The present invention relates to a method of producing a cellulose-based product (103,700), wherein the method comprises the steps of: (i) providing at least two layers including one first (104a) and one second (104b) layer, and wherein said first (104a) and second layer (104b) each comprise cellulose fibers, and wherein at least one side of said first (104a) and/or said second (104b) layer is pre-treated with an adhesive coating, (ii) arranging said at least two layers including the one first (104a) and the one second (104b) layers in a superimposed relationship to each other in a forming mold (102) of a form press (101), thereby generating a stack (104) of said at least two layers including the one first (104a) and the one second (104b) layers, wherein said first (104a) and second (104b) layers are oriented within the stack (104) such that said at least one pre-treated side of said respective first (104a) and/or second (104b) layer is facing towards the superimposed layer, (iii) form pressing said stack (104) of at least two layers including the one first (104a) and the one second (104b) layers in a forming mold (102) at a forming temperature of at least 50° C. up to a forming end-pressure of at most 1100 MPa, into a cellulose based product (103, 700) of a predetermined shape and a single layer configuration, wherein in said step (iii) said layers including said one first (104a) and said one second (104b) layers are moveable with respect to each other until said forming end-pressure is reached.

The present invention relates to a method of producing a cellulose-based product (103,700), wherein the method comprises the steps of: (i) providing at least two layers including one first (104a) and one second (104b) layer, and wherein said first (104a) and second layer (104b) each comprise cellulose fibers, and wherein at least one side of said first (104a) and/or said second (104b) layer is pre-treated with an adhesive coating, (ii) arranging said at least two layers including the one first (104a) and the one second (104b) layers in a superimposed relationship to each other in a forming mold (102) of a form press (101), thereby generating a stack (104) of said at least two layers including the one first (104a) and the one second (104b) layers, wherein said first (104a) and second (104b) layers are oriented within the stack (104) such that said at least one pre-treated side of said respective first (104a) and/or second (104b) layer is facing towards the superimposed layer, (iii) form pressing said stack (104) of at least two layers including the one first (104a) and the one second (104b) layers in a forming mold (102) at a forming temperature of at least 50° C. up to a forming end-pressure of at most 1100 MPa, into a cellulose based product (103, 700) of a predetermined shape and a single layer configuration, wherein in said step (iii) said layers including said one first (104a) and said one second (104b) layers are moveable with respect to each other until said forming end-pressure is reached.

A laminate body including a base material and a flat silicone sealing layer adhered thereto, generally without any voids, is provided. Also provided is a curable hot melt silicone composition layer with a particular curable hot melt silicone composition, providing a laminate body that does not readily cause stress on a substrate after the curable hot melt silicone composition is cured. A laminate body comprises a base material, and a curable hot melt silicone composition layer in contact with the base material. The curable hot melt silicone composition includes an organopolysiloxane resin containing siloxane units selected from a group containing T units or Q units making up at least 20 mol % or more of all siloxane units. The curable hot melt silicone composition generally has a melt viscosity as measured using a flow tester at a pressure of 2.5 MPa and at 100° C. of 5,000 Pa.Math.s or less.

A composite structure manufacturing method comprising: a lamination step in which a plurality of fiber-reinforced resin sheets are laminated to form a plate-shaped laminate; a pressing deformation step in which a third roller or similar, which rolls along a plate surface of the laminate, is used to press the plate surface of the laminate, thereby forming a recessed section or a protruding section in a prescribed section of the laminate; a short direction deformation step in which, after the pressing deformation step, the laminate is deformed in the short direction to make the long direction cross-section into a prescribed shape; and a long direction deformation step in which, after the pressing deformation step, the laminate is deformed in the long direction to make the short direction cross-section into a prescribed shape.

A decorative sheet for vacuum forming is difficult to peel off during vacuum forming between a first vinyl chloride-based resin layer and a second vinyl chloride-based resin layer and can give a design of various colors. This decorative sheet for vacuum forming includes: a first vinyl chloride-based resin layer containing a vinyl chloride-based resin and a coloring agent; and a second vinyl chloride-based resin layer which is laminated on the first vinyl chloride-based resin layer, contains a vinyl chloride-based resin, and is transparent, wherein the content of titanium oxide particles of the coloring agent is less than 1 part by mass, the first vinyl chloride-based resin layer contains inorganic particles, and at least some of the inorganic particles are calcium carbonate particles.

A membrane device for manufacturing a crash pad for a vehicle including a real wood sheet includes a vacuum device main body having a plurality of vacuum holes such that a real wood sheet to be temporarily attached to a core is mounted in the vacuum device main body, a cover having a silicone film to define a vacuum space together with the vacuum device main body, a vacuum module to suck air in the vacuum device main body through the vacuum holes, and a control unit to compress the real wood sheet and the core, which are temporarily attached and mounted on the vacuum device main body, for a preset time by sucking air in the vacuum space through the vacuum holes in a state in which the vacuum device main body is covered by the cover.

A membrane device for manufacturing a crash pad for a vehicle including a real wood sheet includes a vacuum device main body having a plurality of vacuum holes such that a real wood sheet to be temporarily attached to a core is mounted in the vacuum device main body, a cover having a silicone film to define a vacuum space together with the vacuum device main body, a vacuum module to suck air in the vacuum device main body through the vacuum holes, and a control unit to compress the real wood sheet and the core, which are temporarily attached and mounted on the vacuum device main body, for a preset time by sucking air in the vacuum space through the vacuum holes in a state in which the vacuum device main body is covered by the cover.

A method for manufacturing a floor covering product includes the steps of forming a single- or multilayered substrate by extruding of synthetic material-based material in a layer shape; laminating at least one continuous film to the substrate; and impressing the at least one continuous film using a roller provided with a relief on its surface.

A method for manufacturing a floor covering product includes the steps of forming a single- or multilayered substrate by extruding of synthetic material-based material in a layer shape; laminating at least one continuous film to the substrate; and impressing the at least one continuous film using a roller provided with a relief on its surface.

A fiber-reinforced resin material includes: a first fiber-reinforced resin layer; a second fiber-reinforced resin layer having higher ductility and lower elasticity than those of the first fiber-reinforced resin layer; and a third fiber-reinforced resin layer having higher ductility and lower elasticity than those of the second fiber-reinforced resin layer. The first layer, the second layer, and the third layer are laminated and integrated in this order is made of the fiber-reinforced resin material. The manufacturing method includes: stacking a sheet-shaped product obtained by forming continuous fibers into a sheet shape and a resin sheet that serves as a first thermoplastic resin, a second thermoplastic resin, or a third thermoplastic resin so as to obtain a laminated structure in which the first layer, the second layer, and the third layer are laminated in this order; and heating and compressing the obtained stacked product in a stacking direction.