heat amount is applied to the protective layer, and the thermal printer is configured to apply heat to the ink ribbon. And a control unit that performs control to cause the thermal head to generate either the heat of the first heat amount or the heat of the second heat amount.

  According to the present invention, in the ink ribbon, the second protective layer is provided so as to overlap the first protective layer. The first protective layer is transferred to the object by applying a first amount of heat to the protective layer. The second protective layer is transferred to the object when heat having a second heat quantity larger than the first heat quantity is applied to the protective layer. The control unit performs control to cause the thermal head to generate either the heat of the first heat amount or the heat of the second heat amount.

  That is, in the ink ribbon, the second protective layer is provided so as to overlap the first protective layer. Thereby, in an ink ribbon, it can suppress that the area in which a 2nd protective layer and a 1st protective layer are formed becomes large. Thereby, in the structure which provides multiple types of protective layers in an ink ribbon, it can suppress that the length of an ink ribbon becomes unnecessarily long. Therefore, it is possible to suppress an increase in cost in a configuration in which a plurality of types of protective layers are selectively transferred. Therefore, it is possible to selectively transfer a plurality of types of protective layers while suppressing an increase in cost.

It is a block diagram which shows schematic structure of the thermal printer which concerns on Embodiment 1 of this invention. It is a figure which shows a part of ink ribbon which concerns on Embodiment 1 of this invention. It is sectional drawing of the part in which the protective layer is formed among ink ribbons. It is a figure for demonstrating transcription | transfer of the protective layer when the heat | fever of the heat amount P is given. It is a figure for demonstrating transcription | transfer of the protective layer when the heat | fever of heat amount Pa is given. It is a block diagram which shows schematic structure of the thermal printer which concerns on a comparative example. It is a figure which shows a part of ink ribbon used with the thermal printer which concerns on a comparative example. It is sectional drawing of the part in which the protective layer is formed among ink ribbons.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same components are denoted by the same reference numerals. Their names and functions are also the same. Therefore, detailed description thereof may be omitted.

  It should be noted that the dimensions, materials, shapes, relative arrangements, and the like of the constituent elements exemplified in the embodiments are appropriately changed depending on the configuration of the apparatus to which the present invention is applied and various conditions. It is not limited to those examples. Moreover, the dimension of each component in each figure may differ from an actual dimension.

<Comparative example>
Hereinafter, a thermal printer 1000 that performs printing using an ink ribbon will be described as a comparative example. FIG. 6 is a block diagram illustrating a schematic configuration of a thermal printer 1000 according to a comparative example. FIG. 7 is a diagram illustrating a part of the ink ribbon 33 used in the thermal printer 1000 according to the comparative example.

  Referring to FIG. 7, a plurality of transfer areas each including color areas 21 a, 21 b, 21 c and a protective layer 21 d are formed on ink ribbon 33 along the longitudinal direction of ink ribbon 33. Yellow, magenta, and cyan inks are formed in the color regions 21a, 21b, and 21c, respectively. That is, three color areas are formed in one transfer area of the ink ribbon 33. Note that the number of color regions formed in the one transfer region is not limited to 3, and may be 4 or more, for example.

  In the ink ribbon 33, a cue mark 22 is formed at the leading portion (end portion) of each of the color regions 21a, 21b, 21c and the protective layer 21d. The cue mark 22 is detected by a detection mechanism provided in the thermal printer 1000. Thereby, cueing of each color area and the protective layer is performed.

  Next, the printing operation performed by the thermal printer 1000 will be described. First, the drive motor 35a drives (rotates) the take-up side ink ribbon 35 to wind up the ink ribbon 33. When the detection sensor 37 detects the cue mark 22 of the ink ribbon 33, the thermal head 31 and the platen roller 32 are pressed against each other, and the ink ribbon 33 and the paper 34 are sandwiched.

