A manufacturing method of a structure by which a target member can be easily positioned with high accuracy. In a tilting step, at least one target member is positioned by tilting a positioning table and sliding the target member placed on the positioning table to bring the target member into contact with a locking portion.

A method for manufacturing of a wind turbine blade component is provided, including the steps: providing a fabric material and at least one binding agent, cutting the fabric material into a plurality of fabric sheets using a fabric cutting tool and arranging at least one stack of the cut fabric sheets on at least one preform mold tool, wherein the binding agent is arranged in and/or in between the stacked fabric sheets, consolidating the stack of fabric sheets, wherein the stack of consolidated fabric sheets forms a preform part, arranging at least one preform part inside a resin injection mold tool, injecting resin into the preform part, curing the resin, arranging the cured part on a holding means, and treating the cured part using at least one treatment tool for forming the wind turbine blade component.

An apparatus includes a mold. The mold has a first mold part with a first interior surface and a second mold part with a second interior surface. The apparatus additionally includes a movable member disposed proximate the mold. The movable member is movable between a first position and a second position. In the first position the movable member cooperates with the first interior surface and second interior surface to define a first mold cavity, and in the second position the movable member cooperates with the first interior surface and second interior surface to define a second mold cavity. The second mold cavity has a shape distinct from the first mold cavity.

A method for producing a cover element for upholstery of a motor vehicle seat element, includes at least one layer of foam and a cap made at least from a covering material. The forming of the cover element includes the steps of: placing the cap against a matrix defining the visible shape of the cover element, with the covering material on a side of the matrix; holding the cap pressed against the matrix by suction; placing the at least one layer of foam against a back of the covering material; and applying a forming punch defining a rear face of the cover element.

A container treatment system (1, 13) that has at least two working areas (AP). Each of the working areas (AP) respectively comprises at least one exchangeable working tool (2) and/or one adaptable format part. Furthermore, the container treatment system (1, 13) comprises at least one automatic exchange machine (10) which is movable, in particular drivable, to the at least two working areas (AP), which automatic exchange machine (10) can be connected selectively to any of the respective working areas (AP), in particular using centering means (22, 32), and which automatic exchange machine (10) comprises tools for exchanging the working tools (2) and/or for adapting the format parts of the respective working area (AP). The invention further relates to an automatic exchange machine (10) for exchanging working tools (2) and/or for adapting the format parts of at least two different working areas (AP) of a container treatment system (1, 13).

An apparatus for producing plastic containers is provided, comprising a heating device that heats plastic preforms, and including a shaping device provided downstream of this heating device in the transport direction of the plastic preforms, which shaping device shapes the plastic preforms into the plastic containers, wherein a tempering device for tempering the plastic preforms heated by the heating device is provided in the transport direction of the plastic preforms between the heating device and the shaping device, which tempering device has at least one tempering unit provided on a carrier rotatable about a predetermined rotary axis, and which tempering unit has at least two contacting devices, between which at least one section of the plastic preform can be received, which contacting devices can be moved in relation to one another along a predetermined direction.

A manufacturing method for a wind turbine blade is described which utilizes a post-molding station in the manufacturing process. A blade shell forming part of a wind turbine blade is initially molded in a blade mold, the blade shell subsequently transferred to a post-molding station which allows for various post-molding operations to be carried out on the blade shell away from the mold, thereby increasing the productivity of the blade mold in the manufacturing process. The post-molding station may be operable to perform the closing of first and second blade shells to form a wind turbine blade, and may be formed from an adjustable structure which can provide relatively easy access to the contained blade shell for working thereon. Accordingly, the manufacturing equipment may be of reduced cost, combined with an increase in the overall productivity of the manufacturing system.

A manufacturing method for a wind turbine blade is described which utilizes a post-molding station in the manufacturing process. A blade shell forming part of a wind turbine blade is initially molded in a blade mold, the blade shell subsequently transferred to a post-molding station which allows for various post-molding operations to be carried out on the blade shell away from the mold, thereby increasing the productivity of the blade mold in the manufacturing process. The post-molding station may be operable to perform the closing of first and second blade shells to form a wind turbine blade, and may be formed from an adjustable structure which can provide relatively easy access to the contained blade shell for working thereon. Accordingly, the manufacturing equipment may be of reduced cost, combined with an increase in the overall productivity of the manufacturing system.

A manufacturing system includes a plurality of manufacturing process stations for processing a workpiece, and at least one drone for transferring the workpiece among the manufacturing process stations. It is preferable that the manufacturing system includes a detecting station for detecting contamination or corrosion of the at least one drone, and a washing station for washing the at least one drone.

A device for manufacturing a composite product has a first folded layer with a first and second superposed portion extending from a respective first and second free end to a first bend connecting the first and second superposed portions, and a second folded layer with a third and fourth superposed portion extending from a respective third and fourth free end to a second bend connecting the third and fourth superposed portions, wherein the first and second folded layers are laid adjacent to each other in order that the second portion of the first folded layer is in contact with the third portion of the second folded layer, the first and second folded layers being oriented with respect to each other in order to extend from a first side including the first, second, third and fourth free ends to a second side including the first and second bend.