JP2019202444A - Thermal print head - Google Patents

Abstract

To provide a thermal print head that can improve radiation performance.SOLUTION: The thermal print head comprises a substrate 10 having a main surface 11 pointing to a Z-direction, a glaze layer 30 laminated on the main surface 11, an electrode 40 arranged on the glaze layer 30, and a resistance body 50, arranged in a main scanning direction, which includes a plurality of heat generating parts conducted to the electrode 40, which further comprises an intermediate layer 20, interposed between the main surface 11 and the glaze layer 30, whose thermal conductivity is larger than thermal conductivity of the glaze layer 30, where the plurality of heat generating parts overlap with the intermediate layer 20 when viewed from the z-direction.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a thermal print head.

  The thermal print head is a main component of a thermal printer that prints on a recording medium such as thermal paper. Patent Document 1 discloses an example of a conventional thermal print head. The thermal print head disclosed in this document includes an insulating substrate, a glaze layer that covers the insulating substrate, an electrode disposed on the glaze layer, and is electrically connected to the electrode and arranged in the main scanning direction. A plurality of heat generating parts (which constitute a heat generating resistor). When the plurality of heat generating portions selectively generate heat by energization through the electrodes, dot printing is performed on the recording medium.

  In recent years, a thermal print head capable of high-speed printing has been demanded. In order to enable high-speed printing, it is necessary to more quickly lower the temperatures of the plurality of heat generating portions whose temperatures have been increased by energization. Further, if the temperature rise continues in the plurality of heat generating portions, bleeding or the like occurs, and the print quality deteriorates. In order to lower the temperature of the plurality of heat generating portions more quickly, it is necessary to efficiently release the heat generated from the plurality of heat generating portions to the outside.

Japanese Patent Laid-Open No. 10-16268

  In view of the circumstances described above, an object of the present invention is to provide a thermal print head capable of improving heat dissipation.

  According to the present invention, a substrate having a main surface facing the thickness direction, a glaze layer laminated on the main surface, an electrode disposed on the glaze layer, arranged in a main scanning direction, and the A resistor including a plurality of heat generating portions that are electrically connected to the electrode, and is interposed between the main surface and the glaze layer, and has a thermal conductivity larger than that of the glaze layer There is further provided a thermal print head characterized in that a plurality of heat generating portions overlap the intermediate layer when viewed from the thickness direction.

  In the practice of the present invention, preferably, the intermediate layer is in contact with the main surface.

  Preferably, in the embodiment of the present invention, the glaze layer has a covering portion that is in contact with the intermediate layer, and a general portion that is in contact with the main surface and is connected to both ends of the covering portion in the sub-scanning direction. The part has a ridge protruding from the surface of the general part in the thickness direction and extending in the main scanning direction.

  In implementation of this invention, Preferably, the said several heat_generation | fever part is in contact with the said protrusion.

  In the implementation of the present invention, preferably, the thickness of the covering portion from the position where the plurality of heat generating portions are in contact to the surface of the intermediate layer at the center of the protrusion in the sub-scanning direction is the thickness of the general portion. Smaller than that.

  In the implementation of the present invention, it is preferable to further include a protective layer that is in contact with the glaze layer and covers a part of the electrode and the resistor.

  In an embodiment of the present invention, preferably, the intermediate layer includes a pair of first intermediate portions spaced apart from each other in the sub-scanning direction, and a second intermediate portion that fills a gap between the pair of first intermediate portions. The second intermediate portion is concave toward the main surface.

  In the implementation of the present invention, preferably, the protrusion includes a pair of convex portions adjacent in the sub-scanning direction.

  In the implementation of the present invention, preferably, the plurality of heat generating portions are in contact with both of the pair of convex portions.

  Preferably, in the embodiment of the present invention, the glaze layer includes a first layer that covers the main surface and the intermediate layer, and a second layer that covers the first layer, and the protrusions include the second layer. Is formed.

  In the practice of the present invention, preferably, the general portion is in contact with the entire portion of the main surface that is not in contact with the intermediate layer.

  In the practice of the present invention, the intermediate layer preferably contains silver.

  Preferably, the present invention includes a common electrode and a plurality of individual electrodes, the common electrode being separated from the resistor in the sub-scanning direction and extending in the main scanning direction, and the connecting portion A plurality of first strips extending from the resistor to the resistor, and each of the plurality of individual electrodes has the resistance from the opposite side of the resistor to the resistor in the sub-scanning direction. A second belt-like portion extending toward the body, and the second belt-like portion is positioned between the two first belt-like portions adjacent to each other in the main scanning direction.

  In the implementation of the present invention, preferably, the resistor crosses both the plurality of first belt portions and the plurality of second belt portions.

  In the implementation of the present invention, preferably, the plurality of first belt portions and the plurality of second belt portions have a section sandwiched between the glaze layer and the resistor.

  In the embodiment of the present invention, preferably, the common electrode further includes a thin metal layer disposed on the connecting portion and extending in the main scanning direction.

  In the embodiment of the present invention, it is preferable to further include a driving IC mounted on the general part and conducting to the plurality of individual electrodes.