  When the thermal head 31 applies heat to the ink ribbon 33, the dye on the ink ribbon 33 is transferred to the paper 34 and an image for one line is formed. When an image having a designated number of lines corresponding to one screen is transferred to the paper 34, the pressure contact between the thermal head 31 and the platen roller 32 is released. Thereafter, the ink ribbon 33 is wound up by a predetermined length, and the next color is cued.

  The above processing is performed on the color regions 21a, 22b, and 22c. As a result, the colors of the color regions 21a, 22b, and 22c are sequentially transferred to the paper 34. As a result, an image is formed on the paper 34. Finally, the protective layer 21d is transferred.

  FIG. 8 is a cross-sectional view of a portion of the ink ribbon 33 where the protective layer 21d is formed. Referring to FIG. 8, a back surface portion 41 is applied (formed) on the surface of the base material 42 that comes into contact with the thermal head 31. The back surface portion 41 serves to prevent the thermal head 31 and the base material 42 from being fused and to convey the ink ribbon 33 for lubrication. Further, a protective layer 21 d is applied (formed) to the surface of the base material 42 that comes into contact with the paper 34. The protective layer 21d has a function of reducing fading, scratching, and the like of the printed material.

  The protective layer 21 d is composed of a laminated adhesive layer 44 and release layer 43. The adhesive layer 44 adheres to the paper 34 by applying a certain amount of heat to the protective layer 21d. After the adhesive layer 44 adheres to the paper 34 with sufficient adhesive force, the ink ribbon 33 is wound up. Thereby, the peeling layer 43 peels from the base material 42, and the protective layer 21d is transferred (formed) to the paper 34.

  If the amount of heat generated by the thermal head 31 is insufficient during the transfer of the protective layer 21d, the adhesive layer 44 does not adhere to the paper 34 with sufficient adhesive force. When the amount of heat from the thermal head 31 is too large, the adhesive layer 44 is fused to the paper 34. Therefore, when the peeling layer 43 peels from the base material 42, large unevenness is generated on the surface of the protective layer 21d. Therefore, the glossiness of the surface of the protective layer 21d is lost.

  Further, by providing unevenness on the surface of the release layer 43, it is possible to intentionally reduce the glossiness of the surface and to impart matting properties to the surface of the protective layer 21d. As described above, the thermal printer is often required to change the glossiness (glossiness) of the paper surface according to the user's preference.

  Therefore, the following embodiment satisfies the demand described in the comparative example and solves the problem in the related art B described above.

<Embodiment 1>
First, a thermal printer according to one embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a block diagram showing a schematic configuration of a thermal printer 100 according to Embodiment 1 of the present invention. The thermal printer 100 performs printing using an ink ribbon 3 having the characteristics described below.

  Referring to FIG. 1, a thermal printer 100 includes a thermal head 1, a platen roller 2, an ink ribbon 3, a winding side ink ribbon 5, a drive motor 5 a, a supply side ink ribbon 6, and a detection sensor 7. And a control unit 9. Note that the paper 4 is attached to the thermal printer 100. The paper 4 is an object to which the ink (color) of the ink ribbon 3 is transferred.

  The thermal head 1 generates heat to be applied to the ink ribbon 3 under the control of the control unit 9. As will be described in detail later, the thermal head 1 generates heat having a heat quantity P and heat having a heat quantity larger than the heat quantity P. Hereinafter, the heat having a heat quantity larger than the heat quantity P is also referred to as a heat quantity Pa.

  The platen roller 2 is disposed to face the thermal head 1. A part of the ink ribbon 3 and the paper 4 are sandwiched between the platen roller 2 and the thermal head 1.

  FIG. 2 is a diagram showing a part of the ink ribbon 3 according to Embodiment 1 of the present invention. The shape of the ink ribbon 3 is long. Referring to FIG. 2, a plurality of transfer areas composed of color areas 11 a, 11 b, 11 c and a protective layer 11 d are applied (formed) to the ink ribbon 3 along the longitudinal direction of the ink ribbon 3. . That is, the ink ribbon 3 has color regions 11a, 11b, and 11c and a protective layer 11d.

