A doser mechanism includes a cylindrical shell, an auger conveyor, and a check valve. The cylindrical shell includes a hollow cylinder and an end plate. The hollow cylinder at least partially defines an internal enclosure extending between first and second ends of the hollow cylinder, a first opening at the first end, and a second opening through a thickness of the hollow cylinder. The end plate covers the second end. The auger conveyor includes an auger at least partially extending through the internal enclosure through the first end. The check valve has a valve member configured to selectively cover the second opening. The check valve may cause the valve member move between a rest position and an open position to cover or expose the second opening in response to a magnitude of a force applied to the valve member from the internal enclosure through the second opening.

A device (10) for dosing a powder, in particular a pulverulent pharmaceutical, having a storage container (24) which has a storage chamber for storing a stored quantity of the powder to be dosed, wherein the storage container has a dosing opening (32), wherein the device has a dosing control element which can be movably driven and which, in a closing position, closes the dosing opening and, in at least one freeing position, frees the dosing opening for the dispensing of powder from the storage container into a target container to be filled, wherein the device has a vibration means which sets the powder in vibration in order to assist with the dispensing of powder, wherein the storage container has two container parts which are movable relative to one another and which delimit mutually connected sub-chambers of the storage chamber and each store a portion of the stored quantity of powder, wherein a first container part (28) has the dosing opening and wherein the vibration means cooperates with the first container part and thus sets the portion of the powder that is disposed in the first container part in vibration, and wherein the vibration means is uncoupled from the second container part (30).

The present document presents a system and a method for packaging powders in containers (S) through a hopper (T) and a first tube (TC) connected to the hopper (T). Air is sucked both in the area of the first tube and in the area of the hopper. The powder is then drawn directly from inside the hopper thus keeping the flow rate and the degree of compacting of the system constant. Moreover, the powder sucked inside the first tube is thus compacted and can be conveyed compacted towards the outlet. In this way it is possible to control the dosing of the product exiting from the system with high precision.

The present document presents a system and a method for packaging powders in containers (S) through a hopper (T) and a first tube (TC) connected to the hopper (T). Air is sucked both in the area of the first tube and in the area of the hopper. The powder is then drawn directly from inside the hopper thus keeping the flow rate and the degree of compacting of the system constant. Moreover, the powder sucked inside the first tube is thus compacted and can be conveyed compacted towards the outlet. In this way it is possible to control the dosing of the product exiting from the system with high precision.

An apparatus for making a canned food product in a can, the food product including a first composition and a second composition, and the apparatus includes a filling head including a first channel and a second channel for respectively directing the first composition and the second composition into the can. A first supply assembly includes a first supply container containing the first composition, and the first supply container is connected to the first channel; and a second supply assembly. The second supply assembly includes a second supply container containing the second composition; a dosing piston connected to the second supply container through a third channel; a hose connecting the dosing piston to the second channel; and one or more rotary valves between the dosing piston and the filling head.

The invention relates to a method and a production line (1) for producing pouches (2). The product line (1) comprises a supply unit (3), a deformation unit (4), a dosing unit (5), a sealing unit (6) and a cutting unit (7).

The present document presents a system and a method for packaging powders in containers (S) through a hopper (T) and a first tube (TC) connected to the hopper (T). Air is sucked both in the area of the first tube and in the area of the hopper. The powder is then drawn directly from inside the hopper thus keeping the flow rate and the degree of compacting of the system constant. Moreover, the powder sucked inside the first tube is thus compacted and can be conveyed compacted towards the outlet. In this way it is possible to control the dosing of the product exiting from the system with high precision.

Disclosed are a method and an apparatus for dosing products, a predefined amount of which is fed to a package. The dosed amount is defined by opening and closing at least one valve (1). A sleeve-type blocking element (4, 5) is arranged in a housing (3) of said valve (1). By placing said at least one blocking element (4, 5) in a manner that can be controlled or regulated, at least one recess (9, 10) located in the zone of lateral surfaces (7, 8) of the blocking element (4, 5) is disposed in such a way as to create an open or closed position and define a cross-section of an outlet 12). Preferably, the blocking elements (4, 5) are coaxially arranged relative to one another.

Disclosed are a method and an apparatus for dosing products, a predefined amount of which is fed to a package. The dosed amount is defined by opening and closing at least one valve (1). A sleeve-type blocking element (4, 5) is arranged in a housing (3) of said valve (1). By placing said at least one blocking element (4, 5) in a manner that can be controlled or regulated, at least one recess (9, 10) located in the zone of lateral surfaces (7, 8) of the blocking element (4, 5) is disposed in such a way as to create an open or closed position and define a cross-section of an outlet 12). Preferably, the blocking elements (4, 5) are coaxially arranged relative to one another.

A doser mechanism includes a cylindrical shell, an auger conveyor, and a check valve. The cylindrical shell includes a hollow cylinder and an end plate. The hollow cylinder at least partially defines an internal enclosure extending between first and second ends of the hollow cylinder, a first opening at the first end, and a second opening through a thickness of the hollow cylinder. The end plate covers the second end. The auger conveyor includes an auger at least partially extending through the internal enclosure through the first end. The check valve has a valve member configured to selectively cover the second opening. The check valve may cause the valve member to move between a rest position and an open position to cover or expose the second opening in response to a magnitude of a force applied to the valve member from the internal enclosure through the second opening.