A packaged article is composed of a bulk bag having a top end and a bottom end. Further included is a pallet having a first side and a second side. Also included are an outer bag having a first closed end and a first open end and a heatshrink bag having a second closed end and a second open end. The first closed end of the outer bag is between the bottom end of the bulk bag and the first side of the pallet. The first open end of the outer bag is gathered over the top end of the bulk bag to enclose the bulk bag within the outer bag. The second closed end of the heatshrink bag is proximate to the top end of the bulk bag and the second open end contacts the second side of the pallet.

Disclosed is a packing system for a slide of an aircraft evacuation system, the packing system having: a rigid packboard having a first side end and a second side end that opposes the first side end; a first valise flap having a first outer end and a first inner end, the first outer end connected to the first side end of the rigid packboard; a second valise flap having a second outer end and a second inner end, the second outer end connected to the second side end of the rigid packboard; and lacing for tying together the first inner end of the first valise flap and the second inner end of the second valise flap, wherein the first valise flap and the second valise flap are formed of a heat shrink material.

Disclosed is a packing system for a slide of an aircraft evacuation system, the packing system having: a rigid packboard having a first side end and a second side end that opposes the first side end; a first valise flap having a first outer end and a first inner end, the first outer end connected to the first side end of the rigid packboard; a second valise flap having a second outer end and a second inner end, the second outer end connected to the second side end of the rigid packboard; and lacing for tying together the first inner end of the first valise flap and the second inner end of the second valise flap, wherein the first valise flap and the second valise flap are formed of a heat shrink material.

The present invention relates to a method for bundle-packaging batches of products, wherein products are moved in a longitudinal running direction, grouped into batches and wrapped with a film of heat-shrinkable film. Each wrapped batch is heated to form a contraction of each sheet around said batch. Heating of a batch is performed by the circulation of at least one heated air stream and by the expulsion of said stream toward the interior of the enclosure of an oven provided, successively, with first and second sections; the sheet is cooled; during heating, along at least a part of the first section, a first air stream is shaped discontinuously and expelled toward the interior of said enclosure. The method consists, during heating, along said second section, in shaping a second stream as an air knife and expelling said air knife toward said sheet to be smoothed.

In an installation for the treatment of containers, comprising at least one filling station and a packing station for processing film or packaging material blanks and having work components acting upon the packaging material and forming packages, at least one measuring device for dimensional deviations of filled containers, and a control unit for automatically adjusting at least one installation station depending on a dimensional deviation detected, work components in the packing station (P) acting upon the packaging material when the filled containers are packed are automatically adjustable by way of the control unit. In a method for packing filled containers, work components of the packing station acting upon packaging material are adjusted automatically depending on dimensional deviations measured in order to form packages of different dimensions with at least substantially the same packing density.

A material processing system includes an oven that cooks or bakes, with electrical resistance, dough contained within containers. The oven can include a frame defining, devices mounted, in a preselected pattern, on the frame for a reciprocal movement in a vertical direction during use of the system, each device configured to connect voltage to a respective container so as to cook or bake the dough with the electrical resistance, and one or more powered members configured to move the devices in the vertical direction. Conveyors are also provided to convey a plurality of rows of containers with a plurality of containers in each row along a material conveyance path, the conveyors disposed in a series with each other and with the oven along the material conveyance path, one of the conveyors disposed within the oven so as to position a batch of the containers in an alignment with the devices.

A method for packaging piece good batches is provided. A transport device transports a plurality of piece goods in particular in the form of a piece good flow in a specified transport direction, and a first wrapping device wraps a film element around the piece goods, the film element having a specified first width. The first wrapping device has a dispensing assembly which circulates around the piece goods, and the piece goods are supplied to the first wrapping device in order to be wrapped with the film element. The piece goods are wrapped with a strip-like element by means of a strip application device, the strip-like element having a smaller width than the film element.

A method for packaging piece good batches is provided. A transport device transports a plurality of piece goods in particular in the form of a piece good flow in a specified transport direction, and a first wrapping device wraps a film element around the piece goods, the film element having a specified first width. The first wrapping device has a dispensing assembly which circulates around the piece goods, and the piece goods are supplied to the first wrapping device in order to be wrapped with the film element. The piece goods are wrapped with a strip-like element by means of a strip application device, the strip-like element having a smaller width than the film element.

A heat shrink tunnel with width adjustment includes a pair of opposing side wall assemblies, each including an outer wall and an inner perforated wall defining a plenum therebetween. The opposing side walls define a product path with the side wall assemblies being movable toward and away from each other. A heater/blower assembly disposed in each of the opposing side walls and has an outlet directed into the product path. A shroud extends over the side wall assemblies and an open top space between the side all assemblies. The side wall assemblies extend upwardly toward an inside of the shroud so as to define a small gap between tops of the side wall assemblies and the inside of the shroud. The shroud has a bottom wall. A conveyor is configured to convey items through the heat shrink tunnel. A tunnel includes a side wall assembly width adjusting assembly to move the side walls toward and away from one another by actuation of a single actuator.

An apparatus for heat treatment of a heat shrinkable film includes a steam generation apparatus that generates steam, a heated air generation apparatus that generates heated air not lower in temperature than steam generated in the steam generation apparatus, a mixed gas generator that generates mixed gas not lower in temperature than steam generated in the steam generation apparatus by mixing steam generated in the steam generation apparatus and heated air generated in the heated air generation apparatus, a reheating apparatus that generates superheated steam by reheating mixed gas generated in the mixed gas generator, and a supply portion that supplies superheated steam generated in the reheating apparatus to a heat treatment chamber.