Example systems may include an energy source, a material delivery device, and a computing device. The computing device, based on a target height of a layer deposited on a component by directed energy deposition, may control an energy source directed at a component and may control a material delivery device. Controlling the energy source may include advancing an energy beam along a first path to form an advancing molten pool on the component. Controlling the material delivery device may include delivering a material to the advancing molten pool. The material may combine with the advancing molten pool to form a first raised track having an actual height. The layer may include the first raised track. A deposited region of the component may include the layer. The actual height may affect a resultant microstructure within the deposited region.

Example systems may include an energy source, a material delivery device, and a computing device. The computing device, based on a target height of a layer deposited on a component by directed energy deposition, may control an energy source directed at a component and may control a material delivery device. Controlling the energy source may include advancing an energy beam along a first path to form an advancing molten pool on the component. Controlling the material delivery device may include delivering a material to the advancing molten pool. The material may combine with the advancing molten pool to form a first raised track having an actual height. The layer may include the first raised track. A deposited region of the component may include the layer. The actual height may affect a resultant microstructure within the deposited region.

The present disclosure provides three-dimensional (3D) printing methods, apparatuses, and systems using, inter alia, a controller that regulates formation of at least one 3D object (e.g., in real time during the 3D printing); and a non-transitory computer-readable medium facilitating the same. For example, a controller that regulates a deformation of at least a portion of the 3D object. The control may be in situ control. The control may be real-time control during the 3D printing process. For example, the control may be during a physical-attribute pulse. The present disclosure provides various methods, apparatuses, systems and software for estimating the fundamental length scale of a melt pool, and for various tools that increase the accuracy of the 3D printing.

Building a complete ship hull, including many internals (bulkhead, holds), as a single, 3D printed device. A Stewart crane is used for gross positioning, while a multitude of beam deposition arms can be used for finer positioning. In a shipbuilding method, this means that the hull, floors, main piping, tanks, quarters, stairs, doorways, etc. can all be printed, in place, as part of a multi-step process.

In various embodiments, magnetic materials are fabricated in layer-by-layer fashion via additive manufacturing techniques.

A numerical control device includes: a program analyzing unit analyzing a transition of a moving velocity of a machining head and a transition of a supply amount of a material supplied to a beam-irradiation position based on a machining program; a movement distance calculating unit calculating a first distance based on a result of analysis performed by the program analyzing unit, the first distance being a length of a first movement section to a first position at which addition of the material to the workpiece is started, the first movement section being a section through which the machining head is moved while the head is accelerated; and a condition command generating unit generating a supply command to increase the supply amount of the material per hour from zero to a command value according to a machining condition while the machining head is moved through the first movement section.

A beam adjustment method includes: installing, on an irradiation surface to which an electron beam is radiated, a detection part having a Faraday cup catching electrical charges of the electron beam, and installing, on a side of an electron gun further than the detection part, a shielding plate having opening holes through which the electron beam is passable. The method includes causing, upon performing beam diameter measurement processing, the electron beam to pass through the opening holes, and radiating the electron beam to the Faraday cup. In addition, the method includes radiating, upon performing normal processing, the electron beam to the shielding plate.

A beam adjustment method includes: installing, on an irradiation surface to which an electron beam is radiated, a detection part having a Faraday cup catching electrical charges of the electron beam, and installing, on a side of an electron gun further than the detection part, a shielding plate having opening holes through which the electron beam is passable. The method includes causing, upon performing beam diameter measurement processing, the electron beam to pass through the opening holes, and radiating the electron beam to the Faraday cup. In addition, the method includes radiating, upon performing normal processing, the electron beam to the shielding plate.

An electron beam 3D printing machine, comprising a chamber for generating and accelerating an electron beam and an operating chamber in which a metal powder is melted, with the consequent production of a three-dimensional product. The chamber for generating and accelerating an electron beam houses means for generating an electron beam and means for accelerating the generated electron beam, while the operating chamber houses at least one platform for depositing the metal powder, metal powder handling means and electron beam deflection means. The accelerator means for the generated electron beam comprise a series of resonant cavities fed with an alternating signal.

An electron beam 3D printing machine, comprising a chamber for generating and accelerating an electron beam and an operating chamber in which a metal powder is melted, with the consequent production of a three-dimensional product. The chamber for generating and accelerating an electron beam houses means for generating an electron beam and means for accelerating the generated electron beam, while the operating chamber houses at least one platform for depositing the metal powder, metal powder handling means and electron beam deflection means. The accelerator means for the generated electron beam comprise a series of resonant cavities fed with an alternating signal.