JPH08230262A - Heat transfer recording device - Google Patents

Abstract

PURPOSE: To provide a heat transfer recording device in which folding creases are not formed even when the heating stretch of an ink sheet is increased by raising the heating temperature of a thermal head for improving the print density accuracy. CONSTITUTION: A plate-shaped heater is set on a slit component 4 with which an ink sheet 1 after heat transfer is brought into contact, and an unheated section of the ink sheet 1 is reheated and stretched by a heating means to uniformize the tension of the ink sheet. Also, very fine projections are formed on an ink roll on which the ink sheet 1 is passed through after heat transfer, and very fine holes are formed on the unheated section of the ink sheet 1 by a boring means to weaken the tension of the unheated section and uniformize the tension of the ink sheet.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a thermal transfer recording apparatus which prevents wrinkles and folds due to uneven thermal expansion of an ink sheet during thermal transfer by a thermal head.

[0002]

2. Description of the Related Art FIG. 10 is a side view of an essential part showing a conventional thermal transfer recording apparatus disclosed in, for example, Japanese Utility Model Laid-Open No. 6-49044, and FIG. 11 is a perspective view of the essential part. In FIG. 1, 1 is an ink sheet, 2 is an ink sheet supply roll, and 2a is an ink sheet take-up roll that winds up the ink sheet fed from the supply roll 2. 3 is a thermal head, 3a
Is a heating element of the thermal head, 4 is a sliding member provided on the downstream side of the thermal head 3 for conveying the ink sheet, 5 is an ink sheet roller, 6 is a platen, and 7 is paper.

In such a conventional thermal transfer recording apparatus, the platen 6 is rotated while pressing and pinching the ink sheet 1 and the paper 7 between the thermal head 3 and the platen 6. At the same time, the thermal head 3 is heated by an electric signal corresponding to the printed image to thermally transfer the ink of the ink sheet 1 to the paper 7. Then, the sheet 7 is conveyed by the frictional force with the platen 6. Further, the fed ink sheet 1 is bent by the sliding member 4 attached to the thermal head 3, separated from the paper 7, and then wound around the take-up roll 2 a via the ink sheet roller 5.
At this time, by heating the heating element 3 a of the thermal head 3, the ink sheet 1 is heated and stretched by the heating and stretching section 10.
Occurs. The heating / extending portion 10 of the ink sheet is formed by partially extending the base film of the ink sheet 1 by heating, and is in a looser state as compared with the non-heating portion.

FIG. 12 is a plan view showing a state before and after heating the ink sheet. A is a heating extension portion 10 of the ink sheet
Is a tension indicating a weak tension of the ink sheet, and B is a tension indicating a tension of the ink sheet generated at the left and right ends of the unstretched (unheated) ink sheet. Further, C indicates the ink sheet tension immediately before the thermal head 3 corresponding to the tension B at the end of the ink sheet. 22a, 2
Reference numeral 2b denotes a talmi portion which is almost parallel to the tension of the ink sheet immediately before coming into contact with the heating element 3a and becomes a wrinkle. 23
Indicates a fold wrinkle in which the talumi portions 22a and 22b are folded by the thermal head 3 and a transfer failure occurs.

Next, the operation will be described. The ink sheet 1 pressed and conveyed by the platen 6 is transferred to the thermal head 3.
At the time of thermal transfer in the above-mentioned manner, there is a portion that is heated and stretched (stretched) to cause slack and a portion that is not loosened, so that the tension is uneven between the winding roll 2 and the thermal head 3. Eventually, this unevenness causes the tension between the supply roll 2 and the thermal head 3 to increase unevenly. The former non-uniformity is due to heating extension 1
Since it is 0, it concentrates on the unstretched end portion and is substantially parallel to the winding (conveying) direction, but the latter unevenness causes the unstretched end portion ink sheet tension B to pass through the thermal head 3 and supply roll 2 Uneven tension between the thermal head 3 and
A non-uniform tension in an oblique direction corresponding to the ink sheet tension C immediately before is generated.

This diagonal tension causes the talmi portions 22a and 22b to be substantially parallel to the tension. Moreover,
As the heat-expanded ink sheet portion advances, the talumi portions 22a and 22b are accumulated, and eventually the talumi portions 22a and 22b are folded and pass through the thermal head 3, so that folding wrinkles 23 occur and the paper 7 There are some areas where the ink is not transferred properly, which ruins the print itself.

