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.

A method and apparatus are provided for handling beads such as lyophilized beads or cryo beads to enable reliable singulation of the beads and facilitate accurate dosing. The bead handling equipment (100) includes an equipment housing (102) containing a hopper (104) and a bead dispenser (103), a gas delivery system (105), and an inspection system (120). The housing 102 may be pressurized by supplying pressurized gas to the housing 102 from the gas delivery system 105. The bead dispenser includes a piston 106 operative to singulate individual beads from the stream of beads exiting the hopper 104 and to deliver individual beads to a feed channel 108 and to a container 110. The inspection system 120 identifies bead fragments, or beads that are otherwise mis-sized, so that such beads can be rejected and not delivered to the container 110.

A method and apparatus are provided for handling beads such as lyophilized beads or cryo beads to enable reliable singulation of the beads and facilitate accurate dosing. The bead handling equipment (100) includes an equipment housing (102) containing a hopper (104) and a bead dispenser (103), a gas delivery system (105), and an inspection system (120). The housing 102 may be pressurized by supplying pressurized gas to the housing 102 from the gas delivery system 105. The bead dispenser includes a piston 106 operative to singulate individual beads from the stream of beads exiting the hopper 104 and to deliver individual beads to a feed channel 108 and to a container 110. The inspection system 120 identifies bead fragments, or beads that are otherwise mis-sized, so that such beads can be rejected and not delivered to the container 110.

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.

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.

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.

An automatic meal dispenser and a meal dispenser mechanism thereof are provided. The meal dispenser mechanism includes a dispensing module and a mixing unit that includes a body. The body has a first opening and a second opening. The dispensing module includes a shell, a dispensing component, and a first drive assembly. The shell has an inlet opening and an outlet channel. The dispensing component includes an accommodating ring. The first drive assembly is movable along a predetermined direction, and is configured to drive the dispensing component to move between a first position and a second position relative to the shell. When the dispensing component is located at the first position, the accommodating ring corresponds in position to the inlet opening and the second opening. When the dispensing component is located at the second position, the accommodating ring corresponds in position to the outlet channel.

Systems and methods for automatic filling of packaging with a food product that includes both a solid and a liquid are provided. A filling device includes: a vessel configured to hold the food product; a first piston system configured to push a portion of the food product within the vessel through a first through hole in a bottom of the vessel. The first piston system includes: a first piston; and a first sleeve that surrounds at least a portion of the first piston. The filling device further includes first actuators configured to independently actuate the first piston and the first sleeve such as to cause the portion of the food product to be pushed through the first through hole in the vessel.

Systems and methods for automatic filling of packaging with a food product that includes both a solid and a liquid are provided. A filling device includes: a vessel configured to hold the food product; a first piston system configured to push a portion of the food product within the vessel through a first through hole in a bottom of the vessel. The first piston system includes: a first piston; and a first sleeve that surrounds at least a portion of the first piston. The filling device further includes first actuators configured to independently actuate the first piston and the first sleeve such as to cause the portion of the food product to be pushed through the first through hole in the vessel.