JP2003276229A - Thermal head and control method for heating element of thermal head - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a thermal head which generates no unevenness in printing images and prevents an image quality decrease even when an interval of heating elements of a coupling part becomes different from that of the other heating elements without executing highly accurate machining, and a control therefor. <P>SOLUTION: In the thermal head in which a plurality of short thermal heads (A and B) each with a plurality of heating elements arranged in an array are coupled, a plurality of heating elements for overlap printing (heating elements 31<SB>1</SB>-31<SB>5</SB>and heating elements 32<SB>1</SB>-32<SB>5</SB>) are set at the coupling side of the respective short thermal heads to be coupled. One short thermal head to be coupled has heating elements (31<SB>1</SB>-31<SB>8</SB>and the like) of an equal interval, and the other short thermal head to be coupled has heating elements (32<SB>1</SB>-32<SB>5</SB>) for overlap printing which are arranged by an interval different from the interval of the heating elements of the one short thermal head. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plurality of shortened thermal heads (hereinafter referred to as "shortened thermal heads").
A long thermal head (hereinafter,
"Long thermal head" or simply "thermal head"
Say ) Is related to.

[0002]

2. Description of the Related Art As a type of thermal head, there is known a thermal head in which a plurality of ceramic substrates having a plurality of fine heating elements formed on the surface thereof are mounted on a heat sink by further applying a semiconductor circuit forming technique. In recent years, such a thermal head has been widely used as a small-sized printing mechanism for a facsimile using a thermal recording paper as a recording paper.

This type of printing apparatus requires a long thermal head. In a long thermal head in which heat generating elements are arranged in a row on a single heat generating substrate, if the long heat generating substrate has even one defect, it becomes a defective product, resulting in poor yield. Therefore, a plurality of line-type thermal heads are arranged so that the heating elements are arranged substantially in a straight line to form a long thermal head. In this way, when a plurality of line-type thermal heads are joined together to form a long thermal head, a heating element is formed on a long ceramic substrate,
After obtaining a non-defective line type thermal head by cutting the substrate on the heating element array, a plurality of shortened line type thermal heads are spliced together so that the heating element array is almost in a straight line. . In the long thermal head combined in this way, the line type thermal heads are combined so that the substrate end faces at both ends in the heating element arrangement direction face the adjacent substrate end faces, so the mechanical accuracy of the joint is not good. Then, in the joint portion of the heating element array, the interval between the heating elements may become wider than other portions. As a result, a problem that white stripes occur when the connected thermal heads are separated from each other occurs. On the contrary, when the overlap between the connected thermal heads is large, a phenomenon of black stripes occurs.

To solve these problems, Japanese Unexamined Patent Publication No.
Japanese Patent Publication No. 138911 discloses a long thermal head in which a mark is attached to a joint portion of a plurality of shortening thermal heads so that a space between heating elements is a predetermined space.

FIG. 1 is a perspective view of a long thermal head described in JP-A-5-138911. Two
-1,2-2, ... are short line type thermal heads, and each line type thermal head 2-1, 2-2 ,.
Then, on the main surface of the heat generating substrate 6, heat generating elements are formed in a row in the vicinity of the ends on the long side. Reference numeral 8 represents a heating element array. Each line type thermal head 2-1
The heat generating substrates 6 of 2-2, ... Are fixed to the respective support plates 7 with an adhesive or a double-sided adhesive tape. 10 is a protective cover.

As the heat generating substrate 6, for example, a ceramic substrate whose surface is covered with a glassy glaze layer is used, and a heating element and electrodes are arranged on the glaze layer by a thin film method or a thick film method. The protective film is formed on at least the heating element. A semiconductor integrated circuit device for a drive circuit is mounted in the protective cover 10 of each line type thermal head 2-1, 2-2, .... Reference numeral 12 is a connector connected to an external circuit. In the heat generating substrate 6 of each of the line type thermal heads 2-1 to 2-5, the substrates at both ends of the heat generating element array 8 are cut in a direction inclined with respect to the main scanning line direction (direction of the heat generating element arrangement). Is provided with a notch. A plurality of adjacent heat generating substrates are arranged in the main scanning line direction with their cutouts facing each other.

FIG. 2 shows a part of the heating elements and electrodes of the heating substrate 6 shown in FIG. Reference numerals 14a and 14b denote heating elements, which are arranged in a line along the end side 22 on the heating substrate 6. The heating element 14 a is connected to the common electrode 18, the heating element 14 b is connected to the selection electrode 20, and the pair of adjacent heating elements 14 a and 14 b are connected by the connecting electrode 16. 1 by a pair of electrodes 14a and 14b connected by the connection electrode 16
It constitutes a heating element for the dots. Heating elements 14a, 14
A protective film is formed so as to cover b. In addition, the common electrode 18 is connected to a power supply wiring for supplying a power supply for printing,
The selection electrode 20 is connected to the semiconductor integrated circuit device for a drive circuit in order to individually select the heating element. Common electrode 18
The selection electrode 20 and the selection electrode 20 are arranged on the side opposite to the end side 22 with respect to the heating element arrangement.

The edge 26 of the notch is notched so as to be inclined at an angle θ with respect to the main scanning line 24 on which the heating elements are arranged. In order to use the alignment mark in the process of processing the edge 26, in this example, a part of the connecting electrodes is deformed to 16a as the alignment mark,
One side 28 of the connecting electrode 16 a is formed so as to form an angle θ with the main scanning line 24. Notch edge 26
Is cut parallel to one side 28 of the alignment mark 16a and at a position of a distance A from the side 28. At the time of assembly, a pair of adjacent side edges 26 are opposed to each other, and the line type thermal heads are alternately arranged on the paper feed side and the paper discharge side.

[0009]

However, according to the invention disclosed in Japanese Patent Laid-Open No. 5-138911, the minute shortening thermal head is notched so as to be inclined at an angle θ with respect to the main scanning line 24. There is a problem that it must be performed with high accuracy.

