Filling device for filling an aerosol container with a liquid, such as paint, which device comprises a cup for the liquid for the aerosol container, which cup is provided with an injection opening at its bottom surface; a pusher element for pushing the liquid from the cup via the injection opening to the aerosol container; and a piston head that is adapted to be detachably fixed on the end of the pusher element to be in contact with the liquid in the cup when the liquid is transferred from the cup to the aerosol container, which piston head is in the form of a scrap-er in continuous contact with the side wall of the cup during the liquid transferring operation, wherein the detachable fixing of the piston head allows the piston head to be withdrawn together with the pusher element from the cup after the liquid transferring operation is done.

An assembly of the present invention is designed specifically for filling vaporizer cartridges, pods, and other personal vaporizer systems with high viscosity extracts (oils). The assembly includes three main components such as the syringe station, the control box, and foot pedal. The control box includes the software to operate the assembly. The control box has controls for temperature and air pressure (for purging the vessel). The foot pedal operates the syringe for filling cartridges. The syringe station consists of a heated vessel, and a heated pneumatically operated syringe. The syringe system can be used in this configuration and can also be used as part of a larger, fully automated filling machine without limiting the scope of the present invention. The syringe system works well with viscous liquids.

An assembly of the present invention is designed specifically for filling vaporizer cartridges, pods, and other personal vaporizer systems with high viscosity extracts (oils). The assembly includes three main components such as the syringe station, the control box, and foot pedal. The control box includes the software to operate the assembly. The control box has controls for temperature and air pressure (for purging the vessel). The foot pedal operates the syringe for filling cartridges. The syringe station consists of a heated vessel, and a heated pneumatically operated syringe. The syringe system can be used in this configuration and can also be used as part of a larger, fully automated filling machine without limiting the scope of the present invention. The syringe system works well with viscous liquids.

The invention relates to a system for introducing an additive into a container (2). The system comprises an automated device for transporting the container (2) in a horizontal plane (P), such as a rotary wheel. The system further comprises a static microdoser (5) having a nozzle from which a jet (7) of an additive issues upon passage of an opening of the container (2). Additive is so injected into said container (2). According to the invention, the nozzle of the static microdoser (5) is inclined relative to a direction orthogonal to said horizontal plane (P). This limits splashing, in particular when the jet (7) of additive hits an inner wall of the container (2) that is free of liquid. This can be facilitated by an acceleration applied on the container (2) which inclines the free surface (8) of the liquid material present in the container (2). A preferred application is the introduction of a flavored concentrate into a bottle of water.

The invention relates to a system for introducing an additive into a container (2). The system comprises an automated device for transporting the container (2) in a horizontal plane (P), such as a rotary wheel. The system further comprises a static microdoser (5) having a nozzle from which a jet (7) of an additive issues upon passage of an opening of the container (2). Additive is so injected into said container (2). According to the invention, the nozzle of the static microdoser (5) is inclined relative to a direction orthogonal to said horizontal plane (P). This limits splashing, in particular when the jet (7) of additive hits an inner wall of the container (2) that is free of liquid. This can be facilitated by an acceleration applied on the container (2) which inclines the free surface (8) of the liquid material present in the container (2). A preferred application is the introduction of a flavored concentrate into a bottle of water.

A filling device for dosed filling of a product from a product storage container into product dose receiving containers provided in a disposable isolator so to be protected against contamination. The device includes means for holding the product storage container together with the contents outside of the disposable isolator. The device includes a controllable product removal device for a dosed removal of the product from the product storage container. The device includes a product dispensing device for the dosed dispensing of the product to the product dose receiving containers. The device includes a line assembly interconnecting the product storage container and the product dispensing device to conduct the product to the product dispensing device. The device includes at least one ultrasonic flowmeter outside of the disposable isolator fixed to the outside of the line assembly to detect the flow rate. The device includes a controller for measuring the product dose.

A dosing unit for a machine for producing unit dose articles includes a plurality of nozzles carried by respective movable elements and associated to fluid delivery lines, and a plurality of controlled valves associated to respective actuators and arranged for selectively opening and closing a passage of fluid through said fluid delivery lines.

A dosing unit for a machine for producing unit dose articles includes a plurality of nozzles carried by respective movable elements and associated to fluid delivery lines, and a plurality of controlled valves associated to respective actuators and arranged for selectively opening and closing a passage of fluid through said fluid delivery lines.

A manifold for control of fluid and/or vapor flow between a container and a pump cartridge for a compounder system is provided. One or more manifolds may be disposed in a magazine configured to secure and align the manifolds with a plurality of ports in the cartridge. Each manifold may include a needle having forward and rear openings to a central bore. A needle housing may include a slot configured to receive a push rod for actuating the needle forward and backward. In a forward, engaged position, the openings in the needle may be disposed on opposite sides of a sealing member of the manifold to form a fluid pathway through the manifold. In a rearward, disengaged position, both the forward and rear openings in the needle may be disposed on the same side of the sealing member to prevent fluid and vapor from flowing through the manifold.

A manifold for control of fluid and/or vapor flow between a container and a pump cartridge for a compounder system is provided. One or more manifolds may be disposed in a magazine configured to secure and align the manifolds with a plurality of ports in the cartridge. Each manifold may include a needle having forward and rear openings to a central bore. A needle housing may include a slot configured to receive a push rod for actuating the needle forward and backward. In a forward, engaged position, the openings in the needle may be disposed on opposite sides of a sealing member of the manifold to form a fluid pathway through the manifold. In a rearward, disengaged position, both the forward and rear openings in the needle may be disposed on the same side of the sealing member to prevent fluid and vapor from flowing through the manifold.