Apparatus, systems and methods for use in three-dimensional printing
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
B29C-041/02
B29C-041/34
출원번호
US-0189797
(2002-07-03)
발명자
/ 주소
Imiolek,Ireneusz J.
Gaylo,Christopher M.
출원인 / 주소
Therics, Inc.
대리인 / 주소
Hunton &
인용정보
피인용 횟수 :
32인용 특허 :
65
초록▼
Apparatus, systems and methods for use in three-dimensional printing are shown and described. Various embodiments of the invention allow for more precise and controlled delivery of heat to achieve interlayer drying; isolation of the working region from the outside for reasons of cleanliness and in c
Apparatus, systems and methods for use in three-dimensional printing are shown and described. Various embodiments of the invention allow for more precise and controlled delivery of heat to achieve interlayer drying; isolation of the working region from the outside for reasons of cleanliness and in connection with the vapors of organic solvents; better control of the temperature of the working region; better accuracy in the flowrates of binder fluid dispensed; matching of delivered flowrates for multiple dispensers; verification of delivered flowrate or drops; provision for easier changeover of the machine from one powder to another; cleanability; and other needs.
대표청구항▼
What is claimed is: 1. A powder bed assembly for a three-dimensional printing machine, the three-dimensional printing machine having a guide, the powder bed assembly comprising: a perimeter wall engaged with the guide, the perimeter wall being movable with respect to the guide between an operable p
What is claimed is: 1. A powder bed assembly for a three-dimensional printing machine, the three-dimensional printing machine having a guide, the powder bed assembly comprising: a perimeter wall engaged with the guide, the perimeter wall being movable with respect to the guide between an operable position in which the perimeter wall is oriented for use, and an inoperable position in which the perimeter wall is spaced apart from the operable position to facilitate loading powder into the perimeter wall or removing powder out of the perimeter wall; a carrier plate sized and shaped to closely conform to an interior of the perimeter wall, the carrier plate being slidably received within the perimeter wall to raise or lower a quantity of powder during operation of the three-dimensional printing machine; and siderails separated from the perimeter wall by gaps or channels, the gaps or channels being configured to allow powder to drop into them. 2. The powder bed assembly of claim 1, further comprising a gasket or seal located between the carrier plate and the perimeter wall. 3. The powder bed assembly of claim 1, further comprising suction means or an air knife or both, configured to create localized airflow into the gaps or channels so as to induce air which may carry airborne powder to flow into the gaps or channels, whereby the air which may carry airborne powder is discouraged from spreading to other regions of the machine. 4. The powder bed assembly of claim 1 wherein the siderails are configured for a component of the three-dimensional printing machine to roll on. 5. The powder bed assembly of claim 1 wherein a top surface of the perimeter wall and a top surface of the siderail are at the same elevation. 6. The powder bed assembly of claim 1 wherein a top surface of the perimeter wall and a top surface of the siderail are at different elevations. 7. The powder bed assembly of claim 1, further comprising a retaining member removably coupleable to the perimeter wall and the guide when the perimeter wall is in the operable position, such that the perimeter wall can be prevented from being inadvertently moved out of the operable position. 8. A powder bed assembly for a three-dimensional printing machine, the three-dimensional printing machine having a guide, the powder bed assembly comprising: a perimeter wall engageted with the guide, the perimeter wall being movable with respect to the guide between an operable position in which the perimeter wall is oriented for use, and an inoperable position in which the perimeter wall is spaced apart from the operable position to facilitate loading powder into the perimeter wall or removing powder out of the perimeter wall; a carrier plate sized and shaped to closely conform to an interior of the perimeter wall, the carrier plate being slidably received within the perimeter wall to raise or lower a quantity of powder during operation of the three-dimensional printing machine; and a sensor configured to register when the perimeter wall is in the operable position. 9. The powder bed assembly of claim 8, further comprising the alarm being configured to notify an operator when the perimeter wall is not in the operable position or to shut off or disable at least some portions of the three-dimensional printing machine or initiate a shutdown sequence when the perimeter wall is not in the operable position. 10. The powder bed assembly of claim 1, wherein the powder bed assembly is a feed bed assembly. 