A composite floor comprises a coextrusion layer compression molded using a coextrusion process. The layer comprises a first stone-plastic layer, a stone-plastic foaming layer, and a second stone-plastic layer sequentially arranged from top to bottom. The stone-plastic foaming layer is used as the main material layer, which reduces a whole weight of the floor; and the first stone-plastic layer and the second stone-plastic layer are arranged at two sides of the stone-plastic foaming layer, respectively, so that the composite floor is more stable. It is more environmentally friendly and simple in manufacturing to use the coextrusion process for compression molding by avoiding bonding using glue. Use of the coextrusion process makes various layers bond more compact, with little delamination and warpage due to effect of environmental changes. The composite floor has a low expansion rate and shrinkage rate, excellent in performance and long in service life.

A method for producing a thermoplastic moulding compound by means of an extruder (10), which comprises at least one feed zone (20), at least one mixing section (30), at least one venting section (40) and at least one discharge zone (50), wherein in the at least one feed zone (20) a water-containing first component and a second component are supplied, in the at least one mixing section (30) the thermoplastic moulding compound is mixed and contained water is evaporated, in the at least one venting section (40) water vapour is removed from the moulding compound and in the at least one discharge zone (50) the moulding compound is discharged. At least one of the mixing housings (31, 32) is kept at a temperature that is equal to or lower than the temperature of the moulding compound within the mixing section (30).

Described herein are strength characteristics and biodegradation of articles produced using one or more petrochemical-based polymers and one or more carbohydrate-based polymers. A compatibilizer can optionally be included in the article. In some cases, the article can include a film or bag.

Described herein are strength characteristics and biodegradation of articles produced using one or more petrochemical-based polymers and one or more carbohydrate-based polymers. A compatibilizer can optionally be included in the article. In some cases, the article can include a film or bag.

Assay cartridges are described that have a detection chamber, preferably having integrated electrodes, and other fluidic components which may include sample chambers, waste chambers, conduits, vents, bubble traps, reagent chambers, dry reagent pill zones and the like. In certain embodiments, these cartridges are adapted to receive and analyze a sample collected on an applicator stick. Also described are kits including such cartridges and a cartridge reader configured to analyze an assay conducted using an assay cartridge.

A composite and method for producing the composite by incorporating wood or wood pulp fibres with a suitable thermoplastic polymer and coupling agent are described. Homogeneous, void-free transparent/translucent thermoplastic materials in the form of pellets, films or three-dimensional moldable products are produced. The wood pulp fibres can be discrete natural fibres, and flexible assemblies of nano to micro elements, e.g., assemblies of aggregated carbon nanotubes. It is also possible to use our vacuum-assisted co-extrusion process to produce hybrid composites comprising the wood pulp fibre and a further rigid fibre, like glass or carbon fibres, and a flexible fibre or fibrillar network, like cellulose fibres or cellulose filaments. The thermoplastic resin can be, but not limited to, polyolefins, like polypropylene or polyethylene, or polyesters, like polylactic acid, or co-polymers, like acrylonitrile-butadiene-styrene terpolymer.

Assay cartridges are described that have a detection chamber, preferably having integrated electrodes, and other fluidic components which may include sample chambers, waste chambers, conduits, vents, bubble traps, reagent chambers, dry reagent pill zones and the like. In certain embodiments, these cartridges are adapted to receive and analyze a sample collected on an applicator stick. Also described are kits including such cartridges and a cartridge reader configured to analyze an assay conducted using an assay cartridge.

The production method for a polyolefin-based structure of the present invention produces a polyolefin-based structure from a mixed source material containing a polyolefin (A), an acid-modified polyolefin (B) and a gas barrier resin (C) using a molding machine 10, under the condition mentioned below. The molding machine 10 is equipped with a single-screw extruder 11, a die head 12, and an adaptor 13 for feeding the mixed source material from the single-screw extruder 11 to the die head 12. Am+10 C.T1Cm10 C. (1), Cm30 C.T2Cm+30 C. (2), Cm10 C.T3Cm+50 C. (3), Cm30 C.T4Cm+30 C. (4). T1 is a cylinder temperature in a section corresponding to a supply zone 21A and a compression zone 21B, T2 is a cylinder temperature in a section corresponding to a metering zone 21C, T3 is a temperature of an adaptor 13, T4 is a temperature of a die head, Am is the melting point of the component (A), and Cm is the melting point of the component (C).

The invention relates to a method for mechanically treating clay (4), in particular for producing models, the clay (4) being heated by an extruder, extruded and applied to a surface (8), and to a corresponding device for mechanically treating clay (4), in particular for producing models. The invention is characterised in the device comprises an extruder (6) which is designed to heat and extrude clay (4) for applying to a surface (8).

An extrusion assembly, a method of constructing an extrusion assembly, and an additive manufacturing system including an extrusion assembly are disclosed. The extrusion assembly includes an extrusion die; a channel having an inlet and an outlet, which is in fluid communication with the extrusion die; and a heating element that melts a filament material drive through the channel so that the melted material is extruded by the extrusion die. The heating element can be helically wound about the channel or extend parallel to the channel, among other configurations. Further, the extrusion assembly includes a temperature sensor that is positioned adjacent to the channel between the extrusion die and the heating element. The channel, heating element, and temperature sensor are enclosed together within a sheath as a single integral unit. An additive manufacturing system utilizing the extrusion assembly can include a drive assembly, a support assembly, and a controller.