Supports for sintering additively manufactured parts
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B29C-064/40
B29C-064/141
B29C-064/295
B29C-064/245
B29C-031/04
B22F-003/11
B33Y-010/00
B29C-064/165
B29K-025/00
B29C-070/16
B29C-064/118
B29C-064/209
B29K-079/00
출원번호
US-0892741
(2018-02-09)
등록번호
US-10040241
(2018-08-07)
발명자
/ 주소
Mark, Gregory Thomas
출원인 / 주소
MARKFORGED, INC.
대리인 / 주소
Lando & Anastasi, LLP
인용정보
피인용 횟수 :
0인용 특허 :
67
초록▼
A method comprising forming a shrinking platform of layers of a composite, the composite including a metal particulate filler in a first matrix, forming a shrinking support of layers of the composite upon the shrinking platform, forming a first release layer of a release material upon the shrinking
A method comprising forming a shrinking platform of layers of a composite, the composite including a metal particulate filler in a first matrix, forming a shrinking support of layers of the composite upon the shrinking platform, forming a first release layer of a release material upon the shrinking support, the release material including a ceramic particulate and a second matrix, and forming a part of the composite upon the shrinking support to form a portable assembly from the combined shrinking platform, shrinking support, release layer and part, wherein substantially horizontal portions of the part are vertically supported by the shrinking platform, wherein the first release layer is configured, after sintering, to separate the part from the shrinking support and to allow the part to be readily removed from the shrinking support, and wherein the shrinking support is configured to prevent the part from distorting during sintering.
대표청구항▼
1. A method of reducing distortion in an additively manufactured part, comprising: forming a shrinking platform of successive layers of a composite, the composite including a metal particulate filler in a first matrix;forming a shrinking support of successive layers of the composite upon the shrinki
1. A method of reducing distortion in an additively manufactured part, comprising: forming a shrinking platform of successive layers of a composite, the composite including a metal particulate filler in a first matrix;forming a shrinking support of successive layers of the composite upon the shrinking platform;forming a first release layer of a release material upon the shrinking support, the release material including a ceramic particulate and a second matrix; andforming a part of the composite upon the shrinking support to form a portable assembly from the combined shrinking platform, shrinking support, release layer and part that is configured to be transported, debound, and sintered as a unit, wherein substantially horizontal portions of the part are vertically supported by the shrinking platform, wherein the first release layer is configured, after sintering, to separate the part from the shrinking support and to allow the part to be readily removed from the shrinking support, and wherein the shrinking support is configured to prevent the part from distorting from gravitational force during sintering. 2. The method according to claim 1, further comprising: depositing an open cell structure in at least one of the shrinking platform, the shrinking support, and the part; andpenetrating a fluid debinder into the open cell structure to debind at least one of the first matrix and the second matrix from within the open cell structure. 3. The method according to claim 1, wherein forming the first release layer comprises forming the first release layer to intervene at a non-horizontal surface of the part opposing a surface of the shrinking support, the non-horizontal surface of the part including at least one of a vertical surface, a curved surface, and a surface angled with respect to horizontal. 4. The method according to claim 1, wherein the first binder includes a first component and a second component, and further comprising: resisting, with the first component, deformation of the shape of the portable assembly during the simultaneous debinding of the first matrix and second matrix; andresisting, with the second component, deformation of the shape of the brown portable assembly caused by gravitational force. 5. The method according to claim 1, further comprising: forming a lateral support shell of the composite following a lateral contour of the part; andconnecting the lateral support shell to the lateral contour of the part by forming separable attachment protrusions of the composite between the lateral support shell and the part. 6. The method according to claim 1, further comprising: forming soluble support structures that resist downward forces during the forming of the part; anddissolving the soluble support structures before heating the brown portable assembly. 7. The method according to claim 1, further comprising: forming soluble support structures of the release material that resist downward forces during the forming of the part; anddebinding the second matrix to dissolve the second matrix of the soluble support structures and leave loose ceramic particulate before heating the brown portable assembly. 8. The method according to claim 1, further comprising: providing a sliding powder layer below the shrinking platform, of equal or larger surface area than a bottom of the shrinking platform, that reduces lateral resistance between the shrinking platform and an underlying surface;simultaneously, and in a same chamber, debinding a component of the first matrix and of the second matrix in the portable assembly to form a brown portable assembly; andheating the brown portable assembly to shrink all of the shrinking platform, the shrinking support, and the part together at a same rate as neighboring metal particles throughout the shape-retaining brown part assembly undergo atomic diffusion. 