A pharmaceutical order filling system receives pharmaceutical orders and uses a loading device to label containers and load the labeled containers onto a pallet. The loading device is configured with at least one container drop assembly that receives containers to be labelled and loaded onto the pallet and that is in communication with a label assembly configured to print and apply labels to the containers. The loading device also includes at least one loading rotary wheel configured to receive the labelled containers and hold the labelled containers in a pick position to be moved from the pick position to a predetermined position on the pallet. The loading device may be configured to accommodate multiple sizes of containers and to consolidate multiple sizes of labelled containers into a single loading rotary wheel for loading onto the pallet.

A lenticular label for a container, such as a curved glass bottle, is formed of a lenticular array having a plurality of lenticules on a front face and a smooth back face and a compliant base layer having first and second faces. A first adhesive is disposed between the first face of the compliant base layer and the smooth back face of the lenticular array. The first adhesive is in substantial contact with both the first face of the compliant base layer and the smooth back face of the lenticular array. A second adhesive is disposed upon the second face of the base layer.

A lenticular label for a container, such as a curved glass bottle, is formed of a lenticular array having a plurality of lenticules on a front face and a smooth back face and a compliant base layer having first and second faces. A first adhesive is disposed between the first face of the compliant base layer and the smooth back face of the lenticular array. The first adhesive is in substantial contact with both the first face of the compliant base layer and the smooth back face of the lenticular array. A second adhesive is disposed upon the second face of the base layer.

The invention relates to a container handling machine (1) having at least one operative unit (18) comprising first support means (21) to support a base (12) of a filled and closed container (3), second support means (24) cooperating with an end (17) of the container (3) opposite the base (12), a plunger (31) selectively moved along its axis (E) to perform a deformation operation on the base (12) of the container (3) from a first swollen configuration to a second inwardly-retracted configuration, and actuator means (35) selectively activated to move the plunger (31) along its axis (E) between a first position, detached from the base (12) of the container (3), and a second position, in which the plunger (31) defines the second configuration of the base (12); the machine (1) further comprises a control unit (41) configured to selectively activate the actuator means (35) for moving the plunger (31) along its axis (E); the second support means (24) are maintained at a constant distance from the first support means (21) during the deformation operation; the control unit (41) comprises measuring means (42) for measuring the maximum deforming force (F) exerted by the plunger (31) on the base (12) of the container (3) during the deformation operation in order to determine whether the container (3) is correctly filled.

A label application system for applying labels to relatively short, round, straight-walled articles is constructed and designed so that labels to be applied to passing articles are delivered to the label application zone on a carrier web in a short feed orientation, with each label being oriented lengthwise across a width of the carrier web. At the time of labeling, the label is held stationary on a flat vacuum surface, and the label is applied by spinning the articles past the vacuum surface. As a result, the system is capable of labeling articles at processing speeds of at least 450 articles per minute or more.

A label application system for applying labels to relatively short, round, straight-walled articles is constructed and designed so that labels to be applied to passing articles are delivered to the label application zone on a carrier web in a short feed orientation, with each label being oriented lengthwise across a width of the carrier web. At the time of labeling, the label is held stationary on a flat vacuum surface, and the label is applied by spinning the articles past the vacuum surface. As a result, the system is capable of labeling articles at processing speeds of at least 450 articles per minute or more.

The invention relates, inter alia, to a device for marking containers for a container treatment system. The device has a container conveyor for transporting the containers. The device has a coupling unit, a labeling module, and a laser-marking module. The labeling module and the laser-marking module can be interchangeably coupled to the coupling unit. Advantageously, the device can be used particularly flexibly, because the labeling module and the laser-marking module can be coupled to the same coupling unit, so that the device can be used flexibly and as required for labeling with the labeling module or for laser-marking with the laser-marking module.

Apparatuses and methods for applying a transfer material onto the surface of an article are disclosed, including apparatuses and methods of transfer printing on and/or decorating three-dimensional articles, as well as the articles printed and/or decorated thereby. In some cases, the apparatuses and methods involve providing a deposition device, such as a printing device; providing a transfer component; depositing a material onto a portion of the transfer component with the deposition device; modifying the portion of the transfer component with the transfer material thereon to conform the transfer component to at least a portion of the surface of the three-dimensional article; and transferring the transfer material onto the surface of the article.

A label applicator apparatus for applying an adhesive-backed label to a container is disclosed herein. The label is applied accurately at a desired height and positioned to be perfectly horizontal. The apparatus comprises a cradle comprising a headboard, a footboard, and two adjustable parallel rails forming a carriage for the container. The apparatus also includes an adjustable horizontal label stop that has a curved flange curving across the adjustable carriage and an adjustable bottle stop that can slide forwards and backwards. The adjustable bottle stop is positioned to apply the label to the container at a desired height, the container is placed on the carriage, the adjustable horizontal label stop is closed over the container, and the label is applied by aligning the label horizontally such that it touches the label stop at two contact points.

A label applicator system is described comprising one or more, and preferably two, assemblies of rollers and belts. The assemblies are arranged relative to one another such that at least a portion of the belts of each assembly are aligned with one another to define an article receiving lane. The assemblies are arranged and configured such that the lane extends in a zig- zag path, a relatively straight path, and/or an arcuate path. Selection of the lane geometry along with appropriate control of belt velocities enable high rates of applying labels to articles and particularly containers having compound curves.