11. The powder bed assembly of claim 1, wherein the powder bed assembly is a build bed assembly. 12. A powder bed assembly and positioning system for a three-dimensional printing machine comprising: a powder bed assembly comprising a perimeter wall; at least one siderail separated from the perimeter wall by at least one of a gap and a channel; a carrier plate sized and shaped to closely conform to an interior of the perimeter wall, the carrier plate having a top surface configured to support a quantity of powder, the carrier plate being slidably received within the perimeter wall to raise or lower the quantity of powder during operation of the three-dimensional printing machine; and a vertical position controller releasably coupled to the carrier plate, the vertical position controller being operable to raise the carrier plate within the perimeter wall to present powder during operation, and being releasable from the carrier plate to allow the powder bed assembly to be removed from the three-dimensional printing machine. 13. The powder bed assembly and positioning system of claim 12 wherein the vertical position controller comprises a vacuum coupling releasably coupled to a bottom surface of the carrier plate. 14. A powder bed assembly and positioning system for a three-dimensional printing machine comprising: a powder bed assembly comprising a perimeter wall; a carrier plate sized and shaped to closely conform to an interior of the perimeter wall, the carrier plate having a top surface configured to support a quantity of powder, the carrier plate being slidably received within the perimeter wall to raise or lower the quantity of powder during operation of the three-dimensional printing machine; and a vertical position controller releasably coupled to the carrier plate, the vertical position controller being operable to raise the carrier plate within the perimeter wall to present powder during operation, and being releasable from the carrier plate to allow the powder bed assembly to be removed from the three-dimensional printing machine; wherein the vertical position controller further comprises a vacuum coupling releasably coupled to a bottom surface of the carrier plate, and a vacuum sensor to register a magnitude of the vacuum between the vacuum coupling and the bottom surface of the carrier plate. 15. The powder bed assembly and positioning system of claim 14 wherein the vertical position controller further comprises an O-ring to facilitate maintaining a vacuum between the vacuum coupling and the bottom surface of the carrier plate. 16. The powder bed assembly and positioning system of claim 14 wherein the vertical position controller further comprises an alarm configured to notify an operator when the magnitude of the vacuum is outside acceptable operating parameters. 17. A three-dimensional printing machine comprising: a guide fixed with respect to the three-dimensional printing machine; a powder bed assembly engaged with the guide, the powder bed assembly being movable with respect to the guide between an operable position in which the powder bed is oriented for use, and an inoperable position in which the powder bed is out of the operable position to facilitate loading powder into the powder bed or unloading powder from the bed; a retaining member removably coupleable to the powder bed and the guide when the powder bed is in the operable position, such that the powder bed can be prevented from being inadvertently moved out of the operable position; and at least one of a sensor and an alarm, wherein the at least one of a sensor and an alarm is responsive to the position of the retaining member. 18. A powder bed assembly for a three-dimensional printing machine, the three-dimensional printing machine having a global guide, the powder bed assembly comprising: a receiving structure engaged with the global guide, the receiving structure being movable with respect to the global guide between an operable position in which the receiving structure is oriented for use, and an inoperable position in which the receiving structure is spaced apart from the operable position, the receiving structure comprising a local guide; and a tray subassembly comprising: a tray subassembly perimeter wall engaged with the local guide, the tray subassembly perimeter wall being movable with respect to the local guide between an operable position in which the tray subassembly is oriented for use, and an inoperable position in which the tray subassembly is spaced apart from the operable position to facilitate loading powder into the tray subassembly or removing powder from the tray subassembly; and a carrier plate sized and shaped to closely conform to the tray subassembly perimeter wall, and configured to support a powder, the carrier plate being slidably received within the tray subassembly perimeter wall to raise and lower the powder during operation of the three-dimensional printing machine. 