In some embodiments, a sealing and pressure dosing apparatus may be provided. The sealing and pressure dosing apparatus may include a sealing machine having one or more of a driven turret, a sealing head, a pressure sealing member, and a pressure sealing chamber. The sealing and pressure dosing apparatus may also include a pressure dosing system which may be integrated with the sealing machine.

An automated drum manipulation system and methods include at least one among an automated drum rotator, bung locator, bung plug extractor and bung plug installer. The bung locator includes at least two spaced-apart bung location sensors and at least one downwardly-extending foot spaced outwardly relative to the sensors and configured to rest upon the drum's outer rim, positioning the sensors over the upper surface of the drum so they can concurrently detect the presence of opposing sides of the lip of the drum's bung opening as the drum is rotated below the bung locator.

Systems, methods, and apparatuses for sealing bottles with a Roll-on Pilfer Proof (ROPP) closure and a childproof overcap are provided. More specifically, the present disclosure relates to an overcap that can be placed onto or formed onto the ROPP closure. The overcap has a retainer that secures the overcap to the ROPP closure and allows the overcap to move relative to the ROPP closure in a longitudinal axis. The overcap moves between a first position or mode of operation where the overcap can rotate about the ROPP closure and a second position or mode of operation where the overcap engages the ROPP closure to transmit a twisting or torque force to the ROPP closure and open the bottle.

Systems, methods, and apparatuses for sealing bottles with a Roll-on Pilfer Proof (ROPP) closure and a childproof overcap are provided. More specifically, the present disclosure relates to an overcap that can be placed onto or formed onto the ROPP closure. The overcap has a retainer that secures the overcap to the ROPP closure and allows the overcap to move relative to the ROPP closure in a longitudinal axis. The overcap moves between a first position or mode of operation where the overcap can rotate about the ROPP closure and a second position or mode of operation where the overcap engages the ROPP closure to transmit a twisting or torque force to the ROPP closure and open the bottle.

A pharmaceutical order filling system uses a physical parameter that occurs during attaching cap to a pharmaceutical container to determine if the cap is properly engaged. The physical parameter may be torque on the cap when placed on the container. An order processing device receives a pharmaceutical order and sends the order to a dispensing device that fills the container with a pharmaceutical in the pharmaceutical order. A cap device is configured to apply the cap the container containing the pharmaceutical from the dispensing device, wherein the cap device is configured to sense the physical parameter, e.g., torque, to the cap when applying the cap to the container.

A closure head for closing a container with a container closure, for example for closing a container with a screw closure in a beverage filling system is described. The closure head includes a gripping mechanism for gripping the container closure with at least one gripping arm that can be pivoted about a bearing, and a holding jaw disposed on the gripping arm for holding the container closure. The holding jaw is locked on the gripping arm by means of a pre-tensioned pressure pin.

A container having an inverted active cage generally includes an enclosed base portion, a body portion extending upwardly from the base portion, and a top portion with a finish extending upwardly from the body portion. The body portion further includes a central longitudinal axis, a periphery, a plurality of rigidified and non-active surfaces, and a network of pillars or channels. Unlike the prior art, each of the plurality of non-active surfaces is outwardly displaced with respect to the longitudinal axis, while each of the network of pillars or channels is inwardly displaced with respect to the longitudinal axis. The plurality of rigidified or non-active surfaces, together with the network of rigidified channels or pillars, are spaced about the periphery of the container in order to accommodate vacuum-induced volumetric shrinkage of the container resulting from a hot-filling, capping and cooling thereof.

A container having an inverted active cage generally includes an enclosed base portion, a body portion extending upwardly from the base portion, and a top portion with a finish extending upwardly from the body portion. The body portion further includes a central longitudinal axis, a periphery, a plurality of rigidified and non-active surfaces, and a network of pillars or channels. Unlike the prior art, each of the plurality of non-active surfaces is outwardly displaced with respect to the longitudinal axis, while each of the network of pillars or channels is inwardly displaced with respect to the longitudinal axis. The plurality of rigidified or non-active surfaces, together with the network of rigidified channels or pillars, are spaced about the periphery of the container in order to accommodate vacuum-induced volumetric shrinkage of the container resulting from a hot-filling, capping and cooling thereof.

A storage system includes a plurality of vessels each shaped to engage with an adjoining vessel in a top-to-bottom orientation. The volume of the vessels may vary. The lip of each vessel includes a plurality of radially positioned flanges, and the bottom of each vessel includes a plurality of radially positioned locking lugs that correspond and engage with the flanges upon rotation of one vessel relative to the other.

A storage system includes a plurality of vessels each shaped to engage with an adjoining vessel in a top-to-bottom orientation. The volume of the vessels may vary. The lip of each vessel includes a plurality of radially positioned flanges, and the bottom of each vessel includes a plurality of radially positioned locking lugs that correspond and engage with the flanges upon rotation of one vessel relative to the other.