A device for liquid-tight sealing of two partially overlapping packaging components. One of these is a tubular basic body. A further packaging component forms the packaging head or bottom, having at least one mandrel and one die. For the tubular basic body to be easily slid on to the mandrel and removed the expansion elements have sealing jaws which, in their working position, form a closed, encircling outer contour.

A method for manufacturing a plastic fuel tank including: a) inserting a plastic parison including two distinct parts into an open two-cavity mold; b) inserting a core, bearing at least part of a reinforcing element configured to create a link between the two parison parts, inside the parison; c) pressing the parison firmly against the mold cavities, for example by blowing through the core and/or creating suction behind the cavities; d) fixing the part of the reinforcing element to at least one of the parison parts using the core; e) withdrawing the core; f) closing the mold, bringing its two cavities together to grip the two parison parts around their periphery to weld them together; g) injecting a pressurized fluid into the mold and/or creating a vacuum behind the mold cavities to press the parison firmly against the mold cavities; and h) opening the mold and extracting the tank.

The invention relates to a device comprising a first fixing element, comprising a first fixing surface, a further fixing element, comprising a further fixing surface, and a folded planar composite, at least partially fixed between the first fixing surface and the further fixing surface; wherein the folded planar composite comprises a first composite region and a further composite region; wherein the first composite region comprises a first layer sequence, comprising, from the further fixing surface to the first fixing surface, a first composite layer, a second composite layer, a third composite layer and a fourth composite layer; wherein the further composite region comprises a further layer sequence, comprising, from the further fixing surface to the first fixing surface, the first composite layer, the second composite layer and the fourth composite layer; wherein the first composite layer comprises a first carrier layer, the second composite layer a second carrier layer, the third composite layer a third carrier layer, and the fourth composite layer a fourth carrier layer; wherein, in the first composite region, the first or the fourth carrier layer or each of both is characterised by a greater layer thickness than the second or the third carrier layer or each of both and in the further composite region the second carrier layer is characterised by a greater layer thickness than in the first composite region; wherein the further fixing surface comprises a recess and the first composite region and the further composite region are each at least partially located between the recess and the first fixing surface.

The present disclosure is directed to processes for producing ultrasonic sealable film structures and flexible containers with ultrasonic seals. The film structure includes a first multilayer film and a second multilayer film. Each multilayer film includes a backing layer and a seal layer. Each seal layer includes an ultrasonic sealable olefin-based polymer (USOP) having the following properties: (a) a heat of melting, Hm, less than 130 J/g, (b) a peak melting temperature, Tm, less than 125 C., (c) a storage modulus in shear (G) from 50 MPa to 500 MPa, and (d) a loss modulus in shear (G) greater than 10 MPa.

The multilayer films are arranged such that the seal layer of the first multilayer film is in contact with the seal layer of the second multilayer film. The seal layers form an ultrasonic seal having a seal strength from 30 N/15 mm to 80 N/15 mm when ultrasonically sealed at 4 N/mm seal force.

The present invention relates to an induction sealing device for heat sealing of packaging material. The sealing device comprises a conductor partly encapsulated in a supporting body for cooperation with the packaging material during sealing. The coil conductor has a reduced cross sectional area at at least one position along the coil conductor so as to concentrate the magnetic flux induced by the coil conductor at the at least one position. The invention also relates to a method of heat sealing a packaging material using the induction sealing device.

The invention relates in general terms to a device for production of a packaging precursor, wherein the packaging precursor consists to an extent of at least 80% by weight, based on the packaging precursor (1000), of a sheetlike composite, wherein the sheetlike composite includes: i. a composite plastic layer, ii. a composite carrier layer, iii. a first composite edge region, iv. a second composite edge region, wherein the device includes, as device constituents in a flow direction: a) a flat transport unit designed to transport the flat sheetlike composite, wherein the transport unit includes a transport surface designed to bear the composite; downstream of that b) a first heating unit designed to heat the first composite edge region, where the first heating unit includes energy release segments; downstream of that c) a contacting unit designed to bond the first composite edge region to the second composite edge region;
wherein the first heating unit is designed to release energy in the flow direction. The invention further relates to a method, to a packaging precursor obtainable by the method, to a packaging precursor and to a use of the device.

A fluid impervious stitching method for a seam of a vapor-permeable virus-barrier laminate. The laminate comprises: at least one thermoplastic resin fiber layer; at least one vapor-permeable virus-barrier thermoplastic elastomer film layer; and a bonding layer located between the two layers and formed of an adhesive capable of being fused with the two layers. In the stitching method, overlapping or stacking is performed to form a seam, and heat sealing is performed on the laminate at the seam. The temperature of heat sealing is higher than the melting point of a material layer having the highest melting point in the laminate, but lower than the temperature at which perforation or decomposition occurs in any material layer in the laminate. The heat-stitched seam has excellent windproof, vapor-permeable, virus barrier and liquid-barrier performance, has a smooth appearance without wrinkles, and feels soft. Also provided is a protective textile product prepared by means of the stitching method.

The present invention relates to an induction sealing device for heat sealing packaging material for producing sealed packages. The present invention also relates to a method of manufacturing such an induction sealing device. The device comprises at least one inductor made of an alloy comprising silver and copper.

There is described a unit (1, 1, 1) for forming/advancing at least one pack (3) or at least one portion of a pack (3), comprising a frame (11, 12a, 12b), a selectively activatable/deactivatable source of power (42) and at least one carriage (14a, 14b) operationally coupled with source of power (42), movable along a path (13a, 13b) comprising at least one vertical portion (18a, 18b, 19a, 19b), and adapted to convey said at least one pack (3) or said at least one portion of a pack (3); unit (1, 1, 1) comprises stopping means (45) fitted to frame (12a, 12b) and which can be operated: to leave carriage (14a, 14b) free to advance along vertical portion (18a, 18b; 19a, 19b), when source of power (42) is activated, and to stop carriage (14a, 14b) along vertical portion (18a, 18b; 19a, 19b), when source of power is, in use, deactivated.

There is described a packaging apparatus (1) for forming sealed packages (2) from a tube (3). The packaging apparatus (1) has an endless conveyor device (7) arranged in a conveyor zone (8), conveying carts (9) and operative units (10, 10) moved by the plurality of conveying carts (9) along a path (P, Q). Each operative unit (10, 10) moves between an operative configuration, in which the operative unit (10, 10) manipulates the tube (3) and a rest configuration in which the operative unit (10, 10) is detached from the tube (3). Each operative unit (10, 10) has a halfshell (36) and one of a sealing element (37a) or a counter-sealing element (37b) and each operative unit (10, 10) is carried by one respective conveying cart (9) and extends laterally away therefrom so that the conveyor zone (8) is laterally spaced apart from an operative zone (33) where the tube is manipulated.