Three-dimensional printing systems and methods of their use
First Claim
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1. An apparatus for printing a three-dimensional object, the apparatus comprising:
- a platform configured to support a powder bed comprising a powder material;
a layer forming device configured to form multiple layers of the powder material as part of the powder bed, which layer forming device comprises a blade or a roller configured to translate in a first direction over an exposed surface of the powder bed to planarize the exposed surface of the powder bed;
an elevator operationally coupled with the platform, wherein the elevator comprises a motor configured to translate the platform in a second direction substantially perpendicular to the first direction;
a processing chamber having an internal volume configured to enclose at least the exposed surface of the powder bed during the printing, wherein the processing chamber includes a ceiling wall;
a laser configured to generate a laser beam that melts at least a portion of the powder bed to a molten material as part of the three-dimensional object during the printing;
a window coupled to the ceiling wall of the processing chamber, which window is configured to permit the laser beam to pass therethrough to the internal volume of the processing chamber;
a gas flow system configured to provide a flow of gas within the internal volume of the processing chamber, which processing chamber comprises at least one internal wall configured to direct the flow of gas in the internal volume to provide a stream of particles to progressively deposit as an optical mask on an internal surface of the window, which optical mask progressively absorbs energy from the laser beam and modifies a peak power density of the laser beam during melting of at least one of the multiple layers of the powder material, wherein the optical mask causes the peak power density of the laser beam to vary by (i) at least 5% after forming 3,000 cm3 of the molten material as compared to a variation of the peak power density of the laser beam transmitted through the window excluding the optical mask, and (ii) at least 10% after forming 5,000 cm3 of the molten material as compared to the variation of the peak power density of the laser beam transmitted through the window excluding the optical mask;
a galvanometer scanner configured to translate the laser beam across the exposed surface of the powder bed in accordance with a path, wherein the galvanometer scanner is external to the internal volume of the processing chamber; and
one or more controllers operationally coupled with the elevator, the layer forming device and the galvanometer scanner, which one or more controllers is configured to direct (a) the elevator to translate the platform in the second direction, (b) the layer forming device to translate in the first direction, and (c) the galvanometer scanner to translate the laser beam across the exposed surface of the powder bed in accordance with the path.
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Abstract
The present disclosure describes three-dimensional (3D) printing apparatuses, processes, software, and systems for producing high quality 3D objects. Described herein are printing apparatuses that facilitate control of energy beam characteristics using an optical mask during one or more printing operations.
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Citations
30 Claims
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1. An apparatus for printing a three-dimensional object, the apparatus comprising:
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a platform configured to support a powder bed comprising a powder material; a layer forming device configured to form multiple layers of the powder material as part of the powder bed, which layer forming device comprises a blade or a roller configured to translate in a first direction over an exposed surface of the powder bed to planarize the exposed surface of the powder bed; an elevator operationally coupled with the platform, wherein the elevator comprises a motor configured to translate the platform in a second direction substantially perpendicular to the first direction; a processing chamber having an internal volume configured to enclose at least the exposed surface of the powder bed during the printing, wherein the processing chamber includes a ceiling wall; a laser configured to generate a laser beam that melts at least a portion of the powder bed to a molten material as part of the three-dimensional object during the printing; a window coupled to the ceiling wall of the processing chamber, which window is configured to permit the laser beam to pass therethrough to the internal volume of the processing chamber; a gas flow system configured to provide a flow of gas within the internal volume of the processing chamber, which processing chamber comprises at least one internal wall configured to direct the flow of gas in the internal volume to provide a stream of particles to progressively deposit as an optical mask on an internal surface of the window, which optical mask progressively absorbs energy from the laser beam and modifies a peak power density of the laser beam during melting of at least one of the multiple layers of the powder material, wherein the optical mask causes the peak power density of the laser beam to vary by (i) at least 5% after forming 3,000 cm3 of the molten material as compared to a variation of the peak power density of the laser beam transmitted through the window excluding the optical mask, and (ii) at least 10% after forming 5,000 cm3 of the molten material as compared to the variation of the peak power density of the laser beam transmitted through the window excluding the optical mask; a galvanometer scanner configured to translate the laser beam across the exposed surface of the powder bed in accordance with a path, wherein the galvanometer scanner is external to the internal volume of the processing chamber; and one or more controllers operationally coupled with the elevator, the layer forming device and the galvanometer scanner, which one or more controllers is configured to direct (a) the elevator to translate the platform in the second direction, (b) the layer forming device to translate in the first direction, and (c) the galvanometer scanner to translate the laser beam across the exposed surface of the powder bed in accordance with the path. - View Dependent Claims (2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30)
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Specification
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Current AssigneeVelo3D, Inc.
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Original AssigneeVelo3D, Inc.
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InventorsBuller, Benyamin, Murphree, Zachary Ryan
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Primary Examiner(s)Sultana, Nahida
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Application NumberUS15/871,763Time in Patent Office323 DaysField of SearchUS Class CurrentCPC Class CodesB22F 10/28 Powder bed fusion, e.g. sel...B22F 10/32 of the atmosphere, e.g. com...B22F 10/322 of the gas flow, e.g. rate ...B22F 10/36 of energy beam parametersB22F 10/366 Scanning parameters, e.g. h...B22F 10/64 by thermal means control of...B22F 10/66 by mechanical meansB22F 10/77 of gasB22F 12/30 Platforms or substratesB22F 12/41 characterised by the type, ...B22F 12/45 Two or moreB22F 12/63 RollersB22F 12/67 BladesB22F 12/90 Means for process control, ...B22F 2201/40 Metal compoundsB22F 2999/00 Aspects linked to processes...B29C 64/153 using layers of powder bein...B29C 64/214 Doctor bladesB29C 64/232 for motion along the axis o...B29C 64/245 Platforms or substrates sup...View All