  Each of the color regions 11a, 11b, and 11c indicates a color to be transferred to the paper 4 that is a transfer object. Specifically, yellow, magenta, and cyan inks are formed in the color regions 11a, 11b, and 11c, respectively. The protective layer 11d is a layer for improving the durability of the paper 4 on which printing has been performed. In the ink ribbon 3, a cueing mark 12 is formed at the leading portion (end portion) of each of the color regions 11a, 11b, 11c and the protective layer 11d. That is, the cue mark 12 is provided in association with each of the color regions 11a, 11b, 11c and the protective layer 11d.

  FIG. 3 is a cross-sectional view of a portion of the ink ribbon 3 where the protective layer 11d is formed. Referring to FIG. 3, a back surface portion 13 is coated (formed) on the surface of the base material 14 that comes into contact with the thermal head 1. The back surface portion 13 has a role of preventing the thermal head 1 and the base material 14 from being fused and transporting the ink ribbon 3 for lubrication.

  In addition, a protective layer 11 d is applied (formed) to the surface of the base material 14 that contacts the paper 4. The protective layer 11d is a layer for protecting the color transferred to the paper 4 by being transferred to the paper 4 (object). For example, the protective layer 11d has a function of reducing fading, scratching, and the like of the printed material. The printed matter is the paper 4 on which the color (ink) in each of the color regions 11a, 11b, and 11c and the protective layer are transferred.

  The protective layer 11 d includes a protective layer 17 and a protective layer 16. The protective layer 17 has a high glossiness (glossiness) on the surface of the protective layer 17. The protective layer 16 has a low surface glossiness (glossiness). That is, the protective layer 17 has a higher surface gloss than the protective layer 16.

  The protective layer 16 is provided so as to overlap the protective layer 17. That is, the protective layer 16 is provided on the protective layer 17. Specifically, the protective layer 16 is attached (applied) to the surface of the base material 14 near the paper 4. Further, a protective layer 17 is attached (applied) to the surface of the protective layer 16 near the paper 4. The protective layer 16 is provided so as to cover the entire protective layer 17.

  Note that the protective layer 16 is not limited to the configuration provided to cover the entire upper portion of the protective layer 17. For example, the protective layer 16 may be provided so as to cover the upper half of the protective layer 17.

  The protective layer 16 includes a laminated adhesive layer 16s and a release layer 16h. The protective layer 17 includes a laminated adhesive layer 17s and a release layer 17h.

  The protective layer 17 is transferred to the paper 4 (target object) when the thermal head 1 applies heat P to the protective layer 11d (ink ribbon 3).

  Specifically, as shown in FIGS. 4A and 4B, the thermal head 1 applies heat of the amount of heat P to the protective layer 11 d, thereby bonding the adhesive layer 17 s to the paper 4. After the adhesive layer 17s adheres to the paper 4 with sufficient adhesive force, the ink ribbon 3 is wound up by the winding-side ink ribbon 5, and the ink ribbon 3 moves. Thereby, the peeling layer 17h peels from the adhesive layer 16s, and the protective layer 17 is transferred (formed) to the paper 4 (see FIG. 4B).

  Hereinafter, the force applied to the ink ribbon 3 when the ink ribbon 3 is wound by the winding-side ink ribbon 5 is also referred to as a winding force.

  In addition, in the state where the heat P is applied to the protective layer 11d and the adhesive layer 17s is adhered to the paper 4, the peeling layer 16h is peeled off from the substrate 14 by the winding force applied to the ink ribbon 3. The layer 17h is made of a material that can be peeled off with a force smaller than that of the peeling layer 16h. Specifically, the release layer 17h and the release layer 17h are separated so that the force required for the release layer 17h to be released from the adhesive layer 16s is smaller than the force required for the release layer 16h to be released from the substrate 14. Layer 16h is constructed.

