JPH0584937A - Heat transfer recording device - Google Patents

Abstract

PURPOSE:To provide a simple heat transfer recording device whose printed and copied image is free from unevenness in image density. CONSTITUTION:The title device is constituted so that when an angle formed by an arranging direction of heating and resistive elements 2 of a thermal head 3 where the heating and resistive elements 2 are arranged in one row and a direction X meeting at right angles with a conveying direction of an ink sheet and recording paper 1 is made theta, the thermal head 3 is arranged by tilting the same so that a relation of thetanot equal to 0 is given, through which a gap between the heating and resistive elements 2 adjoining to each other is eliminated in the conveying direction Y of the ink sheet and recording paper 1, through which lowering of image density to be generated between dots of printed and copied image is prevented.

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 having a thermal head used in printers, copiers, facsimiles and the like.

[0002]

2. Description of the Related Art An example of a conventional thermal transfer recording apparatus used in a printer or the like will be described with reference to FIGS. First, as shown in FIG. 5, a plurality of heat generating resistors 2 are arranged in a line in a direction X orthogonal to a conveying direction Y of a recording paper 1 and an ink sheet (on the lower side of the recording paper) which overlap each other. A thermal head 3 is provided. Further, as shown in FIG. 6, the pitch of the heating resistors 2 adjacent to the thermal head 3 is set to m ₁ . One end of the heat generating resistor 2 is connected to the common electrode 4, and the other end of the heat generating resistor 2 is connected to the individual electrode 5, respectively, and between the common electrode 4 and the individual electrode 5. An effective heating portion 6 is formed in each. Each of these effective heat generating portions 6 has a rectangular shape in which the dimension a ₁ of the heating resistor 2 and the individual electrode 5 in the array direction is short and the dimension b ₁ of the ink sheet and the recording paper 1 in the transport direction is long. Has been formed.

In such a configuration, the recording sheet 1 overlapping the ink sheet is pressed against the thermal head 3 in which the heating resistors 2 are arranged in a line, and the ink sheet and the recording sheet 1 are integrally conveyed while the ink is being conveyed. An image is recorded on the recording paper 1 by selectively transferring the ink of the sheet onto the recording paper 1.

[0004]

However, the above-mentioned thermal transfer recording apparatus has the following problems. First, as shown in FIG. 6, adjacent heating resistors 2
Since there is a gap c between the two, when uniform solid printing is performed, as shown in FIG. 7, no density appears at the printed image position corresponding to the gap c between the adjacent heating resistors 2. An area (where density is difficult to appear), that is, an area where the image density is reduced occurs. In addition, since the thermal head 3 is heated, wrinkles are generated in the ink sheet due to the expansion thereof (particularly wrinkles are generated in the central portion of the ink sheet), and therefore a means for removing the wrinkles generated in the ink sheet is required. further,
When the image density of a desired printed image becomes high, it is necessary to reduce the pitch m ₁ of the adjacent heating resistors 2, but when the pitch m ₁ is decreased, the heat interaction between the adjacent heating resistors 2 is reduced. (Interaction) becomes large, and the correction technique for the printing timing and the like depending on the presence or absence of adjacent pixels in the printed image becomes very complicated.

Therefore, in the past, there have been proposed some solutions to the above problems. First, as a method for preventing a decrease in image density of a printed image, there are, for example, the following. As a first conventional example thereof, there is a "thermal head" disclosed in JP-A-52-142527. This is to reduce the density unevenness by making the heat-generating portion connected to both ends a zigzag shape or a spiral shape so as to partially overlap the adjacent coloring areas.

A second conventional example is Japanese Patent Laid-Open No. 58-58.
There is a "thermal head" disclosed in Japanese Patent No. 18281. This is to prevent the occurrence of white spots by making the outline of the heat generation area of the thermal head substantially symmetrical in the sub-scanning direction of the thermal head and asymmetrical in the main scanning direction.

