Fixtures for use with medical device label printing systems are disclosed. An example fixture may include a housing designed to be coupled to a printing device. The housing may have an input region for receiving a media (e.g., that may include a backing portion and a label portion) and a return region. A separating member may be disposed within the housing. The separating member may be designed for separating the label portion from the backing portion. The separating member may be designed to shift between a first configuration where the separating member engages the media in order to separate the label portion from the backing portion and a second configuration where the separating member is positioned away from engagement with the media. The fixture may also include an actuator for shifting the separating member between the first configuration and the second configuration.

Disclosed herein is a film fitting head which holds a tubular film fitted on a mandrel in a stable position and can prevent the film from rotating and being displaced in a peripheral direction. The film fitting head (40) includes a mandrel (M) for receiving a tubular film (L) in a fitted state in a film supply position, feeding the tubular film in a film fitting position, and fitting the tubular film onto a body portion of a container. The mandrel (M) includes a film holding portion (85) provided above a lifting member (88) located in a standby position. An outer peripheral surface of the film holding portion (85) has a tapered surface that is tapered down toward a top, and an outer peripheral length of a lower end (85a) of the film holding portion (85) is set to be approximately equal to a peripheral length of the tubular film (L) in an open state.

A self-masking label and method of use for wrapping about elongate articles is presented herein. The label includes a series of label sections positioned end-to-end along the length of the label and supported on a carrier strip during printing. A first label section is configured to be marked or printed with indicia. A second label section may be transparent. A third label section is arranged to overlap the first and second sections and to cover and protect the indicia, during for example, an overcoating procedure. A fourth label section includes a non-sticky tab section.

A machine for applying tubular film to products includes a film feed path along which a supply of continuous tubular film is fed, and a sleeve eject station at which the film tubing is cut into sleeves that are ejected onto products passing the sleeve eject station. At least one sensor is positioned along the film feed path upstream of the sleeve eject station for detecting a splice in tubular film traveling along the film feed path. A controller is configured for controlling the machine such that, upon detection of a splice in the tubular film, a defective sleeve that includes the splice thereon is ejected into a gap between successive products so as to prevent application of the defective sleeve to any product.

According to one embodiment, a label peeling device includes a tray, a pressing unit, and a control unit. The tray is configured to support a label sheet thereon. The pressing unit is configured to be driven in a direction perpendicular to a conveyance direction of the label sheet. The control unit is configured to drive the pressing unit toward a central portion of the label sheet supported on the tray. The control unit performs peeling control to peel a liner sheet and a label body of the label sheet from each other by pressing an edge of the label sheet and thereby curving the label sheet.

An object can be heat-shrinkable packaged by placing an object inside of heat-shrinkable film, sealing the heat-shrinkable film around the object to form a heat-shrinkable package, coupling a first portion of a label to the heat-shrinkable package, and causing the heat-shrinkable film to shrink into heat-shrunk film and the heat-shrinkable package to form into a heat-shrunk package. The label includes an identifier on a second portion of the label. The label remains coupled to the heat-shrunk film after the heat-shrinkable film is caused to shrink into heat-shrunk film. The second portion of the label remains substantially undeformed after the heat-shrinkable film is caused to shrink into heat-shrunk film.

An automated labeling method and apparatus includes a label web-severing mechanism and a label-applying assembly, the web-severing mechanism configured to synchronously sever a plurality of labels from a self-wound label web, and the label-applying assembly configured to synchronously apply the plurality of severed labels to a corresponding plurality of articles to be labeled.

An automated labeling method and apparatus includes a label web-severing mechanism and a label-applying assembly, the web-severing mechanism configured to synchronously sever a plurality of labels from a self-wound label web, and the label-applying assembly configured to synchronously apply the plurality of severed labels to a corresponding plurality of articles to be labeled.

Systems and methods for forming and applying decorations onto substrates are disclosed. According to some aspects, a decoration may be formed on a carrier web at a decoration forming station positioned along a web path. The decorations may be transported along the web path to an application station at which the decorations are applied to substrates from the carrier web.

According to an embodiment of the present disclosure, a method of labeling a plurality of products includes coating a pressure sensitive adhesive to a roll of face stock, the roll of face stock configured to be converted to a plurality of individual labels aligned in a single lane; singulating an individual label from the roll of face stock; and applying the individual label to a product of the plurality of products, wherein the coating, singulating and applying are conducted sequentially in a single continuous operation with a single continuous web of material.