  For example, the release layer 17h and the release layer 16h are configured such that the adhesive force of the release layer 17h is smaller than the adhesive force of the release layer 16h regardless of the amount of heat applied. Thereby, the force with which the peeling layer 17h (protective layer 17) sticks to the adhesive layer 16s is smaller than the force with which the release layer 16h (protective layer 16) sticks to the base material 14.

  The protective layer 16 is transferred to the paper 4 (object) by the thermal head 1 having a heat amount Pa greater than the heat amount P applied to the protective layer 11d (ink ribbon 3). The amount of heat Pa is, for example, 1.1 to 2.0 times the amount of heat P.

  Specifically, as shown in FIGS. 5A and 5B, the thermal head 1 applies heat of the amount of heat Pa to the protective layer 11d (ink ribbon 3), so that the adhesive layer 17s becomes paper. 4 and release layer 17h. After the adhesive layer 17s adheres to the paper 4 and the release layer 17h with sufficient adhesive force, as will be described in detail later, the ink ribbon 3 is taken up by the take-up side ink ribbon 5, and the ink ribbon 3 moves. Thereby, the peeling layer 16h peels from the base material 14, and the protective layer 17 and the protective layer 16 are transferred (formed) to the surface of the paper 4 (see FIG. 5B).

  In addition, in a state where heat of the amount of heat Pa is applied to the protective layer 11d (ink ribbon 3) and the adhesive layer 17s adheres to the release layer 17h, the release layer 17h is removed from the adhesive layer 16s by the winding force applied to the ink ribbon 3. The adhesive layer 16s and the adhesive layer 17s are configured so as not to peel off. That is, when heat of the amount of heat Pa is applied to the protective layer 11d (ink ribbon 3), the force for bonding the release layer 17h and the adhesive layer 16s is greater than the force for bonding the release layer 16h and the base material 14. Thus, the adhesive layer 16s and the adhesive layer 17s are configured.

  Specifically, the configuration of the adhesive layer 16s and the adhesive layer 17s is such that, for example, when the heat of Pa is applied to the protective layer 11d (ink ribbon 3), the adhesive strength of the adhesive layer 16s is the same as that of the adhesive layer 17s. It is the structure (henceforth the structure A) which becomes larger than adhesive force.

  In the following, a material whose adhesion is improved when heat of a heat amount Pa or more is applied is also referred to as material Na. In this case, in the configuration A, for example, the ratio (for example, 80%) in which the adhesive layer 16s includes the material Na is larger than the ratio (for example, 0 to 10%) in which the adhesive layer 17s includes the material Na. .

  Note that the configuration A is not limited to the above, and other configurations may be used as long as the configuration uses a material whose state (for example, adhesive force) changes when heat of a heat amount Pa or more is applied. Good.

  Referring again to FIG. 1, the take-up ink ribbon 5 is configured by winding one side of the ink ribbon 3 around a shaft (not shown). The drive motor 5 a rotates (drives) the winding-side ink ribbon 5 according to the control of the control unit 9. As a result, a part of the ink ribbon 3 is wound around the winding-side ink ribbon 5.

  The supply-side ink ribbon 6 is configured by winding the other side of the ink ribbon 3 around a shaft (not shown). The supply-side ink ribbon 6 supplies the ink ribbon 3 by the length of the wound ink ribbon 3 as the winding-side ink ribbon 5 winds a part of the ink ribbon 3.

  The detection sensor 7 detects the cue mark 12 of the ink ribbon 3 and transmits a detection signal indicating that it has been detected to the control unit 9. The control unit 9 controls the drive motor 5 a and the thermal head 1. Specifically, the control unit 9 controls the torque of the drive motor 5a. The control unit 9 controls the amount of heat generated by the thermal head 1.

  Next, the operation of the thermal printer 100 will be described in detail. First, the control unit 9 of the thermal printer 100 receives print data and protective layer data from an external device. The print data is data for transferring an image to the paper 4.

