The present invention relates to a (meth)acrylic mixture for impregnating a fibrous substrate, characterized in that it comprises: a) a first dispersion comprising at least one (meth)acrylic polymer obtained by emulsion polymerization of one or more (meth)acrylic monomers, b) a second dispersion comprising at least one flame retardant. The invention also relates to a method for impregnating a fibrous substrate with a (meth)acrylic mixture of this kind, and to a method for manufacturing mechanical parts or structured elements, or articles, from the (meth)acrylic mixture. Another objective of the invention is a mechanical part or a structured element or an article made of composite material, obtained by the implementation of the manufacturing method.

Provided is a mold release film capable of transferring a concave-convex structure to the surface of an adhesive film.

Provided is a mold release film capable of transferring a concave-convex structure to the surface of an adhesive film.

A method for polymerizing an open-cell foam including exposing an emulsion comprising a photoinitiator to an Ultraviolet light source, partially polymerizing the top surface of the emulsion, and moving the partially polymerized emulsion to a second polymerization stage.

A method for polymerizing an open-cell foam including exposing an emulsion comprising a photoinitiator to an Ultraviolet light source, partially polymerizing the top surface of the emulsion, and moving the partially polymerized emulsion to a second polymerization stage.

A mold for manufacturing a component for a wind turbine, in particular a rotor blade, is provided. The mold includes a flexible mold part configured for driving staples into the same, the staples being used to attach a fiber material to the mold. The mold may include a lower mold half and an upper mold half. The mold may be made of a polymer material, a plastic material, a metal alloy or a combination thereof.

A production method of a composite material includes placing a fiber base material on a mold. The fiber base material includes a first fiber base material portion and a second fiber base material portion. The method further includes disposing a mold release member in part of a region where the first fiber base material portion and the second fiber base material portion are in contact with each other, and curing a resin with which the first fiber base material portion and the second fiber base material portion are impregnated, so as to mold the composite material.

An automated method for producing a fibrous preform on a tool surface. Such fibrous preform is configured to receive liquid resin via resin infusion. A disposable layer containing a small amount of radiation absorbing material is placed onto the tool surface prior to the automated placement of the first ply of dry fibrous material. Particles of a polymeric or resinous binder are applied on an exposed surface of the disposable layer to enhance adhesion of the first ply. The dry fibrous material may be in the form of elongated, narrow-width fiber tapes or broader fabrics that can be deposited onto the tool surface by an automated placement method. The disposable layer may be in the form of a flexible polymeric film, a release film, a peel ply or a polymer-coated glass cloth.

An automated method for producing a fibrous preform on a tool surface. Such fibrous preform is configured to receive liquid resin via resin infusion. A disposable layer containing a small amount of radiation absorbing material is placed onto the tool surface prior to the automated placement of the first ply of dry fibrous material. Particles of a polymeric or resinous binder are applied on an exposed surface of the disposable layer to enhance adhesion of the first ply. The dry fibrous material may be in the form of elongated, narrow-width fiber tapes or broader fabrics that can be deposited onto the tool surface by an automated placement method. The disposable layer may be in the form of a flexible polymeric film, a release film, a peel ply or a polymer-coated glass cloth.

To provide a film capable of suppressing both of formation of wrinkles when a release film is suction-attached to a cavity surface in compression molding, and formation of wrinkles when the cavity bottom surface to which the release film has been suction-attached is raised; and a method for producing a semiconductor element by using said film. A laminated film 1 comprises a layer 3 of shrinkable film, of which the storage elastic modulus E at 180 C. is at least 70 MPa, and the thermal shrinkage in 30 minutes at 180 C., with reference to 20 C., in each of the machine direction (MD) and the transverse direction (TD), is at least 3%, and a fluororesin layer 5 present on one side or both sides of the shrinkable film layer 3.