A computer system (110) for part production using additive design receives a computer-aided design (CAD) file that describes physical dimensions of a target object (120). The computer system (110) identifies a physical boundary portion (300) of the target object within the CAD file. The computer system determines a target flow rate to infill the physical boundary portion (300) with the infill material. Additionally, the computer system (110) generates a first tool path to flow infill material into the physical boundary portion (300). Further, the computer system (110) sends instructions to a computer system in communication with a dispenser (100) that cause the dispenser to implement the first tool path while flowing the infill material into the physical boundary portion (300).

A method for reducing an additional printing time of a 3D object related to printing of an outer wall of the 3D object, the outer wall having an outer surface with an enhanced smoothness. The outer wall is arranged to envelope an inner part of the 3D object. The outer wall includes at least one region having a first outer wall part and a second outer wall part. The first outer wall part forms the outer surface with the enhanced smoothness. The second outer wall part is arranged between the first outer wall part and the inner part and provides a low-resolution part of the outer wall having a less smooth outer surface than the first outer wall part. Hence, the additional printing time related to printing the outer wall having an outer surface with an enhanced smoothness can be reduced. A 3D printing system adapted to perform the method and to a 3D printed object having the abovementioned outer wall.

A method for reducing an additional printing time of a 3D object related to printing of an outer wall of the 3D object, the outer wall having an outer surface with an enhanced smoothness. The outer wall is arranged to envelope an inner part of the 3D object. The outer wall includes at least one region having a first outer wall part and a second outer wall part. The first outer wall part forms the outer surface with the enhanced smoothness. The second outer wall part is arranged between the first outer wall part and the inner part and provides a low-resolution part of the outer wall having a less smooth outer surface than the first outer wall part. Hence, the additional printing time related to printing the outer wall having an outer surface with an enhanced smoothness can be reduced. A 3D printing system adapted to perform the method and to a 3D printed object having the abovementioned outer wall.

The present disclosure relates to composites, systems, and methods for making the same. In particular, the present disclosure relates to composites that are useful for thermal protection applications, and systems and methods for making the same.

The present disclosure relates to composites, systems, and methods for making the same. In particular, the present disclosure relates to composites that are useful for thermal protection applications, and systems and methods for making the same.

A method for making a dental appliance configured to position at least one tooth of a patient includes printing a hardenable liquid resin composition on a major surface of a polymeric material to form a pattern thereon, wherein the hardenable liquid resin composition includes a glass ionomer, a resin modified glass ionomer, and mixtures and combinations thereof. A dental appliance is formed from the polymeric material that includes an arrangement of cavities configured to receive one or more teeth.

A method for making a dental appliance configured to position at least one tooth of a patient includes printing a hardenable liquid resin composition on a major surface of a polymeric material to form a pattern thereon, wherein the hardenable liquid resin composition includes a glass ionomer, a resin modified glass ionomer, and mixtures and combinations thereof. A dental appliance is formed from the polymeric material that includes an arrangement of cavities configured to receive one or more teeth.

This disclosure provides an encapsulated cleansing composition that is free of talc and that includes a core particle including (1) tapioca starch, (2) potato starch, (3) at least one anionic surfactant, and (4) at least one amphoteric surfactant. The encapsulated cleaning composition also includes a coating disposed about at least a portion of the core particle and includes a polysaccharide.

A surface equalization apparatus designed to be compatible with a wide variety of part technologies, composite materials and part geometries. The apparatus works with software, chemistry, abrasives and media and includes an oblong, elongated input tank for holding media and a part. The input tank is connected to a motor mount, which is connected to an eccentric motor. When the motor is activated, the input tank begins to move in a vibrational, sinusoidal manner. The motion of the tank on attached springs generates a rotational flow of media in the tank. This creates a low amplitude/high frequency movement of the part through the tank. Surface structures divert media to prevent the part from contacting the side of the tank. Spray nozzles are positioned above the input tank. Acoustic damping foam is positioned around the central components. A cooling fan allows airflow through the apparatus.

A surface equalization apparatus designed to be compatible with a wide variety of part technologies, composite materials and part geometries. The apparatus works with software, chemistry, abrasives and media and includes an oblong, elongated input tank for holding media and a part. The input tank is connected to a motor mount, which is connected to an eccentric motor. When the motor is activated, the input tank begins to move in a vibrational, sinusoidal manner. The motion of the tank on attached springs generates a rotational flow of media in the tank. This creates a low amplitude/high frequency movement of the part through the tank. Surface structures divert media to prevent the part from contacting the side of the tank. Spray nozzles are positioned above the input tank. Acoustic damping foam is positioned around the central components. A cooling fan allows airflow through the apparatus.