The compact thermal printing mechanism according to the invention is applicable for handheld payment terminals. The invention provides a printer chassis (1) with reinforced flat area (20) by at least one reinforcing element comprising a fold of the printer chassis (1). This folded portion of the printer chassis strengthens the chassis and provides a very strong resistance to bending forces of the lateral pressure means (18) of the platen roller (6). The stable and uniform pressure distribution across the paper width ensures uniform print quality.

According to one embodiment, a printer includes an input interface and a processor. The input interface inputs a distance signal output from a distance sensor opposite to a rotating surface of a roll around which a sheet material is wound in a roll shape. The processor detects an amount of change in a distance from the distance sensor to the rotating surface of the roll based on a plurality of distance signals input at different timings, detects a vibration convergence state of the roll from the amount of change in the distance, and detects a diameter of the roll based on the distance signal input in the vibration convergence state.

A CPU of a printing apparatus energizes heat-generating elements for a predetermined period of time in a first divided printing cycle of two divided printing cycles obtained by dividing one printing cycle, according to a yellow energization pattern, and forms a first yellow print dot without causing a heat-sensitive tape to develop another color. Then, the CPU energizes the heat-generating elements for a predetermined period of time in a second divided printing cycle of the two divided printing cycles, and forms a second yellow print dot on the heat-sensitive tape. By forming two print dots in one printing cycle, the CPU secures a large color reproduction range.

The present disclosure provides a thermal print head and a method manufacturing thereof and a thermal printer including the thermal print head, which are capable of suppressing low manufacturing efficiency and enhancing wear-resistance against a recording medium. The thermal print head includes: a substrate, having a main surface facing a thickness direction; a resistance layer, including multiple heating portions arranged in a main scan direction and formed on the main surface; a wiring layer, formed on the resistance layer and connected to the heating portions; and a protection layer, covering a part of the main surface, the heating portions and the wiring layer.

The present disclosure provides a method for manufacturing a thermal print head. The method includes: forming an electrode layer on a substrate; and forming a resistor layer including a plurality of heat generating portions connected to the electrode layer. The electrode layer includes a plurality of individual electrodes including a plurality of first striped portions extending in a secondary scan direction and spaced apart in a main scan direction, and a common electrode including a plurality of second striped portions extending in the secondary scan direction. The forming of the resistor layer includes: a coating process of applying a resistor paste in a stripe that overlaps the first striped portions and the second striped portions; a firing process of firing the resistor paste to form a resistor film; and a removal process of removing a removal region in the resistor paste or the resistor film.

According to one or more embodiments, a motor driving device includes a first substrate, a motor drive circuit, a first temperature sensor, a second temperature sensor, and a controller. The first substrate is connected to a motor via a first wiring. The motor drive circuit is provided on the first substrate. The first temperature sensor is provided on the first substrate and detects a first temperature of the motor drive circuit. The second temperature sensor detects a second temperature of an ambient environment where the motor is being used. The controller controls the motor drive circuit based on the first temperature from the first temperature sensor and the second temperature from the second temperature sensor.

The present disclosure provides a thermal print head and a method manufacturing thereof and a thermal printer including the thermal print head, which are capable of suppressing low manufacturing efficiency and enhancing wear-resistance against a recording medium. The thermal print head includes: a substrate, having a main surface facing a thickness direction; a resistance layer, including multiple heating portions arranged in a main scan direction and formed on the main surface; a wiring layer, formed on the resistance layer and connected to the heating portions; and a protection layer, covering a part of the main surface, the heating portions and the wiring layer.

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.

A printer includes a thermal head, an electrical connector capable of being connected to and disconnected from the thermal head, and a head cover of the thermal head. The head cover moves between a first position and a second position different from the first position to connect and disconnect the thermal head and the electrical connector.