The present invention has been made in view of the above problems, and in a thermal head in which a plurality of shortened thermal heads in which a plurality of heating elements are arranged in a row are connected,
Even if the distance between the heating elements in the connecting part is different from that between other heating elements without high-precision processing, non-uniformity in the printed image does not occur and the thermal quality does not deteriorate the image quality. It is intended to provide a head and its control.

[0011]

In order to solve the above problems, the present invention employs means for solving the problems having the following features.

According to the first aspect of the present invention, in a thermal head in which a plurality of shortening thermal heads in which a plurality of heating elements are arranged in a row are connected, the shortening thermal heads to be connected overlap each other. A plurality of heating elements for printing, one shortened thermal head to be connected, has heating elements at equal intervals, and the other shortened thermal head to be connected is the distance between the heating elements of the one shortened thermal head. It is characterized in that it has a heating element for overlapping printing which is arranged at different intervals.

According to the invention described in claim 1, a plurality of heating elements for overlapping printing are provided on the connection side of each of the shortening thermal heads to be coupled, and one of the shortening thermal heads to be coupled has an equal interval. The other shortening thermal head that has a heating element and is connected to the other shortening thermal head has a heating element for overlapping printing that is arranged at an interval different from the spacing of the heating elements of the one shortening thermal head, thereby performing highly accurate processing. To provide a thermal head that does not cause non-uniformity in a printed image and does not deteriorate the image quality even if the interval of the heating elements of the connecting portion is different from that of the other heating elements without performing. You can

According to a second aspect of the present invention, in the thermal head according to the first aspect, the other shortening thermal head to be connected is arranged at a distance narrower than that of the heating elements of the one shortening thermal head. It is characterized by having a heating element for overlapping printing.

According to the second aspect of the present invention, the other shortening thermal head to be connected is provided with a heating element for overlapping printing, which is arranged at an interval narrower than the spacing between the heating elements of the one shortening thermal head. As a result, it is possible to disperse the nonuniformity of the printed image such as black streaks due to the overlap of the thermal heads whose overlap standard value is larger than 0, and to mitigate the effect to a minimum.

According to a third aspect of the present invention, in the thermal head according to the first aspect, the other shortening thermal heads to be connected are arranged with a spacing wider than a spacing between heating elements of the one shortening thermal head. It is characterized by having a heating element for overlapping printing.

According to the third aspect of the present invention, the other shortening thermal head to be connected is provided with a heating element for overlapping printing, which is arranged at an interval wider than the spacing between the heating elements of the one shortening thermal head. As a result, it is possible to disperse the nonuniformity of the printed image such as white stripes due to the overlap of the thermal heads with the overlap standard value smaller than 0, and reduce the influence thereof to the minimum.

According to a fourth aspect of the present invention, in the thermal head according to the first aspect, the other shortening thermal head to be connected has a gap narrower than a gap between heating elements of the one shortening thermal head and one of the one shortening thermal head. It is characterized in that it has a heating element for overlapping printing in which the intervals of the heating elements of the shortened thermal head and the intervals thereof are alternately arranged.

According to the fourth aspect of the invention, the other shortening thermal heads to be connected are smaller than the spacing between the heating elements of one shortening thermal head and equal to the spacing between the heating elements of one shortening thermal head. By having the heating elements for overlapping printing in which the intervals and the intervals are alternately arranged, the nonuniformity of the printed image such as black streaks due to the overlap of the thermal head having the overlap standard value larger than 0 is dispersed, and its influence is exerted. It is possible to reduce to a minimum, and by controlling the heating element adjacent to the part where the overlap is matched, the end heating element is not affected by the energy of the adjacent heating element. Can be eliminated.

According to a fifth aspect of the present invention, in the thermal head according to the first aspect, the other shortening thermal head to be connected has a spacing wider than a spacing between heating elements of the one shortening thermal head and the one of the one shortening thermal head. It is characterized in that it has a heating element for overlapping printing in which the intervals of the heating elements of the shortened thermal head and the intervals thereof are alternately arranged.

According to the invention described in claim 5, the other shortening thermal heads to be connected are wider than the spacing between the heating elements of the one shortening thermal head and the spacing between the heating elements of the one shortening thermal head. By providing the heating elements for overlapping printing in which the same intervals are alternately arranged, the non-uniformity of the printed image such as white stripes due to the overlap of the thermal head having the overlap standard value smaller than 0 is dispersed, The effect can be minimized, and by controlling the heating elements adjacent to the overlapped part, the end heating elements cannot be affected by the energy of the adjacent heating elements. It is possible to eliminate non-uniformity of the printed image.

According to a sixth aspect of the present invention, in the thermal head according to the first aspect, the plurality of heating elements for overlapping printing in the other shortened thermal head to be connected have a space between the heating elements on the connecting side. It is characterized in that it is arranged so as to be narrower than the space between the heating elements of one of the shortening thermal heads and to be arranged so that the space between the heating elements on the non-connected side is larger than the space between the heating elements of the one shortening thermal head.

According to the invention described in claim 6, the interval between the heating elements on the connecting side is narrower than the interval between the heating elements of the one thermal head, and the interval between the heating elements on the non-connecting side is shortened by the one. By arranging the thermal head so as to be wider than the space between the heating elements, even if the standard value of the overlap is around 0, non-uniformity of the printed image such as white stripes and black stripes due to the overlap is dispersed. The impact can be minimized.

According to a seventh aspect of the present invention, in the thermal head according to the first aspect, the plurality of heating elements for overlapping printing in the other shortening thermal head to be connected have a space between the heating elements on the connecting side. It is characterized in that it is arranged so as to be wider than the space between the heating elements of one of the shortened thermal heads and smaller than the space between the heating elements of the non-connected side thermal head.

According to the invention described in claim 7, in the plurality of heating elements for overlapping printing in the other shortening thermal head to be connected, the interval of the heating elements on the connecting side is set to the interval of the heating elements of the one shortening thermal head. Even if the standard value of the overlap is around 0, the white stripes due to the overlap are arranged by arranging the gap between the heat generating elements on the side not to be connected to be wider and narrower than the space between the heat generating elements of one shortened thermal head. It is possible to disperse non-uniformity of the printed image such as black streaks, and reduce the effect to a minimum.

