Abstract: A thermal head has heating elements that can be selectively driven independently from one another during a driving operation to directly heat, and thereby thermally activate, regions of a heat-sensitive adhesive layer of a heat-sensitive adhesive sheet while the heat-sensitive adhesive sheet is moved relative to the thermal head with the heating elements disposed in opposing relation to the respective regions of the heat-sensitive adhesive layer.

Abstract: A thermal activation device has a thermal activation head that thermally activates a heat-sensitive adhesive layer of a sheet material having a printing layer on one surface of a sheet-like base material and the heat-sensitive adhesive layer formed on the other surface thereof. A platen roller conveys the sheet material and is disposed in pressure contact with the thermal activation head so that the platen roller and the thermal activation head apply a holding force on the sheet material. A pair of conveyor rollers hold and convey the sheet material and are disposed on a downstream side of the thermal activation head in a conveying direction of the sheet material. A holding force applied on the sheet material by the pair of conveyor rollers being larger than a holding force applied on the sheet material by the platen roller and the thermal activation head.

Abstract: A thermal activation device includes a platen lock mechanism for locking a platen roller of a platen unit and a heating unit or printing unit into press contact with each other. The platen lock mechanism has a lock arm mounted to undergo rotation about a rotational axis, a shaft member provided in one of the platen unit and the lock arm, an engagement recess for engagingly receiving the shaft member and provided in the other of the platen unit and the lock arm, and an urging member for urging the lock arm in a direction for bringing the shaft member into engagement with the engagement recess. In a state in which the heating unit or printing unit is in press contact with the platen roller, a distance between the rotational axis of the lock arm and an axis of the shaft member is greater than a distance between the rotational axis of the lock arm and the rotational axis of the platen roller.

Abstract: A printer selectively prints on heat-sensitive adhesive sheets and ordinary sheets that have no heat-sensitive adhesive. The printer has a printing unit that prints on one surface of a sheet and a printing platen roller that transports the sheet in a forward direction. A cutter unit cuts the printed sheet to a predetermined length, and a thermal activation unit disposed downstream of the cutter unit has a thermal head for heating the other surface of the sheet and a thermal activation platen roller that transports the sheet in the forward direction. A detector detects whether the sheet is a heat-sensitive adhesive sheet or an ordinary sheet, and a control device controls operation of the thermal activation unit so that both the thermal head and the thermal activation platen roller are operated in response to detection of a heat-sensitive adhesive sheet and so that the thermal activation platen roller but not the thermal head is operated in response to detection of an ordinary sheet.

Abstract: An adhesive label printer has a thermal activation device that thermally activates a thermally active adhesive layer of a thermally active adhesive sheet. The thermally active sheet has a recording surface formed on one side of a sheet-like base and the thermally active layer formed on the other side thereof. A recording device records information on the recording surface of the thermally active adhesive sheet. A platen roller conveys the thermally active adhesive sheet and has a roller portion made of least a fluorine atom containing rubber material.

Abstract: Provided is a thermal activation device capable of preventing a heat-sensitive adhesive sheet from being partially excessively heated, keeping a short distance between a contact between a thermal head and a platen roller, and a discharge port, and preventing a structure of the thermal activation device from being complicated and a size thereof from increasing. While a heat-sensitive adhesive sheet (2) is transported along a transport path (15) through rotations of insertion rollers (3) and a platen roller (5), a heat-generating portion (4a) of the thermal head (4) is caused to generate heat, thereby thermally activating a heat-sensitive adhesive layer of the heat-sensitive adhesive sheet (2). When a trailing edge of the heat-sensitive adhesive sheet (2) reaches a position where the trailing edge thereof is not in contact with the platen roller (5), a transporting force is not transmitted to the heat-sensitive adhesive sheet (2), thereby stopping transportation thereof.

Abstract: A thermal activation apparatus includes a thermal head for thermal activation, a platen roller for thermal activation pressed against the thermal head, and an air cooling mechanism. The air cooling mechanism includes partitions for separating the thermal activation apparatus from the outside, an air outlet in a lower part thereof, first and second air inlets in an upper part thereof, and a fan for exhausting air through the air outlet. While a heat-sensitive adhesive agent layer of the heat-sensitive adhesive sheet is heated by the platen roller and the thermal head to be thermally activated during transporting the heat-sensitive adhesive sheet, the fan is actuated to generate airflow from the first and second air inlets and around the platen roller, the thermal head, and a heat sink, in this order, to be discharged to the outside from the air outlet.