[0007]

Therefore, in the conventional apparatus, the degree of heating by the thermal head is adjusted to adjust the unevenness of the tension within the limit, or the amount of the wrinkle that causes folding wrinkles is set within the limit. The ink sheet tension immediately before the thermal head can be adjusted, the tension that winds up the ink sheet can be adjusted, the uneven tension in the sliding part, the shape that alleviates the uneven distribution, and the fine adjustment of the friction force, Although the sheet roller was made thicker to increase the amount of tarmi of the ink sheet that was heated and stretched to make the tension uniform, in either case, if the heating temperature of the thermal head is increased to improve the printing density accuracy, the heating will increase. There was a problem that the expansion was large and the folds and wrinkles did not disappear.

The present invention has been made in order to solve the above problems, and in order to improve the printing density accuracy, even if the heating temperature of the thermal head is raised to increase the heat expansion of the ink sheet, folding wrinkles are generated. It is an object of the present invention to provide a thermal transfer recording device that does not generate heat.

[0009]

SUMMARY OF THE INVENTION A thermal transfer recording apparatus according to the present invention includes a platen, a thermal head that is disposed opposite to the platen so as to be able to come into contact with and separate from the platen, and that thermally transfers an image onto a sheet through an ink sheet, and the ink sheet. Is provided on the downstream side of the printing of the thermal head, and
And a heating means for heating the base film side of the ink sheet after being separated from the paper.

Further, the thermal head is provided with a sliding member for bending the ink sheet to separate it from the paper, and heating means is provided at a portion of the sliding member which is in contact with the ink sheet.

Further, a platen, a thermal head which is disposed so as to be able to come into contact with and separate from the platen and thermally transfers an image onto a sheet through an ink sheet, a conveying means for conveying the ink sheet, and a printing downstream of the thermal head. And a perforating means for forming fine holes in the ink sheet after being separated from the paper.

Further, the thermal head is provided with a sliding member for bending the ink sheet to separate it from the paper, and a perforation means is provided in a portion of the sliding member which is in contact with the ink sheet.

Further, the perforating means is a heating element which is provided at a predetermined interval in the width direction of the ink sheet and selectively generates heat.

Furthermore, the perforating means is composed of an ink sheet roller having minute protrusions formed on its periphery.

A heating member is housed in the ink sheet roller.

Further, a heat insulating member is interposed between the thermal head and the sliding member.

[0017]

In the present invention, the ink sheet after thermal transfer is heated by the heating means to thermally expand the unheated ink sheet portion to eliminate the uneven tension of the ink sheet.

Further, the unheated ink sheet portion is thermally expanded by heating by the heating means provided on the sliding member to eliminate uneven tension of the ink sheet.

Further, fine holes are formed in the ink sheet after thermal transfer by the perforation means to weaken the tension of the unheated ink sheet portion and eliminate the uneven tension of the ink sheet.

Further, fine holes are formed by perforating means provided on the sliding member for the ink sheet after thermal transfer to weaken the tension of the unheated ink sheet portion and eliminate uneven tension of the ink sheet.

Also, the ink sheet after thermal transfer is melted by a heating element that selectively generates heat to form minute holes to weaken the tension of the unheated ink sheet portion and eliminate uneven tension of the ink sheet.

In addition, the ink sheet after thermal transfer is formed with minute holes by minute protrusions of the ink sheet roller to weaken the tension of the unheated ink sheet portion and eliminate uneven tension of the ink sheet.

Further, the ink sheet after the thermal transfer is heated and melted by the minute projections of the ink sheet roller to form minute holes to weaken the tension of the unheated ink sheet portion and to heat and extend the unheated ink sheet portion. Eliminate uneven tension on the ink sheet.

The heat insulating member prevents heat conduction from the heating means to the thermal head.

[0025]

【Example】

Example 1. 1 and 2 are side views of essential parts of a thermal transfer recording apparatus showing Embodiment 1 of the present invention. FIG. 1 shows a state in which the thermal head is in contact with the platen, and FIG. 2 shows the thermal head separated from the platen. It shows the state of being done. FIG. 3 is a plan view showing a state before and after heating the ink sheet in Example 1. In FIG. 1, 1 is an ink sheet, 2 is an ink sheet supply roll, and 2a is an ink sheet take-up roll that winds up the ink sheet fed from the supply roll 2. 3 is a thermal head, 3a is a heating element of the thermal head, 4 is a sliding member which is provided on the downstream side of the ink sheet conveyance of the thermal head 3, and is in contact with the base film side of the ink sheet 1, 5 is an ink sheet roller, and 6 is an ink sheet roller. A platen, 7 is a sheet, and 9 is a plate-shaped heater as a heating means embedded in a portion of the sliding member 4 which is in contact with the ink sheet 1. The plate-shaped heater is wider than the ink sheet 1. Reference numeral 10 is an ink sheet portion heated and expanded by the plate heater 9,
Reference numeral 1 denotes an ink sheet portion heated and expanded by the thermal head 3 at the time of printing, and reference numerals 12 and 13 denote uniform tensions generated on the ink sheet 1.