According to an eighth aspect of the invention, in a thermal head in which a plurality of shortening thermal heads in which a plurality of heating elements are arranged in a row are connected, the shortening thermal heads to be connected overlap each other. Having a plurality of heating elements for printing, the interval between the plurality of heating elements for overlapping printing of one connected short thermal head, and the interval between the plurality of heating elements for overlapping printing of the other short thermal head connected. It is characterized in that they are arranged differently.

According to the invention described in claim 8, the interval between the plurality of heating elements for overlapping printing of one shortening thermal head to be connected and the plurality of heat generation for overlapping printing of the other shortening thermal head to be connected. By arranging the elements so as to be different from the interval between the elements, it is possible to disperse the nonuniformity of the printed image due to the overlap and reduce the influence thereof to the minimum.

According to a ninth aspect of the invention, in a thermal head in which a plurality of shortening thermal heads in which a plurality of heating elements are arranged in a row are connected, the shortening thermal heads to be connected overlap each other. A plurality of heating elements for printing are provided, and an interval between the heating elements except for the predetermined heating element for overlapping printing in one shortening thermal head to be connected and a predetermined heat generation for overlapping printing in the other shortening thermal head to be connected The interval between the heating elements excluding the elements is equal, and the interval between the predetermined heating elements for overlapping printing of one shortening thermal head to be connected is the predetermined heating for overlapping printing of the other shortening thermal head to be connected. It is characterized in that it is arranged narrower or wider than the space between the elements.

According to the invention described in claim 9, the interval between the heat generating elements excluding the predetermined heat generating elements for overlapping printing in one of the shortening thermal heads to be connected and the overlap of the other shortening thermal head to be connected. The interval between the heating elements other than the predetermined heating element to be printed is equal, and the overlap between the one shortening thermal heads to be connected is the overlap between the other shortening thermal heads to be connected. By arranging the gap narrower or wider than the space between the predetermined heating elements to be printed, the influence can be minimized regardless of whether the standard value of overlap is wide or narrow.

The invention described in claim 10 is claim 1
In the method of controlling the heating element in the thermal head described, in the other short thermal head to be connected, the interval between the plurality of overlapping heating elements is narrow, and the heat of the adjacent heating element excessively affects the dots printed by the heating element. If
The feature is that the amount of energy to generate heat is set to be small.

The invention described in claim 11 is the same as claim 1.
In the method for controlling the heating element in the thermal head described above, the interval between a plurality of overlapping heating elements of the other shortening thermal head to be connected is wide, and the heat of the adjacent heating elements affects the dots printed by the heating elements too small. If
It is characterized in that the amount of energy to generate heat is set to be large.

The invention described in claim 12 is the invention according to claim 8.
Alternatively, in the method for controlling a heating element in a thermal head as described in 9, the space between a plurality of overlapping heating elements of the other shortened thermal head to be connected is wide, and the heat of the adjacent heating element is too small for the dots printed by the heating element. If there is an influence, set the amount of energy to generate heat to be large, and the gap between a plurality of overlapping heating elements of the other shortening thermal head to be connected is narrow, and the heat of adjacent heating elements prints on that heating element. When the dots are excessively affected, the amount of energy to generate the heat is set to be small.

The invention described in claim 13 is the same as claim 8.
13. The heating element control method according to any one of claims 1 to 12, based on the setting of a reference heating element in a plurality of heating elements to be overprinted or the setting of an unused heating element among the plurality of heating elements to be overprinted. The heating element is controlled.

The invention described in claim 14 is claim 1
In the heating element control method according to the third aspect, the setting of the heating element or the unused heating element of the plurality of heating elements to be printed in duplicate is performed by an external terminal or an operation panel.

The invention described in claims 10 to 14 is defined by claim 1.
9 is a method for controlling a heating element of a thermal head, which is suitable for the method for controlling a heating element of a thermal head.

Further, when the distance between the heating elements is narrower than that between the other heating elements, the influence on the output image due to the large influence of the adjacent heating elements due to the narrow spacing between the heating elements can be mitigated. .

Further, when the spacing between the heating elements is wider than that between the other heating elements, it is possible to reduce the influence on the output image due to the reduction in the influence of the adjacent heating elements due to the wide spacing between the heating elements. .

Further, the interval between the plurality of overlapping heating elements is
When it is wider than other heating elements, the amount of heat generated is larger than that of equal heating elements, and when it is narrow, it is reduced to reduce the influence of heat from adjacent heating elements caused by the gap and the coloring area per unit. The difference between can be eased.

Further, by operating the external terminal or the operation panel, it is possible to set a reference heating element in a plurality of heating elements to be printed in duplicate or to set a heating element not used in a plurality of heating elements to be printed in duplicate. become able to.

Further, by setting the heating elements that are not used in the overlapping portion, it is not necessary to use the portion where the overlap is shifted due to the overlapping, and a uniform output image can be obtained.

[0041]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

The present invention is a thermal head in which a plurality of unit heating elements are arranged in a row or in a staggered pattern on each of a plurality of ceramic substrates provided on a heat dissipation plate, and at the connecting portion of the plurality of substrates. The thermal head and its control method are characterized in that they have a plurality of heating elements that overlap with each other, and that the heating elements can be individually controlled in heating state and heat generation amount. (Embodiment 1) FIG. 3 is a shortened thermal head in which a plurality of unit heating elements are arranged in one row of the present invention (hereinafter, abbreviated as a head).
3A and 3B are a layout view of heating elements (FIG. 3A) and black solid images (FIGS. 3B and 3C) in a portion where A and the head B are connected.

The head A has heating elements 31 _{1 to} 3 _1.
1 ₈ . ． ． And the distance between each heating element is the same distance L
It is ₁ . On the other hand, the head B includes the heating elements 32 _{1 to} 3 3.
2 ₈ . ． ． Have the spacing between the heating elements ₃₂₁ to 323 ₅ are the same distance _{L 2 (L 2 <L 1} ), heating elements 32
_{6 to} 32 ₈ . ． ． The distance between them is the same distance L ₁ . Further, the heating elements ₃₂₁ to 323 ₅ of the heating elements ₃₁ 1 to 31 ₅ and the head B of the head A is a heating element overlapping printing.

