A card processing device may include a card reader and a printer. The printer may include an ink ribbon cartridge; a thermal head; and a cover member. The ink ribbon cartridge may include a supply roll and a take-up roll. The thermal head may heat the ink ribbon and transfer ink to the card. The card reader may be on a front side of the thermal head, and a part of the card reader may be on a lower side of the supply roll or the take-up roll. The cover member may pivot between a closed position and open position. A conveyance path may be provided inside the card reader and the printer. A part of the conveyance path inside the card reader may be a first conveyance path. The card reader may include an upper frame. The upper frame may pivot between a closed position and open position.

Disclosed herein are an exterior forming method and an exterior forming structure of an electronic component. The exterior forming method of an electronic component may include mounting an injection-molded product, which is injection molded as an electronic component, to an upper portion a heat transferring base unit, mounting a printing film having an ink layer for a heat transfer to the upper portion of the heat transferring base unit such that the ink layer faces an upper surface of the injection-molded product, and heat-transferring the ink layer on the upper surface of the injection-molded product by rotating a heating roll while closely attached at an upper portion of the printing film. The exterior forming method may also include forming an UV coating layer on an upper portion of the ink layer that is heat-transferred on the injection-molded product.

Disclosed herein are an exterior forming method and an exterior forming structure of an electronic component. The exterior forming method of an electronic component may include mounting an injection-molded product, which is injection molded as an electronic component, to an upper portion a heat transferring base unit, mounting a printing film having an ink layer for a heat transfer to the upper portion of the heat transferring base unit such that the ink layer faces an upper surface of the injection-molded product, and heat-transferring the ink layer on the upper surface of the injection-molded product by rotating a heating roll while closely attached at an upper portion of the printing film. The exterior forming method may also include forming an UV coating layer on an upper portion of the ink layer that is heat-transferred on the injection-molded product.

An embodiment of the present invention is a printer that includes a platen roller to feed a print medium, a print head to print on the print medium fed by the platen roller, a connector that is attachable and detachable with respect to the print head the print head, and a controller to stop power supply to the print head via the connector when the platen roller and the print head are separated.

An embodiment of the present invention is a printer that includes a platen roller to feed a print medium, a print head to print on the print medium fed by the platen roller, a connector that is attachable and detachable with respect to the print head the print head, and a controller to stop power supply to the print head via the connector when the platen roller and the print head are separated.

A direct thermal and thermal transfer label combination is provided. The label includes a substrate, and the substrate includes a thermal print coating applied to a front side of the substrate. The label also includes a liner attached to a backside of the substrate along a first side of the liner. Further, an aqueous resin-based thermal transfer coating is applied to a second side of the liner. The front side of the label is capable of being imaged through direct thermal printing while the second side of the liner represents an opposite side of the label that is capable of being imaged through thermal transfer printing.

The disclosure discloses an adhesive tape cartridge including an adhesive tape roll that is disposed in a housing and winds a double-faced adhesive tape. The double-faced adhesive tape comprises a base material layer, a first adhesive layer, a second adhesive layer, and a separation material layer. The first adhesive layer is disposed on one side of the base material layer in a thickness direction and comprises an adhesive with a first pigment. The second adhesive layer is disposed on the other side of the base material layer and comprises an adhesive with a second pigment. The separation material layer is disposed on the other side of the second adhesive layer. An average particle diameter of the first pigment in the first adhesive layer and an average particle diameter of the second pigment in the second adhesive layer is different from each other.

The disclosure discloses an adhesive tape cartridge including an adhesive tape roll that is disposed in a housing and winds a double-faced adhesive tape. The double-faced adhesive tape comprises a base material layer, a first adhesive layer, a second adhesive layer, and a separation material layer. The first adhesive layer is disposed on one side of the base material layer in a thickness direction and comprises an adhesive with a first pigment. The second adhesive layer is disposed on the other side of the base material layer and comprises an adhesive with a second pigment. The separation material layer is disposed on the other side of the second adhesive layer. An average particle diameter of the first pigment in the first adhesive layer and an average particle diameter of the second pigment in the second adhesive layer is different from each other.

The printing machine (1) comprises: a supporting structure (11); a thermal transfer assembly (20) movable in a predetermined horizontal direction (21) and comprising a rotatable motorized transfer roller (30) and heating means (70, 71) associated to the transfer roller (30), wherein the transfer roller (30) and the associated heating means (70, 71) are movable vertically towards and away from a path of the articles (A) to be printed; and supply means (2; 12-16, 33-40) arranged to advance a printing ribbon (N) which on a side facing the articles (A) carries at predetermined intervals images formed of a thermally transferable ink. The thermal transfer assembly (20) further comprises first and second deviation rollers (35, 36) whose axes of rotation are horizontal and substantially parallel to one another and to the axis of rotation (x) of the transfer roller (30). The deviation rollers (35, 36) are arranged one upstream and the other downstream of the transfer roller (30) on the path of the printing ribbon (N) and are displaceable vertically towards and away from said path of the articles (A). The printing machine (1) further comprises first and second motor means (43, 44) associated each with a respective deviation roller (35, 36), said first and second motor means (43, 44) being controllable independently of one another, whereby each of the deviation rollers (35, 36) is selectively displaceable vertically independently of the other one.

The printing machine (1) comprises: a supporting structure (11); a thermal transfer assembly (20) movable in a predetermined horizontal direction (21) and comprising a rotatable motorized transfer roller (30) and heating means (70, 71) associated to the transfer roller (30), wherein the transfer roller (30) and the associated heating means (70, 71) are movable vertically towards and away from a path of the articles (A) to be printed; and supply means (2; 12-16, 33-40) arranged to advance a printing ribbon (N) which on a side facing the articles (A) carries at predetermined intervals images formed of a thermally transferable ink. The thermal transfer assembly (20) further comprises first and second deviation rollers (35, 36) whose axes of rotation are horizontal and substantially parallel to one another and to the axis of rotation (x) of the transfer roller (30). The deviation rollers (35, 36) are arranged one upstream and the other downstream of the transfer roller (30) on the path of the printing ribbon (N) and are displaceable vertically towards and away from said path of the articles (A). The printing machine (1) further comprises first and second motor means (43, 44) associated each with a respective deviation roller (35, 36), said first and second motor means (43, 44) being controllable independently of one another, whereby each of the deviation rollers (35, 36) is selectively displaceable vertically independently of the other one.