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 molded product and an electrical product comprising a molded article that includes a main body made of resin and a standing wall made of resin. The standing wall integrally stands up from the end portion of the main body. A decorative sheet includes a base film and a conductive circuit layer. The base film continuously covers from the main body front surface to a wall front surface. The conductive circuit layer is disposed between the base film and the main body front surface. The decorative sheet is integrated with the molded article to implement a decoration with the base film. A flexible printed circuit board is disposed between the molded article and the conductive circuit layer. The flexible printed circuit board is partially embedded into and integrated with the standing wall. The flexible printed circuit board is electrically connected to the conductive circuit layer.

This document relates to a molding tool for forming and back-injecting a bendable sheet including a mold that includes a first mold half and a second mold half. The first half is arranged opposite the second half forming a cavity for receiving the bendable sheet and a melt. Further, the mold includes at least one pin for holding the bendable sheet and the pin is retractable in response to a force exerted on the pin by a pressure of the injected melt during back injection.

This document relates to a molding tool for forming and back-injecting a bendable sheet including a mold that includes a first mold half and a second mold half. The first half is arranged opposite the second half forming a cavity for receiving the bendable sheet and a melt. Further, the mold includes at least one pin for holding the bendable sheet and the pin is retractable in response to a force exerted on the pin by a pressure of the injected melt during back injection.

The device comprises at least one forming and wrap-around labeling assembly (60) suitable for taking up an active configuration in which said assembly has a forming chamber (36) and a looping chamber (46), which chambers are in axial alignment and communicate with each other via an annular passageway (62) provided through the end wall of the forming chamber. The assembly is further provided with a pusher member (66) configured to push a wrap-around label (27) that is looped in the looping chamber into the forming chamber. At least one portion (36C) in the forming chamber (36) flares going away from the end wall (36B) of the forming chamber and the pusher member is configured to expand radially while pushing the wrap-around label (26A) into said flared portion (36C) of the forming chamber (36).

The device comprises at least one forming and wrap-around labeling assembly (60) suitable for taking up an active configuration in which said assembly has a forming chamber (36) and a looping chamber (46), which chambers are in axial alignment and communicate with each other via an annular passageway (62) provided through the end wall of the forming chamber. The assembly is further provided with a pusher member (66) configured to push a wrap-around label (27) that is looped in the looping chamber into the forming chamber. At least one portion (36C) in the forming chamber (36) flares going away from the end wall (36B) of the forming chamber and the pusher member is configured to expand radially while pushing the wrap-around label (26A) into said flared portion (36C) of the forming chamber (36).

A molded product and an electrical product comprising a molded article that includes a main body made of resin and a standing wall made of resin. The standing wall integrally stands up from the end portion of the main body. A decorative sheet includes a base film and a conductive circuit layer. The base film continuously covers from the main body front surface to a wall front surface. The conductive circuit layer is disposed between the base film and the main body front surface. The decorative sheet is integrated with the molded article to implement a decoration with the base film. A flexible printed circuit board is disposed between the molded article and the conductive circuit layer. The flexible printed circuit board is partially embedded into and integrated with the standing wall. The flexible printed circuit board is electrically connected to the conductive circuit layer.

A cushion material manufacturing method for obtaining a cushion material is provided. The cushion material have a foam body having a surface portion formed of an air permeability control surface portion and an air permeability uncontrol surface portion and a covering material configured to cover the air permeability uncontrol surface portion. The cushion material manufacturing method includes covering the air permeability uncontrol surface portion of the foam body with the covering material.

In a first aspect of the invention there is provided a method of manufacturing a wind turbine blade. The method comprises providing a mould for a shell of the wind turbine blade, the mould extending in a longitudinal direction from a root end to a tip end; providing a plurality of elongated root inserts; providing a root plate with a plurality of arcuately arranged connection points; at the connection points, connecting the root inserts to the root plate, such that the connected root inserts jointly form a contour of a portion of a root section of the wind turbine blade; and positioning the root plate relative to the mould in order to place the contour formed by the root inserts at least partially into the mould. The method further comprises providing a spacer having a decreasing thickness, and the connecting of the root inserts to the root plate comprises providing the spacer between the root inserts and the root plate.

In a first aspect of the invention there is provided a method of manufacturing a wind turbine blade. The method comprises providing a mould for a shell of the wind turbine blade, the mould extending in a longitudinal direction from a root end to a tip end; providing a plurality of elongated root inserts; providing a root plate with a plurality of arcuately arranged connection points; at the connection points, connecting the root inserts to the root plate, such that the connected root inserts jointly form a contour of a portion of a root section of the wind turbine blade; and positioning the root plate relative to the mould in order to place the contour formed by the root inserts at least partially into the mould. The method further comprises providing a spacer having a decreasing thickness, and the connecting of the root inserts to the root plate comprises providing the spacer between the root inserts and the root plate.