The present disclosure relates to a method of forming a paperboard packaging container from a rectangular body blank, the method comprising the steps of providing a rectangular body blank having a first end edge and a second side edge, forming a tubular container body from the rectangular body blank, sealing together the first and the second side edge of the body blank, closing the first end opening by pressing a paperboard disc into the first end opening, pressing the first end of the tubular container body into a curl forming portion of a curling tool, filling the packaging container with bulk solids, and closing the second end opening.

This invention relates to an apparatus for manufacturing a container, the container being made of paperboard and being formed from at least two elements adhered together. An apparatus for use in manufacturing a container comprises a first inlet connected to a supply of dry steam; a second inlet connected to a supply of hot air; a mixing chamber, the first inlet and the second inlet being fluidly connected to the mixing chamber such that a flow of dry steam from the first inlet mixes with a flow of hot air from the second inlet; and a delivery nozzle fluidly connected to the mixing at least one of said elements.

This invention relates to an apparatus for manufacturing a bottle, the bottle comprising an inner pouch and an outer paperboard shell, the shell being made from a sheet blank comprising a main body panel, a first neck panel and a second neck panel. An apparatus for use in manufacturing a bottle comprises a former having a cavity for receiving said pouch, the former comprising a main body section, a neck section and a shoulder section extending between the main body section and the neck section; at least two neck press elements, each neck press element including a press surface facing and aligned with at least a part of the neck section of the former, and each neck press element being moveable into a clamping position to clamp a part of one of said neck panels between the neck press element and the neck section of the former; and at least two shoulder press elements, each shoulder press element including a press surface facing and aligned with the shoulder section of the former, and each shoulder press element being moveable into a

A packaging box is disclosed, able to have smoothly curved wall portions. The box includes a perimeter wall defining a void thereby. The perimeter wall includes a first fold line and a second fold line. The first fold line and the second fold line may be parallel. A distance around the perimeter wall from the first fold line to the second fold line measured in a first plane perpendicular to the first and second fold lines in a first rotational sense is the same as a distance around the perimeter wall from the first fold line to the second fold line in the first plane in a second rotational sense opposite to the first rotational sense. When the first fold line is fully unfolded, the perimeter has a continuous surface including the first fold line. A tube, blank, method and machine for forming the box are also disclosed.

Described are methods, systems, and apparatus relating to a modular data center. In some embodiments, a modular data center includes one or more data modules. The modular data center includes a network module connected to the one or more data modules, the network module containing equipment for facilitating data communications by the one or more data modules. The modular data center includes a power module connected to the one or more data modules and the network module, the power module containing electronics equipment for conditioning and distributing power to the one or more data modules and the network module. In the modular data center, each module of the one or more data modules, the network module, and the power module comprises: an enclosure defining an internal space; a floor within the enclosure separating the internal space into an above-floor space and a sub-floor space; and a plurality of bays in the subfloor space, each bay of the plurality of bays configured to contain a field-replaceable environmental management component.

An apparatus for forming an upper edge of a paperboard container includes a pocket including a shell having a cavity with a mouth configured to receive the container along an axis such that the rim extends beyond the mouth. A workstation includes a forming member having a first forming surface which is actuatable toward the axis from a retracted position spaced from the rim to an extended position lying adjacent an upper end of the rim, and a forming segment having a second forming surface which is actuatable along the axis and the forming member in response to axial movement thereof such that the second forming surface is positioned spaced from a lower end of the rim. The second forming surface is actuatable along the axis towards the first forming surface to form the rim therebetween.

Described are a machine and a method for forming containers from blanks, including a plurality of shaping hoppers, an endless conveyor which defines a feed path and on which the hoppers are mounted in succession and a plurality of pushing elements which are movable in such a way as to follow the respective shaping hoppers along at least a stretch of the feed path and which have a to-and-fro operating movement towards and away from the respective hopper along a direction transverse, preferably perpendicular, to the feed path. The machine also includes folding means disposed along the feed path downstream of the pushing elements and configured to produce, respectively, a top closure and/or a bottom closure of the tubular blank.

A coating process of a segmented paper pulp bottle blank includes: S1, placing a film raw material into a bottle blank to be coated; S2, folding an upper edge of the film raw material to fix the upper edge onto a mouth of the bottom blank; S3, placing the bottle blank fixed with the film raw material into a coating mold; S4, placing a hot-air blowing pipe into the bottle blank; and S5, sucking air by the coating mold to absorb the bottle blank onto inner cavity walls of the coating mold, blowing in hot air by the hot-air blowing pipe to make the film raw materia1, after being heated and softened, to be expanded and adhered to the inner wall of the bottle blank, and finally opening the coating mold to take out a finished product. Moreover, a production process of a segmented paper pulp bottle is provided.

A method and device for thermal activation of tube-shaped packaging sleeves made of cardboard/plastic composite material, wherein a hot gas is applied to the tube-shaped packaging sleeve by a heating device in order to produce the base or the head of the packaging. To achieve even heating for the activation of the contact surfaces with production using simple construction, wherein the energy required for the activation process is used as completely as possible for the heating of the surfaces to be activated, the heating device is placed into effective contact with the surfaces to be activated by the heating device being moved inside the tube-shaped packaging sleeves for activation. The heating device has at least one nozzle element with an outlet opening, the external shape of which nozzle element corresponds to the internal shape of the end of the tube-shaped packaging sleeve to be activated.

An anvil device (10) is for insertion into an end closure of a partially formed container. The anvil device (10) comprises a bracket (12) and an anvil body (14) connected to one end of the bracket (12). The anvil body (14) comprises four corners (C1 to C4) where the distance between one pair of diagonally opposite corners (C1, C3) is less than the distance between the other pair of diagonally opposite corners (C2, C4). The anvil body (14) is asymmetric and one corner (C1) is closer to the centre of the anvil body (14) than each of the other three corners (C2 to C4).