[0044] In the arrangement of the heating elements of FIG. 3 (A), the spacing of the heating elements in the heating elements ₃₂₁ to 323 ₅ overlapping print head B is the distance _{L 2,} the heat generation of the other head A and the head B The distance between the elements is the distance L ₁ .

Further, in FIG. 3 (A), the When there is no heating elements ₃₂₁ to 323 ₅ overlapping print head B, the heating elements of the head A and the head B, the distance _L 3 _(L 3 <
They are connected at an interval of L ₁ ). Figure 3 (A)
In no heating elements 321 _to 323 ₅ overlapping print head B, and that only the right side of the heat generating element from dotted line 40, the heat generating element distance between the head end of the connecting portion, the distance L between the heating elements Since it is narrower than _1, the image printed by all the heating elements is an image in which the dot overlap in the X portion is large, as shown in FIG. If the dot overlap is large, that portion appears as a dot larger than the other dots in the upper and lower images, resulting in an output image having black stripes in the upper and lower parts.

By the way, in the case of FIG.
Since the space between the heat generating elements is slightly narrowed in the overlapped printing portion, the heat generating elements of the head A and the head B coincide with each other at some point (including the case where they substantially coincide with each other. The same applies hereinafter). Exists (in FIG. 3 (A), the heating element at the position of 30). Therefore, ₃₁ 4 ~ of the pixel that generates heat head A
31 ₈ . ． ． And heating elements 32 _{2 to} 3 of head B
2 ₈ . ． ． By printing with, the distance L ₃ between the heating elements of the head A and the head B can be eliminated. At this time, the left of the head A to 31 _4, the heat generating element 32 ₂ of the head B
When printed with the heating element on the right side of FIG. 3, a normal image shown in FIG. 3B can be obtained.

The distance between the head A and the head B is such that heat is generated.
Distance between elements L₁Explain when it is narrower
However, the distance between the head A and the head B is between the heating elements.
Distance L ₁The same applies to wider cases. (Embodiment 2) FIG. 4 shows a portion where head A and head C are connected.
Of the heating element layout (Fig. 4 (A)) and solid black image
(FIGS. 4B and 4C).

The head A has heating elements 31 _{1 to} 3 _1.
1 ₈ . ． ． And the distance between each heating element is the same distance L
It is ₁ . On the other hand, the head C includes the heating elements 33 _{1 to} 3 3.
3 ₈ . ． ． Have the spacing between the heating elements ₃₃ to 333 ₅ is the same distance _{L 3 (L 3> L 1} ), heating elements 33
_{6 to} 33 ₈ . ． ． The distance between them is the same distance L ₁ . Further, the heating elements ₃₃ to 333 ₅ of the heating elements ₃₁ 1 to 31 ₅ and the head B of the head A is a heating element overlapping printing.

[0049] In the arrangement of the heating element of FIG. 4 (A), the interval of the heating elements in the heating elements ₃₃ to 333 ₅ overlapping print head C is a distance _{L 3,} the heat generation of the other head A and the head B The distance between the elements is the distance L ₁ .

[0050] Further, in FIG. 4 (A), the When there is no heating elements ₃₃ to 333 ₅ overlapping print head C, the heating elements of the head A and head C, the distance _L 5 _(L 5>
They are connected at an interval of L ₁ ). Figure 4 (A)
In no heating elements 33 _to 333 ₅ overlapping print head C, and only the right side of the heating element from dotted line 40, the heat generating element distance between the head end of the connecting portion, the distance L between the heating elements Since it is wider than _1, the image printed by all the heating elements is an image in which the dot overlap in the Y portion is small as shown in FIG. 4 (C). If the dot overlap is small, that portion appears as dots smaller than other dots in the upper and lower images, resulting in an output image having white stripes in the upper and lower parts.

By the way, in the case of FIG.
Since the space between the heating elements is slightly widened in the overlapping print portion, there is a location where the heating elements of the head A and the head B coincide with each other (in FIG. 4 (A), the heating elements at the position of 30). ). Therefore, the pixels for generating heat of the head A ₃₁ 4 to 3
1 ₈ . ． ． Heating elements _{33 2-33} 8 the head C. ． ．
If printed with, the distance L between the heating elements of head A and head C
₅ can be eliminated. At this time, the left of the head A to 31 _4, when printing from the heater element 33 ₂ of the head C at the right side of the heating element, can be obtained FIG. 4 (B) is a normal image.

The distance between the head A and the head B is that heat is generated.
Distance between elements L₁Explain when it is wider
However, the distance between the head A and the head B is between the heating elements.
Distance L ₁The same is true for narrower cases. (Embodiment 3) FIG. 5 shows a portion in which the head A and the head D are connected.
Of the heating element layout (Fig. 5 (A)) and solid black image
(FIGS. 5B and 5C).

The head A has a heating element 31.₁~ 3
1₁₀． ． ． Has the same distance between each heating element
L₁Is. On the other hand, the head D includes the heating element 34.₁~ 34
₁₀． ． ． Having a heating element 34₁~ 34₇Interval between
Is the heating element 34₁~ 34_TwoDistance L ₁, Heating element 3
Four_Two~ 34_ThreeDistance L₆(L₆<L₁), Heating element 3
Four_Three~ 34_FourDistance L₁Like L₁And distance L
₆And are arranged alternately. In addition, the heating element 34₈~
34₁₀． ． ． The distance between them is the same distance L₁Is. Well
Also, the heating element 31 of the head A₁~ 31₇And head D
Thermal element 34₁~ 34₇However, it is a heating element that prints
It

In the arrangement of the heating elements of FIG. 5A, the heating elements 34 _{1 to} 34 ₇ of the head D for overlapping printing are arranged between the heating elements 34 _{2 to} 34 _{3 and} between the heating elements 34 _{4 to} 34 ₅ and the heating element 34. _6-34 spacing between ₇ is the distance _{L 6,} the spacing of the heating elements of the other of the head a and the head D, the distance L
It is ₁ .

