Provided are systems and methods for forming a casing liner in a wellbore of a hydrocarbon well. The forming including disposing a casing liner print head in an annular region located between a casing pipe disposed in a wellbore of a hydrocarbon well and a wall of the wellbore, conducting a downhole lining operation including operating the casing liner print head to eject casing liner integrated structure material into the annular region to form, in the annular region, a casing liner integrated structure including contiguous voids formed in the casing liner integrated structure material, and depositing a cementitious material into the contiguous voids formed in the casing liner material to form, in the annular region, a casing liner including the casing liner integrated structure material and the cementitious material.

Described are systems and methods for multi-material printing. The systems and methods can utilize a stereolithographic printing device, a moving stage, and a microfluidic device. The microfluidic device can include a plurality of reservoirs, each reservoir housing a different ink for printing, and a microfluidic chip. The microfluidic chip can include a chamber that comprises a plurality of inlets, a printing region, and one or more outlets as well as an elastic membrane.

Described are systems and methods for multi-material printing. The systems and methods can utilize a stereolithographic printing device, a moving stage, and a microfluidic device. The microfluidic device can include a plurality of reservoirs, each reservoir housing a different ink for printing, and a microfluidic chip. The microfluidic chip can include a chamber that comprises a plurality of inlets, a printing region, and one or more outlets as well as an elastic membrane.

Embodiments related to systems and methods of forming structures on substrates (e.g., flexible substrates, fabrics, textiles, leathers) are disclosed. In some embodiments, a method of forming a structure on a substrate is provided. The method may involve submerging at least one surface of the substrate into a resin bath. The method may include patterning electromagnetic radiation through a window onto one or more regions of the substrate to polymerize the resin onto the one or more regions of the substrate. An alternative method may involve covering a surface of the substrate with a layer of polymeric powder. The alternative method may include directing electromagnetic radiation toward one or more regions on the surface of the substrate to heat the polymeric powder to form a layer on the surface of the substrate. A method of depositing an ultraviolet (UV)-curable material onto a substrate by a valve jetting process is also provided.

Embodiments related to systems and methods of forming structures on substrates (e.g., flexible substrates, fabrics, textiles, leathers) are disclosed. In some embodiments, a method of forming a structure on a substrate is provided. The method may involve submerging at least one surface of the substrate into a resin bath. The method may include patterning electromagnetic radiation through a window onto one or more regions of the substrate to polymerize the resin onto the one or more regions of the substrate. An alternative method may involve covering a surface of the substrate with a layer of polymeric powder. The alternative method may include directing electromagnetic radiation toward one or more regions on the surface of the substrate to heat the polymeric powder to form a layer on the surface of the substrate. A method of depositing an ultraviolet (UV)-curable material onto a substrate by a valve jetting process is also provided.

In an example, a method includes receiving, at a processor, object model data representing at least a portion of an object to be generated by an additive manufacturing apparatus by fusing build material. Using a processor and from the object model data, a property diffusion model for the object in object generation may be determined. Using a processor and based on the property diffusion model, a manufacturing boundary object shell around the object and encompassing an external volume may be determined. The shell may have a variable thickness determined so as to include build material for which, in generation of the object, the property modelled in the property diffusion model has a value which is predicted to conform to a predetermined parameter.

A method of making a three-dimensional object (11) from a light polymerizable dual cure resin (16), includes the steps of: (a) producing a green intermediate object by light polymerization of the resin in a stereolithography process (e.g., continuous liquid interface production); (i) the object comprising a body portion and a circumferential boundary portion (12) included in at least part of the body portion i (ii) the stereolithography process including overexposing the boundary portion (as compared to the exposure of the body portion) with light; (b) cleaning the intermediate object; and then (c) baking the object to produce the three-dimensional object.

A method of making a three-dimensional object (11) from a light polymerizable dual cure resin (16), includes the steps of: (a) producing a green intermediate object by light polymerization of the resin in a stereolithography process (e.g., continuous liquid interface production); (i) the object comprising a body portion and a circumferential boundary portion (12) included in at least part of the body portion i (ii) the stereolithography process including overexposing the boundary portion (as compared to the exposure of the body portion) with light; (b) cleaning the intermediate object; and then (c) baking the object to produce the three-dimensional object.

A multi-head 3D printing machine has first and second common guides for a plurality of deposition heads and provides a relative displacement between the deposition heads along a third guide, the first, second and third guides identifying a reference frame. The 3D printing machine further includes a control unit programmed to process a sequence of discretized position information within the reference frame and deposition information so as to deposit non-replica, non-mirrored segments while the deposition heads simultaneously operate.

A multi-head 3D printing machine has first and second common guides for a plurality of deposition heads and provides a relative displacement between the deposition heads along a third guide, the first, second and third guides identifying a reference frame. The 3D printing machine further includes a control unit programmed to process a sequence of discretized position information within the reference frame and deposition information so as to deposit non-replica, non-mirrored segments while the deposition heads simultaneously operate.