A three-dimensional molding apparatus is provided and includes a reservoir portion, a nozzle portion, a liquid-sending unit, and a temperature control unit that correspond to each of the two or more different types of materials, a molding stage, a relative movement mechanism for moving the stage and the nozzle portions, and a control computer. By using this apparatus, industrial additive manufacturing with two or more different types of materials can be realized with high precision, and high-definition molded products in which different types of materials are arbitrarily combined can be produced.

A print head for an additive manufacturing system includes a print head having a nozzle configured to a flowable extrudate to form an object, and an additive injection device configured to add an additive to the flowable extrudate prior to exiting the nozzle.

A print head for an additive manufacturing system includes a print head having a nozzle configured to a flowable extrudate to form an object, and an additive injection device configured to add an additive to the flowable extrudate prior to exiting the nozzle.

Provided is a method of producing a metal-plastic multi-layered hybrid structure by using laser three-dimensional (3D) printing, the method including printing a metal structure on a substrate by using a first laser, patterning an upper surface of the metal structure by using the first laser, printing a polymer bonding layer on the patterned metal structure by using the first laser, and printing a polymer structure on the polymer bonding layer by using a second laser having a wavelength longer than a wavelength of the first laser, wherein the printing of the polymer bonding layer includes forming an intermediate phase at an interface between the metal structure and the polymer bonding layer. A layered structure produced using the above method may include the intermediate phase having the effect of an oxygen inclusion connecting a metal and a polymer.

The present invention is a printing device using multiple inks and a printing method using thereof, and more specifically, relates to a three-dimensional printing method of a printed product with a cross-sectional pattern comprising a step of providing different inks into each partitioned spaces and applying the same pressure condition to the inks retained in the ink-receiving part, thereby extruding the inks into a single extruding port to prepare and print an extruded ink product, using the printing device comprising an ink extruding member comprising an ink-receiving part receiving the multiple inks in each partitioned space, and an ink-extruding part equipped with a single passage in which the multiple inks received in the ink-receiving part are passed together.

The present invention is a printing device using multiple inks and a printing method using thereof, and more specifically, relates to a three-dimensional printing method of a printed product with a cross-sectional pattern comprising a step of providing different inks into each partitioned spaces and applying the same pressure condition to the inks retained in the ink-receiving part, thereby extruding the inks into a single extruding port to prepare and print an extruded ink product, using the printing device comprising an ink extruding member comprising an ink-receiving part receiving the multiple inks in each partitioned space, and an ink-extruding part equipped with a single passage in which the multiple inks received in the ink-receiving part are passed together.

Various embodiments provide a method of additively manufacturing a part including depositing a layer of a powder on a working surface, depositing a binder solution on the layer of the powder at first locations, and depositing a sintering aid solution on the layer of the powder at second locations. The sintering aid solution comprises a sintering aid in a solvent. In various embodiments, the sintering aid enables an increased brown strength as compared to parts containing unbound powder. The method enables binders that provide high green strength to be used at the edges of the part, while also balancing a shortened debind time with an increased brown strength. Embodiments in which binder solution is deposited according to a predetermined pattern at second locations are also described.

Various embodiments provide a method of additively manufacturing a part including depositing a layer of a powder on a working surface, depositing a binder solution on the layer of the powder at first locations, and depositing a sintering aid solution on the layer of the powder at second locations. The sintering aid solution comprises a sintering aid in a solvent. In various embodiments, the sintering aid enables an increased brown strength as compared to parts containing unbound powder. The method enables binders that provide high green strength to be used at the edges of the part, while also balancing a shortened debind time with an increased brown strength. Embodiments in which binder solution is deposited according to a predetermined pattern at second locations are also described.

The invention relates to a device (1) for the production, in particular the production and metering, of a powder mixture for an additive manufacturing process. The powder mixture for the additive manufacturing process comprises a first powder arranged in a first container (2), and at least one further, in particular a second, powder arranged in at least one further, in particular a second, container (2′). An inlet of a first means of powder transport and/or metering (4) is arranged at the outlet (6) of the first container (2), and an inlet of a further, in particular a second, means of powder transport and/or metering (4′), is arranged at the outlet (6′) of the further, in particular the second, container (2′). The first powder can be supplied by means of the first means of transport and/or metering (4) and the further, in particular the second, powder can be supplied by means of the further, in particular the second, means of transport and/or metering (4′), in each case in a controlled manner, in particular in a controllable and/or regulatable manner, to at least one mixing container (5), preferably comprising at least one screen (10). The outlet (7) of the first means of transport and/or metering (4) and the outlet (7′) of the further, in particular the second, means of transport and/or metering (4′) are arranged in or above the mixing container (5) above each other, or next to each other, preferably above each other, or next to each other, and in each case above the screen (10).

A system is disclosed for additively manufacturing an object. The system may include a support, and a print head operatively connected to and moveable by the support. The print head may include an outlet configured to discharge a material, a leading device, and a trailing device pivotally connected to the leading device. The leading device may be configured to engage and move over the material after discharge. The trailing device may be configured to engage and move over the material at a location trailing the leading device.