Further, as a third conventional example, JP-A-62-62
"Thermal head" disclosed in JP-A-130860
There is. This is because the print density is improved by the oblique heating resistor provided between the first electrode portion and the second electrode portion in the row adjacent to the first electrode portion. It is a thing.

On the other hand, the following are examples of those that prevent wrinkles from occurring on the ink sheet. First, as a fourth conventional example, Japanese Patent Laid-Open No. 60-2245
There is an "ink sheet conveyance device for a thermal transfer printer" disclosed in Japanese Patent No. 66. This is achieved by at least two guide rollers that tilt in the vertical and horizontal directions in response to changes in the tension generated in the width direction of the ink sheet.
This is to prevent wrinkles from occurring on the ink sheet.

As a fifth conventional example, JP-A-60-
There is a "transfer printer" disclosed in Japanese Patent No. 157889. This is provided with a roller that rotates in a direction that gives a vertical tension to the ink sheet, and the portion of the roller that abuts the ink sheet has a spiral shape that runs while rotating from the center side of the ink sheet to the outside. The formation prevents the wrinkles of the ink sheet.

However, in the case of the above-mentioned first and second conventional examples, the shape of the effective heating portion of the heating resistor becomes complicated, so that there is a problem in terms of manufacturing cost and reliability of the heating resistor. is there. Further, in the case of the third conventional example, since the dots of the printed image have a shape similar to the shape of the effective heating portion of the heating resistor, the roundness thereof deteriorates. Further, in the case of the fourth and fifth conventional examples, since the roller for preventing the wrinkle of the ink sheet is used, the mechanism is complicated and the cost cannot be denied.

[0011]

According to a first aspect of the present invention, the recording sheet that overlaps the ink sheet is pressed into contact with the thermal head in which the heating resistors are arranged in a line, so that the ink sheet and the recording sheet are integrated. In a thermal transfer recording apparatus that performs printing on the recording paper while being conveyed, when the angle formed by the arrangement direction of the heating resistors and the direction orthogonal to the conveying direction of the ink sheet and the recording paper is θ, θ ≠
The thermal head was disposed so as to be zero.

According to a second aspect of the present invention, in the first aspect of the present invention, when the pitch of adjacent heating resistors of the thermal head is m and the pixel pitch of the printed image is p, the adjacent heating resistors are adjacent. The pitch m of m = p / cos θ
(However, θ ≠ 0).

According to a third aspect of the invention, in the first aspect of the invention, the pitch of adjacent heating resistors of the thermal head is m, the pixel pitch of the printed image is p, and a positive integer is n.
And the pitch m of the adjacent heating resistors is m =
n · p / sin θ (where θ ≠ 0).

According to a fourth aspect of the present invention, in the first aspect of the present invention, when the length of the thermal head at a portion corresponding to the width of the ink sheet and the recording paper is L, the ink sheet and the recording paper are At least L · s in the transport direction
In the range of in θ (where θ ≠ 0), the area where the ink sheet and the recording paper are brought into pressure contact with the thermal head is flat.

According to a fifth aspect of the present invention, the thermal head in which the heating resistors are arranged in a line is pressed against a recording paper overlapping the ink sheet to convey the ink sheet and the recording paper integrally. In a thermal transfer recording apparatus for printing on a recording paper, the effective heating portion of the heating resistor is formed in a square shape, and the arrangement direction of the heating resistor and a direction orthogonal to the conveying direction of the ink sheet and the recording paper. When the angle formed by θ is θ, the thermal head is θ = 4.
It was arranged so as to be inclined at 5 °.

According to a sixth aspect of the present invention, the thermal head in which the heating resistors are arranged in a line is pressed against a recording paper that overlaps with the ink sheet to convey the ink sheet and the recording paper integrally. In a thermal transfer recording apparatus for printing on a recording sheet, the thermal head is arranged on both sides in the width direction of the ink sheet and the recording sheet from the upstream side to the downstream side in the conveying direction of the ink sheet and the recording sheet. The sheet was formed in a V-shape from the side toward the center, and was arranged so as to be symmetrical with respect to the center in the width direction of the ink sheet and the recording paper.