  The thermal print head according to the present invention can improve heat dissipation.

  Other features and advantages of the present invention will become more apparent from the detailed description given below with reference to the accompanying drawings.

It is a top view of the thermal print head concerning a 1st embodiment of the present invention. FIG. 2 is a bottom view of the thermal print head shown in FIG. 1. It is sectional drawing which follows the III-III line of FIG. FIG. 2 is a partially enlarged plan view of the thermal print head shown in FIG. 1 (through a protective layer). FIG. 5 is a partially enlarged view of FIG. 4 (through a protective layer). It is sectional drawing which follows the VI-VI line of FIG. It is sectional drawing which follows the VII-VII line of FIG. It is sectional drawing which follows the VIII-VIII line of FIG. It is sectional drawing explaining the manufacturing method of the thermal print head shown in FIG. It is sectional drawing explaining the manufacturing method of the thermal print head shown in FIG. It is sectional drawing explaining the manufacturing method of the thermal print head shown in FIG. It is sectional drawing explaining the manufacturing method of the thermal print head shown in FIG. It is sectional drawing explaining the manufacturing method of the thermal print head shown in FIG. It is sectional drawing explaining the manufacturing method of the thermal print head shown in FIG. It is sectional drawing explaining the manufacturing method of the thermal print head shown in FIG. FIG. 6 is a partially enlarged plan view (through a protective layer) of a thermal print head according to a second embodiment of the present invention. It is sectional drawing which follows the XVII-XVII line of FIG. It is sectional drawing which follows the XVIII-XVIII line of FIG. It is sectional drawing which follows the XIX-XIX line | wire of FIG. It is sectional drawing explaining the manufacturing method of the thermal print head shown in FIG. It is sectional drawing explaining the manufacturing method of the thermal print head shown in FIG. It is sectional drawing explaining the manufacturing method of the thermal print head shown in FIG. It is sectional drawing of the thermal print head concerning the modification of 2nd Embodiment of this invention.

  A mode for carrying out the present invention (hereinafter referred to as “embodiment”) will be described with reference to the accompanying drawings.

[First Embodiment]
A thermal print head A10 according to the first embodiment of the present invention will be described with reference to FIGS. The thermal print head A10 includes a substrate 10, a glaze layer 30, an electrode 40, and a resistor 50. In addition to these, the thermal print head A10 further includes an intermediate layer 20, a protective layer 60, a drive IC 71, a sealing resin 72, a connector 73, and a heat sink 74. Of these figures, FIGS. 4 and 5 are transmitted through the protective layer 60 for the sake of convenience. The hatched region by a plurality of points shown in FIG.

  The thermal print head A10 shown in these drawings selectively heats a plurality of heat generating portions 51 (details will be described later) included in the resistor 50, so that a recording medium 81 such as thermal paper as shown in FIG. Is an electronic device that prints on Since the structure of the thermal print head A10 is a flat type, the recording medium 81 used for printing is limited to a roll wound paper or the like in advance. The thermal print head A10 is a so-called thick film type in which the resistor 50 is formed by printing and baking.

  Here, for convenience of explanation, the main scanning direction of the thermal print head A10 is referred to as “x direction”, and the sub-scanning direction of the thermal print head A10 is referred to as “y direction”. The thickness direction of the substrate 10 is referred to as the “z direction”. The z direction is orthogonal to both the x and y directions. In the following description, “viewed from the z direction” refers to a plan view. “One side in the y direction” refers to the side where the first connecting portion 412 (details will be described later) of the common electrode 41 (electrode 40) is located with respect to the resistor 50. “The other side in the y direction” refers to the side where the driving IC 71 is located with respect to the resistor 50.

As shown in FIGS. 1 and 2, the substrate 10 has a strip shape extending in the x direction. The substrate 10 is a ceramic mainly composed of alumina (Al ₂ O ₃ ), for example. The constituent material of the substrate 10 is alumina, a synthetic resin binder, or the like. In addition to these, the constituent material of the substrate 10 may include a light shielding material. The light shielding material is, for example, carbon (C). As shown in FIG. 3, the substrate 10 has a main surface 11 and a back surface 12 that face opposite sides in the z direction.

  As shown in FIGS. 6 to 8, the intermediate layer 20 is interposed between the main surface 11 of the substrate 10 and the glaze layer 30. The intermediate layer 20 has a strip shape extending in the x direction. The intermediate layer 20 is in contact with the main surface 11. The surface 20A of the intermediate layer 20 (excluding the part in contact with the main surface 11) is covered with the glaze layer 30 throughout. The thermal conductivity of the intermediate layer 20 is greater than the thermal conductivity of the glaze layer 30. The constituent material of the intermediate layer 20 is a metal paste in which glass frit is contained in metal particles. As the metal particles, silver (Ag), mixed particles of silver and palladium (Pd), ruthenium (Ru), or the like can be used.