9. The method according to claim 8, wherein the underlying surface comprises a portable build plate, wherein forming the shrinking platform comprises forming the shrinking platform above the portable build plate, wherein providing the sliding powder layer comprises forming the sliding powder layer below the shrinking platform and above the portable build plate with the release material, and wherein the method further comprises: keeping the portable assembly together as a unit during the debinding;sintering the brown portable assembly during the heating; andkeeping the brown portable assembly together during sintering, and after sintering, separating the build plate, sliding powder layer, shrinking platform, first release layer and shrinking support from the part. 10. The method according to claim 8, further comprising: powderizing the first release layer during the heating to leave loose ceramic powder between the opposing surfaces. 11. The method according to claim 1, wherein forming the shrinking platform comprises forming the shrinking platform to form a foundation for the shrinking support, all portions of the part configured to commonly shrink from lateral positions located to be supported by the foundation of the shrinking platform, and wherein the shrinking platform is configured to hold the part and the shrinking support in relative position during shrinking of the same composite and to prevent movement of the shrinking support versus the part that tends to distort the part. 12. The method according to claim 11, further comprising: forming an interior support structure of the composite in a location supported by the part; andforming a second release layer of the release material intervening between the part and the interior support structure, wherein the second support structure is configured to be displaced through space while continuously supported by the part during shrinking of the brown portable assembly, and the second release layer is configured to powderize during the heating to leave a loose powder that allows the interior support structure to be readily removed from the part after sintering. 13. The method according to claim 12, further comprising: forming a third release layer of the release material intervening between a surface of the part and a top surface of the shrinking platform; andforming a lowermost portion of the part from successive layers of the composite directly upon the third release layer and directly opposing the top surface of the shrinking platform. 14. The method according to claim 11, further comprising: interconnecting the composite of the shrinking platform to the composite of the shrinking support to permit mass diffusion between neighboring metal particles found in the shrinking platform adjacent metal particles found in the shrinking support, to unitarily shrink the shrinking platform and the shrinking support. 15. The method according to claim 1, wherein the metal particulate filler includes metal particles distributed in a range of sizes. 16. A method of reducing distortion in an additively manufactured part; comprising: depositing a shrinking platform of successive layers of a composite, the composite including a metal particulate filler in a first matrix;depositing a plurality of shrinking supports of successive layers of the composite upon the shrinking platform;interconnecting the composite of the shrinking platform to the plurality of shrinking supports to permit mass diffusion between neighboring metal particles found in the shrinking platform that are adjacent to metal particles found in the plurality of shrinking supports, to unitarily shrink the shrinking platform and plurality of shrinking supports and providing a continuous foundation for the plurality of shrinking supports;depositing a first release layer of a release material upon the plurality of shrinking supports, the release material including a ceramic powder and a second matrix;depositing a part of the composite upon the plurality of shrinking supports;depositing a portable assembly from the combined shrinking platform, the plurality of shrinking supports, release layer and part;debinding the first matrix and second matrix within the portable assembly simultaneously and in a same chamber to form a brown portable assembly; andheating the brown portable assembly to a temperature sufficient to simultaneously sinter and shrink all of the shrinking platform, the plurality of shrinking supports, and the part together at a uniform rate as neighboring metal particles undergo mass diffusion, and to powderize the first release layer to leave loose ceramic powder between opposing surfaces, wherein the loose ceramic powder separates the part from the plurality of shrinking supports and allows the part to be readily removed from the plurality of shrinking supports after sintering. 17. The method according to claim 16, further comprising: depositing an open cell structure in at least one of the shrinking platform, the plurality of shrinking supports, and the part; andpenetrating a fluid debinder into the open cell structure to debind the matrix from within the open cell structure. 