Next, the printing operation will be described. Ink sheet 1 and paper 7 are attached to thermal head 3 and platen 6
The platen 6 is rotated while being pressed and held between and. At the same time, the thermal head 3 is heated by an electric signal corresponding to the printed image to thermally transfer the ink of the ink sheet 1 to the paper 7. At this time, the degree of heating to the ink sheet 1 partially varies depending on the image depending on the presence or absence of the image, the amount of transferred ink, and the density. Therefore, the ink sheet 1 partially has a different degree of extension due to heat, and an ink sheet portion 11 having an unextended portion on the same surface is formed. However, the ink seal
The sheet 1 is further conveyed and bent by the sliding member 4 to form the sheet 7
Separated from At this time, since the portion of the sliding member 4 that contacts the ink sheet 1 is heated to the extent that the base film of the ink sheet 1 is softened by the plate-shaped heater 9,
In this bent portion, a portion of the ink sheet 1 which is not stretched due to heating of the thermal head 3 is mainly brought into contact with the plate-shaped heater 9 of the sliding member 4 to be stretched, and the entire surface of the ink sheet 1 is uniformly stretched. .

As described above, when the ink sheet, which is partially expanded by heating the thermal head during printing, is heated and expanded again, a uniform tension 12 is generated in the ink sheet 1, and wrinkles can be prevented. . When the thermal head 3 is separated from the platen 6, the sliding member 4 and the ink sheet 1 are not in contact with each other, and the ink sheet 1 is not unnecessarily heated when the ink sheet is conveyed except for the printing operation. .

Embodiment 2 FIG. FIG. 4 is a side view of a main part of a thermal transfer recording apparatus showing a second embodiment of the present invention, and FIG. 5 is a plan view showing a state before and after heating an ink sheet in the second embodiment.
In the figure, 1 to 7 and 9 to 11 are the same as those described in the first embodiment. 8 is an ink seal of the sliding member 4.
A thermal head or perforation heater provided as a perforation means provided in a portion in contact with the belt 1 is formed wider than the ink sheet 1. This thermal head 8 is an ink seal
An electric signal is passed through a heating element provided at a predetermined interval in the width direction of the sheet to heat the heating element instantaneously to melt and perforate the ink sheet 1 to open a minute hole 10c as shown in FIG.

According to this embodiment, the unextended portion of the ink sheet 1 that has been thermally transferred is most in contact with the thermal head 8, and the portion that has been thermally expanded and loosened during thermal transfer has a slight gap and is thermal. It is conveyed so as to contact the head 8. Then, while the ink sheet 1 is being conveyed, it is heated and melted by energizing the ink sheet 1 at appropriate time intervals to open the micropores 10c in the unstretched portion, weaken the strength of this portion, and make the tension even and uniform to prevent wrinkles. To prevent. The heat-expanded and slackened portion is not directly heated due to the void, but the ink sheet 1 is slightly expanded due to the heat of the heating element because the portion having a higher tension is close to the thermal head 8. Therefore, the uniform dispersion of the tension is further improved.

Further, the heating element is selected to be energized to prevent the fine holes 10c from concentrating locally in the ink sheet 1a, and the energization time interval is made variable so that wrinkles are most unlikely to occur. Easy to maintain control.

Example 3. Embodiment 3 FIG. 6 is a side view of the essential parts of a thermal transfer recording apparatus showing Embodiment 3 of the present invention. In the figure, 1
11 are the same as those described in the first and second embodiments. Reference numeral 14 is a heat insulating member interposed between the thermal head 8 or the sliding member 4 provided with the plate-shaped heater 9 and the thermal head 3. According to this embodiment,
Since the heat insulating member 14 is interposed, the heat of the thermal head 8 or the plate-shaped heater 9 is not conducted to the thermal head 3, so that the thermal head 3 is prevented from being adversely affected during printing.