  The protective layer data is classified into gloss data and mat data. The gloss data is data for transferring the protective layer 17 to the paper 4 so that the protective layer 17 having a high glossiness is the outermost layer. The matting data is data for transferring the protective layer 16 to the paper 4 so that the protective layer 16 having a low glossiness is the outermost layer.

  The control unit 9 drives the drive motor 5a so that the winding-side ink ribbon 5 starts winding the ink ribbon 3 in response to the reception of the print data and the protective layer data.

  When the detection sensor 7 detects the cue mark 12 provided in association with the color region 11a (yellow), the control unit 9 stops driving the drive motor 5a. Thereby, the conveyance (movement) of the ink ribbon 3 is stopped. The control unit 9 performs control so that the thermal head 1 and the platen roller 2 are in pressure contact with each other.

  The control unit 9 causes the thermal head 1 to apply heat corresponding to the image data to the ink ribbon 3 every time the ink ribbon 3 and the paper 4 are moved by a distance (one pixel) corresponding to one line of the image. The thermal head 1 is controlled. As a result, the yellow ink (dye) is thermally transferred to the paper 4. A yellow image is printed on the paper 4 by performing the above processing on each line constituting the image.

  When the printing of the yellow image is completed, the control unit 9 performs the rewinding of the paper 4 and the winding of the ink ribbon 3 around the winding-side ink ribbon 5 in order to cue the color area 11b in the ink ribbon 3. Control to make the removal.

  As in the case of the color region 11a described above, the control unit 9 stops driving the drive motor 5a when the detection sensor 7 detects the cue mark 12 provided in association with the color region 11b (magenta). . Thereby, the conveyance (movement) of the ink ribbon 3 is stopped. The control unit 9 performs control so that the thermal head 1 and the platen roller 2 are in pressure contact with each other. Next, the control unit 9 prints a magenta image by performing the same control as the process for printing a yellow image.

  Thereafter, the control unit 9 sequentially performs a process for transferring (printing) a cyan image and a process for transferring the protective layer. The process for transferring the cyan image and the protective layer is the same as the process described above for printing the yellow image. Then, the thermal printer 100 discharges the paper 4 and ends the printing operation.

  Next, a process for transferring the protective layer (hereinafter also referred to as a protective layer transfer process) will be specifically described. In the protective layer transfer process, the control unit 9 controls the thermal head 1 to cause the thermal head 1 to generate either heat of the heat amount P or heat of the heat amount Pa.

  Here, it is assumed that the protective layer data received by the control unit 9 is gloss data. In this case, in the protective layer transfer process, the control motor 9 drives the drive motor 5a so that the ink ribbon 3 is wound until the detection sensor 7 detects the cue mark 12 provided in association with the protective layer 11d. To control.

  Then, every time the control unit 9 moves the ink ribbon 3 and the paper 4 by a distance (one pixel) corresponding to one line of the image, the thermal head 1 causes the ink ribbon 3 (protective layer 11d) ) To control the thermal head 1 (see FIG. 4A). Thereby, as described above, the adhesive layer 17s adheres to the paper 4.

  Then, as described above, after the adhesive layer 17s adheres to the paper 4 with sufficient adhesive force, the control unit 9 drives the drive motor 5a so that the ink ribbon 3 is taken up by the take-up side ink ribbon 5. Let As described above, the force applied to the ink ribbon 3 when the ink ribbon 3 is wound by the winding-side ink ribbon 5 is referred to as a winding force. That is, the controller 9 controls the winding force applied to the ink ribbon 3 by driving the drive motor 5a.

  When the winding force is applied to the ink ribbon 3, the ink ribbon 3 moves in the direction of the winding-side ink ribbon 5. Along with the movement of the ink ribbon 3, a force in a direction away from the adhesive layer 16s (base material 14) is applied to the release layer 17h.

