A three-dimensional (3D) printing method includes applying a build material composition having a polymer particle and a radiation absorbing additive mixed with the polymer particle, the radiation absorbing additive being selected from the group consisting of inorganic near-infrared absorbers, organic near-infrared absorbers, and combinations thereof. The build material composition is preheated to a temperature below the melting temperature of the polymer particle by exposing the build material composition to radiation, the radiation absorbing additive increasing radiation absorption and accelerating the pre-heating of the build material composition. A fusing agent is selectively applied on at least a portion of the build material composition. The method further includes exposing the build material composition to radiation, whereby at least the polymer particle in the at least the portion of the build material composition in contact with the fusing agent at least partially fuses.

A printing system for producing at least one three dimensional (3D) printed part is described. The printing system includes a deposition system configured to continuously deposit a layer onto a cylinder to outwardly extend a diameter of the cylinder, wherein the layer comprises a first pattern. The printing system also includes a rotating system configured to rotate the cylinder, and a control system configured to synchronize the deposition system with the cylinder.

A printing system for producing at least one three dimensional (3D) printed part is described. The printing system includes a deposition system configured to continuously deposit a layer onto a cylinder to outwardly extend a diameter of the cylinder, wherein the layer comprises a first pattern. The printing system also includes a rotating system configured to rotate the cylinder, and a control system configured to synchronize the deposition system with the cylinder.

A method of providing high-speed three dimensional (3D) printing is described. The method includes producing at least one three dimensional (3D) printed part. Producing the 3D part includes continuously constructing to extend outwardly a diameter of a rotating cylindrical core via continuous deposition of a layer, and defining a first pattern in the continuously deposited layer corresponding to a cross-section of the at least one 3D printed part.

A method of providing high-speed three dimensional (3D) printing is described. The method includes producing at least one three dimensional (3D) printed part. Producing the 3D part includes continuously constructing to extend outwardly a diameter of a rotating cylindrical core via continuous deposition of a layer, and defining a first pattern in the continuously deposited layer corresponding to a cross-section of the at least one 3D printed part.

A three-dimensional molding device includes: a stage; an ejection unit including a tip end portion in which a first nozzle hole and a second nozzle hole are formed adjacent to each other at a predetermined interval along a first axis, and configured to eject a material from the first nozzle hole and the second nozzle hole toward the stage; a position changing unit configured to change relative positions of the stage and the ejection unit along a second axis that is parallel to a deposition surface and that is orthogonal to the first axis; and a pressing unit disposed on a rear side in a movement direction of the ejection unit relative to the stage and configured to press the material deposited on the stage. The pressing unit presses a first deposition portion formed by the material that is ejected from the first nozzle hole and deposited, and a second deposition portion formed by the material that is ejected from the second nozzle hole and deposited at an interval from the first deposition portion, so as to couple the first deposition portion and the second deposition portion.

A three-dimensional molding device includes: a stage; an ejection unit including a tip end portion in which a first nozzle hole and a second nozzle hole are formed adjacent to each other at a predetermined interval along a first axis, and configured to eject a material from the first nozzle hole and the second nozzle hole toward the stage; a position changing unit configured to change relative positions of the stage and the ejection unit along a second axis that is parallel to a deposition surface and that is orthogonal to the first axis; and a pressing unit disposed on a rear side in a movement direction of the ejection unit relative to the stage and configured to press the material deposited on the stage. The pressing unit presses a first deposition portion formed by the material that is ejected from the first nozzle hole and deposited, and a second deposition portion formed by the material that is ejected from the second nozzle hole and deposited at an interval from the first deposition portion, so as to couple the first deposition portion and the second deposition portion.

A trim article includes an outer casing having an inner surface defining an interior portion of the outer casing. The outer casing includes a front surface having a plurality of through apertures disposed thereon. A core portion is disposed within the interior portion of the outer casing and includes first and second portions having variated densities relative to one another. The first and second portions include lattice matrices having variated patterns of interconnected links and associated cells that provide variated force deflection parameters between the first and second portions of the core portion. The outer casing and the core portion are integrated to define a monolithic structure comprised of a common material.

A trim article includes an outer casing having an inner surface defining an interior portion of the outer casing. The outer casing includes a front surface having a plurality of through apertures disposed thereon. A core portion is disposed within the interior portion of the outer casing and includes first and second portions having variated densities relative to one another. The first and second portions include lattice matrices having variated patterns of interconnected links and associated cells that provide variated force deflection parameters between the first and second portions of the core portion. The outer casing and the core portion are integrated to define a monolithic structure comprised of a common material.

A compactor is disclosed for use with an additive manufacturing print head. The compactor may include a housing connectable to the additive manufacturing print head. The compactor may also include a compacting wheel, and at least one spring disposed in the housing and configured to exert an axial force on the compacting wheel. The compactor may further include a piston moveable to adjust a distance between the housing and the compacting wheel.