Example 4. FIG. 7 is a side view of a main part of a thermal transfer recording apparatus showing a fourth embodiment of the present invention, and FIG. 8 is a plan view showing a state before and after heating an ink sheet in the fourth embodiment. In the figure, 1 is an ink sheet, 2 is an ink sheet supply roll, 2a is an ink sheet take-up roll,
The ink sheet fed from the supply roll 2 is wound up.
3 is a thermal head, 3a is a heating element of the thermal head,
Reference numeral 4 denotes a sliding member that is provided on the downstream side of the thermal head 3 for conveying the ink sheet, and is in contact with the base film side of the ink sheet 1. Reference numeral 50 denotes an ink sheet roller as a perforating means, which is provided with a minute projection 50a around the periphery. There is. Reference numeral 6 is a platen, 7 is a sheet, and 10a is a minute hole perforated in the ink sheet 1.

Next, the printing operation will be described. The platen 6 is rotated while pressing and holding the ink sheet 1 and the paper 7 between the thermal head 3 and the platen 6. At the same time, the thermal head 3 is heated by an electric signal corresponding to the printed image to thermally transfer the ink of the ink sheet 1 to the paper 7. At this time, the thermal head 3 is attached to the ink sheet 1.
The printing heat is applied to the ink sheet 1 so that the ink sheet 1 is partially expanded and the ink sheet portion 11 in which the printing is expanded appears. However, the ink sheet 1 is further conveyed, passes through the sliding member 4, reaches the ink sheet roller 50, and the minute holes 50a are opened by the minute protrusions 50a as the ink sheet roller 50 rotates. This minute hole 10a is an ink seal.
The microprojection 5 is exposed at a portion of the gland 1 where the tension is large, that is, a portion that is not heated and is not stretched, and that is stretched by heating and slackened.
There is little contact of 0a with the ink sheet 1, and the minute holes 10a are almost invisible. The strength of the ink sheet 1 is weakened in the portion where the minute holes 10a are formed, and the tension is dispersed by the extension of this portion, so that the ink sheet in which the entire surface is uniformly stretched.
Become

As described above, the minute holes 10a are formed in the ink sheet 1 where the tension is large and the tension is dispersed, so that the uniform tension 12 is generated in the ink sheet 1 and wrinkles are generated. Can be prevented.

Example 5. Fourth Embodiment FIG. 9 is a side view of a main portion of a thermal transfer recording apparatus showing a fourth embodiment of the present invention. In the figure, 1
7 to 7 are the same as those described in the fourth embodiment.
Reference numeral 50 is an ink sheet roller as a perforation means, and a minute projection 50a is provided around the periphery of the ink sheet roller. 50b is ink
With the rod-shaped heater as a heating member incorporated in the inside of the roller 50, when the minute holes 10b are formed in the ink sheet 1, the minute protrusions 50a are heated by the rod-shaped heater 50b.
A micro hole 10b as shown in is opened.

In this way, by heating and softening the ink sheet 1 to open the fine holes 10b, cracking of the fine holes 10b is prevented and the ink sheet 1 is not cut. Also,
When the tension of the ink sheet 1 is weakened and the tension of the ink sheet 1 is weakened by the micropores 10b, the ink sheet 1 itself is heated and stretched, so that the tension is more uniformly dispersed and equalized as compared with the fourth embodiment. It is effective in preventing the generation of wrinkles.

[0037]

Since the present invention is constructed as described above, it has the following effects.

By providing heating means on the downstream side of the printing of the thermal head for heating the base film side of the ink sheet after being separated from the paper, the unheated ink sheet portion is thermally expanded, so that the tension of the ink sheet is increased. The unevenness is eliminated, and the wrinkles of the ink sheet can be prevented.

Further, since the heating means is provided at the portion of the thermal head that is in contact with the ink sheet of the sliding member that bends the ink sheet and separates it from the paper, the unheated ink sheet portion is thermally expanded in the vicinity of the print. Therefore, the tension of the ink sheet is not uneven, and it is possible to prevent the ink sheet from wrinkling.

Further, since the perforating means for forming fine holes in the ink sheet after being separated from the paper is provided on the downstream side of the printing of the thermal head, the unheated ink sheet portion is relieved in tension by the fine holes. The unevenness of the tension of the ink sheet is eliminated, and the wrinkles of the ink sheet can be prevented from being folded.

Further, the thermal head is provided with a sliding member for bending the ink sheet to separate it from the paper, and the perforating means is provided at a portion of the sliding member which is in contact with the ink sheet.
Since the unheated ink sheet portion in the vicinity of the print is relieved of the tension by the fine holes, the uneven tension of the ink sheet is eliminated and the folding wrinkles of the ink sheet can be prevented.