  Thereby, the peeling layer 17h peels from the adhesive layer 16s, and the protective layer 17 is transferred (formed) to the paper 4 (see FIG. 4B). That is, the protective layer 17 is transferred to the paper 4. In other words, the thermal head 1 transfers heat P to the protective layer 11d (ink ribbon 3), so that the protective layer 17 is transferred to the outermost layer of the paper 4 (object). .

  Thus, the protective layer transfer process is completed. Note that the surface of the protective layer 17 (release layer 17h) has high glossiness (glossiness). Therefore, a printed product having a high glossiness on the surface can be obtained.

  Next, it is assumed that the protective layer data received by the control unit 9 is mat data. In this case, in the protective layer transfer process, the control motor 9 drives the drive motor 5a so that the ink ribbon 3 is wound until the detection sensor 7 detects the cue mark 12 provided in association with the protective layer 11d. To control.

  Then, every time the control unit 9 moves the ink ribbon 3 and the paper 4 by a distance (one pixel) corresponding to one line of the image, the thermal head 1 causes the ink ribbon 3 (protective layer 11d) to generate heat of the amount of heat Pa. ) To control the thermal head 1 (see FIG. 5A). Thereby, as described above, the adhesive layer 17s adheres to the paper 4 and the release layer 17h.

  Then, as described above, after the adhesive layer 17s adheres to the paper 4 and the release layer 17h with sufficient adhesive force, the controller 9 drives so that the ink ribbon 3 is wound up by the winding-side ink ribbon 5. The motor 5a is driven. That is, the controller 9 controls the winding force applied to the ink ribbon 3 by driving the drive motor 5a.

  Specifically, the winding force applied to the ink ribbon 3 by the drive motor 5a so that the release layer 16h is peeled from the base material 14 in a state where heat of the amount of heat Pa is applied to the protective layer 11d (ink ribbon 3). Is controlled by the control unit 9.

  When the winding force controlled as described above is applied to the ink ribbon 3, the ink ribbon 3 moves toward the winding-side ink ribbon 5. Along with the movement of the ink ribbon 3, a force in a direction away from the substrate 14 is applied to the release layer 16 h.

  As a result, the peeling layer 16h peels from the base material 14, and the protective layer 17 and the protective layer 16 are formed on the surface of the paper 4 (see FIG. 5B). That is, the protective layer 17 and the protective layer 16 are transferred to the paper 4. That is, the protective layer 16 is transferred by the thermal head 1 so as to be the outermost layer of the paper 4 (target object) when heat of Pa is applied to the protective layer 11d (ink ribbon 3). .

  Thus, the protective layer transfer process is completed. Thereby, the surface of the uppermost protective layer 16 (peeling layer 16h) transferred to the paper 4 has low gloss (glossiness). Therefore, a printed matter having a mat property can be obtained.

  When the protective layer data received by the control unit 9 is mat data, the winding force (torque) of the drive motor 5a is made larger than when the protective layer data is gloss data. Hereinafter, the winding force will be specifically described.

  As described above, when heat of the amount of heat Pa is applied to the protective layer 11d (ink ribbon 3), the force for bonding the release layer 17h and the adhesive layer 16s is the force for bonding the release layer 16h and the base material 14 The adhesive layer 16s and the adhesive layer 17s are configured to be larger. That is, when heat of the amount of heat Pa is applied to the protective layer 11d (ink ribbon 3), in order to transfer the protective layer to the paper 4, a force for peeling the peeling layer 16h from the substrate 14 is required. .

  In the following, the peeling layer 17h is peeled from the adhesive layer 16s in a state where heat of the heat amount P is applied to the protective layer 11d (ink ribbon 3) by the protective layer transfer process when the protective layer data is gloss data. This force is also referred to as force PW1. That is, the force for peeling the release layer 16h from the base material 14 in a state where the heat of Pa is applied to the protective layer 11d (ink ribbon 3) is larger than the force PW1.

