The sampling control station comprises at least one grasping and transporting group (22) for picking up containers or bottles (16) from conveying means (18) and transporting them to at least one measuring module (21,21,21), the containers or bottles (16) being provided with a body tapered into a neck and ending with a mouth, wherein an annular ribbing (19) is foreseen at the mouth, and it is characterized in that the grasping and transporting group (22) comprises gripping means (23) connected to a mobile support structure (30), the gripping means (23) being mobile between a gripping position, in which they are engaged with the neck of the container (16) at and below the annular ribbing (19), and a release position in which they are not engaged with the container (16).

A bottle with sensors for probing and optimizing bottling line performance is disclosed. According to one embodiment a bottle, comprises an outer layer and a reservoir tube inside the outer layer that connects a reservoir inside the outer layer to a neck of the bottle. The bottle has a battery inside the outer layer and one or more sensors powered by the battery.

A capping head for applying caps on containers or bottles and a capping assembly are provided. The capping head comprises a gripping assembly having a hollow body longitudinally extending along a vertical axis and internally defining a seat for the cap, the seat being delimited at its lower end by an inlet mouth for the introduction of the cap. A moving assembly is connected to the gripping assembly for controlling the movements thereof and is hermetically separated therefrom, and an ejector member is housed inside the hollow body of the gripping assembly, in such a manner that it is free to axially slide. The ejector member carries first and second magnetic elements such that a relative axial approach of the second magnetic element towards the first magnetic element results in a translation of the ejector member towards the lower inlet mouth of the gripping assembly.

Automated setup and operation of a container capping machine is achieved by providing motors, each under computer control, to make the necessary adjustments regarding setup and operation, and a plurality of sensors and other devices adapted to send information related to container and cap configurations and machine operation to the computer.

Automated setup and operation of a container capping machine is achieved by providing motors, each under computer control, to make the necessary adjustments regarding setup and operation, and a plurality of sensors and other devices adapted to send information related to container and cap configurations and machine operation to the computer.

Method and systems for capping are described. In one embodiment, an order processing device, a cap device, a plurality of feeders and a capping implement are provided. The order processing device processes orders with containers. The cap device is adapted to cap the container and is communicatively connected to the order processing device. The cap device is adapted to receive dispensation preferences from the order processing device. The cap device includes a plurality of feeders and a capping implement. Each feeder has a unique type of crown portion of a cap for capping. The capping implement is adapted to grasp the crown portion from the feeder. The cap device is adapted to select a feeder from which to grasp the crown portion based on the dispensation preferences. Additional methods and systems are disclosed.

Method and systems for capping are described. In one embodiment, an order processing device, a cap device, a plurality of feeders and a capping implement are provided. The order processing device processes orders with containers. The cap device is adapted to cap the container and is communicatively connected to the order processing device. The cap device is adapted to receive dispensation preferences from the order processing device. The cap device includes a plurality of feeders and a capping implement. Each feeder has a unique type of crown portion of a cap for capping. The capping implement is adapted to grasp the crown portion from the feeder. The cap device is adapted to select a feeder from which to grasp the crown portion based on the dispensation preferences. Additional methods and systems are disclosed.

A capping machine for screwing a threaded cap on a threaded container having a threaded finish, the capping machine receiving the threaded cap from a cap distributor. The capping machine includes a cap guiding element provided above cap screwing belts, both being provided above a conveyor. The cap guiding element is movable between an upper position and a lower position. The cap guiding element is configured for abutting downwardly against the threaded cap when the threaded cap is in register therewith and maintaining the threaded cap in a predetermined attitude for at least part of the screwing process. The cap guiding element moves towards the lower position as the cap screwing belts screw the threaded cap on the threaded container.

Method and systems for accumulation are described. In one embodiment, a dispensing station includes a receiving opening, a dispensing opening and a storage area. The dispensing station receives and dispenses a container. A transportable storage system includes multiple partitions disposed on a carrier portion to define multiple carriage sections. The carriage sections are electronically identifiable and selectively hold or eject the container. A bin apparatus for receiving the container includes a movable portion to selectively hold and release the container. A control unit for commanding the bin apparatus to dispense the container to a desired carriage section of the transportable storage system is provided. Additional methods and systems are disclosed.

Method and systems for accumulation are described. In one embodiment, a dispensing station includes a receiving opening, a dispensing opening and a storage area. The dispensing station receives and dispenses a container. A transportable storage system includes multiple partitions disposed on a carrier portion to define multiple carriage sections. The carriage sections are electronically identifiable and selectively hold or eject the container. A bin apparatus for receiving the container includes a movable portion to selectively hold and release the container. A control unit for commanding the bin apparatus to dispense the container to a desired carriage section of the transportable storage system is provided. Additional methods and systems are disclosed.