A three-dimensional, additive manufacturing system is disclosed. The first and second printer modules form sequences of first patterned single-layer objects and second patterned single-layer objects on the first and second carrier substrates, respectively. The patterned single-layer objects are assembled into a three-dimensional object on the assembly plate of the assembly station. A controller controls the sequences and patterns of the patterned single-layer objects formed at the printer modules, and a sequence of assembly of the first patterned single-layer objects and the second patterned single-layer objects into the three-dimensional object on the assembly plate. The first transfer module transfers the first patterned single-layer objects from the first carrier substrate to the assembly apparatus in a first transfer zone and the second transfer module transfers the second patterned single-layer objects from the second carrier substrate to the assembly apparatus in a second transfer zone. The first and second printer modules are configured to deposit first and second materials under first and second deposition conditions, respectively. The first and second materials are different and/or the first and second deposition conditions are different.

A three-dimensional, additive manufacturing system is disclosed. The first and second printer modules form sequences of first patterned single-layer objects and second patterned single-layer objects on the first and second carrier substrates, respectively. The patterned single-layer objects are assembled into a three-dimensional object on the assembly plate of the assembly station. A controller controls the sequences and patterns of the patterned single-layer objects formed at the printer modules, and a sequence of assembly of the first patterned single-layer objects and the second patterned single-layer objects into the three-dimensional object on the assembly plate. The first transfer module transfers the first patterned single-layer objects from the first carrier substrate to the assembly apparatus in a first transfer zone and the second transfer module transfers the second patterned single-layer objects from the second carrier substrate to the assembly apparatus in a second transfer zone. The first and second printer modules are configured to deposit first and second materials under first and second deposition conditions, respectively. The first and second materials are different and/or the first and second deposition conditions are different.

A method of forming a multi-principal element alloy may include selecting a targeted composition, the targeted composition defining two or more elements and their respective proportions, determining a theoretical relative feed rate of two or more feedstock materials, determining a series of feedstock relative feed rates based on the theoretical relative feed rate, each member of the series defining a relative feed rate of the feedstock materials, forming a functionally graded material article in a directed energy deposition test process by successively matching a test deposition relative feed rate to each member of the series of feedstock relative feed rates, analyzing the functionally graded material article to determine a empirical feedstock relative feed rate of the series of feedstock relative feed rates, and forming the multi-principal element alloy in a directed energy deposition production process by matching a production deposition relative feed rate to the empirical feedstock relative feed rate.

A method of forming a multi-principal element alloy may include selecting a targeted composition, the targeted composition defining two or more elements and their respective proportions, determining a theoretical relative feed rate of two or more feedstock materials, determining a series of feedstock relative feed rates based on the theoretical relative feed rate, each member of the series defining a relative feed rate of the feedstock materials, forming a functionally graded material article in a directed energy deposition test process by successively matching a test deposition relative feed rate to each member of the series of feedstock relative feed rates, analyzing the functionally graded material article to determine a empirical feedstock relative feed rate of the series of feedstock relative feed rates, and forming the multi-principal element alloy in a directed energy deposition production process by matching a production deposition relative feed rate to the empirical feedstock relative feed rate.

A method of depositing a multiphase material. The method includes providing a Continuous Multifunctional Composite (CMC) phase containing at least one continuous element in a polymeric matrix, passing the CMC phase through a feeding system containing a cutting system, producing a predetermined length of the CMC phase, providing a flow a molten polymer such that the molten polymer and the CMC phase are merged into a continuous co-extrusion nozzle so as to produce a co-extruded multiphase material, and depositing the co-extruded multiphase material onto a surface. An apparatus for depositing a multiphase material. The apparatus contains a co-extrusion nozzle, a means to introduce a CMC phase and a molten polymer into the co-extrusion nozzle, such that the molten polymer and the CMC phase are co-extruded and deposited on a surface. An article containing a CMC phase containing continuous elements embedded in a polymer resin forming a multiphase structure.

The disclosure relates in particular to a machine for additive manufacturing by sintering or melting powder using an energy beam acting on a powder layer in a working zone, said machine comprising a device for layering said powder. The device is configured to distribute the powder that are able to travel over the working zone in order to distribute the powder in a layer having a final thickness suitable for additive manufacturing; transfer the powder to a distribution structure by gravity, and control the quantity of powder transferred to the distribution structure.

A coating device arrangement 1 for a 3D printer 100 is described, comprising a coating device 3 having a carrier structure 21a to 21c and a container 17 fixed to the carrier structure, defining an inner cavity for receiving particulate construction material, which leads to an opening for outputting the particulate construction material, a vibration device 23 configured to vibrate particulate construction material received in the container and thereby to influence the discharge of construction material from the opening, and a stroking member 15a attached to the coating device, configured to stroke particulate construction material output from the opening to thereby level and/or compress the output particulate material, and/or a closing device 31 configured to selectively close the opening and comprising a closing member 31a attached to the coating device 3, wherein the stroking member 15a and/or the closing member 31a are fixed to the carrier structure to be vibration-decoupled from the vibration generated by means of the vibration device in the container 17.

A powder handling system that includes a first powder deposition device for depositing a primary powder on a surface at a predetermined speed; and a second powder deposition device for depositing a secondary powder onto the primary powder in at least two directions relative to the surface, wherein the second powder deposition device includes a reservoir for containing the secondary powder; and a rotating shaft connected to the reservoir, wherein the rotating shaft includes a speed of rotation, an angle of rotation, a number of rotations, and a notch geometry, and wherein the rotating shaft is adapted to deposit the secondary powder onto the primary powder at a predetermined rate of deposition, and wherein the predetermined rate of deposition is controlled by adjusting the speed of rotation of the shaft, adjusting the angle of rotation of the shaft, adjusting the number of rotations of the shaft, adjusting the notch geometry of the shaft, or a combination thereof.

The invention relates to a feeding device (1) for feeding welding filler elements (310) for deposition welding processes, a positioning sleeve (300, 302) for a feeding device (1), a processing unit and a method for deposition welding. In particular, the invention relates to a feeding device (1) for feeding welding filler elements (310), in particular a wire-shaped and/or rod-shaped welding filler element (310), for a deposition welding processes, comprising a receiving unit (100) for receiving at least one welding filler element (310), a guide unit (200), which is arranged and designed to feed the welding filler element (310) to a deposition welding processes, the receiving unit (100) and the guide unit (200) being arranged and designed such that the welding filler element (310) is provided discontinuously to the guide unit (200).

The invention relates to a feeding device (1) for feeding welding filler elements (310) for deposition welding processes, a positioning sleeve (300, 302) for a feeding device (1), a processing unit and a method for deposition welding. In particular, the invention relates to a feeding device (1) for feeding welding filler elements (310), in particular a wire-shaped and/or rod-shaped welding filler element (310), for a deposition welding processes, comprising a receiving unit (100) for receiving at least one welding filler element (310), a guide unit (200), which is arranged and designed to feed the welding filler element (310) to a deposition welding processes, the receiving unit (100) and the guide unit (200) being arranged and designed such that the welding filler element (310) is provided discontinuously to the guide unit (200).