Methods for fabricating a multi-material composite structure are described. Methods for fabricating a multi-material composite structure include forming a first colloidal ink solution with a first material matrix, water, and a rheology modifying agent; forming a second colloidal ink solution with a second material matrix, water, and a rheology modifying agent; printing a first layer on a substrate using a first printing nozzle carrying the first colloidal ink solution; printing a second layer on top of the first layer using a second printing nozzle carrying the second colloidal ink solution; forming a 3D structure by printing a plurality of layers including the first layer and the second layer printed in an alternating pattern; and sintering the 3D structure to form the multi-material composite structure.

Methods for fabricating a multi-material composite structure are described. Methods for fabricating a multi-material composite structure include forming a first colloidal ink solution with a first material matrix, water, and a rheology modifying agent; forming a second colloidal ink solution with a second material matrix, water, and a rheology modifying agent; printing a first layer on a substrate using a first printing nozzle carrying the first colloidal ink solution; printing a second layer on top of the first layer using a second printing nozzle carrying the second colloidal ink solution; forming a 3D structure by printing a plurality of layers including the first layer and the second layer printed in an alternating pattern; and sintering the 3D structure to form the multi-material composite structure.

The present disclosure relates to an additive manufacturing system. In one embodiment the system makes use of a reservoir for holding a granular material feedstock. A nozzle is in communication with the reservoir for releasing the granular material feedstock in a controlled fashion from the reservoir to form at least one layer of a part. An excitation source is included for applying a signal which induces a controlled release of the granular material feedstock from the nozzle as needed, to pattern the granular material feedstock as necessary to form a layer of the part.

The present disclosure relates to an additive manufacturing system. In one embodiment the system makes use of a reservoir for holding a granular material feedstock. A nozzle is in communication with the reservoir for releasing the granular material feedstock in a controlled fashion from the reservoir to form at least one layer of a part. An excitation source is included for applying a signal which induces a controlled release of the granular material feedstock from the nozzle as needed, to pattern the granular material feedstock as necessary to form a layer of the part.

An additive manufacturing system (100) includes a build tool (110) configured to deposit a feedstock material and/or deliver consolidation energy promoting consolidation of the feedstock material within an accessible range defining a build space. The system also includes a controller (120) configured to determine a build trajectory through the build space, where the build trajectory includes build points at which the feedstock material and/or the consolidation energy is applied (202), determine respective consolidation times of the feedstock material for one or more of the plurality of the build points (204), determine a deposition rate at which the feedstock material is deposited and/or consolidation energy is delivered to the feedstock material based at least in part on the determined consolidation times of the feedstock material (204), and cause the build tool to build an object in accordance with the determined build trajectory and the determined deposition rate (208).

An additive manufacturing system (100) includes a build tool (110) configured to deposit a feedstock material and/or deliver consolidation energy promoting consolidation of the feedstock material within an accessible range defining a build space. The system also includes a controller (120) configured to determine a build trajectory through the build space, where the build trajectory includes build points at which the feedstock material and/or the consolidation energy is applied (202), determine respective consolidation times of the feedstock material for one or more of the plurality of the build points (204), determine a deposition rate at which the feedstock material is deposited and/or consolidation energy is delivered to the feedstock material based at least in part on the determined consolidation times of the feedstock material (204), and cause the build tool to build an object in accordance with the determined build trajectory and the determined deposition rate (208).

An additive manufacturing system (100) includes a build tool (110) configured to deposit a feedstock material and/or deliver consolidation energy promoting consolidation of the feedstock material within an accessible range defining a build space. The system also includes a controller (120) configured to determine a build trajectory through the build space, where the build trajectory includes build points at which the feedstock material and/or the consolidation energy is applied (202), determine respective consolidation times of the feedstock material for one or more of the plurality of the build points (204), determine a deposition rate at which the feedstock material is deposited and/or consolidation energy is delivered to the feedstock material based at least in part on the determined consolidation times of the feedstock material (204), and cause the build tool to build an object in accordance with the determined build trajectory and the determined deposition rate (208).

A three-dimensional shaping device includes: a discharge unit configured to discharge a shaping material; a weight measuring unit configured to measure a weight of the shaping material discharged from the discharge unit; and a control unit configured to control the discharge unit and the weight measuring unit to shape a three-dimensional shaped object by stacking layers of the shaping material in a shaping region of a stage, in which the control unit is configured to control the weight measuring unit to measure the weight of the shaping material discharged from the discharge unit, determine whether a predetermined amount of the shaping material is discharged from the discharge unit based on the weight measured by the weight measuring unit, and when it is determined that the predetermined amount of the shaping material is not discharged, control the discharge unit so that the predetermined amount of the shaping material is discharged from the discharge unit.

A three-dimensional shaping device includes: a discharge unit configured to discharge a shaping material; a weight measuring unit configured to measure a weight of the shaping material discharged from the discharge unit; and a control unit configured to control the discharge unit and the weight measuring unit to shape a three-dimensional shaped object by stacking layers of the shaping material in a shaping region of a stage, in which the control unit is configured to control the weight measuring unit to measure the weight of the shaping material discharged from the discharge unit, determine whether a predetermined amount of the shaping material is discharged from the discharge unit based on the weight measured by the weight measuring unit, and when it is determined that the predetermined amount of the shaping material is not discharged, control the discharge unit so that the predetermined amount of the shaping material is discharged from the discharge unit.

A printer includes a heat control device configured to prevent a temperature of a part that is printed by the printer from decreasing by more than about 5° C. as a height of the part increases from about 0 mm to about 30 mm. The heat control device includes a gas curtain source that is configured to generate a gas curtain that at least partially surrounds at least a portion of the part.