The forming apparatus comprises a forming device with a tubular element adapted to form continuous tow material into a continuous tubular rod. The forming device comprises a fluid compressor for generating pressurized fluid, the fluid compressor being in fluid connection with the tubular element to provide pressurized fluid to the continuous tubular rod to heat or cool the continuous tubular rod. The forming device further comprises several fluid conduits to provide pressurized fluid from the fluid compressor to several injection sites arranged along the transport path, wherein at least two fluid conduits of the several fluid conduits comprise a pressure control unit including a pressure sensor and a pressure influencer.

The present disclosure relates to a container sleeving device, system and method for arranging sleeves on a plurality of containers, wherein the sleeves are made of tubular foil material made to pass over the circumferential outer surface of a spreading element, the container sleeving device comprising:—a spreading element configured to spread open the tubular foil material passing from a proximal spreading element portion (31) towards a distal spreading element portion (34);—a cutting unit (25) for cutting the spread-open tubular foil material to form a sleeve;—a sleeve discharge unit (28) configured to accelerate the sleeve to move over the outer surface of the distal spreading element portion so as to discharge the sleeve towards a container; wherein the distal spreading element portion and/or the proximal spreading element portion has one or more pressure regulating openings configured to regulate the pressure close to the outer surface of the distal spreading element portion and/or of the proximal spreading element portion.

A non-penetrating multi-layer continuous hose and a preparation method thereof are provided. The hose includes an outer coating, a reinforcement layer, and an inner coating. The inner coating and the outer coating can have one or more layers with different materials and have an adjustable thickness. The hose is prepared by simultaneously performing extrusion coating inside and outside the reinforcement layer rather than penetrating the fiber reinforcement layer. The hose exhibits improved layer-to-layer adhesion and has high strength, and continuous production can be achieved to meet the length requirement in various kinds of construction, which has high applicability.

A low cost biodegradable drinking straw comprising structurally non-altered corn starch mixed with one or more than one improver. The improver comprises a biological enzyme preparation and a colloid preparation. The low cost biodegradable drinking straw is made by providing 98% structurally non-altered corn starch mixed with one or more than one improver to make a biodegradable powder. The edible biodegradable powder is formed into a drinking straw shape and extruded to a drinking straw shape. When the extruded drinking straw shapes are cooled, they are cut into an appropriate drinking straw length. The cut drinking straws are then dried and packaged.

A method includes mixing a solvent with a dry cathode mixture to form a slurry. The dry cathode mixture includes a cathode active material, a conductive diluent, and a polymeric binder. The method further includes removing the solvent from the slurry to form a composition and calendering, in a first calendering step, the composition to form a sheet. The calendering the composition includes passing the composition between calender rollers.

A versatile silicone resin reflective substrate which exhibits high reflectance of high luminance light from an LED light source over a wide wavelength from short wavelengths of approximately 340-500 nm, which include wavelengths from 380-400 nm near lower limit of the visible region, to longer wavelength in the infra-red region. The silicone resin reflective substrate has a reflective layer which contains a white inorganic filler powder dispersed in a three-dimensional cross linked silicone resin, the inorganic filler powder having a high reflective index than the silicone resin. The reflective layer is formed on a support body as a film, a solid, or a sheet. The silicone resin reflective substrate can be easily formed as a wiring substrate, a packaging case or the like, and can be manufactured at low cost and a high rate of production.

A method of manufacturing a piezoelectric microactuator having a wrap-around electrode includes forming a piezoelectric element having a large central electrode on a top face, and having a wrap-around electrode that includes the bottom face, two opposing ends of the device, and two opposing end portions of the top face. The device is then cut through the middle, separating the device into two separate piezoelectric microactuators each having a wrap-around electrode.

A method for producing a composite part. According to the method, a substrate is provided, the substrate having an integrated mixing portion for mixing a component system close to the substrate. The substrate provided is introduced into a cavity of a coating tool in an additional step. The substrate is then coated by flooding the cavity with the component system. The component system is mixed inside the cavity by means of the mixing portion of the substrate.

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 method of manufacturing a wind turbine blade shell part is described. Fibre mats and a root end insert are laid up in a mould part in a layup procedure by use of an automated layup system. The fibre mats are laid up by use of a buffer so that the fibre mats may continuously be laid up on the mould surface, also during a cutting procedure. The root end insert is prepared in advance and mounted on a mounting plate. The root end insert is lowered onto the mould by use of the mounting plate and a lowering mechanism. After the wind turbine blade shell has been moulded, the mounting plate is removed.