[0055] Further, in FIG. 5 (A), when the no heating elements ₃₄ 1 to 34 ₇ duplicate print head D is the heating elements of the head A and the head D, the distance _L 7 _(L 7 <
They are connected at an interval of L ₁ ). Figure 5 (A)
In no heating elements 34 ₁ to 34 ₇ duplicate print head D is, when only the right side of the heat generating element from dotted line 40, the heat generating element distance between the head end of the connecting portion, the distance L between the heating elements Since it is narrower than _1, the image printed by all the heating elements is an image in which the dot overlap in the X portion is large, as shown in FIG. 5 (C). If the dot overlap is large, that portion appears as a dot larger than the other dots in the upper and lower images, resulting in an output image having black stripes in the upper and lower parts.

By the way, in the case of FIG.
Since the intervals of the heating elements are overlapping print portions and the narrow intervals are arranged at intervals, the heating elements of the head A and the head D coincide with each other (FIG. 5 (A)).
Then, the heating element at the position of 30). Therefore, the pixels that generate heat are referred to as head elements 31 _{6 to} 31 ₁₀ . ． ． And the heating elements 34 _{2 to} 34 _{10 of the} head D. ． ． By printing with, the distance L ₇ between the heating elements of the head A and the head D can be eliminated. At this time, the left of the head A to 31 _6, when printing from the heating element 34 ₂ of the head D between the right of the heater element, it is possible to obtain 5 (B) is a normal image.

The distance between the head A and the head D is such that heat is generated.
Distance between elements L₁Explain when it is narrower
However, the distance between the head A and the head D is between the heating elements.
Distance L ₁The same applies to wider cases. (Embodiment 4) FIG. 6 shows a portion in which the head A and the head E are connected.
Of the heating element layout (Fig. 6 (A)) and a solid black image
(FIGS. 6B and 6C).

The head A has a heating element 31.₁~ 3
1₁₀． ． ． Has the same distance between each heating element
L₁Is. On the other hand, the head E includes the heating element 35.₁~ 35
₁₀． ． ． Having a heating element 35₁~ 35₇Interval between
Is the heating element 35₁~ 35_TwoDistance L ₁, Heating element 3
5_Two~ 35_ThreeDistance L₈(L₈> L₁), Heating element 3
5_Three~ 35_FourDistance L₁Like L₁And distance L
₈And are arranged alternately. In addition, the heating element 35₈~
35₁₀． ． ． The distance between them is the same distance L₁Is. Well
Also, the heating element 31 of the head A₁~ 31₇And head E
Thermal element 35₁~ 35₇However, it is a heating element that prints
It

In the arrangement of the heating elements shown in FIG. 6A, the heating elements 35 _{1 to} 35 ₇ of the head E for overlapping printing are arranged between the heating elements 35 _{2 to} 35 _{3 and} between the heating elements 35 _{4 to} 35 ₅ and the heating element 35. _6-35 spacing between ₇ is the distance _{L 8,} the distance between the heating elements of the other of the head a and the head E, the distance L
It is ₁ .

[0060] Further, in FIG. 6 (A), the When no heating elements ₃₅ 1 to 35 ₇ duplicate print head E is, heating elements of the head A and the head E, the distance _L 9 _(L 9>
They are connected at an interval of L ₁ ). FIG. 6 (A)
In no heating elements 35 ₁ to 35 ₇ duplicate print head E is, when only the right side of the heat generating element from dotted line 40, the heat generating element distance between the head end of the connecting portion, the distance L between the heating elements Since it is wider than _1, the image printed by all the heating elements is an image in which the overlap of dots in the Y portion is small, as shown in FIG. 6 (C). If the dot overlap is small, that portion appears as dots smaller than other dots in the upper and lower images, resulting in an output image having white stripes in the upper and lower parts.

By the way, in the case of FIG.
Since the space between the heating elements is overlappingly printed and the wide spaces are arranged every other space, there is a location where the heating elements of the head A and the head E coincide with each other (FIG. 6A).
Then, the heating element at the position of 30). Therefore, the pixels that generate heat are referred to as head elements 31 _{6 to} 31 ₁₀ . ． ． Heating element _{35 2-35 10} the head E. ． ． If the printing is performed with, the distance L ₇ between the heating elements of the head A and the head E can be eliminated. At this time, the left of the head A to 31 _6, when printing from the heater element 35 ₂ of the head E in the right of the heating element, can be obtained FIG. 6 (B) is a normal image.

The case where the distance between the head A and the head E is wider than the distance L ₁ between the heating elements has been described, but the same applies when the distance between the head A and the head E is narrower than the distance L ₁ between the heating elements. Is. (Embodiment 5) FIG. 7 is a layout diagram of heating elements (FIG. 7A) and a solid black image (FIGS. 7B and 7C) in a portion where head A and head F are connected. .

The head A has a heating element 31.₁~ 3
1₁₁． ． ． Has the same distance between each heating element
L₁Is. On the other hand, the head F has a heating element 36.₁~ 36
₁₁． ． ． Having a heating element 36₁~ 36₈Interval between
Is the heating element 36₁~ 36_TwoDistance L ₁₀, Heating element
36_Two~ 36_ThreeDistance L₁₁(L₁₀> L₁₁), Departure
Thermal element 36_Three~ 36_FourDistance L₁₂(L₁₁>
L₁₂), L₁₀> L₁₁> L ₁₂> L_Thirteen>
L₁₄> L₁₅> L₁₆It is arranged. Also fever
Element 36 ₉~ 36₁₁． ． ． The distance between them is the same distance L₁
Is. In addition, the heating element 31 of the head A₁~ 31₈And f
Heating element 36 of the hood F₁~ 36₈However, fever that causes duplicate printing
It is an element.

In the arrangement of the heating elements shown in FIG.
Heating element 36 for overlapping printing of F₁~ 36₈Fever in
Element spacing is L₁₀> L₁₁> L₁₂> L_Thirteen> L₁₄
> L ₁₅> L₁₆And other heads A
And the heating element of the head F is separated by a distance L₁Is.

