According to one embodiment, a thermal print head includes a heat sink; a head substrate placed on the heat sink and having a plurality of heat generating elements arranged in a primary scanning direction; a circuit board placed on the heat sink so as to be adjacent to the head substrate in an auxiliary scanning direction and provided with a connection circuit; and a control element electrically connected to the heat generating element via a first bonding wire and electrically connected to the connection circuit via a second bonding wire, in which at least one of the first bonding wire and the second bonding wire includes any of a copper wire, a copper alloy wire, and a wire mainly made of copper and coated with a metal different from copper.

An asymmetric thermal print head includes a print head body and a plurality of print elements supported on the print head body. The print elements are aligned along a first axis. Each print element includes a heater portion having a burn width measured along the first axis corresponding to a first print resolution, and a burn length measured along a second axis, which is perpendicular to the first axis, corresponding to a second print resolution. The second print resolution is higher than the first print resolution. One or more control circuits are configured to individually activate the print elements.

Certain embodiments provide a thermal print head including: a first heat storage layer formed on a substrate; a heat generator formed on the first heat storage layer; an electrode formed from the first heat storage layer to the substrate and electrically connected to the heat generator; and a barrier layer that covers the electrode and is formed by a CVD method.

A thermal print head structure includes a fixed electrode layer, a movable electrode layer opposite to the fixed electrode layer, a protection layer group covering the fixed electrode layer and the movable electrode layer, a heat source used to heat the fixed electrode layer, and a number of spacers. The fixed electrode layer includes a fixed electrode line. The movable electrode layer includes a flexible electrode line which is intersected with the fixed electrode line. These spacers are located between the fixed electrode layer and the protection layer group such that gaps are defined between the fixed electrode layer and the protection layer group. When a potential difference is generated between the fixed electrode line and the flexible electrode line, the movable electrode layer contacts the fixed electrode layer through the gap.

A thermal head includes a substrate, a glaze layer, and a reinforced conductor layer. The glaze includes a first glaze and a second glaze. The first glaze extends in a predetermined direction on the surface of the substrate. The second glaze is spaced part from the first glaze to one side in a direction perpendicular to the predetermined direction on the surface of the substrate. The reinforced conductor layer includes a lateral side part. The lateral side part extends on the surface of the substrate from the first glaze side to the second glaze side and is partially located on the second glaze. An edge part on the first glaze side in the second glaze includes a cutout portion cut out toward the one side in the direction perpendicular to the predetermined direction. The lateral side part passes through the cutout portion.

According to one embodiment, a thermal print head includes a heat sink, a head substrate having a plurality of heat generating elements placed on the heat sink and disposed in a primary scanning direction, a circuit board placed on the heat sink so as to be adjacent to the head substrate in an auxiliary scanning direction and provided with a connection circuit, and a control element electrically connected to the heat generating element via a first bonding wire and electrically connected to the connection circuit via a second bonding wire, wherein a plurality of first bonding wires is disposed in parallel in the primary scanning direction, and among the first bonding wires, the first bonding wire having a length of at least 2 mm or more is a metal wire having a Young's modulus greater than that of gold.

The present invention relates to a method for manufacturing a thermal print head. Dispose a silicon substrate on a carrier, and dispose sequentially a glaze layer, a thermal resistance layer, an electrode pattern layer, and a passivation layer on the silicon substrate for forming a thermal print head. In addition, the size of the silicon substrate disposed on the carrier can be changed according to the opening on the carrier for providing a large-size thermal print head or one-time large-size printing.

The present invention relates to a method for manufacturing a thermal print head. Dispose a silicon substrate on a carrier, and dispose sequentially a glaze layer, a thermal resistance layer, an electrode pattern layer, and a passivation layer on the silicon substrate for forming a thermal print head. In addition, the size of the silicon substrate disposed on the carrier can be changed according to the opening on the carrier for providing a large-size thermal print head or one-time large-size printing.

A thermal print head includes: a substrate having an obverse surface; a plurality of heat generators arranged on the substrate in a main scanning direction; and a wiring layer provided on the substrate and constituting an energization path to the heat generators. The substrate has a protrusion protruding from the obverse surface and extending in the main scanning direction. The protrusion has a top portion having the largest distance from the obverse surface, and an inclined portion connected to the top portion in a sub-scanning direction. The inclined portion is inclined relative to the obverse surface at a predetermined angle. Each of the plurality of heat generators extends across a boundary between the top portion and the inclined portion. Each of the heat generators is formed on at least a part of the top portion and at least a part of the inclined portion in the sub-scanning direction.

A thermal printhead includes a substrate, a resistor layer with heat generation portions supported by the substrate and aligned in a primary scanning direction, a wiring layer supported by the substrate to form a conductive path to the heat generation portions, an insulating layer interposed between the substrate and the resistor layer, and a reflection layer located opposite to the heat generation portions with respect to the insulating layer. The reflection layer overlaps with the heat generation portions as viewed in a thickness direction of the heat generation portions and has a greater heat reflectivity than the insulating layer.