A container comprises a substantially rigid outer container and a readily deformable inner bag, wherein the outer container and the inner bag consist of different thermoplastic plastic materials such that the outer container and the inner bag do not undergo a weld connection with one another, with a container opening and at least one pressure balancing opening in the wall of the outer container for balancing the pressure in the gap between the outer container and the inner bag when the inner bag contracts, wherein integrated into the layer of the inner bag, which is directed towards the outer container, and/or into the layer of the outer container, which is directed towards the inner bag, are microbodies, of a material which does not melt during the manufacture of the container, which produce irregularities on the surface of the layer(s) in which microbodies are imbedded.

A method for producing a shoe sole. To be able to produce the shoe sole in an economical fashion and with easily selectable spring and damping characteristics, the invention has the following steps: a) extruding a plastic hose and feeding the plastic hose into a blow mold; b) blow molding the plastic hose into a sole hollow body, wherein recesses are introduced on mutually opposing walls of the sole hollow body during the blow molding process, such that parts of the walls are brought into contact with one another and form a supporting structure between the mutually opposing walls; c) removing the blow-molded sole hollow body from the blow mold; d) at least partially filling the blow-molded sole hollow body with plastic bodies, wherein the plastic bodies are added through a first opening in the sole hollow body.

The invention relates to a method for producing a plastic article and a blow molding tool for performing the method. The method comprises extruding an approximately tube-shaped preform, dividing the melt flow within the extrusion head or separating the extrudate exiting or already exited from the extrusion head, such that a preform having an approximately C-shaped cross section is obtained, forming the preform into a hollow part within a multipart blow molding tool using differential pressure, wherein an expansion and partial preforming of the preform first takes place with the blow molding tool partially closed, then in a further step at least one insert is inserted into the interior of the partially preformed article between the not completely closed blow molding tool and through the open side of the preform, and in a further step the blow molding tool is completely closed, wherein the article is completely formed, forming at least one at least partially circumferential pinch-off seam.

A container includes a plastics pressure vessel defining a hollow interior volume suitable for containing a quantity of a liquid, and comprising an inlet/outlet aperture extending through a wall thereof, and being in fluid communication with the hollow interior thereof. An insert, manufactured from a different, harder plastics material to that of the pressure vessel is provided within the inlet/outlet aperture, which is sealingly united (fused) with a periphery of the container to be securely retained therein. The plastics pressure vessel can be blow moulded around the insert so as to sealingly unite or fuse with the insert in the region of the interface between the different materials of which vessel and insert are formed. The insert may have a series of flats machined or otherwise formed around and into its outer circumferential surface so the insert is inhibited from axially or rotationally displacing relative to the pressure vessel.

Apparatus for forming hollow containers (110), suitable to contain in particular one or more liquid or semi-liquid food products, starting from parisons (F) made of thermoplastic material. The apparatus comprises a matrix (11) defined by a pair of molds (12) cooperating with each other to define a cavity (13) shaped like the container (110) to be formed, and to define a support channel (14), configured to define an additional portion (112) of said container (110). The apparatus also comprises a forming punch (17), operatively mobile through said support channel (14) to enter into/exit from said cavity (13) so as to thrust and blow one of said parisons (F) against the walls of said cavity (13) to form at least said container (110).

A container comprises a substantially rigid outer container and a readily deformable inner bag, wherein the outer container and the inner bag consist of different thermoplastic plastic materials such that the outer container and the inner bag do not undergo a weld connection with one another, with a container opening and at least one pressure balancing opening in the wall of the outer container for balancing the pressure in the gap between the outer container and the inner bag when the inner bag contracts, wherein integrated into the layer of the inner bag, which is directed towards the outer container, and/or into the layer of the outer container, which is directed towards the inner bag, are microbodies, of a material which does not melt during the manufacture of the container, which produce irregularities on the surface of the layer(s) in which microbodies are imbedded.

A hollow body forming mold includes left and right half molds, a bottom of the left half mold is provided with a left avoidance slot, a bottom of the right half mold is provided with a right avoidance slot, a left bottom slider is disposed in the left avoidance slot, a right bottom slider is disposed in the right avoidance slot, and the left and right bottom sliders constitute a group of sliders. The mold design resolves a difficult problem that a fabrication hole exists during forming of a hollow body with a built-in component by using an existing conventional process. The hollow body forming method has the advantages of a short forming period, the high production efficiency, good combination between a built-in component and an inner wall of an fuel tank, and the high location stability.

A blow mold assembly is disclosed having removable neck insert mold components for forming features of a container for engaging a removable container closure and manually operable retention devices for releasably retaining the neck insert mold components with mating mold components of the mold assembly. Advantageously, each manually operable retention device includes a clamp mechanism movable between a release position and a clamp position by manual operation and the clamp mechanism is effective to resist forces acting on the clamp to move the clamp to a release position when the clamp is in the clamp position. Each manually operable retention device is retained with an associated mating mold component when a neck insert mold component is removed from or installed to the mold assembly.

A method for producing a plastic container by internal pressure forming including arranging a hose-shaped preform between the molding dies of a mold, formed having a mold cavity; closing the mold and forming or preforming a container from the preform by internal pressure, wherein a circumferential section of the preform is pressed through a mold gap into a chamber surrounding the mold cavity and is pressed in the chamber against claw pairs having stationary inner retaining claws and movable outer tear-away claws; and laterally moving the outer tear-away claws, causing the circumferential section between the outer tear-away claws and the inner retaining claws to be torn open and the container to be split into two container halves. Also disclosed is a mold suitable for performing the method.

The drone comprises M antennas, with in particular two offset antennas located symmetrically at the ends of two arms for the connection to the propulsion units (24), and a ventral antenna under the drone body. The radio transmission is operated simultaneously on N similar RF channels, with 2?N<M. An antenna switching circuit couples selectively each of the N RF channels to N antennas out of the M antennas according to a plurality of different coupling schemes, dynamically through a piloting logic selecting one of the coupling schemes. The selection is operated as a function of a signal delivered by the drone-borne microprocessor, as a function of the flight and signal transmission conditions, determined at a given instant.