A shrink wrapping apparatus, and associated process, includes a housing (turbine) having a wall forming a passage dimensioned to receive the associated container assembly and associated sleeve. The passage has an inlet and an outlet spaced therefrom. A steam/hot air path communicates with the passage to provide steam from an associated steam source to at least a portion of the passage in order to shrink wrap the associated sleeve on the associated container assembly as the container assembly and sleeve move through the passage. The apparatus also includes a stop member for engaging the associated container assembly and holding in the passage for a predetermined amount of time.

One embodiment is a shrink labeler for use to shrink a shrink label onto a bottle including: a containment wall having a gas/steam inlet; and a showerhead container capable of holding the bottle in close proximity to orifices disposed therein and having an aperture through which the bottle may be introduced thereinto; wherein the gas/steam inlet is coupled to a plenum disposed between the containment wall and the showerhead container.

Shrink wrap films that are customized to have a shape matching a shape of a particular part or parts are disclosed. The shrink wrap films can be formed using unique manufacturing techniques that involve heating the part or parts prior to applying the shrink wrap film. The resultant part or parts will have substantially wrinkle-free and defect-free shrink wrap film applied thereon. In some embodiments, additional functional and cosmetic features are formed in the shrink wrap film. In some embodiments, a laser cutting procedure is used to form the features in the shrink wrap film. Methods can be used to provide visually and tactilely smooth and aesthetically appealing shrink wrapped consumer products.

Disclosed is object a method for operating a retraction device of an automatic bundler that is designed to be used in a facility for processing products that are delivered in the form of bundles that each group multiple products held together with a retractable film; with the retraction device being equipped with a retraction furnace including at least one heating unit that is designed to heat the air of the furnace and at least one air circulation unit that is designed to distribute the hot air in the furnace; with the operating method including a production mode during which the bundler is adjusted to be able to produce output and a superficial standby mode that helps save energy. The superficial standby mode includes the reduction in speed of at least one air circulation unit, compared to production mode, to a non-zero value. Also disclosed is a corresponding device.

The invention relates to a shrinking a heat-shrink film around palletized goods. The heat-shrink film projects beyond the top edge of the goods stack. Firstly the heat-shrink film is shrunk in the region of a first lateral surface sub-region of the four lateral surface sub-regions of the goods stack. The shrinkage direction is from bottom to top and then the shrinkage direction is changed 90°. In a further step either, the shrinkage direction is changed a further 90°, the heat-shrink film is shrunk from top to bottom in the region of that lateral surface sub-region of the goods stack, or, the shrinkage direction is changed a further 90°, and the heat-shrink film is preheated from top to bottom in the region of that lateral surface sub-region which is located oppositely from the first lateral surface sub-region, and is then shrunk in the opposite direction from bottom to top.

The invention relates to a shrinking a heat-shrink film around palletized goods. The heat-shrink film projects beyond the top edge of the goods stack. Firstly the heat-shrink film is shrunk in the region of a first lateral surface sub-region of the four lateral surface sub-regions of the goods stack. The shrinkage direction is from bottom to top and then the shrinkage direction is changed 90°. In a further step either, the shrinkage direction is changed a further 90°, the heat-shrink film is shrunk from top to bottom in the region of that lateral surface sub-region of the goods stack, or, the shrinkage direction is changed a further 90°, and the heat-shrink film is preheated from top to bottom in the region of that lateral surface sub-region which is located oppositely from the first lateral surface sub-region, and is then shrunk in the opposite direction from bottom to top.

A method of enclosing a surgical item identification tag in a fluorinated shrink wrap, including cutting one or more elongated pieces from a shrink wrap tube to form cut shrink wrap pieces, placing cut shrink wrap pieces into cavities in a tray, inserting an identification tag into each of the cut shrink wrap pieces, heating the cut shrink wrap pieces to cause the cut shrink wrap pieces to shrink and wrap around the identification tag, sealing an upper end and lower end of the cut shrink wrap pieces.

System, assemblies, and methods for heat shrink sealing open-topped containers wherein the system includes a two-part housing or enclosure wherein a majority of a bulk roll of film material is accessible when the cover is open. The system preferably includes a movable feed roll to improve the efficiency associated with reloading operations. In a preferred aspect, the system includes a movable sealing unit that accommodates use of the lidding system with open ended containers having various sizes and shapes. In a more preferred aspect, the system includes an indicia generating device operable to label sealed containers and a knife that generates a perforation in the film during sealing operations.

The present disclosure relates to a container sleeving device, system and method for arranging sleeves on a plurality of containers, wherein the sleeves are made of tubular foil material made to pass over the circumferential outer surface of a spreading element, the container sleeving device comprising:—a spreading element configured to spread open the tubular foil material passing from a proximal spreading element portion (31) towards a distal spreading element portion (34);—a cutting unit (25) for cutting the spread-open tubular foil material to form a sleeve;—a sleeve discharge unit (28) configured to accelerate the sleeve to move over the outer surface of the distal spreading element portion so as to discharge the sleeve towards a container; wherein the distal spreading element portion and/or the proximal spreading element portion has one or more pressure regulating openings configured to regulate the pressure close to the outer surface of the distal spreading element portion and/or of the proximal spreading element portion.

The present disclosure relates to a container sleeving device, system and method for arranging sleeves on a plurality of containers, wherein the sleeves are made of tubular foil material made to pass over the circumferential outer surface of a spreading element, the container sleeving device comprising:—a spreading element configured to spread open the tubular foil material passing from a proximal spreading element portion (31) towards a distal spreading element portion (34);—a cutting unit (25) for cutting the spread-open tubular foil material to form a sleeve;—a sleeve discharge unit (28) configured to accelerate the sleeve to move over the outer surface of the distal spreading element portion so as to discharge the sleeve towards a container; wherein the distal spreading element portion and/or the proximal spreading element portion has one or more pressure regulating openings configured to regulate the pressure close to the outer surface of the distal spreading element portion and/or of the proximal spreading element portion.