Systems and methods disclosed herein relate to a label and a method of application of the label on a container that both protects confidential information and functions to allow for the placement of auxiliary labels even if an overall length of a label exceeds the perimeter of the container to which it is applied. The auxiliary labels are disposed in a fanned fashion, attached to a primary label portion by, for example, a micro perforation line, and where the auxiliary labels are separated from each other by micro perforation lines and where the adhesive back of each pair of auxiliary labels are attached to each other in order to form a plurality of protrusions.

Methods for forming high shrink wrap label sleeves directly from a roll are disclosed herein. A seaming agent is applied to the label, where the trailing edge will overlap the leading edge to form a seam. The seaming agent is then exposed to radiation to cure the seaming agent and form a sleeve. The label comprises a film with at least one external layer that has a Hildebrand solubility parameter, and the seaming agent includes a component having a Hildebrand solubility parameter that is within 2.2 MPa.sup.1/2 or within 4.4 calories.sup.1/2.Math.cm.sup.3/2 of the Hildebrand solubility parameter of the external layer of the film. The seaming agent also has a viscosity of at least 1 centipoise and less than 1000 centipoise when measured at any temperature between ambient temperature and 60 C.

Broadly described herein are methods for using the same pumping and metering system to apply two different seaming agents consecutively without cleaning the system between the two seaming agents. This is useful when it is desired to produce high shrink wrap labels and low-shrink labels on the same production line. The two seaming agents are soluble in each other at loadings (w/w) of 1:10 to 10:1. Two sets of seaming agents are also disclosed, (a) a polar low-shrink seaming agent and a polar high-shrink seaming agent; and (b) a non-polar low-shrink seaming agent and a non-polar high-shrink seaming agent.

Systems and methods for applying decorations onto substrates. Decorations can be transported on a web along the web path to an application station at which the decorations are applied to substrates. Movement of substrates through the application station can be controlled to effect transfer of a decoration to a substrate. The web and a substrate support that urges a substrate into contact with a decoration on the web can be moved in the same direction, e.g., at different speeds. The substrate can be rotated during decoration transfer about an axis that passes through the substrate, e.g., the substrate can be rotated 180 degrees or more during transfer.

The present application relates to a method and system for labeling one or more products such as packages transported along a conveyer, and more specifically to applying a label on a respective package by way of a vertically adjustable assembly positioned above the conveyor. The adjustable assembly includes at least a label printer and an applicator for printing and applying the label on a surface of the package on the conveyor.

Provided is a pressure sensitive adhesive sheet for tires that enables continuous and efficient labeling on tires using a labeling apparatus. The pressure sensitive adhesive sheet includes a release material (C), a first pressure sensitive adhesive layer (B1), a first substrate (A1), a second pressure sensitive adhesive layer (B2), and a second substrate (A2), in this order, and satisfies Requirement (1): in a planar view of the pressure sensitive adhesive sheet, the outline of the first pressure sensitive adhesive layer (B1) exists inside the outline of the second substrate (A2); and Requirement (2): the MD stiffness of the second substrate (A2), measured in the Gurley method according to JIS L 1085, is 0.10 mN or more.

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).

The present disclosure provides an improved system and related methods for automating the sizing and labeling of articles of arbitrary shape, size and orientation, whether still or moving. The system comprises a detection and interrogation zone, one or more proximity sensors, one or more interrogation devices, a processor, a controller, a labeling device, and an electromechanical label applicator arm. Detection of an article by a proximity sensor triggers an interrogation device to interrogate the detection and imaging zone for one or more observable properties when the article is located therein. Analysis of the interrogation data yields the height of the article. Combined with a conveyor rate, article height determines the signals sent to the controller, which commands when and how far a label applicator arm should extend from the labeling apparatus to label the article.

The present disclosure provides an improved system and related methods for automating the sizing and labeling of articles of arbitrary shape, size and orientation, whether still or moving. The system comprises a detection and interrogation zone, one or more proximity sensors, one or more interrogation devices, a processor, a controller, a labeling device, and an electromechanical label applicator arm. Detection of an article by a proximity sensor triggers an interrogation device to interrogate the detection and imaging zone for one or more observable properties when the article is located therein. Analysis of the interrogation data yields the height of the article. Combined with a conveyor rate, article height determines the signals sent to the controller, which commands when and how far a label applicator arm should extend from the labeling apparatus to label the article.

An apparatus for labeling support structures includes: a chassis having a locomotive assembly, and supporting a label generator and an effector assembly with an end movable relative to the chassis and carrying a label manipulator with an image sensor; a controller coupled to the locomotive assembly, label generator, effector assembly and label manipulator, and configured to: obtain label placement data defining a location relative to a support structure reference feature for replacement of a previous label with a new label; control the locomotive assembly to travel to the support structure; detect the reference feature via image data captured at the image sensor; control the effector assembly to place the label manipulator at the location relative to the reference feature; control the effector assembly and the label manipulator to remove and discard the previous label, retrieve the new label from the label generator, and place the new label at the location.