A label-sensing method includes the steps of aligning a sensor to an exposed portion of a strip of release paper that supports a row of labels, switching the sensor to a setting mode, determining whether an existing threshold is to be used for the roll of labels, transferring an existing threshold to the sensor if an existing threshold is to be used for the roll of labels, using the sensor to scan the exposed portion of the release paper and produce a sensed value if no existing threshold is to be used for the roll of labels, and calculating a threshold based on the sensed value, storing the threshold and transferring the threshold to the sensor.

The present invention relates to a labelling machine (1) for applying labels (2) to receptacles (3) comprising a web (11) having a succession of decorative patterns (15); a cutting unit (12) configured to cut said web (11) so as to obtain individual labels (2); a conveying means (14) configured to advance the individual labels (2); a control unit (17) configured to control a positioning of the web (11) in relation to a reference station (18); a determination device (19) configured to determine and/or detect a relative positioning of the decorative patterns (15) in relation to the reference station (18); and a removal device (20) configured to remove incorrect labels (2) that are determined and/or detected as a function of the relative positioning of the decorative patterns (15) in relation to the reference station (18). Also included is a method for applying labels (2).

A method of applying a linerless label to an article wherein a web of joined labels is die cut from a web of label material in which the adhesive is protected by a water-soluble coating which provides a cushion between an anvil and die cutting means. The water-soluble coating is at least partially removed by exposure to water in a press following die-cutting, in a label applicator, or in an off-line unit. The web of joined labels may be wound and unwound between each of the above options. The web of joined labels may be separated in a label applicator by breaking a weakened boundary between adjoining labels or by cutting at a boundary between the label and the adjoining label. The linerless label may contain anti-counterfeit means that may be subsequently identified overtly and/or covertly.

An apparatus and method for printing labels (1), in particular labels provided on a liner (2). The apparatus includes at least one label feed device (3) for providing and feeding labels, a transport device (4) including at least one transport element (9, 10) for transporting the labels, which have been fed by the label feed device, in a transport direction, a printing device (11) including a printing head (11a) for printing the labels transported by the transport device, and a capturing device (12) for capturing the position of the respective label in a section of the transport device. The capturing device has a line-scan or area-scan camera (13) with which the side of the transport element that faces the labels during correct use and/or a gap (19) formed between two transport element sections (17, 18) in the transport direction is optically capturable in a capturing region (14).

The present disclosure relates to the field of hub packaging technology, and specifically to an automatic hub labeling device and a production line. A conveying mechanism conveys a hub to a camera identification module to determine a hub model, a printer can print multiple models of bar code or two-dimensional code labels and can automatically print a bar code or two-dimensional code label according to the wheel model, and the bar code or two-dimensional code label can be automatically pasted to a specified position according to the wheel model, so that automatic identification of the wheel model, automatic printing of the label and automatic pasting of the label are achieved, personnel participation is reduced, the production efficiency is improved, and customer complaints are reduced.

A cutting unit comprising a cutting drum, a drum knife, a counterpart knife, and a double-joint controller that controls swiveling about a first joint, which swivels the counterpart knife between a cutting position and a waiting position, and swiveling about a second joint, which permits adjustment of a knife gap that forms between the counterpart knife and the drum knife in the cutting position. The drum knife is disposed on a circumference of the drum such that rotation of the drum guides the drum knife past the counterpart knife to cut a label when the counterpart knife is in the cutting position. In the waiting position, the counterpart knife is out of active engagement with the drum knife. The second joint permits adjustment of the knife gap such that the knife gap remains adjusted independently of swiveling about the first joint.

A baggage labeling system is disclosed. The baggage labeling system includes a baggage labeling module. The baggage labeling module includes a housing, a workstation interface, a controller communicatively coupled to the workstation interface. a baggage sensor communicatively coupled to the controller, a conveyor system communicatively coupled to the controller and configured to move a baggage item. The baggage labeling module includes a printing assembly communicatively coupled to the controller. The printing assembly includes a printer head configured to print a label directly onto the baggage item and a positioning arm mechanically coupled to the printer head configured to rotate the positioning arm relative to at least one plane, or translate the positioning arm relative to a first axis. The baggage labeling system further includes a workstation communicatively coupled to the baggage labeling module.

A baggage labeling system is disclosed. The baggage labeling system includes a baggage labeling module. The baggage labeling module includes a housing, a workstation interface, a controller communicatively coupled to the workstation interface. a baggage sensor communicatively coupled to the controller, a conveyor system communicatively coupled to the controller and configured to move a baggage item. The baggage labeling module includes a printing assembly communicatively coupled to the controller. The printing assembly includes a printer head configured to print a label directly onto the baggage item and a positioning arm mechanically coupled to the printer head configured to rotate the positioning arm relative to at least one plane, or translate the positioning arm relative to a first axis. The baggage labeling system further includes a workstation communicatively coupled to the baggage labeling module.

A peel plate with a rotating rod is provided. The peel plate with the rotating rod may be used in a label dispensing system in place of a standard peel plate having a narrow-edged portion. The peel plate with the rotating rod reduces the friction over a liner (e.g., having labels disposed on both sides) during label dispensing of a first side, which would thereby reduce or eliminate the curling effect of the liner for subsequent (second side) label dispensing.

A label including a first strip including a first end and a second end opposite the first end. The first strip includes an opaque material. The first strip further includes a first area proximate the first end. The first area includes a first length along a longitudinal axis common to the first strip. The label also includes a second strip including a third end and a fourth end opposite the third end, wherein the second strip includes a transparent material. The second strip is laminated over the first strip such that the third end is disposed outside the first area. The fourth end extends beyond the second end a distance at least equal to the first length.