Layers of build and support material on an intermediate transfer surface are exposed to a solvent using a solvent application station to make the build material tacky, without affecting the support material. Then, the intermediate transfer surface moves past a transfuse station (the transfuse station is positioned to receive the layers after exposure to the solvent) and a platen moves relative to the intermediate transfer surface to contact the platen to one of the layers on the intermediate transfer surface. The intermediate transfer surface transfers a layer of the build material and the support material to the platen each time the platen contacts the layers on the intermediate transfer surface at the transfuse station to successively form a freestanding stack of the layers of build and support material on the platen.

An additive manufacturing system for forming 3D parts includes a platen, a gantry, at least one print head, and a retention device. The gantry is configured to move the platen along a vertical axis. The at least one print head is configured to extrude part and/or support material onto a sheet substrate that is positioned on a support surface of the platen. The retention device includes a frame that is configured to press two or more edge portions of the sheet substrate against the support surface of the platen when the retention device is in a lowered position relative to the platen or support surface.

An additive manufacturing method produces a 3D part utilizes electrophotography-based additive manufacturing and molding processes. A layered structure having a cavity is printed on a build platform using at least one electrophotographic (EP) engine to develop imaged layers of powder material, and a transfusion assembly to stack and fuse the imaged layers on the build platform. Molding material is deposited into the cavity as the layered structure is printed, using a deposition unit. The molding material solidifies to form at least a portion of the 3D part, which may also include portions formed from imaged powder material.

A method of manufacturing a pattern includes providing a pattern of a first liquid on a medium, applying a powder material to the provided pattern, and providing a second liquid to the powder material applied to the first liquid.

A 3D part and a support structure is printed using an electrophotography-based additive manufacturing system. A support layer of the support structure is developed with a first electrophotography engine using a support material and transferred to a transfer medium. A large-particle part layer corresponding to a first portion of the 3D part is developed with a second electrophotography engine using a first part material and transferred to a transfer medium, and a plurality of small-particle part layers corresponding to a second portion of the 3D part are developed with one or more additional electrophotography engines using a second part material and transferred to a transfer medium. An average size of the first part material particles is at least two times that of the second part material particles. The transferred support layer, large-particle part layer and small-particle part layers are transfused to previously-printed layers using a layer transfusion assembly.

A part material for printing three-dimensional parts with an electrophotography-based additive manufacturing system, the part material including a composition having a semi-crystalline thermoplastic material and a charge control agent. The part material is provided in a powder form having a controlled particle size, and is configured for use in the electrophotography-based additive manufacturing system having a layer transfusion assembly for printing the three-dimensional parts in a layer-by-layer manner.

An information processing method for generating slice data in a shaping apparatus configured to manufacture a three-dimensional object including a shaping object by sequentially stacking shaping materials based on the slice data generated for each layer, the information processing method including the steps of: acquiring cross-sectional data; judging the presence/absence of a support required region; determining a type of the support to be disposed in the support required region; and generating, as the slice data of a target layer, image data including a structure region indicating the cross-section of the shaping object in the target layer and a support region indicating the cross-section of the support.

A support material contains at least one member selected from the group consisting of low molecular weight saccharides, polyvinyl alcohols, and polyalkylene glycols; non-water-soluble cellulose fibers; and a water-soluble cellulose derivative.

A 3D object according to the invention involves substrate layers infiltrated by a hardened material. The 3D object may be fabricated by a method comprising the following steps: Flatten a substrate layer. Position powder on all or part of a substrate layer. Repeat this step for the remaining substrate layers. Stack the substrate layers. Transform the powder into a substance that flows and subsequently hardens into the hardened material. The hardened material solidifies in a spatial pattern that infiltrates positive regions in the substrate layers and does not infiltrate negative regions in the substrate layers. In a preferred embodiment, the substrate is carbon fiber and excess substrate is removed by abrasion.

An additive manufacturing system comprising a transfer medium configured to receive the layers from a imaging engine, a heater configured to heat the layers on the transfer medium, and a layer transfusion assembly that includes a build platform, and is configured to transfuse the heated layers onto the build platform in a layer-by-layer manner to print a three-dimensional part.