According to a seventh aspect of the invention, in the sixth aspect of the invention, the length of one side of the V-shaped thermal head is L, and the length of one side of the V-shaped thermal head and the ink are When the angle formed by the direction orthogonal to the sheet and recording paper conveyance direction is θ, at least L · sin θ in the conveyance direction of the ink sheet and recording paper (where θ
In the range of ≠ 0, the area where the ink sheet and the recording paper are pressed against the thermal head is flat.

[0018]

According to the first aspect of the present invention, the thermal head is arranged so that the angle θ formed by the arrangement direction of the heating resistors of the thermal head and the direction orthogonal to the conveying direction of the ink sheet and the recording paper is θ ≠ 0. By inclining, it becomes possible to eliminate the gap between the adjacent heat generating resistors of the thermal head in the transport direction of the ink sheet and the recording paper, and thus prevent the image density from decreasing between the dots of the printed image. It becomes possible.

According to the second aspect of the invention, when the thermal head is tilted with respect to the direction orthogonal to the conveying direction of the ink sheet and the recording paper, the pitch m of the adjacent heating resistors of the thermal head is m = p. / Cos θ (where θ ≠
0), it is possible to eliminate the gap between the adjacent heat generating resistors of the thermal head in the conveyance direction of the ink sheet and the recording sheet, and therefore decrease the image density generated between the dots of the printed image. It becomes possible to prevent it.

According to the third aspect of the invention, the pitch m between adjacent heating resistors of the thermal head is m = n · p /
By tilting the thermal head with respect to the direction orthogonal to the conveyance direction of the ink sheet and the recording sheet so that sin θ (where θ ≠ 0), the interval between the adjacent pixels of the printed image is set to the ink sheet and the recording sheet. Pixel pitch p in the transport direction
Therefore, it is not necessary to correct the timing for driving each heating resistor when printing a thin line or the like.

In the fourth aspect of the invention, the length L of the thermal head at a portion corresponding to the width of the ink sheet and the recording paper and the direction orthogonal to the conveying direction of the thermal head, the ink sheet and the recording paper are formed. The relationship with the angle θ is at least L · sin θ in the conveying direction of the ink sheet and the recording paper.
In the range of (.noteq..noteq.0), by flattening the area where the ink sheet and the recording paper are brought into pressure contact with the thermal head, it is possible to make the pressure contact force in that area uniform, and therefore the pressure unevenness is caused. It is possible to obtain a printed image without image density unevenness due to.

According to a fifth aspect of the present invention, the effective heating portion of the heating resistor has a square shape, and the angle θ formed by the arrangement direction of the heating resistors and the direction orthogonal to the conveying direction of the ink sheet and the recording paper. It is possible to obtain a printed image of pixels with good roundness by inclining the thermal head so that the relation of θ = 45 ° is satisfied.

According to the sixth aspect of the invention, the thermal head formed in a V-shape that is symmetrical with respect to the widthwise center of the ink sheet and the recording sheet causes wrinkles generated in the ink sheet to the center. Therefore, it is possible to efficiently remove both sides.

According to the invention of claim 7, the length L of one of the V-shaped thermal heads and the direction orthogonal to the conveying direction of the V-shaped thermal head and the ink sheet and the recording paper. The relationship with the angle θ formed by at least L · sin θ (where θ
In the range of ≠ 0), the pressure contact force of the area can be made uniform by flattening the area where the ink sheet and the recording paper are in pressure contact with the thermal head. It is possible to obtain a printed image that does not have

[0025]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention will be described with reference to FIGS. Conventional examples (see FIGS. 5 to 7)
The same parts as those described in 1 are denoted by the same reference numerals, and the description thereof will be omitted (the same applies to the following embodiments). As shown in FIG. 1, a thermal head 3 in which heating resistors 2 are arranged in a line is provided. The thermal head 3 is tilted so that θ ≠ 0, where θ is an angle formed by the arrangement direction of the heating resistors 2 and the direction X orthogonal to the transport direction Y of the ink sheet 7 and the recording paper 1. It is arranged in a closed state. Further, as shown in FIG. 2, the effective heating portion 6 of the heating resistor 2 formed between the common electrode 4 and the individual electrode 5 has a short dimension a in the arrangement direction of the heating resistor 2, The heating resistor 2 is formed in a rectangular shape having a longer dimension b in the direction orthogonal to the arrangement direction.