[0065] Also, In FIG. 7 (A), when not heating elements ₃₆ 1 to 36 ₈ overlapping print head F is, heating elements of the head A and the head F, the distance _{L 17 (L} 17>
They are connected at an interval of L ₁ ). Figure 7 (A)
In no heating elements 36 ₁ to 36 ₇ duplicate print head F is, when only the right side of the heat generating element from dotted line 40, the heat generating element spacing L ₁₇ of both the head end of the connecting portion,
Since the distance is larger than the interval L ₁ between the heating elements, the image printed by all the heating elements is an image in which the dot overlap in the Y portion is small, as shown in FIG. 7C. If the dot overlap is small, that portion appears as dots smaller than other dots in the upper and lower images, resulting in an output image having white stripes in the upper and lower parts.

By the way, in the case of FIG. 7A, the head F
Since the heating element spacing is in the overlapping print area and is arranged in order from wide to narrow from the left side to the right side,
There is a location where the heating elements of the head A and the head F coincide with each other (the heating element at the position 30 in FIG. 7A). Therefore, the pixels that generate heat are set to the heads 31 _{8 to} 31
_{1 1} . ． ． And the heating elements 36 _{1 to} 3 of the head F
6 ₁₁ . ． ． If the printing is performed with, the distance L ₁₇ between the heating elements of the head A and the head F can be eliminated. At this time,
And from the left of the head A to 31 _8, the heating elements 3 of the head F
When 6 ₁ printed at the right side of the heating element, can be obtained FIG. 7 (B) is a normal image.

The case where the distance between the head A and the head F is wider than the distance L ₁ between the heating elements has been described, but the same applies when the distance between the head A and the head F is narrower than the distance L ₁ between the heating elements. Is. (Embodiment 6) FIG. 8 is a layout view of heating elements (FIG. 8A) and a solid black image (FIGS. 8B and 8C) in a portion where head A and head G are connected. .

The head A has a heating element 31.₁~ 3
1₁₁． ． ． Has the same distance between each heating element
L₁Is. On the other hand, the head G has a heating element 37.₁~ 37
₁₁． ． ． Having a heating element 37₁~ 37₈Interval between
Is the heating element 37₁~ 37_TwoDistance L ₁₈, Heating element
37_Two~ 37_ThreeDistance L₁₉(L₁₈<L₁₉), Departure
Thermal element 37_Three~ 37_FourDistance L₂₀(L₁₉<
L₂₀), L₁₈<L₁₉<L ₂₀<L₂₁<
L₂₂<L₂₃<L₂₄It is arranged. Also fever
Element 37 ₉~ 37₁₁． ． ． The distance between them is the same distance L₁
Is. In addition, the heating element 31 of the head A₁~ 31₈And f
Heating element 37 of the pad G₁~ 37₈However, fever that causes duplicate printing
It is an element.

In the arrangement of the heating elements shown in FIG.
Heating element 37 for G overlapping printing₁~ 37₈Fever in
Element spacing is L₁₈<L₁₉<L₂₀<L₂₁<L₂₂
<L ₂₃<L₂₄And other heads A
And the heating element of the head G are separated by a distance L₁Is.

[0070] Further, in FIG. 8 (A), the When no heating elements ₃₇ 1 to 37 ₈ overlapping print head G is the heating elements of the head A and the head G, the distance _{L 25 (L} 25 <
They are connected at an interval of L ₁ ). Figure 8 (A)
In no heating elements 37 ₁ to 37 ₈ overlapping print head G is, when only the right side of the heat generating element from dotted line 40, the heat generating element spacing L ₂₅ of both the head end of the connecting portion,
Since the distance is smaller than the interval L ₁ between the heating elements, the image printed by all the heating elements is an image in which the dot overlap in the X portion is large, as shown in FIG. 8C. If the dot overlap is large, that portion appears as a dot larger than the other dots in the upper and lower images, resulting in an output image having black stripes in the upper and lower parts.

By the way, in the case of FIG.
Since the heating element spacing is in the overlapping print area and is arranged in order from the narrowest to the widest from the right side to the left side,
There is a location where the heating elements of the head A and the head G coincide with each other (the heating element at the position 30 in FIG. 8A). Therefore, the pixels that generate heat are set to the heads 31 _{8 to} 31
_{1 1} . ． ． And heating elements 37 _{1 to} 3 of the head G
7 ₁₁ . ． ． If the printing is performed with, the distance L ₂₅ between the heating elements of the head A and the head G can be eliminated. At this time,
And from the left of the head A to 31 _8, the heating elements 3 of the head G
When 7 ₁ printed at the right side of the heating element, can be obtained FIG. 8 (B) is a normal image.

The case where the distance between the head A and the head G is narrower than the distance L ₁ between the heating elements has been described. However, the same is true when the distance between the head A and the head G is wider than the distance L ₁ between the heating elements. Is. (Embodiment 7) FIG. 9 is a layout view of heating elements (FIG. 9A) and a solid black image (FIGS. 9B and 9C) in a portion where head I and head G are connected. .

The head I has a heating element 38.₁~ 3
8₁₁． ． ． Having a heating element 38₁~ 38 _FourInterval between
Are the same distance L₂₆(L₂₆> L₁) Is the heating element
38₅~ 38 ₁₁． ． ． The distance between them is the same distance L₁And
It On the other hand, the head H includes the heating element 39 ₁~ 3
9₁₁． ． ． Having a heating element 39₁~ 39_FourInterval between
Are the same distance L_{Two 7}(L₂₇<L₁) Is the heating element
39₅~ 39₁₁． ． ． The distance between them is the same distance L₁And
It Further, the heating element 38 of the head I₁~ 38₈And head
H heating element 39₁~ 39₈However, the heating element that performs duplicate printing
Is.

In the arrangement of the heating elements shown in FIG. 9A, the head is
I heating element 38₁~ 38_FourThe distance is L₂₆(L
₂₆> L₁), The heating element 39 of the head H.₁~
39 _FourThe distance is L₂₇(L₂₇<L₁) Placed in
The distance between the heating elements of the other heads I and H is
Distance L₁It is located in.