Abstract: A thermal activation apparatus comprises a housing having an insertion slot for insertion therethrough of a heat-sensitive adhesive sheet. A sensor detects the heat-sensitive adhesive sheet inserted through the insertion slot and outputs a corresponding detection signal for determining a start time of the thermal activation apparatus. A transfer unit transfers the heat-sensitive adhesive sheet and a thermal activation unit thermally activates a heat-sensitive adhesive layer of the heat-sensitive adhesive sheet. An ejection unit ejects the heat-sensitive adhesive sheet after thermal activation. A control unit disposed within the housing controls operation of the thermal activation apparatus and includes a printer communication unit for communicating the thermal activation apparatus with a printer for printing on a printable surface of the heat-sensitive adhesive sheet before or after thermal activation of the heat-sensitive adhesive layer of the heat-sensitive adhesive sheet.

Abstract: Provided is a thermal activation device including a thermal activation head (11) for thermally activating a heat-sensitive adhesive layer of a sheet material (3) having a printing layer provided on one surface of a sheet-like base material and having the heat-sensitive adhesive layer provided on the other surface thereof, and a platen roller (12) for holding and conveying the sheet material (3), the platen roller (12) being brought into press contact with the thermal activation head (11). Moreover, the thermal activation head (11) thermally activates the heat-sensitive adhesive layer asymmetrically with respect to a centerline in a width direction perpendicular to a conveying direction of the sheet material (3). Furthermore, a plate spring (18) which urges the sheet material (3) to be pressed onto a peripheral surface of the platen roller (12) is provided, the plate spring (18) being located on an upstream side of the thermal activation head (11) in the conveying direction of the sheet material (3).

Abstract: A thermal activation device has a thermal head having heat generating elements for generating heat to heat a thermal activation sheet. A radiator absorbs and dissipates heat generated by the heat generating elements of the thermal head. The radiator has a portion disposed in contact with an introduction path along which the thermal activation sheet is introduced toward the thermal head for contacting the thermal activation sheet to preheat the thermal activation sheet as the thermal activation sheet advances in the introduction path.

Abstract: A thermal activation method for a heat-sensitive adhesive sheet having a front end and a rear end. A heat-sensitive adhesive sheet is conveyed between a thermal head for generating heat and a platen roller by rotating the platen roller against the thermal head to thermally activate the heat-sensitive adhesive sheet. The thermal head is driven to cause the thermal head to generate heat in synchronization with conveyance of the heat-sensitive adhesive sheet by the platen roller so that the thermal head starts generating heat before the front end of the heat-sensitive adhesive sheet enters between the thermal head and the platen roller and while the platen roller rotates less than once between the point at which the thermal head starts generating heat and the point at which the front end of the heat-sensitive adhesive sheet enters between the thermal head and the platen roller.

Abstract: A printer apparatus has a thermal head for printing by making contact with a heat-sensitive coloring layer of a heat-sensitive adhesive sheet comprised of the heat-sensitive coloring layer and a heat-sensitive adhesive layer formed on opposite sides of a sheet-like base material. A thermal head heats the heat-sensitive adhesive layer to activate the same, and a conveying roller conveys the heat-sensitive adhesive sheet in a predetermined direction to an ejection hole which ejects the heat-sensitive adhesive sheet out of the apparatus. A sheet holding unit holds the printed sheet with part of the same exposed to the outside from the ejection hole.

Abstract: A printer has a sheet housing unit for storing a heat-sensitive adhesive sheet having a heat-sensitive adhesive layer on one side and a printable surface on the other side. A set of pull-out rollers pulls the heat-sensitive adhesive sheet out of the sheet housing unit and transports the sheet in a given direction, and a cutter device cuts the heat-sensitive adhesive sheet that has been transported by the pull-out rollers. A printing device has a thermal print head for printing letters or images on the printable surface of the heat-sensitive adhesive sheet, and a print platen roller for transporting the heat-sensitive adhesive sheet in the given direction. A thermal activation device has a thermal-activation thermal head for heating the heat-sensitive adhesive layer, and a thermal activation platen roller for transporting the heat-sensitive adhesive sheet in the given direction. A first drive unit drives the pull-out rollers and a second drive unit drives the print platen roller.

