A molded fiber part production line includes a forming station, a part transfer system, a press station, and a removal system. The forming station includes a slurry tank, a forming mold, and a mold actuation system. The part transfer system includes a part transfer feature and a conveyance mechanism. The press station includes a core mold, a cavity mold compatible with the core mold, and a press actuation system. The removal system includes a removal feature defining a plurality of part vacuum channels and a plurality of trim vacuum channels. The removal system also includes a conveyance mechanism for moving the removal feature from a position in engagement with at least one of the core mold and the cavity mold to another position.

A molded fiber part production line includes a forming station, a part transfer system, a press station, and a removal system. The forming station includes a slurry tank, a forming mold, and a mold actuation system. The part transfer system includes a part transfer feature and a conveyance mechanism. The press station includes a core mold, a cavity mold compatible with the core mold, and a press actuation system. The removal system includes a removal feature defining a plurality of part vacuum channels and a plurality of trim vacuum channels. The removal system also includes a conveyance mechanism for moving the removal feature from a position in engagement with at least one of the core mold and the cavity mold to another position.

A molded fiber part production line includes a forming station, a part transfer system, a press station, and a removal system. The forming station includes a slurry tank, a forming mold, and a mold actuation system. The part transfer system includes a part transfer feature and a conveyance mechanism. The press station includes a core mold, a cavity mold compatible with the core mold, and a press actuation system. The removal system includes a removal feature defining a plurality of part vacuum channels and a plurality of trim vacuum channels. The removal system also includes a conveyance mechanism for moving the removal feature from a position in engagement with at least one of the core mold and the cavity mold to another position.

A molded fiber part production line includes a forming station, a part transfer system, a press station, and a removal system. The forming station includes a slurry tank, a forming mold, and a mold actuation system. The part transfer system includes a part transfer feature and a conveyance mechanism. The press station includes a core mold, a cavity mold compatible with the core mold, and a press actuation system. The removal system includes a removal feature defining a plurality of part vacuum channels and a plurality of trim vacuum channels. The removal system also includes a conveyance mechanism for moving the removal feature from a position in engagement with at least one of the core mold and the cavity mold to another position.

Provided are: a powdered material for slush molding; and a manufacturing process therefor. The powdered material is less odorous, exhibits excellent powder fluidity, and does not suffer from troubles resulting from the sliding-down or agglomeration of a pigment even when the resin particles have been pigmented on the surfaces thereof. Thus, the powdered material ensures high productivity. The powdered material is a powdered polyurethane urea resin composition which comprises (D) a polyurethane urea resin that has a total content of bimolecular condensate of acetone, bimolecular condensate of methyl ethyl ketone, and bimolecular condensate of methyl isobutyl ketone of 1,000 ppm or less and (N) an additive, wherein the polyurethane urea resin (D) takes the form of thermoplastic polyurethane urea resin particles (P) that have a volume-mean particle diameter of 20 to 500 m and that have protrusions and recesses on the surfaces. The powdered polyurethane urea resin composition is manufactured by a manufacturing process which includes a step of mixing (A) an isocyanato-terminated urethane prepolymer with (B) an alicyclic diamine and/or an aliphatic diamine in an aqueous medium by stirring to form the resin particles (P).

Provided are: a powdered material for slush molding; and a manufacturing process therefor. The powdered material is less odorous, exhibits excellent powder fluidity, and does not suffer from troubles resulting from the sliding-down or agglomeration of a pigment even when the resin particles have been pigmented on the surfaces thereof. Thus, the powdered material ensures high productivity. The powdered material is a powdered polyurethane urea resin composition which comprises (D) a polyurethane urea resin that has a total content of bimolecular condensate of acetone, bimolecular condensate of methyl ethyl ketone, and bimolecular condensate of methyl isobutyl ketone of 1,000 ppm or less and (N) an additive, wherein the polyurethane urea resin (D) takes the form of thermoplastic polyurethane urea resin particles (P) that have a volume-mean particle diameter of 20 to 500 m and that have protrusions and recesses on the surfaces. The powdered polyurethane urea resin composition is manufactured by a manufacturing process which includes a step of mixing (A) an isocyanato-terminated urethane prepolymer with (B) an alicyclic diamine and/or an aliphatic diamine in an aqueous medium by stirring to form the resin particles (P).

A deposition nozzle has a housing, an inlet into the housing arranged to receive a solution carrying randomly oriented fibers, an orientation component within the housing, the orientation component positioned to receive the solution from the inlet and operate to produce aligned fibers in a predetermined, single direction, and an outlet on the housing arranged to receive the aligned fibers and deposit them on a substrate. A system includes a porous substrate, a deposition nozzle, a reservoir of randomly oriented fibers in solution connected to the deposition nozzle, the deposition nozzle position adjacent the porous substrate and connected to the reservoir, the nozzle to receive the randomly oriented fibers and output aligned fibers, and a vacuum connected to the porous substrate to remove fluid from the porous substrate as the deposition nozzle deposits the aligned fibers on the porous substrate to produce a fiber pre-form having aligned fibers. A method includes providing a reservoir of randomly oriented fibers in a solution, dispensing the solution of randomly oriented fibers through a nozzle having an orientation component onto a porous substrate as a solution of aligned fibers, and immobilizing the fibers to form a fiber pre-form.

A molded fiber part former includes a first forming mold defining a first mold area and at least one fluid inlet. The molded fiber part former also includes a wall substantially surrounding the first mold area. The molded fiber part former includes a fluid channel disposed adjacent to and surrounding the wall, wherein the channel is fluidically connected to the at least one fluid inlet and defines a fluid channel outlet.

A molded fiber part former includes a first forming mold defining a first mold area and at least one fluid inlet. The molded fiber part former also includes a wall substantially surrounding the first mold area. The molded fiber part former includes a fluid channel disposed adjacent to and surrounding the wall, wherein the channel is fluidically connected to the at least one fluid inlet and defines a fluid channel outlet.

A molded fiber part former includes a first forming mold defining a first mold area and at least one fluid inlet. The molded fiber part former also includes a wall substantially surrounding the first mold area. The molded fiber part former includes a fluid channel disposed adjacent to and surrounding the wall, wherein the channel is fluidically connected to the at least one fluid inlet and defines a fluid channel outlet.