[0075] Further, in FIG. 9 (A), the heating elements ₃₉ 1 to the heating elements ₃₈ 1 to 38 ₄ and the head H of the head I
When 39 ₄ no heating elements of the head I and the head H is, so that it is attached in intervals of a distance _{L 28 (L 28 <L 1} ). Since the heating element spacing L ₂₈ at both ends of the connecting portion is smaller than the spacing L ₁ between the heating elements, the image printed by all the heating elements is as shown in FIG. 9C. , X is an image in which the dot overlap is large. If the dot overlap is large, that portion appears as a dot larger than the other dots in the upper and lower images, resulting in an output image having black stripes in the upper and lower parts.

By the way, in the case of FIG. 9A, the head I
Heating elements ₃₈ 1 to 38 the spacing between ₄ distance _L 26 (L of
₂₆ > L ₁ ), and the heating elements 39 ₁ to
The interval between 39 ₄ are arranged at a distance _{L 27 (L 27 <L 1} ), somewhere in the heating elements of the head I and the head H are places exist that match (FIG. 9 (A), the Heating element at position 30). Therefore, the pixel that generates heat is
8 _{8 to} 38 ₁₁ . ． ． And heating elements 39 _{1 to} 3 of the head H
9 ₁₁ . ． ． If the printing is performed with, the distance L ₂₈ between the heating elements of the head I and the head H can be eliminated. At this time,
And from the left of the head I to 38 _8, the heating elements 3 of the head H
When 9 ₁ printed at the right side of the heating element, can be obtained FIG. 9 (B) is a normal image.

Although the case where the distance between the head I and the head H is narrower than the distance L ₁ between the heating elements has been described, the same applies when the distance between the head I and the head H is wider than the distance L ₁ between the heating elements. Is. This is shown in FIG.
Since FIG. 10 is based on FIG. 9, description will be omitted. (Control of Thermal Head) It is well known that, when heat is applied to a medium that develops color by heat using a heat generating element to generate color, the color is affected by the adjacent heat generating elements depending on the amount of heat generation and the distance. Here, when the distance between heating elements and the amount of energy of heat generation affect adjacent dots, and when the spacing between heating elements is narrower, the dots are thicker and the colors are colored because they are more affected by the heat of adjacent heating elements. The area becomes large. On the other hand, when the interval is wide, the influence of heat from the adjacent heat generating elements is small, and the size and the color development area of the dots are both close to the case where there is no influence of adjacent dots.

Therefore, when a plurality of overlapping heating elements of the other shortened thermal head to be connected are wide and the heat of the adjacent heating elements has an excessively small effect on the dots printed by the heating elements, the energy to generate the heat is generated. If the distance between the overlapping heating elements of the other shortening thermal head to be connected is narrow and the heat of the adjacent heating elements excessively affects the dots printed by that heating element, The amount of energy to generate heat is set and controlled so as to be reduced.

Control of the thermal head will be described with reference to FIG. FIG. 11 shows a thermal head 50, an image memory 41, a head setting memory 42, a system control unit 43, a head control unit 44, an operation panel 45, a power supply 47, an interface 46, a network, and an external terminal 48 provided via a cable or the like. It is configured. The thermal head 50 is the head 49
_A to head 49 _N. Further, the interface 46 serves as an interface between the system control unit 43 and an external terminal.

The image to be printed is stored in the image memory 41 line by line. The system control unit 43 reads out image data for each line from the image memory 31, and outputs the data for one line to the selection electrode of the thermal head 40 via the head control unit 44.

The head control unit 44 individually controls on / off and heat generation amount of each heating element of the heads 49 _A to 49 _N based on the setting data stored in the setting memory 42. You can The head control unit 44 includes the setting memory 4
The heating element used for 2 and the data of the distance between the heads are passed to the head control unit 44,
In the head control unit 44, based on the data, the amount of printing energy is controlled by the printing data of the surrounding dots that affect the printed image, and printing is performed.

The setting of the setting memory 42 can be set by the operation panel 45 and / or the external terminal 48. Input from the operation panel 45 or external terminal 48
Command inputs and the like are processed in the system control unit 43. In this way, the setting memory 42 stores the state of the connection portion of the heat generating boards. For example, in the setting memory 42, the heating elements that are not involved in the printing, the information regarding the intervals between the heating elements in the connecting portion,
The information of the heating elements and the like for printing at the same position in 8 is stored.

The overlap standard in the present invention
The value is the heat generated in the head in FIG.
Distance L between elements₁Of the heating element between the heads
Distance L_ThirtyRepresents how different the values of Overlap value = L₁-L_Thirty Is.

[0084]

As described above, according to the present invention, in a thermal head in which a plurality of shortened thermal heads in which a plurality of heating elements are arranged in a row are connected, a connecting portion of a connecting portion can be formed without performing highly accurate processing. It is possible to provide a thermal head and its control that do not cause non-uniformity in a printed image even if the spacing between heating elements differs from that between other heating elements, and do not reduce image quality.

[0085]

[Brief description of drawings]

FIG. 1 is a diagram (No. 1) for explaining a conventional example.

FIG. 2 is a diagram (part 2) for explaining a conventional example.

FIG. 3 is a diagram for explaining the first embodiment. FIG. 9 is a diagram in which the intervals of a plurality of heating elements that overlap the right thermal head and the left thermal head are narrower than those between other heating elements.

FIG. 4 is a diagram for explaining a second embodiment. FIG. 9 is a diagram in which the intervals of a plurality of heating elements overlapped with the left thermal head of the right thermal head are wider than between other heating elements.

FIG. 5 is a diagram for explaining a third embodiment. FIG. 9 is a diagram in which the intervals of a plurality of heating elements that overlap the right thermal head and the left thermal head are narrower than those of other heating elements and are equal to each other.

FIG. 6 is a diagram for explaining a fourth embodiment. FIG. 6 is a diagram in which the intervals of a plurality of heating elements that overlap with the left thermal head of the right thermal head are wider than those between other heating elements and are equal to each other.

FIG. 7 is a diagram for explaining a fifth embodiment. FIG. 7 is a diagram in which the intervals of a plurality of heating elements that overlap the right thermal head and the left thermal head are arranged in order from a narrower one to a wider one than between other heating elements.