Further, the following conditions are set for the present apparatus thus constructed. First, when the pitch of the adjacent heating resistors 2 of the thermal head 3 is m (see FIG. 2) and the pixel pitch of the printed image is p, the pitch m of the adjacent heating resistors 2 is m = p
It is set to have a relationship of / cos θ.

Further, when a positive integer is n, the pitch m of the adjacent heating resistors 2 of the thermal head 3 is m.
Is set so that m = n · p / sin θ.

Further, when the length of the thermal head 3 at the portion corresponding to the width of the ink sheet 7 and the recording paper 1 is L (see FIG. 1), the ink sheet 7 and the recording paper 1 are conveyed. In at least the range of L · sin θ in the direction Y, as shown in FIG. 3, the region where the ink sheet 7 and the recording paper 1 are pressed against the thermal head 3 is set flat.

In such a structure, first, with the movement of the ink sheet 7 and the recording paper 1, with respect to the direction X orthogonal to the transport direction Y of the ink sheet 7 and the recording paper 1, θ
The ink sheet 7 and the recording paper 1 are pressed into contact with the thermal head 3 in a state of being inclined so that ≠ 0. At this time, the pitch m between adjacent heating resistors 2 of the thermal head 3, the pixel pitch p of the printed image, the arrangement direction of the heating resistors 2 and the direction orthogonal to the transport direction Y of the ink sheet 7 and the recording paper 1. The relationship with the angle θ formed by X is m = p / cos θ ∴m> p = m _1, where θ ≠ 0 m ₁ : The conventional pitch of adjacent heating resistors (see FIG. 6). As a result, the pixel pitch p of the printed image is p = m
Because of the relationship of cos θ, the dimension a of the effective heating portion 6 in the arrangement direction of the heating resistors 2 can be made longer than the dimension a ₁ of the conventional effective heating portion 6 (see FIG. 6). ..
Moreover, in the transport direction Y of the ink sheet 7 and the recording paper 1, it is possible to eliminate the gap c (see FIG. 6) between the adjacent heating resistors 2. Therefore, it is possible to prevent a decrease in image density that occurs at the printed image position (between the dots of the printed image) corresponding to the gap c between the adjacent heating resistors 2.

Further, the pitch m between adjacent heating resistors 2 is
And the relationship between the pixel pitch p of the printed image and the angle θ formed by the arrangement direction of the heating resistors 2 and the direction orthogonal to the transport direction Y of the ink sheet 7 and the recording paper 1 are: m = n · p / sin θ (n: positive integer). As a result, the pixel pitch p of the printed image is np
= M · sin θ, the adjacent pixels in the printed image are separated from each other by an integer n times the pixel pitch p in the transport direction Y of the ink sheet 7 and the recording paper 1. Therefore, it is possible to obtain a good printed image without controlling the printing timing and the like.

Further, paying attention to the fact that the image density of the printed image largely depends on the pressure contact force between the thermal head 3 and the ink sheet 7 and the recording paper 1, as shown in FIG. 1 in the transport direction Y of at least L · s
In the range of in θ, by holding the ink sheet 7 and the recording paper 1 in a flat plate shape by the thermal head 3, it is possible to uniformly press the ink sheet 7 and the recording paper 1 to all the heating resistors 2. Therefore, it is possible to obtain a good printed image without uneven image density due to uneven pressure.

