An example disclosed printer configured to peel media from a backing, the printer having a peeler assembly that is engageable between a peeling position, wherein the printer is configured to peel the media from the backing, and a non-peeling position, wherein the printer is not configured to peel the media from the backing. The printer further including a sensor configured to send a signal corresponding to a position of the peeler assembly. The printer further including a communication interface configured to receive the position of the peeler assembly from the sensor and configured to transmit the position of the peeler assembly to a secondary component.

An example disclosed printer configured to peel media from a backing, the printer having a peeler assembly that is engageable between a peeling position, wherein the printer is configured to peel the media from the backing, and a non-peeling position, wherein the printer is not configured to peel the media from the backing. The printer further including a sensor configured to send a signal corresponding to a position of the peeler assembly. The printer further including a communication interface configured to receive the position of the peeler assembly from the sensor and configured to transmit the position of the peeler assembly to a secondary component.

The present invention provides a method for manufacturing thermal print heads. By forming a molybdenum antioxidation layer on the electrode pattern layer, the oxidation or erosion phenomena on the electrode pattern layer (formed by aluminum or aluminum-copper alloy) in the manufacturing process can be prevented, and hence improving the reliability and lifetime of thermal print heads.

The present invention provides a pressure adjusting structure for printing head. A first pressure plate is disposed on a circuit board. Two elastic members are disposed on the first pressure plate. One end of the two elastic members provides downward force, respectively; the other end thereof is against a second pressure plate, respectively. An adjusting member passes through the second pressure plate. One end of the adjusting member is projective to the second pressure plate such that a user can adjust the downward pressure of the first pressure plate. By ensuring the pressure value within the optimum pressure range, the superior printing quality can be achieved.

The present invention provides a conversion board for printing circuit board and the packaging structure thereof, which is disposed on a plurality of first joint parts of a board member. A plurality of first package pin members are disposed below a first circuit board. The plurality of first package pin members are connected electrically to the corresponding plurality of first joint parts, respectively. The conversion board is disposed on the first circuit board. The conversion board uses a plurality of second joint parts to connect electrically to the plurality of first package pin members. A plurality of second package pin members are disposed below a second circuit board. The plurality of second package pin members are connected electrically to the corresponding plurality of second joint parts, respectively.

A thermal printing apparatus includes a frame, an endless ribbon to transport ink on its outer face, a coating device to coat the endless ribbon with ink, a printhead to print by thermal transfer a substrate with a part of the ink, a plurality of first rollers supporting and transporting the endless ribbon by its inner face along a path from the coating device to the printhead and from the printhead to the coating device in a cyclic manner, at least one first conveyor arranged to support the inner face of the endless ribbon between two adjacent first rollers along its path from the coating device to the printhead; the first conveyor including a plate fixed in translation and rotation with the frame and having a first convex surface supporting the inner face, a heat exchanger designed to cool down the first surface of the plate at a predefined temperature.

An electronic device includes a switching element, a first common-electrode wiring, at least a part of the first common-electrode wiring being covered with the switching element, a plurality of second common-electrode wirings branched from the part of the first common-electrode wiring covered with the switching element, a plurality of individual power-output terminals arranged in a row in the switching element, and a plurality of individual-electrode wirings arranged in a row, the plurality of individual-electrode wirings being connected to the plurality of individual power-output terminals, respectively. Each of the plurality of second common-electrode wirings is disposed between the plurality of individual-electrode wirings.

An image forming system includes an image forming unit configured to form a toner image on a recording material; a fixing device configured to fix the toner image on the recording material on which the toner image is formed by the image forming unit; a first cooling unit capable of cooling the recording material passing through the fixing device; a second cooling unit capable of cooling the recording material passing through the first cooling unit; and a control unit configured to carry out control so that during execution of an image forming job, the image forming job is stopped when both the first cooling unit and the second cooling unit are out of order and is continued when only one of the first cooling unit and the second cooling unit is out of order.

The method and apparatus for protecting the printhead heating elements in a thermal printer includes preparing the printer for label dispensing and then covering the printhead heating elements such that the label run or thermal material passing over the same does not contact the printhead heating elements. The cover for the printhead heating elements can take various forms. In one implementation, the cover is a sleeve configured to fit over the entire printhead assembly of the thermal printer. In another implementation, the cover is a shim placed between the printhead and a label run path. The printhead cover has a low coefficient of friction.

An example thermal printhead apparatus includes a top end; a bottom end located opposite the top end; an electrical interface positioned proximate to the bottom end; a first distal end; a second distal end located opposite the first distal end; a printing face defined by the top end, the bottom end, the first distal end and the second distal end, the printing face includes a thermal element; a mounting face that is opposite the printing face, the mounting face defined by the top end, the bottom end, the first distal end and the second distal end, the mounting face including at least two mounting components, comprising: one or more holes configured to mount the printhead apparatus to a printer; and one or more grooves configured to mount the printhead apparatus to a printer, the one or more grooves extending substantially parallel to the top end and the bottom end.