The glaze layer 30 is laminated | stacked on the main surface 11 of the board | substrate 10, as shown in FIGS. The glaze layer 30 has a multilayer structure including a first layer 301 that covers the main surface 11 and the intermediate layer 20, and a second layer 302 that covers the first layer 301. The constituent material of the glaze layer 30 is amorphous glass for both the first layer 301 and the second layer 302. Thereby, the glaze layer 30 exhibits transparency or white. The amorphous glass is, for example, SiO ₂ —BaO—Al ₂ O ₃ —SnO—ZnO-based glass.

  As shown in FIGS. 5 to 8, the glaze layer 30 has a covering portion 31 and a general portion 32. The covering portion 31 is in contact with the surface 20 </ b> A of the intermediate layer 20. The general portion 32 is in contact with the main surface 11 and connected to both ends of the covering portion 31 in the y direction. Thereby, the general part 32 is divided | segmented into two area | regions by the coating | coated part 31 in the y direction. The general portion 32 is in contact with the entire portion of the main surface 11 that is not in contact with the intermediate layer 20. The general portion 32 has a surface 30 </ b> A that faces the main surface 11 of the substrate 10 in the z direction. The surface 30A is smooth.

  As shown in FIGS. 6 and 7, the covering portion 31 has a protrusion 33. The protrusion 33 protrudes from the surface 30A of the general portion 32 in the z direction. As shown in FIG. 5, the protrusion 33 extends in the x direction. As shown in FIG. 8, the plurality of heating portions 51 of the resistor 50 are in contact with the protrusion 33. The thickness t1 of the covering portion 31 from the position B where the plurality of heat generating portions 51 are in contact with the surface 20A of the intermediate layer 20 at the center in the y direction of the ridge 33 is smaller than the thickness t2 of the general portion 32.

  As shown in FIGS. 6 and 7, the electrode 40 is disposed on the surface 30 </ b> A and the protrusion 33 that are on the glaze layer 30. The electrode 40 constitutes a conductive path for energizing the resistor 50. The electrode 40 includes a common electrode 41 and a plurality of individual electrodes 42. In the thermal print head A <b> 10, current flows from the plurality of individual electrodes 42 toward the common electrode 41 via the resistor 50. For this reason, the common electrode 41 is a negative electrode, and the plurality of individual electrodes 42 are positive electrodes. An example of the constituent material of the electrode 40 is a resinate paste containing gold as a main component. The thickness of the electrode 40 is 0.6 μm or more and 1.2 μm or less.

  As shown in FIGS. 4 and 5, the common electrode 41 has a first connecting portion 412 and a plurality of first strip portions 411. The first connecting portion 412 has a strip shape that is separated from the resistor 50 in the y direction and extends in the x direction. The 1st connection part 412 is corresponded to the "connection part" as described in the claim concerning this invention. The first connecting portion 412 is disposed on one side of the substrate 10 in the y direction. The first connecting portion 412 corresponds to the downstream end of the current flowing through the electrode 40.

  As shown in FIGS. 4 and 5, the plurality of first belt-like portions 411 have a belt-like shape extending toward the resistor 50. The plurality of first strip portions 411 are arranged at equal intervals in the x direction. Each of the plurality of first strip portions 411 includes a base portion 411A and an extension portion 411B. The base portion 411A has a rectangular shape and is connected to the first connecting portion 412 on one side in the y direction. The extending portion 411B extends from the base portion 411A toward the resistor 50. The width (dimension in the x direction) of the extending portion 411B is smaller than the width (dimension in the x direction) of the base portion 411A. The width of the extending portion 411B is 25 μm or less. The base portion 411A is sandwiched between the first connecting portion 412 and the extending portion 411B in the y direction.

  As shown in FIGS. 5 to 7, the thin metal layer 401 is disposed on the first connecting portion 412. The thin metal layer 401 extends in the x direction. The constituent material of the metal thin layer 401 is a conductive paste in which glass frit is contained in silver particles. The electrical resistivity of the thin metal layer 401 is lower than the electrical resistivity of the electrode 40.

  As shown in FIGS. 4 and 5, the plurality of individual electrodes 42 extend from the other side in the y direction toward the resistor 50. The plurality of individual electrodes 42 are arranged in a bundle corresponding to each driving IC 71 on the glaze layer 30. The plurality of individual electrodes 42 apply a voltage to the individually selected portions of the resistor 50. The plurality of individual electrodes 42 are arranged in the x direction. Each of the plurality of individual electrodes 42 includes a second strip portion 421, a second connection portion 422, and a connection portion 423.

  As shown in FIGS. 4 and 5, the second band-shaped portion 421 extends from the opposite side of the first connecting portion 412 to the resistor 50 in the y direction (the other side in the y direction) toward the resistor 50. It is strip-shaped. The second strip portion 421 is located between two first strip portions 411 adjacent in the x direction. The 2nd strip | belt-shaped part 421 has the base part 421A and the extension part 421B. The base portion 421A has a rectangular shape and is connected to the second connecting portion 422 on the other side in the y direction. The extending part 421B extends from the base part 421A toward the resistor 50. The width (dimension in the x direction) of the extending portion 421B is smaller than the width (dimension in the x direction) of the base portion 421A. The width of the extending part 421B is 25 μm or less. The base portion 421A is sandwiched between the second connecting portion 422 and the extending portion 421B in the y direction.