The thermal head 3 is formed so that the relationship between the dimension a and the dimension b of the effective heating portion 6 of the heating resistor 2 is a = b.
And the transport direction Y of the ink sheet 7 and the recording paper 1
If it is arranged in a tilted state so that the angle θ formed by the direction X orthogonal to is in the relationship of θ = 45 °, one pixel of the printed image is one of the heating resistor 2 in which the square is rotated by 45 °. Since the shape is close to the shape of the effective heat generating portion 6, it is possible to obtain a printed image of pixels with good roundness. For example, it is possible to obtain a good printed image with no difference in the width between the vertical line and the horizontal line.

Next, a second embodiment of the present invention will be described with reference to FIG. The thermal head 3 in which the heating resistors 2 are arranged in a line extends in the width direction of the ink sheet 7 and the recording paper 1 from the upstream side to the downstream side in the transport direction Y of the ink sheet 7 and the recording paper 1. It is formed in a V-shape from both sides toward the center. The thermal head 3 is arranged so as to be bilaterally symmetrical with respect to the widthwise center of the ink sheet 7 and the recording paper 1. Further, the length of one side of the V-shaped thermal head 3 is L ₁ , and the length of one side of the V-shaped thermal head 3 and the conveyance direction Y of the ink sheet 7 and the recording paper 1 is Y. When the angle formed by the orthogonal directions is θ, the ink sheet 7 and the recording paper 1
At least L ₁ · sin θ in the transport direction Y (where θ ≠
In the range 0), the ink sheet 7 and the recording paper 1 are
The area where the above is pressed against the thermal head 3 is set to be flat.

With such a construction, in the conventional thermal transfer recording apparatus (see FIGS. 5 to 7), the ink sheet 7 and the recording paper 1 are pulled in the conveying direction Y by a uniform force, and a wrinkle escape area is formed near the center. However, in the present embodiment, the thermal head 3 uses the ink sheet 7 and the recording paper 1.
Since it is V-shaped symmetrically with respect to the center portion in the width direction of the ink sheet, wrinkles near the center of the ink sheet 7 can be released from the center portion to both side sides with a simple configuration. .. Further, in the range of at least L ₁ · sin θ in the transport direction Y of the ink sheet 7 and the recording sheet 1, the ink sheet 7
By holding the recording paper 1 on the thermal head 3 in a flat plate shape, the ink sheet 7 and the recording paper 1 can be uniformly pressed against all the heating resistors 2. Therefore,
It is possible to obtain a good printed image without uneven image density due to uneven pressure.

[0035]

According to the first aspect of the present invention, the recording sheet that overlaps the ink sheet is pressed against the thermal head in which the heating resistors are arranged in a line to convey the ink sheet and the recording sheet integrally. However, in a thermal transfer recording apparatus that performs printing on the recording paper, when the angle formed by the arrangement direction of the heating resistors and the direction orthogonal to the transport direction of the ink sheet and the recording paper is θ, θ ≠ 0. Since the thermal head is arranged so as to be inclined, the angle θ formed by the arrangement direction of the heat generating resistors of the thermal head and the direction orthogonal to the conveyance direction of the ink sheet and the recording paper is θ ≠ 0. By tilting the head, it is possible to eliminate the gap between the heat generating resistors adjacent to each other in the transport direction of the ink sheet and the recording paper, and therefore, the image density generated between the dots of the printed image can be eliminated. In which it is possible to prevent a decrease of.

According to a second aspect of the present invention, in the first aspect of the invention, when the pitch of adjacent heating resistors of the thermal head is m and the pixel pitch of the printed image is p, the adjacent heating resistors are adjacent. Since the pitch m of the thermal head is set to m = p / cos θ (where θ ≠ 0), when the thermal head is inclined with respect to the direction orthogonal to the transport direction of the ink sheet and the recording paper, the heat generation resistances adjacent to the thermal head are Since the body pitch m is m = p / cos θ, it is possible to eliminate a gap between adjacent heating resistors of the thermal head in the ink sheet and recording paper conveyance direction. It is possible to prevent a decrease in image density that occurs between dots.