18. The method according to claim 16, wherein depositing the first release layer comprises forming the first release layer to intervene at a non-horizontal surface of the part opposing a surface of the plurality of shrinking supports, the non-horizontal surface of the part including at least one of a vertical surface, a curved surface, and a surface angled with respect to horizontal. 19. The method according to claim 16, wherein the first binder includes a first component and a second component, and wherein the method further comprises: resisting, with the first component, deformation of the shape of the portable assembly during the simultaneous debinding of the first matrix and second matrix; andresisting, with the second component, deformation of the shape of the brown portable assembly caused by gravitational force. 20. The method according to claim 16, further comprising: forming a lateral support shell of the composite following a lateral contour of the part; andconnecting the lateral support shell to the lateral contour of the part by forming separable attachment protrusions of the composite between the lateral support shell and the part. 21. The method according to claim 16, further comprising: forming soluble support structures that resist downward forces during the depositing of the part; anddissolving the soluble support structures before heating the brown portable assembly. 22. The method according to claim 16, further comprising: forming soluble support structures of the release material that resist downward forces during the depositing of the part; anddebinding the second matrix to dissolve the second matrix of the soluble support structures and leave loose ceramic particulate before heating the brown portable assembly. 23. The method according to claim 16, further comprising: providing a sliding powder layer below the shrinking platform, of equal or larger surface area than a bottom of the shrinking platform, that reduces lateral resistance between the shrinking platform and an underlying surface;transporting the portable assembly together as a unit from a printer to a first location for the debinding; andfollowing debinding, transporting the brown portable assembly together from the first location to a second location for sintering; andsintering the brown portable assembly at the second location during the heating. 24. The method according to claim 23, wherein the underlying surface comprises a portable build plate, wherein depositing the shrinking platform comprises forming the shrinking platform above the portable build plate, wherein providing the sliding powder layer comprises forming the sliding powder layer below the shrinking platform and above the portable build plate with the release material, wherein transporting the portable assembly comprises transporting the portable assembly together with the build plate as the unit from the printer to the first location for the debinding, wherein transporting the brown portable assembly comprises, following debinding, transporting the brown portable assembly together with the build plate from the first location to the second location for sintering, and wherein the method further comprises, following sintering, separating the build plate, sliding powder layer, shrinking platform, first release layer and the plurality of shrinking supports from the part. 25. The method according to claim 23, further comprising: powderizing the first release layer during the heating to leave loose ceramic powder between the opposing surfaces. 26. The method according to claim 16, wherein depositing the shrinking platform comprises forming the shrinking platform to be laterally larger than the part, and wherein the shrinking platform holds the part and the support structure in relative position during shrinking of the composite and prevents movement of the support structure versus the part that tends to distort the part. 27. The method according to claim 16, further comprising: forming an interior support structure of the composite in a location supported by the part; andforming a second release layer of the release material intervening between the part and the interior support structure, wherein the interior support structure is displaced through space while continuously supported by the part during shrinking of the brown portable assembly, and the second release layer powderizes during the heating to leave a loose powder that allows the interior support structure to be readily removed from the part after sintering. 28. The method according to claim 16, further comprising: forming a third release layer of the release material intervening between a surface of the part and a top surface of the shrinking platform; andforming a lowermost portion of the part from successive layers of the composite directly upon the third release layer and directly opposing the top surface of the shrinking platform. 29. The method according to claim 16, wherein the metal particulate filler includes metal particles distributed in a range of sizes. 30. The method according to claim 16, wherein the composite including the metal composite material is deposited by one of fused deposition modeling or binder jetting.
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Marcus Harris L. (Austin TX) Lakshminarayan Udaykumar (Austin TX) Bourell David L. (Austin TX), Method of producing parts by selective beam interaction of powder with gas phase reactant.
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