Abstract: Provided is a printer apparatus, including: a thermal print head that performs printing by contacting a heat-sensitive color-developing layer of a heat-sensitive adhesive sheet that includes a printable surface made from the heat-sensitive color-developing layer on one surface of a sheet-like base material, and a heat-sensitive adhesive layer on another surface of the sheet-like base material; a thermal-activation thermal head that activates the heat-sensitive adhesive layer by heating; a cutter device that cuts the heat-sensitive adhesive sheet; a transporting unit that transports the heat-sensitive adhesive sheet; and a controlling unit that controls the thermal print head, the thermal-activation thermal head, and the cutter device.

Abstract: Provided is a printing and thermal activation device for a heat-sensitive adhesive sheet that is compact, lightweight, and simple in structure. The heat-sensitive adhesive device for a heat-sensitive adhesive sheet includes a thermal head capable of printing on a printable layer and thermal activation for a heat-sensitive adhesive layer. When the heat-sensitive adhesive sheet is inserted, a platen roller and the thermal head are operated to transport the heat-sensitive adhesive sheet while printing on the printable layer. The heat-sensitive adhesive sheet is cut with a cutter unit at a predetermined position and then the cut sheet passes through a transporting roller pair and is guided to a reversing mechanism.

Abstract: There are disclosed a platen roller capable of inhibiting at least one of drop of an adhesive force of a thermally active adhesive layer and deterioration of the platen roller which are seen in a case where recording and thermal activating are performed with respect to a thermally active adhesive sheet having the thermally active adhesive layer on a backside of a recording surface of a sheet-like substrate, and a recording device, a thermal activation device, and a sticking label printer which are provided with the platen roller. As a platen roller for conveying the thermally active adhesive sheet having the thermally active adhesive layer on the backside of the recording surface of the sheet-like substrate, a platen roller is used whose roller portion contains a fluorine atom containing rubber.

Abstract: There are disclosed a platen roller capable of inhibiting drop of an adhesive force of a thermally active adhesive layer, which is seen in a case where recording and thermal activating are performed with respect to a thermally active adhesive sheet having the thermally active adhesive layer on a backside of a recording surface of a sheet-like substrate, a method of manufacturing the platen roller, and a recording device and a sticking label printer which are provided with the platen rollers. As the platen roller for conveying the thermally active adhesive sheet having the thermally active adhesive layer on the backside of the recording surface of the sheet-like substrate, a platen roller is used which is subjected to a contact treatment to bring the surface of a roller portion into contact with a compound (a) containable as a solid plasticizer in the thermally active adhesive layer.

Abstract: A thermal activation apparatus 1 includes a thermal head 2 for thermal activation, a platen roller 4 for thermal activation pressed against the thermal head 2 for thermal activation, and an air cooling mechanism. The air cooling mechanism includes partitions 5 for separating the thermal activation apparatus 1 from the outside, an air outlet 6 in a lower part thereof, first and second air inlets 7a and 7b in an upper part thereof, and a fan 8 for exhausting air in the air outlet 6.

Abstract: Provided is a thermal activation apparatus in which a discharge path of a heat-sensitive adhesive label is not adversely affected by adhesive residue. The thermal activation apparatus includes a discharge roller (5) for completely discharging a heat-sensitive adhesive label with its heat-sensitive adhesive agent layer formed on the back side that is heated by a thermal head from between the thermal head and a platen roller. Grooves (53) are formed along the circumferential direction of the discharge roller 5 at places which correspond to the lateral edges of various kinds of heat-sensitive adhesive labels.

Abstract: The objectives of the present invention are to provide a device for the thermal activation of a heat-sensitive adhesive sheet, and a method therefor, that can improve the reliability with which the adhesive property of a heat-sensitive adhesive layer is manifested, and a printer that includes the device. According to the present invention, a thermal activation method, for manifestation of the adhesive quality of a heat-sensitive adhesive layer deposited on a heat-sensitive adhesive sheet, includes a step of: applying thermal energy, to locations on of the heat-sensitive adhesive sheet, that varies in consonance with the location.