According to a third aspect of the present invention, in the first aspect of the present invention, when the pitch of adjacent heating resistors of the thermal head is m, the pixel pitch of the printed image is p, and a positive integer is n, The pitch m of the adjacent heating resistors is set to m = n
Since p / sin θ (where θ ≠ 0) is set, the pitch m between adjacent heating resistors of the thermal head is m = n · p /
By tilting the thermal head with respect to the direction orthogonal to the conveying direction of the ink sheet and the recording paper so as to be sin θ, the interval between adjacent pixels of the printed image is an integer n times in the conveying direction of the ink sheet and the recording paper. Therefore, it is possible to separate them from each other, so that it is unnecessary to correct the timing of driving each heating resistor when printing a thin line or the like.

According to a fourth aspect of the present invention, in the first aspect of the invention, when the length of the thermal head at the portion corresponding to the width of the ink sheet and the recording paper is L, the ink sheet and the recording paper are At least L · si in the transport direction
In the range of nθ (where θ ≠ 0), the area where the ink sheet and the recording paper are pressed against the thermal head is made flat, so that the length of the thermal head at the portion corresponding to the width of the ink sheet and the recording paper. As long as the relationship between L and the angle θ formed by the thermal head and the direction orthogonal to the transport direction of the ink sheet and the recording sheet is at least L · sin θ in the transport direction of the ink sheet and the recording sheet, the ink sheet and the recording sheet By flattening the area that is pressed against the thermal head, it is possible to make the pressure contact force in that area uniform, and thus it is possible to obtain a printed image without image density unevenness due to pressure unevenness. ..

According to a fifth aspect of the present invention, the recording sheet overlapping the ink sheet is pressed against the thermal head in which the heating resistors are arranged in a line, and the ink sheet and the recording sheet are integrally conveyed, In a thermal transfer recording apparatus for printing on a recording paper, the effective heating portion of the heating resistor is formed in a square shape, and the arrangement direction of the heating resistor and a direction orthogonal to the conveying direction of the ink sheet and the recording paper. When the angle formed by θ is θ, the thermal head is θ = 45.
Since the heat generating resistors are arranged so as to be inclined, the effective heat generating portion of the heat generating resistors has a square shape, and the angle θ formed by the arrangement direction of the heat generating resistors and the direction orthogonal to the conveying direction of the ink sheet and the recording paper is θ. By tilting the thermal head so that the relation of θ = 45 ° is obtained, it is possible to obtain a printed image of pixels with good roundness.

According to a sixth aspect of the present invention, the recording sheet overlapping the ink sheet is brought into pressure contact with the thermal head in which the heating resistors are arranged in a row, and the ink sheet and the recording sheet are conveyed integrally with each other. In a thermal transfer recording apparatus for printing on a recording sheet, the thermal head is arranged on both sides in the width direction of the ink sheet and the recording sheet from the upstream side to the downstream side in the conveying direction of the ink sheet and the recording sheet. The ink sheet and the recording paper are formed in a V-shape from the side toward the center and are arranged symmetrically with respect to the widthwise center of the ink sheet and the recording paper. The wrinkles that occur in the ink sheet are efficiently removed from the center to both sides by the thermal head formed in a V-shape that is symmetrical with respect to the center. One in which it is bet.

According to a seventh aspect of the present invention, in the sixth aspect of the invention, the length of one portion of the V-shaped thermal head is L, and the length of one portion of the V-shaped thermal head is equal to that of the ink. When the angle formed by the direction orthogonal to the sheet and recording paper conveyance direction is θ, at least L · sin θ in the conveyance direction of the ink sheet and recording paper (where θ ≠
In the range of 0), the area where the ink sheet and the recording paper are pressed against the thermal head is flat,
The relationship between the length L of one of the V-shaped thermal heads and the angle θ formed by one of the V-shaped thermal heads and the direction orthogonal to the transport direction of the ink sheet and the recording paper is the ink sheet and the recording paper. In the range of at least L · sin θ in the transport direction of, the flattening of the area where the ink sheet and the recording paper are brought into pressure contact with the thermal head makes it possible to make the pressure contact force in that area uniform.
It is possible to obtain a printed image having no image density unevenness due to pressure unevenness.