  As shown in FIGS. 4 and 5, the second connecting portion 422 has a strip shape extending from the second strip portion 421 to the other side in the y direction. The second connecting part 422 connects the second belt-like part 421 and the connecting part 423. The second connecting part 422 has a parallel part 422A and a skew part 422B. The parallel portion 422A is connected to the connection portion 423 on the other side in the y direction and is along the y direction. The width (dimension in the x direction) of the parallel portion 422A is set to 20 μm or less. The skew portion 422B is inclined with respect to the y direction. The skew portion 422B is connected to the base portion 421A of the second belt-shaped portion 421 on one side in the y direction and connected to the parallel portion 422A on the other side in the y direction. Further, as shown in FIG. 4, in the plurality of individual electrodes 42 arranged in a bundle corresponding to each drive IC 71, the boundary position between the parallel portion 422A and the skew portion 422B is compared at both ends in the x direction. Then, a deviation ΔL in the y direction occurs.

  As shown in FIG. 4, the connection portion 423 is located on the opposite side in the y direction with respect to the second coupling portion 422. The connecting portion 423 is connected to the parallel portion 422A of the second connecting portion 422. The connection unit 423 includes a first connection unit 423A and a second connection unit 423B. The second connection portion 423B is located on the other side in the y direction with respect to the first connection portion 423A. Thereby, the plurality of first connection portions 423A and the plurality of second connection portions 423B are staggered in the x direction. The width (dimension in the x direction) of the parallel part 422A connected to the second connection part 423B and located between the two adjacent first connection parts 423A is 10 μm or less. A plurality of wires 49 are connected to the plurality of connection portions 423. The constituent material of the plurality of wires 49 is, for example, gold.

As shown in FIGS. 1 and 4, the resistor 50 has a strip shape extending in the x direction. The resistor 50 is in contact with the protrusion 33 of the glaze layer 30 (second layer 302). The resistor 50 intersects both the plurality of first strip portions 411 and the plurality of second strip portions 421 (both electrodes 40). As shown in FIG. 5, the plurality of first strip portions 411 and the plurality of second strip portions 421 have a section sandwiched between the protrusion 33 and the resistor 50. For this reason, the resistor 50 covers a part of each of the plurality of first strip portions 411 and the plurality of second strip portions 421. Of the resistor 50, a region sandwiched between a portion covering the first belt-like portion 411 and a portion located next to the first belt-like portion 411 and covering the second connecting portion 422 is defined as the heat generating portion 51. ing. Thus, the resistor 50 has a configuration including a plurality of heat generating portions 51 arranged in the x direction and conducting to the electrode 40. The plurality of heat generating portions 51 selectively generate heat by being selectively energized by the electrode 40. Thereby, dot printing is performed on the recording medium 81 shown in FIG. As the constituent material of the resistor 50, a material having an electrical resistivity larger than that of the electrode 40 is selected. The constituent material of the resistor 50 is, for example, a conductive paste in which glass frit is contained in ruthenium oxide (RuO ₂ ) particles. The maximum thickness of the resistor 50 is 6 μm or more and 10 μm or less.

  As shown in FIG. 5, the plurality of heat generating portions 51 overlap the intermediate layer 20 when viewed from the z direction. Further, as shown in FIG. 8, the plurality of heat generating portions 51 are in contact with the protrusions 33.

  As shown in FIGS. 6 to 8, the protective layer 60 is in contact with the surface 30 </ b> A of the glaze layer 30 and the protrusions 33. The protective layer 60 covers a part of the electrode 40 and the resistor 50. A part of the plurality of individual electrodes 42 including the plurality of connection portions 423 is not covered with the protective layer 60. The constituent material of the protective layer 60 is amorphous glass like the glaze layer 30. The protective layer 60 has a surface 60 </ b> A and a protrusion 61. The front surface 60A faces the side to which the main surface 11 of the substrate 10 faces in the z direction. The protruding portion 61 protrudes from the surface 60A in the z direction. The protruding portion 61 is in contact with the protrusion 33 and covers the resistor 50. For this reason, the protrusion 61 extends in the x direction. The protruding portion 61 has a height h1 that is a dimension in the z direction from the surface 60A to the vertex C of the protruding portion 61.

  As shown in FIGS. 1 and 3, the drive IC 71 is located on the other side in the y direction with respect to the resistor 50. The drive IC 71 is mounted on the general portion 32 (surface 30 </ b> A) of the glaze layer 30. A plurality of pads (not shown) are provided on the upper surface of the drive IC 71. A plurality of wires 49 connected to the connection portions 423 of the plurality of individual electrodes 42 corresponding to the driving IC 71 are connected to some of the plurality of pads. Thereby, the drive IC 71 is electrically connected to the plurality of individual electrodes 42 corresponding thereto. In addition, a plurality of wires 49 connected to wirings arranged on the main surface 11 of the substrate 10 are connected to the other plurality of pads. The drive IC 71 selectively energizes the plurality of individual electrodes 42 via the plurality of wires 49. As a result, the plurality of heat generating portions 51 included in the resistor 50 selectively generate heat. In addition to the example shown by the thermal print head A10, the drive IC 71 may be mounted on a wiring board that is separated from the board 10 in the y direction and supported by the heat sink 74. In the wiring board, for example, a wiring made of a metal such as copper is arranged on a base material made of glass epoxy resin.

