A system is disclosed for additively manufacturing a composite structure. The system may include a head configured to discharge a continuous reinforcement that is at least partially coated with a matrix, and a housing trailing from the head and configured to at least partially enclose the continuous reinforcement after discharge. The system may also include a heat source disposed at least partially inside the oven, and a support configured to move the head during discharging.

Methods and systems for imprinting, including receiving template slippage data about a change in a position of a template relative to a reference position. Also, a desired actinic radiation pattern to expose formable material in an imprinting field under a template border region of the template may be received. In addition, a new actinic radiation pattern to expose the template border region that compensates for the template slippage may be determined. The formable material in the imprinting field on the substrate may be contacted with the template. The template border region may be exposed to the new actinic radiation pattern while the template is in contact with the formable material.

A vessel for receiving a stereolithographic resin that includes an oxygen permeable element comprising a stereolithographic resin receiving surface that is an interior vessel surface. The oxygen permeable element comprises at least one marginal surface separate from the stereolithographic resin receiving surface in fluid communication with a gas comprising oxygen for ingress of the oxygen and transport thereof to the stereolithographic resin receiving surface.

A nozzle structure for discharging printing material onto a substrate is presented. The nozzle structure comprises a tubular member having a distal part that faces the printing plane when in operation and defining an elongated inner cavity along the tubular member for placement a filament printing material. The tubular member comprises light input ports on the proximal part thereof for directing light toward inner surfaces thereof. The tubular member has an elongated tube portion and a distal tip portion at the distal part thereof, configured and operable as a light guide trapping and guiding the input light along the tubular member in a general direction toward the distal part, thereby continuously transferring light field to distal regions of the elongated inner cavity. The distal tip portion is configured to allow the trapped light to escape towards the printing plane, thereby heating a location on the printing plane facing the nozzle.

There is provided a 3D printing system, methods, and materials for the 3D printing of objects that include a cured hydrogel material, an uncured hydrogel material, and a support material. The cured hydrogel material may define a scaffold for organs or other biological structures. The 3D printing system selectively deposits the hydrogel material and support material, dries the hydrogel material, and selectively applies a catalyst to the hydrogel material to selectively cure the hydrogel material. Once the 3D printing has completed, the uncured hydrogel material may be drained and the support material may be melted or dissolved leaving a scaffold of cured hydrogel material that may be infused with living cells of the desired organ or biological structure.

Disclosed herein is a device (100) for making an object. The device (100) comprises a vessel (44) for receiving a radiation hardenable material (42). The device (100) comprises a fabrication platform assembly (7) comprising a fabrication platform (8) and having a first mode in which an orientation of the fabrication platform (8) is adjustable and a second mode in which the orientation of the fabrication platform (8) is fixed, and configured for positioning at the vessel (44) in the second mode to form a layer of the radiation hardenable material when so received between the fabrication platform (8) and a wall (46) of the vessel (44). The device (100) comprises a radiation source (48) arranged to illuminate the layer of radiation hardenable material when so formed to form one of a plurality of layers of the object. The device (100) comprises a guide (28) configured to receive the fabrication platform assembly (7) in the first mode and orientate the fabrication platform (8) when so received with respect to the guide (28). Also disclosed herein is a method for making an object.

The present disclosure provides methods of making a hydrated orthodontic article is provided. One method includes a) providing a photopolymerizable composition; b) selectively curing the photopolymerizable composition using actinic radiation to form an article in the shape of an orthodontic article having a plurality of layers of at least one photopolymerized polymer; and c) exposing the article to water by submersion in water, thereby hydrating the article. A sheet of the at least one photopolymerized polymer has a bending modulus when hydrated of 100 MPa or greater and 2200 MPa or less. Another method includes exposing the orthodontic article to water vapor and hermetically sealing the hydrated orthodontic article in a container. Hydrated orthodontic articles are also provided, including an orthodontic article that is prepared according to one of the methods. The present disclosure further provides kits, including an orthodontic article and instructions for exposing the orthodontic article to water to hydrate the orthodontic article, as well as including a hydrated orthodontic article hermetically sealed in a container.

A method of additive manufacturing (AM) includes dispensing a first building material formulation to form an outer region, and dispensing a second building material formulation to form an inner region, the outer region surrounding the inner region, the inner and outer regions being shaped to form a layer of the object; exposing the layer to a first curing condition, repeating the dispensing and the exposing to sequentially form a plurality of layers of the object and collectively exposing the plurality of layers to a second curing condition. The selections are such that the first building material formulation is hardened to a higher degree than the second building formulation. The outer regions form a hardened coating that at least partially encapsulates the inner regions. The second curing condition is other than the first curing condition and is selected to increase the degree that the inner region is hardened.

Described herein is an automatic or automated process for injection molding of coated components, more particularly coated soles of plastic, where first of all the molding tool is lined with a release agent composition and, after flashing of this release agent composition, a composition for forming the component is injected. After crosslinking of these two compositions, the coated component produced is removed from the molding tool and subjected optionally to an aftertreatment.

According to examples, an apparatus includes a processor and a memory on which is stored machine readable instructions. The instructions may cause the processor to identify an intended surface property level for a surface of a three-dimensional (3D) object, determine an amount of radiation to be applied as a flash of radiation onto the surface to obtain the intended surface property level, and output the determined amount of radiation to be applied as a flash of radiation, in which a radiation source is to flash apply the determined amount of radiation onto the surface of the 3D object.