A method for manufacturing a resin sheet includes a coating step; a heating step; and a pressurizing step. In the coating step, linear metal nanomaterial is coated on a surface of a resin film having thermal plasticity. In the heating step, the resin film having the linear metal nanomaterial coated on the surface thereof is heated and softened. In the pressurizing step, the resin film having the linear metal nanomaterial coated on the surface thereof is pressurized to press the linear metal nanomaterial along a direction orthogonal to the surface on which the linear metal nanomaterial is coated. Thus, the coated linear metal nanomaterial penetrates the resin film to obtain the resin sheet containing the linear metal nanomaterial.

A flow control device (10) operates on digital instruction from a controller, especially in association with a tire curing press. A valve body (42) has a flow conduit, along which a seat (52) is formed. A valve stem (48) has a valve seal (50) positioned in the flow conduit and an end that extends out of the valve body at a valve bonnet (54). The seal moves toward and away from the valve seat. A smart motor (20) in bi-directional communication (300) with the controller (500) sets the position of the seal by rotating an output shaft (22) to a predetermined position. An actuator (7) arranged between the stepper motor and the valve body translates rotation of the outlet shaft into axial movement of the valve stem. A spring (76) in the actuator moves the valve stem to a predetermined default position in the event of loss of power.

Systems and methods are provided for securing laminates to mandrels. One embodiment is a method for facilitating layup of preforms, the method including selecting a mandrel that includes at least one receptacle, disposing a first vacuum bag atop the mandrel that covers the receptacle, selecting a Ply Location Template (PLT) that includes a securement element, aligning a portion of the securement element with the receptacle, pressing the portion of the securement element downward into the first vacuum bag and driving the portion of the securement element into the receptacle, and abutting a preform against the PLT.

A method for manufacturing a cellulose product, comprising the steps: dry forming a cellulose blank in a dry forming unit; arranging the cellulose blank in a forming mould; heating the cellulose blank to a forming temperature in the range of 100? C. to 200? C.; and pressing the cellulose blank in the forming mould with a forming pressure of at least 1 MPa.

A method for manufacturing a cellulose product, comprising the steps: dry forming a cellulose blank in a dry forming unit; arranging the cellulose blank in a forming mould; heating the cellulose blank to a forming temperature in the range of 100? C. to 200? C.; and pressing the cellulose blank in the forming mould with a forming pressure of at least 1 MPa.

A flow control device (10) operates on digital instruction from a controller, especially in association with a tire curing press. A valve body (42) has a flow conduit, along which a seat (52) is formed. A valve stem (48) has a valve seal (50) positioned in the flow conduit and an end that extends out of the valve body at a valve bonnet (54). The seal move toward and away from the valve seat. A smart motor (20) in bi-directional communication with the controller sets the position of the seal by rotating an output shaft (22) to a predetermined position. An actuator (7) arranged between the stepper motor and the valve body translates rotation of the outlet shaft into axial movement of the valve stem. A spring (76) in the actuator moves the valve stem to a predetermined default position in the event of loss of power.

An imprint device and an imprint method which form mold patterns on both surfaces of a molding target. An imprint device transfers mold patterns on both surfaces of a molding target using flexible first and second dies and includes first and second casings which each apply pressure of first and second pressurizing rooms respectively, to the first and second dies respectively and the molding target, a pressurizer that adjusts the pressures of the pressurizing rooms, first and second moving units that move the first and second dies respectively and the molding target in a direction coming close to or distant from each other, a depressurizer that depressurizes a depressurizing room formed between the first and second casings, and eliminates fluids present between the dies and the molding target, and a pressure adjuster that adjusts pressures to reduce pressure differences between the depressurizing room and the pressurizing rooms.

A device for producing an edgefold on a component is suggested, wherein the component includes a support and a cover layer. The component may be an inner lining part of a motor vehicle, without limitation thereto. The device comprises an elastic body, which is set up to pull the cover layer over an edge of the support by deforming the elastic body.

The present invention relates to a method of manufacturing a cellulose product having a flat or non-flat product shape by a pressure moulding apparatus comprising a forming mould. The forming mould has a forming surface defining said product shape, The method comprises the steps of: arranging a cellulose blank containing less than 45 weight percent water in said forming mould; heating said cellulose blank to a forming temperature in the range of 100? C. to 200? C.; and pressing said cellulose blank by means of said forming mould with a forming pressure acting on the cellulose blank across said forming surface, said forming pressure being in the range of 1 MPa to 100 MPa.

A method for manufacturing a cellulose product, comprising the steps: dry forming a cellulose blank in a dry forming unit; arranging the cellulose blank in a forming mould; heating the cellulose blank to a forming temperature in the range of 100? C. to 200? C.; and pressing the cellulose blank in the forming mould with a forming pressure of at least 1 MPa.