  As shown in FIG. 3, the sealing resin 72 covers the drive IC 71 and the plurality of wires 49. In addition to these, the sealing resin 72 further covers some regions (such as the plurality of connection portions 423) of the plurality of individual electrodes 42 that are not covered by the protective layer 60. The constituent material of the sealing resin 72 is, for example, a black and soft synthetic resin used for underfill.

  As shown in FIGS. 1 to 3, the connector 73 is disposed at the end of the substrate 10 located on the other side in the y direction with respect to the drive IC 71. The connector 73 is used to connect the thermal print head A10 to the thermal printer. The connector 73 is connected to wiring disposed on the main surface 11 of the substrate 10. Accordingly, the connector 73 is electrically connected to the plurality of individual electrodes 42 via the wiring, the drive IC 71 and the plurality of wires 49. The connector 73 is electrically connected to the first connecting portion 412 of the common electrode 41 through the wiring.

  As shown in FIGS. 2 and 3, the heat sink 74 is bonded to the back surface 12 of the substrate 10 via a bonding material (not shown). The bonding material is, for example, a double-sided tape having a relatively high thermal conductivity. The constituent material of the heat sink 74 is, for example, aluminum (Al).

  Next, the operation of the thermal print head A10 will be described.

  As shown in FIG. 3, the plurality of heat generating portions 51 of the thermal print head A <b> 10 are opposed to the platen roller 82 incorporated in the thermal printer via the protective layer 60. A recording medium 81 is sandwiched between the region of the protective layer 60 that covers the plurality of heat generating portions 51 and the platen roller 82. During operation of the thermal printer, the platen roller 82 rotates to feed the recording medium 81 at a constant speed. At this time, when the plurality of heat generating portions 51 selectively generate heat, the heat is transmitted to the recording medium 81 through the protective layer 60, whereby printing is performed on the recording medium 81. At the same time, the heat generated from the plurality of heat generating portions 51 is also transmitted to the glaze layer 30. A part of the heat is stored in the glaze layer 30. The remainder of the heat is released to the outside of the thermal print head A10 through the substrate 10 and the heat sink 74.

  Next, an example of a method for manufacturing the thermal print head A10 will be described with reference to FIGS.

  First, as shown in FIG. 9, a substrate 10 is prepared. The substrate 10 is a ceramic mainly composed of alumina.

  Next, as shown in FIG. 10, an intermediate layer 20 in contact with the substrate 10 is formed. In forming the intermediate layer 20, first, a metal paste in which glass frit is contained in metal particles such as silver is thick-film printed in a strip shape extending in the x direction so as to have a predetermined width (dimension in the y direction). Then, the intermediate layer 20 is formed by baking this.

  Next, as shown in FIGS. 11 and 12, a glaze layer 30 is formed to be laminated on the main surface 11 of the substrate 10. In forming the glaze layer 30, as shown in FIG. 11, after forming the first layer 301 covering the main surface 11 and the intermediate layer 20, the second layer 302 covering the first layer 301 as shown in FIG. Form. The first layer 301 and the second layer 302 are formed by printing a thick film of an amorphous glass paste and then firing it. As shown in FIG. 12, when the second layer 302 is formed, the covering portion 31 of the second layer 302 protrudes from the surface 30A of the general portion 32 of the second layer 302 in the z direction and in the x direction. An extending ridge 33 is formed.

  Next, as shown in FIG. 13, the electrode 40 disposed on the glaze layer 30 (the surface 30 </ b> A and the protrusion 33) is formed. In forming the electrode 40, first, a resinate paste containing gold as a main component is printed on a thick film, and then the conductor layer is formed by firing the paste. Then, the electrode 40 is formed by performing patterning by etching on the conductor layer. After the electrode 40 is formed, a thin metal layer 401 is formed that is stacked on a part of the region of the electrode 40 (the first connecting portion 412 of the common electrode 41). The thin metal layer 401 is formed by printing a conductive paste containing silver frit in a glass frit and then baking the conductive paste.

  Next, as shown in FIG. 14, a resistor 50 that is electrically connected to the electrode 40 is formed. In forming the resistor 50, first, a conductive paste having a relatively high electrical resistivity in which glass frit is contained in ruthenium oxide particles is overlapped with the intermediate layer 20 as viewed from the z direction and is in contact with the electrode 40. Then, thick film printing is performed on the protrusion 33 of the glaze layer 30 in a strip shape extending in the x direction. Then, this is baked. Finally, the resistor 50 is formed by appropriately performing trimming for adjusting the resistance value of the fired product.

