The invention relates to a tube manufacturing method comprising steps of: enclosing a parison (14) in a mold (6) to form a blank (15) having a first end portion shaped to form a first tube head, a tubular central portion, and a second end portion shaped to form a second tube head, and cutting the tubular central portion (22) into a first skirt and a second skirt to obtain two separate tubes, namely a first tube including the first tube head and the first skirt, and a second tube including the second tube head and the second skirt.

A method for manufacturing tubular bodies (1) exhibiting an inner circumferential surface (8) and outer circumferential surface (7) for packaging tubes out of a strip-shaped film substrate (2), which exhibits at least one weldable plastic layer (3) or consists of the latter, and which encompasses a first edge face (5) extending in the longitudinal direction of the film substrate (2) or a second edge face (6) spaced apart from the first edge face (5) by the width of the film substrate (2), wherein the first edge face (5) runs at a first angle (α) relative to a first thickness extension direction on a first radially innermost border (9) of the first edge face (5), and the second edge face (6) runs at a second angle (β) relative to a second thickness extension direction on a second radially outermost border of the second edge face (6), and wherein the first and second edge faces (6) are placed opposite each other and joined together during exposure to heat, wherein the first angle (α) and second angle (β) differ in size, in that the selected first angle (α) is smaller than the second angle (β) by an angular difference of between 3° and 70°, and that the edge faces (5, 6) are situated in such a way that an outwardly open longitudinal gap (11) is delimited by the first and second edge faces (5, 6).

The invention relates to a tube head (1, 2) intended to form a packaging, the head (3, 6) being intended to be welded to a tubular skirt (8, 9) in order to form the said packaging, and the tube head (1 2) being thermoformed from a sheet (20, 21). The invention also relates to a method for manufacturing such a tube head (1, 2) and a tube with said head (3, 6).

A tubular container and container forming device and method according to the present invention provides a dispensing tubular container having a dispensing end, a sealed end, and a region along the length of the tubular container having surface variations (e.g. outward extending teeth) formed along the length of the tubular container as part of the tubular container over which a movable compression device may move, engage and be longitudinally retained as it is advanced toward the dispensing end. The teeth may have a radial and lateral wall thicknesses similar or equal to the tubular container wall thickness, to thicknesses greater than the tubular container wall thickness, and further include varying radial thickness or profile along an exterior dimension (e.g. length) of the tubular container. Also included are structures and processes to provide an injection molded polyethylene or polypropylene tubular container having longitudinal formations of desired wall thicknesses or profile.

Systems and methods are presented herein for a method of attaching a strip to a housing. An internal support member is inserted into a collapsible housing, such that it is arranged along a longitudinal axis of an inner surface of the collapsible housing. An outer support member is arranged along an outer surface the collapsible housing opposite the internal support member. A strip is positioned along the outer surface using the outer support member and the internal support member. Then the strip is permanently welded to the outer surface using a welding element. Welding is performed by a welding element located in one (or both) of the internal support member or the outer support member.

The invention concerns in particular a device for moulding an article in which the article is obtained by compression moulding a dose (14) of material in the molten state and comprises at least one orifice (23) after the compression moulding operation, said device comprising at least one die (10), one mandrel (11) cooperating with said die (10) to effect the operation of compression moulding of the dose and one orifice rod (12) sliding in said die (10), said device further comprising a shape endpiece (13) placed between the mandrel (11) and the orifice rod (12) to form the orifice (23) of the article.

A method for forming a multi-layer packaging laminate including the following steps in the mentioned order: i) providing a polyolefin film as a base layer of the laminate, wherein the base layer forms a first outer most polymer surface of the laminate, ii) applying a first polymer layer arrangement in a flowable state onto the base layer at a first application station, the first polymer layer arrangement having at least one polymer layer, iii) transporting the base layer with the applied first polymer layer arrangement to a further application station, iv) applying a second polymer layer arrangement onto the first polymer layer arrangement at the further application station, the second polymer layer arrangement having at least one polymer layer, wherein the second polymer layer arrangement forms a second outermost polymer surface of the laminate, wherein at least one of the first and the second polymer layer arrangement contains a water vapor and/or oxygen transmission polymer barrier layer, wherein the second polymer layer arrangement is applied to the first polymer layer arrangement in a flowable state.

A method for handling containers (I) of collapsible type in a filling machine (20) comprising consecutively arranged stations (S1, S2, S3, S4, S5, S6) comprising a filling station (S3) and a gas filling station (S5), the method comprising intermittently moving the containers (I) to the consecutively arranged stations (S1, S2, S3, S4, S5, S6), supplying, at the filling station (S3), liquid product into the product compartment (5) and supplying, at the gas filling station (S5), gas into the handle compartment (7). The filling station (S3) and the gas filling station (S5) are operated such that liquid product is supplied to the product compartment (5) of one of the containers (I) while gas is supplied to the handle compartment (7) of another of the containers (I). The step of supplying gas at the gas filling station (S5) comprises providing a first gas flow (Qi) at a first pressure (Pi) and delivering said first gas flow (Qi) from the nozzle (30) to the handle compartment (7) via said inlet (11), and subsequently providing a second gas flow (Q.sub.2) at a second pressure (P.sub.2), lower than said first pressure (P.sub.1), and delivering said second gas flow (Q.sub.2) from the nozzle (30) to the handle compartment (7) via said inlet (11) for establishing a target pressure (P.sub.T) inside said handle compartment (7) corresponding to said second pressure (P.sub.2).

A method comprises in sequence the steps of: dispensing a continuous polymeric extrudate in a molten state; separating from the continuous extrudate a dose substantially having the shape of a parallelepiped, the dose having a separation surface at which the dose has been separated from the continuous extrudate, the dose further having a face adjacent to the separation surface; conveying the dose towards a mould comprising a first mould part and a second mould part; shaping the dose in the mould by moving the first mould part and the second mould part one towards the other in a moulding direction arranged transversally to said face, thereby obtaining a dispensing part of a container.

The dispensing part comprises: an edge zone suitable for being joined to a container body; a neck surrounding a passage through which a product contained in the container can be dispensed; a membrane which closes the passage, the passage being intended to be opened after the shaping step, so that said product can flow out.

A combination of a sonotrode and anvil, includes a sonotrode/anvil surface and a first row of sonotrode/anvil welding contact elements. The first/second series of each of the sonotrode/anvil welding contact element of a first row includes a first/second adapted lateral surface that joins at least one part of the first/second plateau surface with at least one part of the sonotrode/anvil surface side. The first/second adapted lateral surface includes a first/second curved surface positioned between the first/second plateau surface and the first/second substantially straight surface. The first/second curved surface has a convex outward arch. The welding contact element is positioned in relation to the anvil welding contact element such that the sonotrode welding contact element is positioned during welding next to the anvil welding contact element and is provided to form at least one part of a weld seam.