FIG. 8 is a diagram for explaining a sixth embodiment. FIG. 7 is a diagram in which the intervals of a plurality of heating elements that overlap the right thermal head and the left thermal head are arranged in order from one that is wider than the other heating elements to one that is narrower.

FIG. 9 is a diagram for explaining the seventh embodiment. This is an example when the heating element spacing between the heads is narrow.

FIG. 10 is an example of the same thermal head as in FIG. 9 with a large heating element spacing between the heads.

FIG. 11 is a functional schematic diagram of an image output device that performs settings from an external terminal, a panel, or the like.

FIG. 12 is a diagram for explaining a standard value of overlap.

[Explanation of symbols]

A, I Left-side shortened thermal head B to H Right-side shortened thermal head 30 Arrow indicating a reference heating element (the arrowhead of 30 is a reference heating element) 31 to 39 Heating element 40 It is assumed that there is no duplicate heating element. Line 41 showing the head end at time Image memory 42 Head setting memory 43 System control unit 44 Head control unit 45 Operation panel 46 Interface 47 Power supply 48 External terminal 50 Thermal head

Claims (14)

[Claims] 1. In a thermal head in which a plurality of shortening thermal heads in which a plurality of heating elements are arranged in a row are connected, a plurality of heating elements for overlapping printing are provided on the connection side of each shortening thermal head to be connected. One of the shortened thermal heads to be connected has heating elements at equal intervals,
The thermal head is characterized in that the other shortening thermal head to be connected has a heating element for overlapping printing arranged at an interval different from that of the heating element of the one shortening thermal head. 2. The shortening thermal head to be connected to the other shortening thermal head has a heating element for overlapping printing, which is arranged at an interval narrower than an interval of the heating element of the one shortening thermal head. Thermal head. 3. The shortened thermal head to be connected to the other shortened thermal head has a heating element for overlapping printing, which is arranged at a distance wider than a distance between the heating elements of the one shortened thermal head. Thermal head. 4. The other shortening thermal head to be connected is arranged such that a gap narrower than a gap between heating elements of the one shortening thermal head and a gap equal to a gap between heating elements of the one shortening thermal head are alternately arranged. 2. The thermal head according to claim 1, further comprising a heating element for overlapping printing. 5. The other shortening thermal head to be connected is arranged such that a spacing wider than a spacing between heating elements of the one shortening thermal head and a spacing equal to a spacing between heating elements of the one shortening thermal head are alternately arranged. 2. The thermal head according to claim 1, further comprising a heating element for overlapping printing. 6. The plurality of heating elements for overlapping printing in the other shortening thermal head to be connected have a spacing between heating elements on the coupling side narrower than a spacing between heating elements on the one shortening thermal head and not to be coupled to each other. 2. The thermal head according to claim 1, wherein the heating elements are arranged such that the spacing between the heating elements is wider than the spacing between the heating elements of the one shortened thermal head. 7. The plurality of heating elements for overlapping printing in the other shortening thermal head to be connected have a spacing between heating elements on the coupling side that is wider than a spacing between heating elements on the one shortening thermal head, and are not to be coupled to each other. 2. The thermal head according to claim 1, wherein the heating elements are arranged such that the spacing between the heating elements is narrower than the spacing between the heating elements of the one shortened thermal head. 8. A thermal head in which a plurality of shortening thermal heads in which a plurality of heating elements are arranged in a row are connected, a plurality of heating elements for overlapping printing are provided on the connection side of each shortening thermal head to be connected. However, it is arranged so that the interval between the plurality of heating elements for overlapping printing of one connected short thermal head and the interval between the plurality of heating elements for overlapping printing of the other short thermal head to be connected are different. The thermal head. 9. A thermal head in which a plurality of shortening thermal heads in which a plurality of heating elements are arranged in rows are connected, and a plurality of heating elements for overlapping printing are provided on the connecting side of each of the shortening thermal heads to be connected. And the space between the heating elements excluding the predetermined heating elements for overlapping printing in one shortened thermal head to be connected, and the space between the heating elements excluding the predetermined heating elements for overlapping printing in the other shortening thermal head to be connected. Is equal to each other, and the interval between the predetermined heating elements for overlapping printing of one of the connected short thermal heads is narrower than the interval between the predetermined heating elements for overlapping printing of the other short thermal head to be connected or A thermal head that is widely arranged. 10. The method for controlling a heating element in a thermal head according to claim 1, wherein a plurality of overlapping heating elements of the other shortened thermal head to be connected have a narrow gap, and the heat of the adjacent heating element is the same as that of the heating element. A method for controlling a heating element, which is characterized in that when a dot to be printed is excessively affected, the amount of energy to generate the heat is set to be small. 11. The method of controlling a heat generating element in a thermal head according to claim 1, wherein a plurality of overlapping heat generating elements of the other short thermal head to be connected have a wide interval, and the heat of the adjacent heat generating element is the same as that of the heat generating element. A method for controlling a heating element, wherein when a dot to be printed has an excessively small influence, the amount of energy to generate heat is set to be large. 12. The method for controlling a heating element in a thermal head according to claim 8 or 9, wherein a plurality of overlapping heating elements of the other shortening thermal head to be connected have a large gap, and the heat of the adjacent heating element is generated by the heat generation. If the dots printed by the element are too small, set the amount of energy to generate heat to a large value, and the space between the overlapping heating elements of the other shortening thermal head to be connected is narrow and A method for controlling a heating element, characterized in that when the heat excessively affects the dots printed by the heating element, the amount of energy for heating is set to be small. 13. The heating element control method according to claim 8, wherein the heating element is set as a reference in a plurality of heating elements to be printed in duplicate, or is used in a plurality of heating elements to be printed in duplicate. A method for controlling a heating element, characterized in that the heating element is controlled based on the setting of the heating element. 14. The heat generating element according to claim 13, wherein the heat generating element is set or a heat generating element that is not used among the plurality of heat generating elements to be printed in duplicate is set by an external terminal or an operation panel. Control method.