A thermal print head includes a semiconductor substrate, a resistor layer with heat generating portions arranged in the main scanning direction, a wiring layer included in a conduction path for energizing the heat generating portions, and a protective layer covering the resistor layer and the wiring layer. The semiconductor substrate includes a projection protruding from the obverse surface of the substrate and elongated in the main scanning direction. The projection has first and second inclined side surfaces spaced apart from each other in the sub-scanning direction. The heat generating portions are arranged to overlap with the first inclined side surface of the projection as viewed in plan view.

A thermal head includes a substrate, an electrode, a bonding material, an electrically conductive member, and a sealing material. The electrode is located on the substrate. The bonding material is located on the substrate or the electrode. The electrically conductive member is located on the bonding material and is electrically connected to the electrode via the bonding material. The sealing material is located on the substrate and covers the bonding material and the electrically conductive member. The bonding material includes a protruding portion located at an outer circumferential edge of the electrically conductive member away from the substrate and the electrically conductive member.

A thermal print head includes a substrate, a resistor layer and a wiring layer. The substrate is made of a single crystal semiconductor and includes an obverse surface facing in one sense of a thickness direction. The resistive layer is supported by the substrate and includes a plurality of heat generating parts arranged side by side in a main scanning direction. The wiring layer is supported by the substrate and forms a conductive path to the plurality of heat generating parts. The wiring layer includes a conductive part and a heat generating sub-part for each of the plurality of heat generating parts, where the conductive part has a lower resistance value per unit length in a sub-scanning direction than the heat generating part, and where the heat generating sub-part has a resistance value per unit length in the sub-scanning direction that falls between the respective resistance values of the heat generating part and the conductive part. The substrate includes a ridge raised from the obverse surface and extending in the main scanning direction. The heat generating part, the heat generating sub-part and the conductive part are disposed on the ridge. The heat generating sub-part is located between the heat generating part and the conductive part in the sub-scanning direction.

Provided is a thermal print head including: a substrate having a convex part thereon; a wiring layer over the convex part; a heat storage layer over the wiring layer; a heating resistive part that is formed over the heat storage layer and is arranged along a main scanning direction; a first electrode in contact with the heating resistive part on one side in a sub-scanning direction; a second electrode in contact with the heating resistive part on another side in the sub-scanning direction; and a connection wiring formed in an opening that passes through the heating resistive part and the heat storage layer and reaches the wiring layer, in which the first electrode is electrically connected to the wiring layer via the connection wiring.

A printer printing an image on a print medium based on print data including print dot data for each of print lines. The printer includes a print head including heating elements arranged along a direction of the print lines, and a controller finding the number of print dots on each print line and determining a first or second control mode as a control mode of the heating elements for printing each print line based on the found number of print dots. In the first control mode, the heating elements are divided into first groups including two or more adjacent heating elements and are heated at a different timing. In the second control mode, the heating elements are divided into second groups including two or more heating elements with at least two thereof spaced apart and are heated at a different timing.

A thermal head includes a substrate; a plurality of heat generating portions; a common electrode disposed on the substrate and electrically connected to the plurality of heat generating portions; a plurality of individual electrodes disposed on the substrate and each electrically connected to a corresponding one of the plurality of heat generating portions; a first insulation layer disposed on the heat generating portions, a part of the common electrode, and a part of the individual electrodes; a second insulation layer located adjacent to the first insulation layer and disposed on a part of the individual electrodes; and a static removing layer disposed on the first insulation layer and grounded. The static removing layer includes a first portion disposed on an upper surface of the first insulation layer and a second portion electrically connected to the first portion and disposed on an upper surface of the second insulation layer.

A thermal contact device may include a thermal contact die embedded in a moldable material. The thermal contact die may include a number of resistors integrated into the thermal contact die, and a number of heater drivers integrated into the thermal contact die and electronically coupled to the resistors. The moldable material is coplanar with a thermal contact side of the thermal contact device. Further, the moldable material includes at least one gradient edge along a medium feed path.

In some examples, a thermal imaging head includes a resistor and conductors connected to end portions of the resistor to pass an electrical current through the resistor. The resistor includes gaps at the end portions of the resistor, each gap of the gaps reducing a cross-sectional area of a respective end portion of the end portions of the resistor relative to a cross-sectional area of a central portion of the resistor.

The present invention relates to a thermal printing device, which comprises a circuit board and a plurality of heating components. A plurality of installation strips are disposed from the top down and horizontally on the circuit board. A plurality of first installation grooves are disposed in the plurality of installation strips. Each of the plurality of first installation grooves includes a first end and a second end. When being disposed from the top down, the first end of one of the plurality of first installation grooves located below is aligned with, the second end of one of the plurality of first installation grooves located above. The plurality of heating components are disposed in the plurality of first installation grooves, respectively. One end of one of the plurality of heating components is disposed on the same plane with the other end of one of the adjacent plurality of heating components in the radial direction. By using the above structure, the problem of fine seams between wide heating components can be solved and hence improving the printing quality.

A thermal contact device may include a thermal contact die embedded in a moldable material. The thermal contact die may include a number of resistors integrated into the thermal contact die, and a number of heater drivers integrated into the thermal contact die and electronically coupled to the resistors. The moldable material is coplanar with a thermal contact side of the thermal contact device. Further, the moldable material includes at least one gradient edge along a medium feed path.