  Next, as shown in FIG. 15, a protective layer 60 that is in contact with the surface 30 </ b> A of the glaze layer 30 and the protrusions 33 and covers a part of the electrode 40 and the resistor 50 is formed. The protective layer 60 is formed by baking an amorphous glass paste after thick printing.

  After forming the protective layer 60, the drive IC 71 is mounted on the surface 30A of the glaze layer 30 (general portion 32) by die bonding. Next, a plurality of wires 49 are formed by wire bonding, and then a sealing resin 72 is formed. Next, the substrate 10 is cut along the y direction. Finally, the thermal print head A10 is obtained by attaching the connector 73 and the heat sink 74 to the substrate 10.

  Next, the function and effect of the thermal print head A10 will be described.

  The thermal print head A <b> 10 includes an intermediate layer 20 that is interposed between the main surface 11 of the substrate 10 and the glaze layer 30 and has a thermal conductivity larger than that of the glaze layer 30. As viewed from the z direction, the plurality of heating portions 51 of the resistor 50 overlap the intermediate layer 20. As a result, when the thermal print head A10 is used, heat generated from the plurality of heat generating portions 51 and transmitted to the glaze layer 30 is easily transmitted to the substrate 10 via the intermediate layer 20. Therefore, according to the thermal print head A10, it is possible to improve heat dissipation.

  The intermediate layer 20 is in contact with the main surface 11 of the substrate 10. Thereby, the heat generated from the plurality of heat generating portions 51 is more easily transmitted to the substrate 10 via the intermediate layer 20.

  By improving the heat dissipation of the thermal print head A10, the printing quality on the recording medium 81 and the durability of the resistor 50 can be improved. Further, the uneven temperature distribution of the plurality of heat generating portions 51 is suppressed, and the color development of the recording medium 81 becomes more uniform.

  The glaze layer 30 includes a covering portion 31 in contact with the intermediate layer 20 and general portions 32 connected to both ends of the covering portion 31 in the y direction. The covering portion 31 has a protrusion 33 that protrudes in the z direction from the surface 30A of the general portion 32 and extends in the x direction. The plurality of heat generating portions 51 are in contact with the ridge 33. As a result, a protruding portion 61 that protrudes in the z direction from the surface 60A is formed on the protective layer 60 that covers the protrusion 33 and the plurality of heat generating portions 51. Therefore, when the thermal print head A10 is used, the contact area of the recording medium 81 with respect to the protective layer 60 is suppressed by the recording medium 81 coming into contact with the protruding portion 61, so that the print quality applied to the recording medium 81 is good. It will be something.

  The thickness of the covering portion 31 from the position B where the plurality of heat generating portions 51 contact to the surface 20A of the intermediate layer 20 at the center in the y direction of the ridge 33 is smaller than the thickness of the general portion 32. Thereby, the heat generated from the plurality of heat generating portions 51 can be transmitted to the intermediate layer 20 more quickly via the covering portion 31.

  The general portion 32 is in contact with the entire portion of the main surface 11 of the substrate 10 that is not in contact with the intermediate layer 20. Thereby, it can avoid that the thermal storage property which the glaze layer 30 has falls extremely. Further, the drive IC 71 can be mounted on the general part 32 without providing a protective medium different from the glaze layer 30 on the main surface 11.

  The common electrode 41 of the electrode 40 is disposed on the first connecting portion 412 and has a thin metal layer 401 extending in the x direction. Thereby, a part of the current flowing through the first connecting portion 412 flows through the thin metal layer 401, so that the current can flow through the common electrode 41 more quickly. Therefore, it can be avoided that excessive heat is continuously generated from the plurality of heat generating portions 51.

[Second Embodiment]
A thermal print head A20 according to the second embodiment of the present invention will be described with reference to FIGS. In these drawings, elements that are the same as or similar to those of the thermal print head A10 described above are denoted by the same reference numerals, and redundant description is omitted. Of these drawings, FIG. 16 is transmitted through the protective layer 60 for convenience of understanding. The hatched region with a plurality of points shown in FIG. 16 indicates the intermediate layer 20.

  In the thermal print head A20, the configurations of the intermediate layer 20, the glaze layer 30, the resistor 50, and the protective layer 60 are different from those of the above-described thermal print head A10.

  As shown in FIGS. 17 to 19, the intermediate layer 20 includes a pair of first intermediate portions 21 and a second intermediate portion 22. The pair of first intermediate portions 21 are separated from each other in the y direction. The dimension in the y direction of the first intermediate portion 21 is not less than 0.5 mm and not more than 1.5 mm. The second intermediate portion 22 fills the gap Gp between the pair of first intermediate portions 21. The dimension in the y direction of the gap Gp is not less than 0.2 mm and not more than 0.4 mm. The maximum dimension in the y direction of the second intermediate portion 22 is not less than 0.4 mm and not more than 0.6 mm. The second intermediate portion 22 is concave toward the main surface 11 of the substrate 10.

