Various implementations include a mat having a lower surface and first and second edge portions that define at least a portion of a perimeter of the mat. The mat also includes a plurality of ribs that extend away from the lower surface of the mat for contacting the floor. Each rib has a longitudinal axis that extends between ends of the rib, and at least a portion of the plurality of ribs includes one or more branches that extend transversely to the longitudinal axis and are axially spaced apart from each other. The ribs are spaced apart from each other over the lower surface such that adjacent ribs define a valley therebetween. Water and/or debris can flow through the valleys. In addition, the longitudinal axis of each rib intersects the first and second edge portions of the mat at angles that are greater than 0° and less than 90°.

A method for producing a vehicle composite component with a layer structure having a core layer in a molding tool, the core layer being formed with regions of different thickness is provided. Steps for this method may include placing a cover layer, in particular a preformed cover layer, which in particular forms an outer skin of the vehicle composite component, onto a mold base plate of the open molding tool; introducing a first fiber layer, which is impregnated with PU resin and has not been subjected to forming, between the cover layer and a first mold counterplate of the open molding tool; closing the molding tool and compression molding the first fiber layer, which is impregnated with PU resin, against the cover layer, as a result of which a preform with a first support layer containing the first fiber layer is formed and hardened while supplying heat.

A large area patterned film includes a first patterned area; a second patterned area; and a seam joining the first patterned area and the second patterned area, wherein the seam has a width less than about 20 micrometers. A method for tiling patterned areas includes depositing a predetermined thickness of a curable material; contacting a first portion of the curable material with a mold; curing the first portion of the curable material; removing the mold from the cured first portion of the curable material; contacting a second portion of the curable material with the mold, such that the mold contacts a portion of the cured first portion of the curable material; curing the second portion of the curable material; and removing the mold to yield a seam between the cured first portion of the curable material and the cured second portion of the curable material, wherein the seam has a dimension less than about 20 micrometers.

A machining apparatus includes an apparatus body and a setting jig. The setting jig has a frame body including openings to expose molding regions, which are to be molded by the apparatus body, of the sheet material, and a restraining portion to restrain a periphery of the molding regions. The apparatus body includes a support member that supports the setting jig at a position where the molding regions are disposed between an upper die and a lower die, and a first urging member to urge the support member toward the upper die so as to separate the molded body from the lower die, with the upper die disengaged from the lower die.

A food mold (1), comprising a food mold body (2) made of a mold body material, having one or more cells (3) with flexible wall, said one or more cells (3) being open on a common access face (4) itself having a peripheral rim (5) extending radially outward from an inner edge (5d) marking the boundary with the cell or cells (3) and to a free outer edge (5c), the peripheral rim (5) being provided with a peripheral stiffening element (10) in the form of a continuous annular reinforcement (100) with, if necessary, one or more intermediate stiffening elements (101, 102); the peripheral stiffening element (10) is entirely embedded in the mold body material; around the peripheral stiffening element (10), the mold body material has no through passages free or blocked between the peripheral stiffening element (10) and the outer surface of the material.

A method for manufacturing a joining connection between a luminously efficacious part and a metal component of a lighting device of a vehicle. A microstructure is generated in a joining surface of the metal component, the microstructure having undercuts with respect to the joining surface. The plastic material of the plastic part is softened in an area of the complementary joining surface near the surface with the aid of an introduction of heat. The plastic part and the metal component are pressed together with a pressure force in such a way that a portion of the softened plastic material penetrates the undercuts of the microstructure. The plastic material of the plastic part is cooled thereby forming a new strength of the softened plastic material of the plastic part.

[Object] To provide a method for the production of a thin plate-like laminate having a film-like resin layer in which a concave/convex shape can stably be formed with high accuracy on the film-like resin layer laminated on a thin plate-like substrate.

[Achieving Means] There are provided a step of creating a mold retention structure 100 in which molds 110, which have been heated to a thermal deformation temperature of a film-like resin composition 84, are arranged on both surface sides of a workpiece 85, and a step of introducing the mold retention structure in which the heated molds are arranged between two compression rollers 52, 54 and compressing outer surfaces of the molds by rotating the compression rollers to integrally thermocompression-bond the film-like resin composition and a substrate 81 to form a thin plate-like laminate 80 having a film-like resin layer 82.

A carbon fiber-reinforced resin molded body of the present invention derives from kneaded materials of a thermoplastic resin and a carbon fiber and includes at least a three-dimensional complex shaped region and a substantially flat plate-shaped region arranged in a profile direction. Fluidity of the kneaded materials at predetermined temperature is such that fluidity of the kneaded material forming the substantially flat plate-shaped region is lower than fluidity of the kneaded material forming the three-dimensional complex shaped region, which makes it unlikely to cause defects in ribs, posses, and other portions. Thus, a carbon fiber-reinforced resin molded body with low cost and high strength can be provided.

Methods of producing polymer-metal hybrid components that are bonded by C—O-M bonds at the interface using at least one of the hot pressing, rolling, and injection molding methods to create chemical bond formation conditions at the polymer and metal interface. When the thermal cycle and compressive pressure specified herein is combinationally created at the polymer and metal interfaced, strong C—O-M bonds forms at the interface and strongly bonds the metal and polymer together through the reaction carbonyl groups (C═O) in polymer and the metal surface. For polymers lacking enough carbonyl groups, new functional groups can be in-situ generation through introducing distributed air pockets at the polymer-metal interface for forming 3-dimensional distributed C—O-M bonds at the interface.

A stacked workpiece molding device 1 includes: a first mold 20 configured to suck and hold a workpiece body 42; and a second mold 30 having on an inner surface a pattern that can be transferred to a surface of a sheet material 44 stacked on the workpiece body 42 and press the sheet material 44 against the workpiece body 42. The inner surface of the second mold 30 includes a groove portion 31 that is positioned at a peripheral edge portion of the workpiece body 42, the second mold 30 includes a through-hole 32 extending to open into the groove portions 31, the through-hole 32 is connected to a first suction device 51 that sucks the sheet material 44, and the first mold 20 includes a suction hole 22 for sucking the workpiece body 42, and the suction hole 22 is connected to a second suction device 52.