A method is described for filling packages open on one side with flowable products in a filling machine. In order for the packages open on one side to be processed reliably, it is provided that hot air, drying air, sterilising agent and/or flowable product is introduced via at least one nozzle into packages open on one side, that the packages are moved from a starting position, before the introduction of the air, agent, and/or flowable product, into an end position, after the introduction of the air, agent, and/or flowable product, and that the packages, during the introduction of the air, agent, and/or flowable product, are moved along a straight or continuously curved transport direction defined by the starting position and the end position and are moved in a processing movement overlaying the transport direction and extending at least in sections transversely to the transport direction.

A method is described for filling packages open on one side with flowable products in a filling machine. In order for the packages open on one side to be processed reliably, it is provided that hot air, drying air, sterilising agent and/or flowable product is introduced via at least one nozzle into packages open on one side, that the packages are moved from a starting position, before the introduction of the air, agent, and/or flowable product, into an end position, after the introduction of the air, agent, and/or flowable product, and that the packages, during the introduction of the air, agent, and/or flowable product, are moved along a straight or continuously curved transport direction defined by the starting position and the end position and are moved in a processing movement overlaying the transport direction and extending at least in sections transversely to the transport direction.

A container-filling method includes executing a learning phase by starting a filling operation with a filling parameter that was used to start filling of a another product. The learning phase includes the filling element and saving relationships between a filling parameter, such as expected filling time or foam formation, and a value indicative of that filling parameter. The method includes comparing a saved target with this value to see a termination criterion has been achieved. If not, the filling parameter is varied in response to instructions provided by a simulator and the process repeated.

The present application provides an automated beverage dispenser for dispensing a beverage and ice into a cup. The automated beverage dispenser may include an ice dispensing station with an ice auger and a weight sensor, a beverage dispensing station, and a control device. The control device instructs the ice auger to fill the cup with a predetermined amount of ice and instructs the beverage dispensing station to fill the cup with a predetermined amount of the beverage in response to a weight of the cup as determined by the weight sensor.

A filling valve for liquids, includes a liquid feed into a valve chamber, a valve seat, a closure element, which interacts with the valve seat and moves between an open position and a closed position, an outlet for the liquid, and a cylindrical discharge element arranged at the outlet with a plurality of passages. The surface of the discharge element facing the closure element forms a part of the valve seat. To avoid clogging of the passages in the discharge element by fibers in the liquid, the passages ending at the surface of the discharge element are extended from the surface toward the closure element by tubes. Each tube can be closed by a cap which surrounds the tube at least in the closed position forming an annular space.

A filling valve for liquids, includes a liquid feed into a valve chamber, a valve seat, a closure element, which interacts with the valve seat and moves between an open position and a closed position, an outlet for the liquid, and a cylindrical discharge element arranged at the outlet with a plurality of passages. The surface of the discharge element facing the closure element forms a part of the valve seat. To avoid clogging of the passages in the discharge element by fibers in the liquid, the passages ending at the surface of the discharge element are extended from the surface toward the closure element by tubes. Each tube can be closed by a cap which surrounds the tube at least in the closed position forming an annular space.

A device for changing the jet shape of free-flowing products, in particular of foodstuffs, including: an inflow area for the free-flowing products to enter, an outflow area for the free-flowing products to exit, and several channels through which to pass the free-flowing products. Each channel has an inlet allocated to the inflow area and an outlet allocated to the outflow area. Each inlet of a channel has a first cross sectional area. Each outlet of a channel has a second cross sectional area. In order to make it easy to adjust the shape and velocity profile of the filling jet, it is proposed that the second cross sectional area of at least one channel be larger than the first cross sectional area of this channel.

A device for changing the jet shape of free-flowing products, in particular of foodstuffs, including: an inflow area for the free-flowing products to enter, an outflow area for the free-flowing products to exit, and several channels through which to pass the free-flowing products. Each channel includes an inlet allocated to the inflow area and an outlet allocated to the outflow area. The inlets together form an inflow surface with a width and height lying in the inflow area. The outlets together form an outflow surface with a width and height lying in the outflow area. In order to reduce splashing when filling packagings with a non-rotationally symmetrical cross section, the outflow surface is non-rotationally symmetrical.

A device for changing the jet shape of free-flowing products, in particular of foodstuffs, including: an inflow area for the free-flowing products to enter, an outflow area for the free-flowing products to exit, and several channels through which to pass the free-flowing products. Each channel includes an inlet allocated to the inflow area and an outlet allocated to the outflow area. The inlets together form an inflow surface with a width and height lying in the inflow area. The outlets together form an outflow surface with a width and height lying in the outflow area. In order to reduce splashing when filling packagings with a non-rotationally symmetrical cross section, the outflow surface is non-rotationally symmetrical.

The invention concerns a method of degasification of a carbonated beverage-filled container in an apparatus for blowing and filling containers, the apparatus comprising: a mold (12) enclosing a blown and carbonated beverage-filled container (14) that comprises a dispensing opening (16), an injection head (24) that is movable along a longitudinal axis (A) passing by the dispensing opening of the container between a sealing position in which the injection head is in a sealing engagement with the dispensing opening and a non-sealing position in which the injection head is at a distance from the dispensing opening, characterized in that the method comprises the following steps: i) moving the injection head (24) away from the sealing position (3A) to a non-sealing position (3B). ii) moving back the injection head to the sealing position (30), iii) moving the injection head away from the Position sealing position to a non-sealing position (3D).