  As illustrated in FIG. 19, each of the pair of first intermediate portions 21 has a vertex D1. The second intermediate portion 22 has a pair of vertices D2 and a bottom point D3. The maximum dimension in the z direction of the pair of first intermediate portions 21 extending from the main surface 11 of the substrate 10 to the vertex D1 is defined as a thickness z1. A dimension in the z direction of the second intermediate portion 22 extending from the main surface 11 to the vertex D2 is a thickness z2. A dimension in the z direction of the second intermediate portion 22 from the main surface 11 to the bottom point D3 is defined as a thickness z3. The magnitude relationship between the thicknesses z1, z2, and z3 is thickness z1> thickness z2> thickness z3.

  As shown in FIGS. 16 to 19, the protrusion 33 of the glaze layer 30 (second layer 302) includes a pair of convex portions 331. The pair of convex portions 331 are adjacent to each other in the y direction. In the thermal print head A20, the pair of convex portions 331 are adjacent to each other in the y direction, but the pair of convex portions 331 may be separated from each other in the y direction. The pair of convex portions 331 extends in the x direction. As viewed from the z direction, the boundary in the y direction of the pair of convex portions 331 overlaps the second intermediate portion 22 of the intermediate layer 20.

  As shown in FIG. 20, the plurality of heat generating portions 51 of the resistor 50 are in contact with both the pair of convex portions 331. In the thermal print head A20 as well, the thickness t1 of the covering portion 31 from the position B where the plurality of heat generating portions 51 are in contact with the surface 20A (bottom point D3) of the intermediate layer 20 at the center in the y direction of the ridge 33 is The thickness of the general portion 32 is smaller than t2.

  As shown in FIG. 20, the protruding portion 61 of the protective layer 60 has a height h <b> 2 that is a dimension in the z direction from the surface 60 </ b> A to the vertex C of the protruding portion 61. The height h2 is smaller than the height h1 of the protrusion 61 of the thermal print head A10 shown in FIG.

  Next, based on FIGS. 20-22, an example of the manufacturing method of thermal print head A20 is demonstrated.

  After preparing the substrate 10 (see FIG. 9), a pair of first intermediate portions 21 are formed in the intermediate layer 20 as shown in FIG. In forming the pair of first intermediate portions 21, first, a metal paste in which glass frit is contained in metal particles such as silver is thickened in a strip shape extending in the x direction so as to have a predetermined width (dimension in the y direction). Print. At this time, a gap Gp having a predetermined length is provided between the pair of first intermediate portions 21. Then, a pair of 1st intermediate parts 21 are formed by baking this.

  Next, as shown in FIG. 21, the second intermediate portion 22 is formed in the intermediate layer 20. In forming the second intermediate portion 22, the metal paste used for forming the pair of first intermediate portions 21 is printed in a thick film in a strip shape extending in the x direction so as to fill the gap Gp. Then, the 2nd intermediate part 22 is formed by baking this. The formed second intermediate portion 22 is concave toward the main surface 11 of the substrate 10.

  Next, as shown in FIG. 22, a glaze layer 30 that is laminated on the main surface 11 of the substrate 10 is formed. In forming the glaze layer 30, the first layer 301 that covers the main surface 11 and the intermediate layer 20 is formed, and then the second layer 302 that covers the first layer 301 is formed. The first layer 301 and the second layer 302 are formed by printing a thick film of an amorphous glass paste and then firing it. When the second layer 302 is formed, the covering portion 31 of the second layer 302 is formed with a protrusion 33 that protrudes from the surface 30A of the general portion 32 of the second layer 302 in the z direction and extends in the x direction. The The protrusion 33 includes a pair of convex portions 331 adjacent in the y direction.

<Modification of Second Embodiment>
A thermal print head A21 according to a modification of the thermal print head A20 will be described with reference to FIG. 23 is the same as the cross-sectional position in FIG.

  In the thermal print head A21 shown in FIG. 23, the shapes of the intermediate layer 20 and the glaze layer 30 are closer to the actual product. In the thermal print head A21, the above-described magnitude relationship between the thicknesses z1, z2, and z3 is thickness z2> thickness z1> thickness z3. For this reason, the pair of vertices D2 of the second intermediate portion 22 is located farther in the z direction from the main surface 11 of the substrate 10 than the vertices D1 of the pair of first intermediate portions 21.

  Next, the function and effect of the thermal print head A20 will be described.

  The thermal print head A <b> 20 includes an intermediate layer 20 that is interposed between the main surface 11 of the substrate 10 and the glaze layer 30 and has a thermal conductivity higher than that of the glaze layer 30. As viewed from the z direction, the plurality of heating portions 51 of the resistor 50 overlap the intermediate layer 20. Therefore, the thermal print head A20 can also improve heat dissipation.

  The intermediate layer 20 includes a pair of first intermediate portions 21 that are separated from each other in the y direction, and a second intermediate portion 22 that fills the gap Gp between the pair of first intermediate portions 21. The second intermediate portion 22 is concave toward the main surface 11 of the substrate 10. Thereby, the protrusion 33 formed in the coating | coated part 31 of the glaze layer 30 becomes a structure containing a pair of convex part 331 adjacent in ay direction.