  Therefore, in the protective layer transfer process when the protective layer data is mat data, the control unit 9 increases the winding force (torque) of the drive motor 5a compared to when the protective layer data is gloss data. Then, the ink ribbon 3 is wound up by the winding-side ink ribbon 5. That is, when the protective layer data is mat data, the control unit 9 sets the winding force applied to the ink ribbon 3 by the drive motor 5a sufficiently larger than that when the protective layer data is gloss data. The ink ribbon 3 is wound up by the winding-side ink ribbon 5.

  That is, as described above, the winding applied to the ink ribbon 3 by the drive motor 5a so that the peeling layer 16h is peeled from the base material 14 in a state where the heat of Pa is applied to the protective layer 11d (ink ribbon 3). The magnitude of the taking force is controlled by the control unit 9.

  As described above, according to the present embodiment, in the ink ribbon 3, the protective layer 16 is provided so as to overlap the protective layer 17. The protective layer 17 is transferred to the paper 4 when heat P is applied to the protective layer 11d. Further, the protective layer 16 is transferred to the paper 4 when heat of a heat amount Pa larger than the heat amount P is given to the protective layer 11d. The control unit 9 performs control to cause the thermal head 1 to generate either heat having a heat amount P or heat having a heat amount Pa.

  That is, in the ink ribbon 3, the protective layer 16 is provided so as to overlap the protective layer 17. Thereby, in the ink ribbon 3, it can suppress that the area in which the protective layer 16 and the protective layer 17 are formed becomes large. Thereby, in the structure which provides multiple types of protective layers in the ink ribbon 3, it can suppress that the length of the ink ribbon 3 becomes unnecessarily long. Therefore, it is possible to suppress an increase in cost in a configuration in which a plurality of types of protective layers are selectively transferred. Therefore, it is possible to selectively transfer a plurality of types of protective layers while suppressing an increase in cost.

  Further, according to the present embodiment, a plurality of types of protective layers can be selected and transferred by controlling the amount of heat applied to the ink ribbon and the winding force (torque) of the drive motor 5a. Therefore, it is possible to provide a printed matter having a high glossiness and a printed matter having a matte property with one kind of ink ribbon. In addition, it is possible to obtain a stable quality for a mat-like print. In addition, necessary surface properties can be obtained without variations.

  Further, according to the present embodiment, the protective layer can be selectively transferred with an appropriate amount of heat. That is, a plurality of types of surface properties can be selected as the surface properties of the protective layer. Therefore, the surface property of the transferred protective layer can be set stably. That is, a stable surface property can be obtained. Further, according to the present embodiment, the length of the ink ribbon is not unnecessarily increased by the above configuration.

  In the related art A described above, the glossiness of the surface of the protective layer is controlled by increasing the heating temperature of the thermal head. However, in Related Art A, the glossiness is lowered by changing the surface of the protective layer. Therefore, it becomes difficult to obtain a stable surface property as the heating temperature is increased. Further, the performance of the release layer is impaired, and the protective layer is difficult to peel from the base material of the ink ribbon. For this reason, the upper limit of the heating temperature needs to be set in a range where the protective layer can be peeled off, and there is a problem that it becomes a constraint for reducing the glossiness.

  In the related art B, the ink ribbon is provided so that two types of protective layers (overcoat layers) do not overlap. For this reason, as described above, the length of the ink ribbon necessary for printing on a predetermined number of sheets increases. For this reason, since the replacement frequency of the ink ribbon is increased, there is a problem that the handling and cost of the user are disadvantageous.

  Therefore, this embodiment can solve the above-described problems in the related technologies A and B by configuring as described above.

  In the protective layer transfer process, heat of heat amounts P and Pa is used, but the present invention is not limited to this. In the protective layer transfer process, the control unit 9 may be configured to control the thermal head 1 so as to further increase the amount of heat Pa given by the thermal head 1 when the protective layer data is mat data.

