Apparatuses and methods for tamping the contents of a container are disclosed. An embodiment of an apparatus includes a tamp head for tamping the contents of the container; and a container support assembly structured and arranged to temporarily support the bottom surface of the container during tamping, the container support assembly comprising a support element having a protrusion extending upward from a substantially flat and horizontal upper surface, wherein the protrusion is sized and shaped to correspond to the size and shape of the bottom surface of the container.

An apparatus configured to provide portioned instances of a compressible material includes a channel assembly, a gas source, a cutting assembly, and a discharge assembly. The channel assembly holds a bulk instance of the material extending through upper and lower channels of a continuous channel. The gas source supplies gas to compress the bulk instance. The cutting assembly moves in relation to the channel assembly to isolate the upper and lower channels, severing upper and lower material portions of the bulk instance. The discharge assembly directs gas to impinge on a lower face of the cutting assembly to discharge the lower material portion as a portioned instance. The channel assembly may be moveable, where operation of the gas source, cutting assembly, and/or discharge assembly are based on moving the channel assembly between various positions. The gas supply may be controlled based on a determined property of the portioned instance.

An apparatus configured to provide portioned instances of a compressible material includes a channel assembly, a gas source, a cutting assembly, and a discharge assembly. The channel assembly holds a bulk instance of the material extending through upper and lower channels of a continuous channel. The gas source supplies gas to compress the bulk instance. The cutting assembly moves in relation to the channel assembly to isolate the upper and lower channels, severing upper and lower material portions of the bulk instance. The discharge assembly directs gas to impinge on a lower face of the cutting assembly to discharge the lower material portion as a portioned instance. The channel assembly may be moveable, where operation of the gas source, cutting assembly, and/or discharge assembly are based on moving the channel assembly between various positions. The gas supply may be controlled based on a determined property of the portioned instance.

An apparatus for packaging of loose product includes a loading station, a box forming station and an uploading station. The loading station includes moveable chutes in spaced apart relation. Each chute has an open top, an open upstream end, and an open downstream end. The open top is configured to receive loose product while moving along a first feed path. The box forming station is operable to partially erect boxes in spaced apart relation with first and second open sides and align the first open side of each box with the downstream end of a corresponding chute while moving along a second feed path. The unloading station includes a stationary vacuum head in communication with the second open side of each box. The vacuum head provides a continuous vacuum source along the second feed path operable to move loose product from the chute into the boxes.

An apparatus for packaging of loose product includes a loading station, a box forming station and an uploading station. The loading station includes moveable chutes in spaced apart relation. Each chute has an open top, an open upstream end, and an open downstream end. The open top is configured to receive loose product while moving along a first feed path. The box forming station is operable to partially erect boxes in spaced apart relation with first and second open sides and align the first open side of each box with the downstream end of a corresponding chute while moving along a second feed path. The unloading station includes a stationary vacuum head in communication with the second open side of each box. The vacuum head provides a continuous vacuum source along the second feed path operable to move loose product from the chute into the boxes.

In an example embodiment, an apparatus for making pouch products includes a conveyor system. The conveyor system includes a first receiving location along a path of the conveyor system, and a dosing location along the path of the conveyor system. The apparatus also includes a first material dispensing station configured to transfer a first material to the first receiving location. The first material includes a first elastic layer and a first support layer. The first material dispensing station includes a dispenser roller configured to hold a roll of the first material, a plurality of rollers configured to convey the first material from the dispenser roller to the first receiving location, and a stripper plate configured remove at least a portion of the first support layer from a portion of the first elastic layer.

In an example embodiment, an apparatus for making pouch products includes a conveyor system. The conveyor system includes a first receiving location along a path of the conveyor system, and a dosing location along the path of the conveyor system. The apparatus also includes a first material dispensing station configured to transfer a first material to the first receiving location. The first material includes a first elastic layer and a first support layer. The first material dispensing station includes a dispenser roller configured to hold a roll of the first material, a plurality of rollers configured to convey the first material from the dispenser roller to the first receiving location, and a stripper plate configured remove at least a portion of the first support layer from a portion of the first elastic layer.

An apparatus and methods for producing at extremely high production speeds small pouches filled with tobacco or other granular, powdered or solid content is provided. An endless web substrate, with or without flavor film thereon, is formed into a tubular shape with a longitudinal seam. The tube is cut to individual lengths, and a procession of tubes is crimp-closed at one end, filled and crimp-closed at the other end to complete pouch production. During production, the seams formed at the crimped ends of the pouch are parallel to one another and the longitudinal seam of the pouch is midway between the sides of the pouch and orthogonal to the seams formed at the crimped ends of the pouch.

An apparatus and methods for producing at extremely high production speeds small pouches filled with tobacco or other granular, powdered or solid content is provided. An endless web substrate, with or without flavor film thereon, is formed into a tubular shape with a longitudinal seam. The tube is cut to individual lengths, and a procession of tubes is crimp-closed at one end, filled and crimp-closed at the other end to complete pouch production. During production, the seams formed at the crimped ends of the pouch are parallel to one another and the longitudinal seam of the pouch is midway between the sides of the pouch and orthogonal to the seams formed at the crimped ends of the pouch.

Systems and methods for metering a granular material for packaging in pouches are disclosed. A system includes a hopper structured and arranged to hold a granular material in a hopper cavity. The system also includes a measuring system including a measuring cavity and a tube that is slidable in the hopper cavity between a first position unaligned with the measuring cavity and a second position over and aligned with the measuring cavity. The measuring system is structured and arranged to move a portion of the granular material from the hopper cavity to the measuring cavity when the tube is in the first position. The measuring system is structured and arranged to move the portion of the granular material from the measuring cavity to a pouch making machine using pressurized gas when the tube is in the second position.