There is little fluctuation in amount of short fibers among individual products of fiber substrate. No damage is caused to a mold for the fiber substrate. Continuous production of the fiber substrates is possible. A method of manufacturing a fiber substrate includes the steps of: preparing slurry by dispersing short fibers in a dispersion medium; pouring the slurry into a cylindrical mold from above the cylindrical mold, the slurry being directed to a slurry diffusion member disposed in the center of the cylindrical mold and having an upward pointing conical or pyramidal shape; pouring the dispersion medium or water onto the slurry diffusion member from above the slurry diffusion member to cause the short fibers adhering to the slurry diffusion member to fall down, after the step of pouring the slurry; and discharging the dispersion medium from the cylindrical mold to accumulate the short fibers in the cylindrical mold to obtain a fiber aggregate.

A molding device and a molding method are provided. The molding device includes an upper molding assembly and a lower molding assembly. The upper molding assembly includes an upper molding plate and a plurality of positioning columns disposed thereon. The mold core and a plurality of matching columns surrounding the mold core are disposed at the same side of the upper molding plate. The lower molding assembly includes a lower molding plate and at least one formation mold, wherein the lower molding plate has at least one accommodating groove, a plurality of matching grooves and a plurality of positioning holes surrounding the accommodating groove. The formation mold is disposed in the accommodating groove, and the formation mold has a formation cavity corresponding to the mold core. Each positioning column is disposed respectively into each positioning hole, and each matching column is disposed respectively into each matching groove.

A method of press molding a molding material to form a molded part of fiber-reinforced resin matrix composite material, the method comprising the steps of: i. providing a mold tool having a lower mold part and an upper mold part, the upper mold part having a first molding surface for molding a first molded surface of the molded part and the lower mold part having a second molding surface for molding a second molded surface of the molded part; ii. providing a multilaminar panel of molding material comprising at least one layer of dry fibers and at least one layer of resin, the multilaminar panel having first and second opposite major surfaces; iii. locating the molding material in the mold tool; iv. closing the mold tool to define a substantially closed mold cavity containing the molding material, the closing step including a compression stage, in which the first molding surface contacts the first major surface and the second molding surface contacts the second major surface, the compression stage compressing the molding material to cause progressive resin impregnation of the dry fibers without increasing the resin pressure to a minimum threshold value to cause excessive resin bleed out from the cavity, optionally to reduce any resin bleed out to no more than 600 grams of resin per square meter of the molding material; v. applying pressure to the molding material in the mold cavity to configure the molding material in a fully molded shape; and vi. substantially fully curing the resin to form a molded part from the molding material.

An apparatus includes a matched die mold including a male die mold and a female die mold wherein the male die mold includes a first contoured surface and the female die mold includes a second contoured surface. The apparatus further includes a frame which defines an opening wherein the frame is positioned between the male die mold and the female die mold such that the frame is adapted to position a film layer across the opening and the opening is positioned in alignment with at least one of the first contoured surface and the second contoured surface.

A rotary tablet press having a rotatably driven rotor and a die plate with a plurality of die bores. A plurality of upper and lower punches are configured to produce tablets in the plurality of die bores. The tablets are monitored for one or more characteristics and are sorted by an ejection apparatus according to the one or more characteristics into a reject channel and a satisfactory channel.

A method of making a sandwich-type, compression-molded, composite component having improved surface appearance is provided. Reinforced thermoplastic skins, first and second sheets of thermoplastic adhesive and a cellulose-based core of a blank or stack of sandwich materials are heated to a softening temperature of the thermoplastics. The heated blank or stack is allowed to cool in the mold cavity until inner surfaces of the skins are bonded to top and bottom surfaces of the core by the sheets to seal core cavities. Air in the sealed cavities urges softened portions of the sheets and portions of the core inwardly towards the cavities of the core as the air in the cavities cools to inhibit debossing and improve surface appearance of a first outer surface of the blank or stack.

There is provided an apparatus for molding a thermoplastic material into a homogenous sample body having a predetermined shape, the apparatus comprising: (a) a main body (110) comprising a first opening (112), a second opening and a hollow bore (116) connecting the first opening (112) with the second opening, the hollow bore (116) being adapted to receive a separation foil shaped to cover at least a part of the hollow bore surface; (b) a piston (120) adapted to fit moveably into the hollow bore (116) containing the separation foil; (c) a base plate (130) comprising a protrusion, wherein the base plate (130) is adapted to be inserted into the first opening (112) in such a manner that the protrusion extends into a part of the hollow bore (116) containing the separation foil, and wherein the base plate (130) is adapted to transfer heat from a heating unit to a thermoplastic material (150) resting on the protrusion (132); (d) a vacuum connector (142) adapted to be connected to a vacuum source; (e) a lid (140) adapted to fit moveably into the second opening and adapted to apply a force to the piston (120) when the vacuum connector (142) is connected to the vacuum source such that the piston (120) applies a compressing force to the thermoplastic material (150) resting on the protrusion. There are further provided a method and a system for molding a thermoplastic material into a homogenous sample body having a predetermined shape.

In a resin sandwich panel, the two resin skin material sheets have peripheral edge portions thereof joined to each other so as to form an internal hollow portion. The resin core material is disposed in the hollow portion. At least one of surfaces of the resin core material opposing the two resin skin material sheets has a groove portion extending across the entire surface, and a depression communicating with the groove portion. At least one of the two resin skin material sheets additionally has an atmosphere-opened through-hole provided in a thickness direction thereof. When the one of the surfaces of the resin core material and the corresponding resin skin material sheet are surface-to-surface adhered to each other in the hollow portion, air between the surfaces and the skin material sheet is guided to the depression via the groove portion, and exhausted out of the atmosphere-opened through-hole.

Disclosed is a laminating apparatus capable of suppressing the generation of voids in a resulting laminate and manufacturing a laminate with improved flatness, including a vacuum laminating device and a first flat press laminating device. The vacuum laminating device includes a pair of plate blocks, and a base material and resin are pressed between the plate blocks. The plate block which is movable forwardly and backwardly includes an elastic pressing plate and a buffer material, and the buffer material has a multi-layer structure comprised of not less than three layers including a fiber layer and a rubber layer. A pressing force against the base material and the resin between the pair of plate blocks is set in the range of 2.5 to 3.97 MPa per 500 mm square area.

A device for manufacturing a window member includes a chamber, a pressure adjustment pump connected to the chamber and configured to adjust an internal pressure of the chamber, a support configured to support a base substrate, the base substrate having a plurality of trenches of which a lengthwise direction is a first direction and an auxiliary film that surrounds at least a portion of the base substrate, a dispenser configured to provide a soft material to one side of the base substrate, a pressurizer disposed within the chamber and configured to apply pressure to the base substrate as the pressurizer moves, a curing machine configured to generate a protective layer by curing the soft material, and a cutting machine configured to cut at least a portion of the protective layer.