The present invention relates to a chamber environment controlling apparatus for a three-dimensional bioprinter including a printing chamber having an internal space in which printing is performed and which is defined by wall surfaces including sidewalls. The apparatus may include a temperature adjustor including a heater configured to heat the internal space of the printing chamber and an air circulator including an air guide portion extending from an outside of the printing chamber along a sidewall on one side and formed so that air flowing in through an inlet moves along an inside, is heated by the temperature adjustor, and is discharged into the internal space of the printing chamber through an outlet, a circulation fan configured to circulate air along the air guide portion, and a filter configured to filter the air circulating along the air guide portion.

An apparatus for heating three-dimensional printing filaments comprising a heating chamber including an insulation lining and spool holders mounted at a base of the heating chamber, a heater fan assembly mounted above the heating chamber, wherein the heater fan assembly comprises a powered fan and heater configured to heat air and circulate the heated air to the heating chamber, and a diverter situated between the heater fan assembly and the heating chamber, wherein the diverter splits and directs the heated air to the heating chamber through a pair of channels. The apparatus further comprising a plurality of exhaust ports at top sidewall portions and bottom sidewall portions of the heating chamber, wherein the plurality of exhaust ports allowing the heated air to escape from the heating chamber, and fitting adapters comprising apertures that allow filament material to be dispensed from the heating chamber.

A three-dimensional printer for generating a printed component, includes a build substrate defining a surface that supports the printed component and a heated nozzle including a nozzle body. The heated nozzle is configured to deposit a build material upon either the build substrate or the printed component. The three-dimensional printer also includes a heated plate including one or more heating elements and a main body that defines an opening for receiving the nozzle body of the heated nozzle. The one or more heating elements are configured to heat at least a portion of the heated plate to a predefined temperature, where a volume of hot air is created between the heated plate and the printed component when the heated plate is heated to the predefined temperature.

A three-dimensional printer for generating a printed component, includes a build substrate defining a surface that supports the printed component and a heated nozzle including a nozzle body. The heated nozzle is configured to deposit a build material upon either the build substrate or the printed component. The three-dimensional printer also includes a heated plate including one or more heating elements and a main body that defines an opening for receiving the nozzle body of the heated nozzle. The one or more heating elements are configured to heat at least a portion of the heated plate to a predefined temperature, where a volume of hot air is created between the heated plate and the printed component when the heated plate is heated to the predefined temperature.

A build material dispensing device may include a material spreader to spread an amount of build material along a build platform, and at least one hopper for dispensing the build material. The at least one hopper dispenses a plurality of doses of the build material in front of the progression of the material spreader as the material spreader is moved over the build platform.

A build material dispensing device may include a material spreader to spread an amount of build material along a build platform, and at least one hopper for dispensing the build material. The at least one hopper dispenses a plurality of doses of the build material in front of the progression of the material spreader as the material spreader is moved over the build platform.

A system is disclosed for additively manufacturing a composite structure. The system may include a support, and a print head connected to and moveable by the support. The print head may have a first tool center point associated with discharge of a first material, and a second tool center point associated with discharge of a second material that is a type different than the first material.

A system is disclosed for additively manufacturing a composite structure. The system may include a support, and a print head connected to and moveable by the support. The print head may have a first tool center point associated with discharge of a first material, and a second tool center point associated with discharge of a second material that is a type different than the first material.

A three-dimensional modeling device includes a modeling unit having a nozzle configured to eject a modeling material, a stage, a movement mechanism unit for changing a relative position between the nozzle and the stage, a measuring unit, a reference unit having a reference surface arranged at a position that corresponds to a deposition surface of the stage in an intersecting direction and where the reference surface can face the measuring unit, the reference unit being separate from the nozzle, and a control unit controlling the modeling unit and the movement mechanism unit. The control unit controls the measuring unit to measure a first distance between the measuring unit and the reference surface and a second distance between the measuring unit and the distal end surface, and decides a distance between a distal end surface of the nozzle and the deposition surface, based on the first and second distances.

A three-dimensional modeling device includes a modeling unit having a nozzle configured to eject a modeling material, a stage, a movement mechanism unit for changing a relative position between the nozzle and the stage, a measuring unit, a reference unit having a reference surface arranged at a position that corresponds to a deposition surface of the stage in an intersecting direction and where the reference surface can face the measuring unit, the reference unit being separate from the nozzle, and a control unit controlling the modeling unit and the movement mechanism unit. The control unit controls the measuring unit to measure a first distance between the measuring unit and the reference surface and a second distance between the measuring unit and the distal end surface, and decides a distance between a distal end surface of the nozzle and the deposition surface, based on the first and second distances.