  When the protrusion 33 includes a pair of protrusions 33, the height h2 of the protrusion 61 formed on the protective layer 60 that covers the protrusion 33 and the plurality of heat generating portions 51 is the protrusion of the thermal print head A10. It becomes smaller than the height h1 of the part 61. As a result, when the thermal print head A20 is used, the recording medium 81 comes into contact with the protruding portion 61, so that the print quality applied to the recording medium 81 is improved as described above. Further, since the height h2 of the protruding portion 61 is smaller than the height h1 of the protruding portion 61 of the thermal print head A10, it is possible to suppress the paper dust of the recording medium 81 from adhering to the base of the protruding portion 61. Therefore, the reliability of the thermal print head A20 can be improved as compared with the thermal print head A10.

  The present invention is not limited to the embodiment described above. The specific configuration of each part of the present invention can be changed in various ways.

A10, A20, A21: Thermal print head 10: Substrate 11: Main surface 12: Back surface 20: Intermediate layer 20A: Front surface 21: First intermediate portion 22: Second intermediate portion 30: Glaze layer 30A: Front surface 301: First layer 302: 2nd layer 31: Covering part 32: General part 33: Projection 331: Convex part 40: Electrode 401: Metal thin layer 41: Common electrode 411: First strip 411A: Base part 411B: Extension part 412: No. 1 connection part 42: individual electrode 421: second band-like part 421A: base part 421B: extension part 422: second connection part 422A: parallel part 422B: skew part 423A: connection part 423A: first connection part 423B: second Connection part 49: Wire 50: Resistor 51: Heat generating part 60: Protective layer 60A: Surface 61: Protruding part 71: Drive IC
72: Sealing resin 73: Connector 74: Radiator 81: Recording medium 82: Platen roller t1, t2: Thickness h1, h2: Height z1, z2, z3: Thickness ΔL: Deviation Gp: Gap B: Position C : Vertex D1, D2: Vertex D3: Bottom point

Claims (17)

A substrate having a main surface facing the thickness direction;
A glaze layer laminated on the main surface;
An electrode disposed on the glaze layer;
Comprising a plurality of heating elements arranged in the main scanning direction and conducting to the electrodes,
Further comprising an intermediate layer interposed between the main surface and the glaze layer and having a thermal conductivity larger than that of the glaze layer;
A thermal print head, wherein a plurality of heat generating portions overlap with the intermediate layer when viewed from the thickness direction.   The thermal print head according to claim 1, wherein the intermediate layer is in contact with the main surface. The glaze layer has a covering portion in contact with the intermediate layer, and a general portion in contact with the main surface and connected to both ends of the covering portion in the sub-scanning direction,
The thermal print head according to claim 2, wherein the covering portion has a protrusion that protrudes in the thickness direction from the surface of the general portion and extends in the main scanning direction.   The thermal print head according to claim 3, wherein the plurality of heat generating portions are in contact with the protrusions.   The thickness of the covering portion from the position where a plurality of the heat generating portions are in contact to the surface of the intermediate layer at the center of the protrusion in the sub-scanning direction is smaller than the thickness of the general portion. 4. The thermal print head according to 4.   The thermal print head according to claim 5, further comprising a protective layer in contact with the glaze layer and covering a part of the electrode and the resistor. The intermediate layer has a pair of first intermediate portions spaced apart from each other in the sub-scanning direction, and a second intermediate portion that fills a gap between the pair of first intermediate portions,
The thermal print head according to claim 6, wherein the second intermediate portion is concave toward the main surface.   The thermal print head according to claim 7, wherein the protrusion includes a pair of protrusions adjacent in the sub-scanning direction.   The thermal print head according to claim 8, wherein the plurality of heat generating portions are in contact with both of the pair of convex portions. The glaze layer includes a first layer covering the main surface and the intermediate layer, and a second layer covering the first layer,
The thermal print head according to claim 5, wherein the protrusion is formed in the second layer.   The thermal print head according to claim 10, wherein the general portion is in contact with an entire portion of the main surface that is not in contact with the intermediate layer.   The thermal print head according to claim 11, wherein the intermediate layer includes silver. The electrode includes a common electrode and a plurality of individual electrodes,
The common electrode includes a connecting portion that is separated from the resistor in the sub-scanning direction and extends in the main scanning direction, and a plurality of first belt-like portions that extend from the connecting portion toward the resistor. And
Each of the plurality of individual electrodes has a second belt-shaped portion extending from the opposite side of the connecting portion to the resistor in the sub-scanning direction toward the resistor.
13. The thermal print head according to claim 11, wherein the second belt-like portion is located between two first belt-like portions adjacent to each other in the main scanning direction.   14. The thermal print head according to claim 13, wherein the resistor crosses both the plurality of first belt portions and the plurality of second belt portions.   The thermal print head according to claim 14, wherein the plurality of first belt portions and the plurality of second belt portions have a section sandwiched between the glaze layer and the resistor.   The thermal print head according to claim 15, wherein the common electrode further includes a thin metal layer disposed on the connecting portion and extending in the main scanning direction.   The thermal print head according to claim 16, further comprising a drive IC mounted on the general part and conducting to the plurality of individual electrodes.

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