[Brief description of drawings]

FIG. 1 is a plan view showing a first embodiment of the present invention.

FIG. 2 is an enlarged partial plan view showing an arrangement state of heating resistors in the thermal head of FIG.

FIG. 3 is a side view of the thermal head of FIG.

FIG. 4 is a plan view showing a second embodiment of the present invention.

FIG. 5 is a plan view showing a conventional example.

FIG. 6 is a partial plan view showing, in an enlarged manner, an arrangement state of heating resistors in the thermal head of FIG.

FIG. 7 is a characteristic diagram showing a distribution of image density in a printed image.

[Explanation of symbols]

 1 Recording Paper 2 Heating Resistor 3 Thermal Head 6 Effective Heating Section 7 Ink Sheet

Claims (7)

[Claims] 1. A thermal head in which heating resistors are arranged in a row is pressed against a recording paper overlapping the ink sheet, and the ink sheet and the recording paper are integrally conveyed while printing is performed on the recording paper. In the thermal transfer recording device,
When the angle formed by the arrangement direction of the heating resistors and the direction orthogonal to the conveying direction of the ink sheet and the recording sheet is θ, the thermal head is arranged so as to be θ ≠ 0. Characteristic thermal transfer recording device. 2. When the pitch of adjacent heating resistors of the thermal head is m and the pixel pitch of the printed image is p, the pitch m of adjacent heating resistors is m = p / cos θ.
The thermal transfer recording apparatus according to claim 1, wherein (note that θ ≠ 0). 3. A pitch of adjacent heating resistors of the thermal head is m, a pixel pitch of a printed image is p, and a positive integer is n.
And the pitch m of the adjacent heating resistors is m =
2. The thermal transfer recording apparatus according to claim 1, wherein n · p / sin θ (where θ ≠ 0). 4. When the length of the thermal head in the portion corresponding to the width of the ink sheet and the recording paper is L, at least L · s in the transport direction of the ink sheet and the recording paper.
2. The thermal transfer recording apparatus according to claim 1, wherein a region where the ink sheet and the recording paper are pressed against the thermal head is flat in a range of in θ (where θ ≠ 0). 5. A thermal head in which heating resistors are arranged in a row is pressed against a recording paper that overlaps the ink sheet, and the ink sheet and the recording paper are conveyed integrally while printing is performed on the recording paper. In the thermal transfer recording device,
When the effective heating portion of the heating resistor is formed in a square shape, and the angle formed by the arrangement direction of the heating resistors and the direction orthogonal to the conveyance direction of the ink sheet and the recording paper is θ, the thermal head Is arranged so as to be θ = 45 °. 6. A thermal head in which heating resistors are arranged in a line is pressed against a recording paper that overlaps the ink sheet, and the ink sheet and the recording paper are conveyed integrally while printing is performed on the recording paper. In the thermal transfer recording device,
The thermal head is V-shaped so that it goes from both sides in the width direction of the ink sheet and the recording sheet toward the center as it goes from the upstream side to the downstream side in the conveying direction of the ink sheet and the recording sheet. The thermal transfer recording apparatus is characterized in that the thermal transfer recording apparatus is formed so as to be symmetrical with respect to the center portions of the ink sheet and the recording paper in the width direction. 7. The length of one portion of the V-shaped thermal head is L, and the length of one portion of the V-shaped thermal head and the direction orthogonal to the conveying direction of the ink sheet and the recording paper. When the angle is θ, at least L · sin θ in the transport direction of the ink sheet and the recording paper (where θ
7. The thermal transfer recording apparatus according to claim 6, wherein an area where the ink sheet and the recording paper are in pressure contact with the thermal head is flat in a range of ≠ 0).