  Hereinafter, the amount of heat Pa indicating a predetermined value Pa0 (a real number greater than 0) is also referred to as the amount of heat Pa0. In the following, the amount of heat Pa greater than the value Pa0 is also referred to as the amount of heat Pa1. Specifically, the control unit 9 may be configured to perform control for causing the thermal head 1 to generate heat having a heat amount Pa (Pa1) larger than a predetermined value Pa0 (hereinafter also referred to as configuration N). .

  The heat of the amount of heat Pa1 is a heat for reducing the glossiness (glossiness) of the surface of the protective layer 16 transferred to the paper 4 (object) when the heat of the amount of heat Pa1 is applied to the protective layer 11d. is there.

  The amount of heat Pa1 is greater than the amount of heat Pa0. The amount of heat Pa1 is, for example, 1.1 to 2.0 times the amount of heat Pa0. The protective layer transfer process of the configuration N is performed when the protective layer data is mat data.

  Specifically, in the protective layer transfer process of configuration N, the control unit 9 performs control to cause the thermal head 1 to generate heat of the amount of heat Pa1. Then, in a state where the adhesive layer 17s is adhered to the paper 4 and the release layer 17h, the control unit 9 increases the winding force (torque) of the drive motor 5a than when the protective layer data is gloss data. The ink ribbon 3 is wound up by the winding-side ink ribbon 5.

  The magnitude of the winding force applied to the ink ribbon 3 by the drive motor 5a so that the release layer 16h is peeled from the base material 14 in a state where heat of the amount of heat Pa1 is applied to the protective layer 11d (ink ribbon 3). Is controlled by the control unit 9.

  As a result, the protective layer 17 and the protective layer 16 are transferred to the paper 4. That is, the protective layer 16 is provided with the heat of the heat amount Pa (heat amount Pa1) larger than the value Pa0 by the thermal head 1 to the protective layer 11d (ink ribbon 3), whereby the outermost surface of the paper 4 (object). Transferred to be a side layer.

  The glossiness of the surface of the protective layer 16 transferred to the paper 4 can be further reduced by the protective layer transfer process of the above configuration N. Thereby, the kind of glossiness (glossiness) of the surface of a printed matter can be increased.

  In the protective layer transfer process, the control unit 9 may be configured to perform control to change the amount of heat applied partially. Thereby, glossiness (glossiness) can be changed in one printed matter.

  In the present invention, the embodiments can be appropriately modified and omitted within the scope of the invention.

  For example, in the present embodiment, the protective layer 11d is composed of two types of stacked protective layers, but is not limited thereto. The protective layer 11d may be composed of three or more types of stacked protective layers.

  1,31 thermal head, 2,32 platen roller, 3,33 ink ribbon, 4,34 paper, 9 control unit, 11a, 11b, 11c, 21a, 21b, 21c color area, 11d, 16, 17, 21d protective layer 12, 22 Cue mark, 13, 41 Back portion, 14, 42 Substrate, 16h, 17h, 43 Release layer, 16s, 17s, 44 Adhesive layer, 100, 1000 Thermal printer.

Claims (2)

Printing using an ink ribbon having a plurality of types of color regions indicating colors to be transferred to an object and a protective layer for protecting the color transferred to the object by being transferred to the object A thermal printer that performs
The protective layer of the ink ribbon is
A first protective layer transferred to the object by applying a first amount of heat to the protective layer;
A second protective layer that is provided so as to overlap on the first protective layer, and is transferred to the object by applying a heat having a second heat amount larger than the first heat amount to the protective layer. ,
The thermal printer is
A thermal head that generates heat to be applied to the ink ribbon;
A thermal printer comprising: a control unit that performs control to cause the thermal head to generate either the first heat quantity heat or the second heat quantity heat. The controller is
Heat for reducing the glossiness of the surface of the second protective layer transferred to the object, which is the heat of the second amount of heat greater than a predetermined value, is applied to the thermal head. The thermal printer according to claim 1, wherein control is performed.

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