19. The powder bed assembly of claim 18, further comprising a gasket or seal located between the carrier plate and the tray subassembly perimeter wall. 20. The powder bed assembly of claim 18, further comprising a powder bed assembly perimeter wall having an internal configuration substantially identical to that of the tray subassembly perimeter wall, the tray subassembly perimeter wall and the powder bed assembly perimeter wall being in substantial alignment with each other when the tray subassembly is in the operable position, so that the carrier plate can pass from being slidably contained within the tray subassembly perimeter wall to being slidably contained within the powder bed assembly perimeter wall. 21. The powder bed assembly of claim 18 wherein the powder bed assembly is a feed bed assembly. 22. The powder bed assembly of claim 18 wherein the powder bed assembly is a build bed assembly. 23. The powder bed assembly of claim 18, further comprising a retaining member removably coupleable to the tray subassembly perimeter wall and the local guide when the tray subassembly perimeter wall is in the operable position, such that the tray subassembly perimeter wall can be prevented from being inadvertently moved out of the operable position. 24. The powder bed assembly of claim 18, further comprising a sensor configured to register when the powder bed assembly is in the operable position. 25. The tray subassembly of claim 18, further comprising a sensor configured to register when the tray subassembly is in the operable position. 26. The powder bed assembly of claim 18 wherein a tray subassembly retaining member is pivotably coupled to the local guide to rotate between a locked position in which a projection on the tray subassembly retaining member obstructs movement of the tray subassembly out of the operable position, and an unlocked position in which the projection on the tray subassembly retaining member does not obstruct movement of the tray subassembly out of the operable position. 27. A powder bed assembly and positioning system for a three-dimensional printing machine having a printhead configured to sequentially deposit fluid onto a plurality of layers of powder, the build bed comprising: a tray subassembly perimeter wall or powder bed assembly perimeter wall having a top edge at least substantially coplanar with a working surface; a carrier plate sized and shaped to closely conform to the tray subassembly perimeter wall, and configured to support the plurality of layers of powder, the carrier plate being slidably received within the tray subassembly perimeter wall to raise and lower the plurality of layers of powder during operation of the three-dimensional printing machine; and a vertical position controller releasably coupled to the carrier plate, the vertical position controller being operable to sequentially lower the carrier plate within the tray subassembly perimeter wall to create room in which each layer of powder can be presented, and being releasable from the carrier plate to allow the tray subassembly perimeter wall and carrier plate to be removed from the powder bed assembly. 28. The powder bed assembly and positioning system of claim 27 wherein the vertical position controller comprises a vacuum coupling releasably coupled to a bottom surface of the carrier plate. 29. The powder bed assembly and positioning system of claim 27 wherein the vertical position controller further comprises a vacuum coupling releasably coupled to a bottom surface of the carrier plate, and an O-ring to facilitate maintaining a vacuum between the vacuum coupling and the bottom surface of the carrier plate. 30. The powder bed assembly and positioning system of claim 27 wherein the vertical position controller further comprises a vacuum coupling releasably coupled to a bottom surface of the carrier plate, and a vacuum sensor to register the magnitude of the vacuum between the vacuum coupling and the bottom surface of the carrier plate. 31. The powder bed assembly and positioning system of claim 27 wherein the vertical position controller further comprises a vacuum coupling releasably coupled to a bottom surface of the carrier plate, a vacuum sensor to register the magnitude of the vacuum between the vacuum coupling and the bottom surface of the carrier plate, and an alarm configured to notify the operator when the magnitude of the vacuum is outside acceptable operating parameters. 32. The powder bed assembly of claim 27 wherein the carrier plate comprises at least one depression configured to receive a liquid during operation of the three-dimensional printing machine. 33. The powder bed assembly of claim 27 wherein the carrier plate comprises holes or porosity configured to permit the passage therethrough of a liquid during operation of the three-dimensional printing machine. 34. The powder bed assembly of claim 1, further comprising a separator structure suitable to limit downward motion of the carrier plate. 35. The powder bed assembly of claim 8, further comprising a separator structure suitable to limit downward motion of the carrier plate.
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