A bulk bag conditioner assembly is disclosed herein. The assembly includes a frame assembly defining a bulk bag conditioning area. The frame assembly includes a first carrier frame with a first ram, and a second carrier frame with a second ram. A first actuator assembly includes a first end fixed to the first carrier frame and a second end fixed to the second carrier frame. A second actuator assembly includes a first end fixed to the first carrier frame and a second end fixed to the second carrier frame. A control unit is configured to simultaneously drive the first ram and the second ram linearly towards each other to engage a bulk bag within the bulk bag conditioning area.

The invention relates to a method for forming package bodies open at one end from package sleeves open at both ends for the manufacture of filled packages. In order to allow packages with a cross section which is neither square nor rectangular to be formed more simply and reliably, the package sleeves are kept ready for further processing in a stack, folded flat along at least two folded edges running in the longitudinal direction of the package sleeve, the flat-folded package sleeves are transferred in succession from the stack to a forming station, the package sleeves are unfolded in a forming station and the unfolded package sleeves are, in the forming station, pushed onto a mandrel in order to close, in particular seal, a longitudinal end of the package sleeve.

The invention relates to a method for forming package bodies open at one end from package sleeves open at both ends for the manufacture of filled packages. In order to allow packages with a cross section which is neither square nor rectangular to be formed more simply and reliably, the package sleeves are kept ready for further processing in a stack, folded flat along at least two folded edges running in the longitudinal direction of the package sleeve, the flat-folded package sleeves are transferred in succession from the stack to a forming station, the package sleeves are unfolded in a forming station and the unfolded package sleeves are, in the forming station, pushed onto a mandrel in order to close, in particular seal, a longitudinal end of the package sleeve.

A container manufacturing method includes: a liquid discharge step in which a predetermined amount of liquid (L) in the container (C) is discharged to the outside by supplying pressurized air from air holes (13) provided in a blow molding mold (11) to a cavity (12) and pushing an outer surface of the container (C) after molding by the air; and a headspace forming step in which a headspace (HS) is formed in the container (C) by separating a filling nozzle (22) from a mouth portion (Ca) of the container (C) in a state in which a predetermined amount of liquid (L) is discharged to the outside.

Improvements in the cold pack with a sustained temperature of between 17-40 degrees Fahrenheit for over 2 hours and as long as 9 hours. The aloe and polyacrylamide cold pack can be configured so it does not continually condense or drip water for over 2 hours when using the ingredients of Ammonium C12-C15, Pareth Sulfate Ammonium C12-C15, Pareth Sulfate, Sodium Chloride, Poloxamer 124 DMDM Hydantoin Pent sodium Pentatate, Sodium Bisulfite. The main ingredients in regulating the ice pack temperature, longevity and hardness is the aloe, H2O and polyacrylamide ratio.

Method for processing hot-filled plastic containers are provided. In some embodiments, the method may include hot-filling a plastic container, sealing the container, and conveying the sealed container, each with an inner annular wall and a push-up portion in a first position. In some embodiments, the method may further include creating a vacuum pressure in the hot-filled and sealed container and repositioning the push-up portion from the first position to a second position under a mechanical force.

Method for processing hot-filled plastic containers are provided. In some embodiments, the method may include hot-filling a plastic container, sealing the container, and conveying the sealed container, each with an inner annular wall and a push-up portion in a first position. In some embodiments, the method may further include creating a vacuum pressure in the hot-filled and sealed container and repositioning the push-up portion from the first position to a second position under a mechanical force.

The invention relates to a jam detecting device (10) for detecting defective packages in a filling machine. The jam detecting device (10) comprises a movable element 5 (12), and a sensor (13) connected to the movable element (12). The jam detecting device (10) is adapted to be positioned in the filling machine such that any defective package will mechanically raise the movable element (12) when passing the same and thereby trigger the sensor (13). The invention also relates to a method for detecting defective packages in a filling machine, and a folding unit (1) and a filling machine for producing packages (2) of pourable food products from sealed packs (3).

The invention relates to a jam detecting device (10) for detecting defective packages in a filling machine. The jam detecting device (10) comprises a movable element 5 (12), and a sensor (13) connected to the movable element (12). The jam detecting device (10) is adapted to be positioned in the filling machine such that any defective package will mechanically raise the movable element (12) when passing the same and thereby trigger the sensor (13). The invention also relates to a method for detecting defective packages in a filling machine, and a folding unit (1) and a filling machine for producing packages (2) of pourable food products from sealed packs (3).

Packages made from flexible material, wherein the packages include one or more self-folds formed by applying activation energy to the flexible material are presented. The packages include a polymeric film, wherein the polymeric film is formed from one type of polymer, and wherein the flexible material defines an enclosed product volume. The packages include a first panel formed from the flexible material and a second panel formed from the flexible material. The packages include a self-fold that has an overall thickness that is about 5% to about 30% greater than a thickness of the flexible material outside of the self-fold. The self-fold has a differential thermal-mechanical set than the flexible material outside of the self-fold, and forms an angle of about 100 degrees to about 170 degrees between the first panel and the second panel.