Further, since the perforating means is provided with a heating element which is provided at a predetermined interval in the width direction of the ink sheet and selectively generates heat, the unheated ink sheet portion is a minute hole formed in an arbitrary pattern. Because the tension is relaxed by
The unevenness of the tension of the ink sheet is eliminated, and the wrinkles of the ink sheet can be prevented from being folded.

Further, since the perforation means is constituted by the ink sheet roller having minute protrusions formed around it, the unheated ink sheet portion is relieved of the tension by the minute holes, so that the uneven tension of the ink sheet is eliminated and the ink sheet -It is possible to prevent wrinkles from folding in.

Further, since the heating member is housed in the ink sheet roller, the unheated ink sheet portion is relieved of tension by the micropores and thermal expansion, so that uneven tension of the ink sheet is eliminated and folding wrinkles of the ink sheet are eliminated. Can be prevented.

Further, since the heat insulating member is interposed between the thermal head and the sliding member, it is possible to prevent thermal adverse effects on the printed image and obtain a high quality printed image.

[Brief description of drawings]

FIG. 1 is a side view of essential parts showing a state in which a thermal head of a thermal transfer recording apparatus according to a first embodiment of the present invention is in contact with a platen.

FIG. 2 is a side view of essential parts showing a state in which the thermal head of the thermal transfer recording apparatus according to the first embodiment of the present invention is separated from the platen.

FIG. 3 is a plan view showing a state before and after heating the ink sheet according to the first embodiment of the present invention.

FIG. 4 is a side view of essential parts of the thermal transfer recording apparatus showing the second embodiment of the present invention.

FIG. 5 is a plan view showing a state before and after heating an ink sheet according to a second embodiment of the present invention.

FIG. 6 is a side view of essential parts of a thermal transfer recording apparatus showing a third embodiment of the present invention.

FIG. 7 is a side view of essential parts of a thermal transfer recording apparatus showing an embodiment 4 of the present invention.

FIG. 8 is a plan view showing a state before and after heating an ink sheet according to a fourth embodiment of the present invention.

FIG. 9 is a side view of essential parts of a thermal transfer recording apparatus showing an embodiment 5 of the present invention.

FIG. 10 is a side view of essential parts showing a conventional thermal transfer recording apparatus.

FIG. 11 is a perspective view of a main part of a conventional thermal transfer recording device.

FIG. 12 is a plan view showing a state before and after heating an ink sheet in a conventional apparatus.

[Explanation of symbols]

1 ink sheet 3 thermal head
3a heating element 4 sliding member 50 ink sheet roller
50a Micro projection 50b Rod-shaped heater 6 Platen
7 Paper 8 Thermal Head 9 Plate Heater
14 Thermal insulation member

Claims (8)

[Claims] 1. A platen, a thermal head that is arranged to face the platen so as to be able to come into contact with and separate from the platen, and thermally transfers an image onto a sheet through an ink sheet, a conveying unit that conveys the ink sheet, and a printing downstream of the thermal head. And a heating unit that heats the base film side of the ink sheet after being separated from the paper. 2. The thermal head is provided with a sliding member that bends the ink sheet to separate it from the paper, and a heating means is provided at a portion of the sliding member that is in contact with the ink sheet. Thermal transfer recording device. 3. A platen, a thermal head that is arranged to face the platen so as to be able to come into contact with and separate from the platen, and thermally transfers an image onto a sheet through an ink sheet, a conveying unit that conveys the ink sheet, and a printing downstream of the thermal head. A thermal transfer recording apparatus, which is provided on the side and has a perforation means for forming fine holes in the ink sheet after being separated from the paper. 4. The thermal head is provided with a sliding member that bends the ink sheet to separate it from the paper, and a perforation means is provided in a portion of the sliding member that is in contact with the ink sheet. Thermal transfer recording device. 5. The thermal transfer recording apparatus according to claim 4, wherein the perforating means is provided with a heating element which is provided at predetermined intervals in the width direction of the ink sheet and selectively generates heat. 6. The thermal transfer recording apparatus according to claim 3, wherein the perforating means is constituted by an ink sheet roller having minute protrusions formed on its periphery. 7. The thermal transfer recording apparatus according to claim 6, wherein a heating member is housed in the ink sheet roller. 8. The thermal transfer recording apparatus according to claim 2, wherein a heat insulating member is interposed between the thermal head and the sliding member.