An apparatus for closing a container with a container closure, for example for closing a drinks container with a roll-on closure, a screw type closure, a press-on closure, a crown cap and/or a press-in closure, comprising a lifting unit which can be displaced in a longitudinal direction and which has a guide unit for predetermining a position of the lifting unit in the longitudinal direction and a closure receiving member which is connected to the lifting unit via a pretensioning device for retaining a container closure and for applying the container closure to a container opening of a container which is intended to be closed with a head pressure which is predetermined by the pretensioning device, and an adjustment apparatus for automatically adjusting the head pressure which is predetermined by the pretensioning device; it further relates to a closure member which comprises an above-mentioned apparatus.

A plastic container comprises an upper portion including a finish adapted to receive a closure, a lower portion including a base, and a sidewall extending between the upper portion and the lower portion. The upper portion, the lower portion, and the sidewall define an interior volume for storing liquid contents. The plastic container further comprises a pressure panel located on the container and moveable between an initial position and an activated position. The pressure panel is located in the initial position prior to filling the container, and is moved to the activated position after filling and sealing the container. Moving the pressure panel from the initial position to the activated position reduces the internal volume of the container and creates a positive pressure inside the container. The positive pressure reinforces the sidewall. A method of processing a container is also disclosed.

A plastic container comprises an upper portion including a finish adapted to receive a closure, a lower portion including a base, and a sidewall extending between the upper portion and the lower portion. The upper portion, the lower portion, and the sidewall define an interior volume for storing liquid contents. The plastic container further comprises a pressure panel located on the container and moveable between an initial position and an activated position. The pressure panel is located in the initial position prior to filling the container, and is moved to the activated position after filling and sealing the container. Moving the pressure panel from the initial position to the activated position reduces the internal volume of the container and creates a positive pressure inside the container. The positive pressure reinforces the sidewall. A method of processing a container is also disclosed.

An aluminum bottle outsert includes an annular inner surface configured to be received and supported on an upper neck portion of an aluminum bottle. The outsert also includes an annular outer surface that has a threaded portion adapted to receive a wine bottle screw top capping assembly.

Closing machine for closing bottles or similar containers (2) using closures (3, 3a), having a plurality of closing stations (11) which each have a closing tool (12, 14) and a container carrier and are formed on the circumference of a rotor (4), which can be driven in circulation around a vertical machine axis (MA), wherein the rotor (4) has formed on it, in the region of the closing stations (11), a sterile chamber (5) which is bounded in the direction of the surroundings by walls or wall portions (6, 7, 8, 9) and into which the containers (2), which are retained in a hanging state on the container carriers, extend by way of their container mouth (2.1) which is to be closed, and wherein the respective closing tool (12, 14) extends into the sterile chamber (5) merely by way of a part which interacts with the container (2) which is to be closed and/or with the closure (3, 3a), all the rest of its functional elements being arranged outside the sterile chamber (5).

A gripping assembly for a capping head for applying caps on containers, as well as a capping head, are provided. The gripping assembly comprises a hollow body longitudinally extending along a vertical axis and internally defining a seat delimited at its lower end by an inlet mouth for the introduction of a cap. An ejector member is housed inside the hollow body such that the ejector member is free to slide axially. The gripping assembly further comprises a suspension member made of magnetic material or magnetizable material, and the ejector member carries a first magnetic element that interacts with the suspension member to determine a suspension condition of the ejector member. The magnetic interaction between the first magnetic element and the suspension member is such that the suspension condition is determined only when the ejector member is brought in close proximity of or, in contact with, the suspension member.

A welding head comprises a welding element for welding a lid to an opening device of a container, a supporting body for supporting the welding element and a compensating device for compensating a possible mutual mispositioning of the welding element and the lid during welding of the lid to the opening device, the compensating device being interposed between the supporting body and the welding element, the compensating device comprising a planar spring arrangement provided with at least one planar spring element having a first member and a second member mutually connected by deformable elements.

Disclosed is a cam curve design method for a cap screwing machine based on a multi-objective method, belonging to the technical field of cap screwing machine cam design. The present disclosure is to solve the problem that the conventional method for redesigning the cam curve cannot optimize the parameters according to the degree of importance such that the operating stability of a cam mechanism is poor. The method comprises: acquiring key point data determined for realizing the functions of a cam of the cap screwing machine; performing dimensionless processing on the key point data to obtain a dimensionless time T and a dimensionless displacement S; writing an n-order polynomial fitting cam curve displacement function, manually interpolating local control points, and obtaining a polynomial fitting cam curve expression and chart in combination with the constraints of key point displacement by using a least squares method; and selecting cam curve optimization objectives and setting weight coefficients to construct an optimized cam curve. The present disclosure is used for the design of a cam curve.

The invention relates to a capping machine comprising a protected area from impurities, an unprotected area divided from the protected area by a parting wall, and an operating unit. The operating unit includes a container support element arranged in the protected area, an operating head arranged in the protected area and configured to apply one capsule on the relative container, a motor assembly arranged in the unprotected area and configured to drive motion of the operating head, a torque control head between the motor assembly and the operating head, and an annular bellows element coaxial with the vertical axis and within the protected area and one opposite axial end crossed in a sealed manner by an output shaft of the torque control head. The torque control head is arranged above the parting wall in the unprotected area and the output shaft crosses said opening and the entire bellows element.

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.