A dosing device for feeding infusion products including a dosing drum rotating about an axis and positioned between a continuous strip of filter material, movable along a feed direction, and a primary hopper for containing a primary infusion product; the dosing drum has a plurality of radial chambers for receiving a first dose of primary infusion product from the primary hopper and for releasing the first dose of primary infusion product above the strip of filter material; the device also includes an independent dosing unit of a secondary product including controlled release elements configured for depositing a second dose of secondary product to define a mixed dose of primary product and secondary product.

A dosing device for feeding infusion products including a dosing drum rotating about an axis and positioned between a continuous strip of filter material, movable along a feed direction, and a primary hopper for containing a primary infusion product; the dosing drum has a plurality of radial chambers for receiving a first dose of primary infusion product from the primary hopper and for releasing the first dose of primary infusion product above the strip of filter material; the device also includes an independent dosing unit of a secondary product including controlled release elements configured for depositing a second dose of secondary product to define a mixed dose of primary product and secondary product.

An ice bagger is provided. The ice bagger includes an ice hopper into which ice is disposed from an ice manufacturer. The ice hopper further includes an ice agitator and defines an ice trough there beneath. An ice auger, housed inside the ice trough, transports ice to an ice delivery chute. A hatch is positioned beneath the ice delivery chute, upon which the bag rests while filling. A scale is positioned on the hatch. The scale weighs the ice being deposited into the bag. When the bag is full, the bag is sealed by a sealer. When the bag is sealed, the hatch opens and the bag of ice is deposited in an bag depository. This Abstract is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

An ice bagger is provided. The ice bagger includes an ice hopper into which ice is disposed from an ice manufacturer. The ice hopper further includes an ice agitator and defines an ice trough there beneath. An ice auger, housed inside the ice trough, transports ice to an ice delivery chute. A hatch is positioned beneath the ice delivery chute, upon which the bag rests while filling. A scale is positioned on the hatch. The scale weighs the ice being deposited into the bag. When the bag is full, the bag is sealed by a sealer. When the bag is sealed, the hatch opens and the bag of ice is deposited in an bag depository. This Abstract is submitted with the understanding that it will not be used to interpret or limit the scope or meaning of the claims.

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.

A dosing apparatus for dosing a product in powder and/or granule form within containers includes a hopper (2) provided with an internal cavity (3) to contain the product, a dosing screw (4) rotatable about, and extending along, a rotation axis (X) inside the hopper and through the internal cavity, and a first driving shaft (5) arranged to rotate the dosing screw; the dosing apparatus also includes a magnetic coupling system (10) to removably connect a first end (6) of the dosing screw (4) to the first driving shaft (5), arranged externally to the hopper (2); the magnetic coupling system includes groups of magnets (21, 22, 23, 24) adapted to magnetically transmit a driving torque from the first driving shaft (5) to the dosing screw (4) and to reversibly fasten, longitudinally along the rotation axis (X), the dosing screw (4) to the first driving shaft (5); the first end (6) of the dosing screw (4) is arranged inside the hopper (2) and the first driving shaft (5) is hermetically separated from the first end (6) of the dosing screw (4) by means of a separation element (8) that is integral with the hopper (2).

A dosing apparatus for dosing a product in powder and/or granule form within containers includes a hopper (2) provided with an internal cavity (3) to contain the product, a dosing screw (4) rotatable about, and extending along, a rotation axis (X) inside the hopper and through the internal cavity, and a first driving shaft (5) arranged to rotate the dosing screw; the dosing apparatus also includes a magnetic coupling system (10) to removably connect a first end (6) of the dosing screw (4) to the first driving shaft (5), arranged externally to the hopper (2); the magnetic coupling system includes groups of magnets (21, 22, 23, 24) adapted to magnetically transmit a driving torque from the first driving shaft (5) to the dosing screw (4) and to reversibly fasten, longitudinally along the rotation axis (X), the dosing screw (4) to the first driving shaft (5); the first end (6) of the dosing screw (4) is arranged inside the hopper (2) and the first driving shaft (5) is hermetically separated from the first end (6) of the dosing screw (4) by means of a separation element (8) that is integral with the hopper (2).

A dosing device for feeding an infusion product includes: a tower for containing product, tubular channels for feeding the product to the tower; each channel configured to pick up the product from the lower and release a quantity of product; a plurality of containers for receiving the product from the channels; a platform movable relative to the channels supporting the containers one after another. The platform is configured for carrying, in sequence, each container to a first position for feeding a quantity of product less than the weight of a programmed dose and, subsequently, to a second position for feeding a remaining quantity of product for reaching the weight of the programmed dose. A plurality of weighing elements control the weight of the product in each container and a control unit controls the quantity of product fed to each container and the relative movement of the platform.

A dosing device for feeding an infusion product includes: a tower for containing product, tubular channels for feeding the product to the tower; each channel configured to pick up the product from the lower and release a quantity of product; a plurality of containers for receiving the product from the channels; a platform movable relative to the channels supporting the containers one after another. The platform is configured for carrying, in sequence, each container to a first position for feeding a quantity of product less than the weight of a programmed dose and, subsequently, to a second position for feeding a remaining quantity of product for reaching the weight of the programmed dose. A plurality of weighing elements control the weight of the product in each container and a control unit controls the quantity of product fed to each container and the relative movement of the platform.

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.