A device for producing filled containers has a transport device which is configured for transporting containers which are filled with a liquid and are closed by a closure. Furthermore, the apparatus has a penetration device which is configured for producing an opening in at least one region of the closure and/or of the container, and an application device, which applies a flowable and in particular gaseous medium to the interior of the container through this opening (or feeds the gaseous medium to this interior). Furthermore, the apparatus has a closing device which closes the opening again.

A sealing bolt for sealing a container (e.g. for fissile materials), the sealing bolt adapted to cooperate, in use, with a locking device for locking a container lid to a container body of the container. The sealing bolt includes an upper part (i.e. adapted to be manipulated by an operator using a tool), a lower part (cooperating with the locking device 46) and an axial rod connecting the upper and lower parts, the upper part, lower part and axial rod being arranged coaxially about an axis. An integrity element is disposed in the upper part and a release arrangement (a detachable conical end-piece 24 retained by a ball 34 and recess 32 arrangement) is disposed so as to be releasably attached to the lower part. The sealing bolt is movable, through a first operator actuation of the upper part, from a first state, in which the integrity element is intact, to a second state, in which the integrity element of the sealing bolt is visibly broken. The sealing bolt is movable, through a second operator actuation of the upper part, from the second state to a third state, in which the release arrangement is released, thereby enabling disengagement of the locking device and removal of the lid from the container body. A locking system for a container, a method of releasably sealing a container, and a method of unsealing a container, are also disclosed.

A sealing bolt for sealing a container (e.g. for fissile materials), the sealing bolt adapted to cooperate, in use, with a locking device for locking a container lid to a container body of the container. The sealing bolt includes an upper part (i.e. adapted to be manipulated by an operator using a tool), a lower part (cooperating with the locking device 46) and an axial rod connecting the upper and lower parts, the upper part, lower part and axial rod being arranged coaxially about an axis. An integrity element is disposed in the upper part and a release arrangement (a detachable conical end-piece 24 retained by a ball 34 and recess 32 arrangement) is disposed so as to be releasably attached to the lower part. The sealing bolt is movable, through a first operator actuation of the upper part, from a first state, in which the integrity element is intact, to a second state, in which the integrity element of the sealing bolt is visibly broken. The sealing bolt is movable, through a second operator actuation of the upper part, from the second state to a third state, in which the release arrangement is released, thereby enabling disengagement of the locking device and removal of the lid from the container body. A locking system for a container, a method of releasably sealing a container, and a method of unsealing a container, are also disclosed.

A seal cover for sealing a filling tube of a container, includes a cover wall and a cover plate. An outer wall of the filling tube is provided with external threads; the seal cover includes an inner cover body and an outer cover body; the cover wall encloses a barrel structure, with one end sealed by the cover plate, and the other end being an open end; an inner surface of the cover wall is provided with internal threads matched with the external threads of the filling tube; a boss is formed on an end face of the open end of the inner cover body; the filling tube is provided with a wedge block; the external threads of the filling tube and the internal threads of the inner cover body are screwed with each other.

A method that protects helium balloons, which are shipped via shipping routes that expose the balloons to elevated temperatures that cause the balloons to lose helium gas at increased rates, from such effects includes providing a shipping box; lining the shipping box with a metalized sheet that provides insulation against heat conduction; placing at least one balloon in the lined shipping box; surrounding the at least one balloon with the metalized sheet from all sides thereof; closing the box; and shipping the box to a customer, whereby the balloons are rendered less susceptible to the elevated temperatures or reduced ambient pressures while travelling over the shipping routes.

Disclosed herein are methods and systems of preparing containment vessels which contain a precise volume of fluid. An auger filler, comprising a rotor and a stator, may dispense this precise volume of fluid into a containment vessel when the rotor is rotated relative to the stator in a first direction, causing fluid contained the auger filler to be dispensed into the containment vessel, until the precise volume of fluid is dispensed. The rotor may then be rotated relative to the stator in a second direction to prevent more fluid from being dispensed, ensuring that the containment vessel is not significantly overfilled past this precise volume of fluid. The containment vessel may then be sealed to define a prepared containment vessel. The methods and systems herein may allow for a continuous process flow that continuously produces prepared containment vessels, with each being near identical to one another.

Disclosed herein are methods and systems of preparing containment vessels which contain a precise volume of fluid. An auger filler, comprising a rotor and a stator, may dispense this precise volume of fluid into a containment vessel when the rotor is rotated relative to the stator in a first direction, causing fluid contained the auger filler to be dispensed into the containment vessel, until the precise volume of fluid is dispensed. The rotor may then be rotated relative to the stator in a second direction to prevent more fluid from being dispensed, ensuring that the containment vessel is not significantly overfilled past this precise volume of fluid. The containment vessel may then be sealed to define a prepared containment vessel. The methods and systems herein may allow for a continuous process flow that continuously produces prepared containment vessels, with each being near identical to one another.

The present invention discloses an equipment for winding medical tubing, employing automated, sequentially-arranged workstations (1, 5, 7) capable of operating simultaneously, comprising one or more conveying units (2), one or more bending units (3) for arranging medical tubing (10) in a U shape, one or more loading units (4), one or more winding stations (5) for winding medical tubing (10), one or more unloading units (6) and, optionally, one or more packaging units (7).

Method for manufacturing a pressurising device for a beverage container, wherein a gas container is provided having a filling opening, into which gas container an amount of dry ice is inserted through the filling opening, where after the filling opening is closed and the dry ice is allowed to sublimate.

Method for manufacturing a pressurising device for a beverage container, wherein a gas container is provided having a filling opening, into which gas container an amount of dry ice is inserted through the filling opening, where after the filling opening is closed and the dry ice is allowed to sublimate.