The present method relates to a manufacturing process of container labels with heat transfer technology, wherein alphanumeric codes are sequentially applied over, between and/or under the layers of specific inks and varnishes which protect said area of eventual friction and wear to which they are subject during transportation, handling and productive tests.

There is provided a label preparing device including: a laser cutting section that forms a cutting line, which is an outline of a label piece, on a media by irradiating the media with laser beams; and a print section that applies ink to at least a peripheral part of the label piece after the cutting line is formed. It is preferable that the laser cutting section irradiates the media in an immobile state with laser beams, and the print section applies ink to the media in which the immobile state is maintained.

A winding device includes: a separation unit that separates sheets layered and simultaneously transported; a winding unit that winds one of the sheets separated by the separation unit; and a pressure contact unit that presses the one of the sheets wound by the winding unit from outside of the wound sheet toward the winding unit.

A label production method includes a label peeling portion forming step of attaching an active energy ray curable composition to a base material and curing the active energy ray curable composition to form a label peeling portion, in which the label peeling portion is formed 10 ?m or more higher than surroundings in the label peeling portion forming step.

A variable gloss heat transfer label includes a carrier, a matting layer on a portion of the carrier and a design layer having a first portion provided over the carrier and a second portion provided over the matting layer. The design layer is configured to separate from the matting layer and the carrier, and transfer and adhere the first and second portions of the design layer to a target object upon application of heat and pressure. The first portion of the design layer that is transferred to the target object from the carrier has a different gloss than the second portion of the design layer that is transferred to the target object from the matting layer. The label can be configured to include a carrier, a glossing layer on a portion of the carrier and a design layer having a first portion provided over the carrier and a second portion provided over the glossing layer.

A printer includes a frame including a discharge port, a fixed blade fixed to the frame, a movable blade attached to the frame so that the movable blade is opposite to the fixed blade across the discharge port, a driving mechanism that reciprocally moves the movable blade between a cutting position and a non-cutting position, a motor for the driving mechanism, a sensor configured to detect that the movable blade has reciprocated once between the cutting and non-cutting positions, and a control unit configured to control the motor to drive the driving mechanism at the time of cutting the label, measure a time taken by the movable blade to reciprocate once between the non-cutting and cutting positions, compare the measured time with a threshold value, and determine that a cleaning timing has been reached if the measured time exceeds the threshold value.

A single-ply liner label combination and liner-label combination roll are provided. Each liner label combination including a liner substrate and a label substrate. The label substrate including at least one inner and partially perforated second label. The backside of the label substrate including adhesive but a first portion of an area of the backside that corresponds to the inner and partially perforated second label including an adhesive deadener applied over the adhesive within the first portion. A second portion of the area retains the adhesive in a pattern along a periphery of the backside that corresponds to the inner and partially perforated second label.

The disclosure discloses a label producing apparatus including a driving roller, a driven roller, a driving force transmission mechanism, and a coordination adjusting mechanism. The driving roller is disposed to a downstream side of a movable blade on a tape feeding path and configured to contact and discharge a label tape. The driven roller is configured to advance and retreat with respect to the tape feeding path. The driving force transmission mechanism is configured to perform a switching operation between a transmission state where a driving force of a motor is transmitted to the driving roller and an interruption state where the transmission of the driving force to the driving roller is interrupted. The coordination adjusting mechanism is configured to adjust an advancing and retreating operation of the driven roller, an advancing and retreating operation of the movable blade, and the switching operation of the driving force transmission mechanism into a desired mutually coordinated-mode, these operations being performed by the driving force of the motor in accordance with a rotation of the motor in one direction.

A label 1 includes a first colored layer 10, a second colored layer 20 having a different color from the first colored layer 10, and an indicating layer 30 having a different color from the first colored layer 10 and the second colored layer 20. The indicating layer 30 is fitted into the first colored layer 10 so as to have an exposed surface on one surface of the first colored layer 10. The second colored layer 20 is laminated on the other surface F2 of the first colored layer 10. The curing shrinkage ratio of the first colored layer 10 is larger than that of the indicating layer 30.

A label winding device is for receiving a medium including a label liner and a label member that is removably attached to the label liner and has at least one label portion and a waste portion, separating the waste portion from the label liner at a waste separation portion, and winding the at least one label portion with the label liner. The label winding device includes: a waste winder for winding the separated waste portion; a label winder for winding the at least one label portion with the label liner without the separated waste portion; a waste guide for guiding the separated waste portion to the waste winder; a support for rotatably supporting the waste guide; a sensor for detecting a rotational speed of the waste guide; and a waste break detector for detecting break of the waste portion on a basis of the detection by the sensor.