Tailoring residual stress and hardness during direct metal deposition
First Claim
1. A method of controlling residual stress in conjunction with an additive manufacturing process, comprising the steps of:
- providing a substrate;
providing a deposition head including a laser outputting a laser beam surrounded by a metal powder feed;
heating a localized region of the substrate with the laser beam to create a melt pool while feeding metal powder into the melt pool to achieve the build-up of material in a deposition zone;
directing the beam of one or more lasers into the zone following the deposition of the material at a temperature less than the melting point of the material as a means of controlling residual stress; and
adjusting the location or intensity of the laser beam(s) used to control the stress to adjust the location and/or magnitude of the residual stress.
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Accused Products
Abstract
In a direct-metal deposition (DMD) process used to deposit successive layers in accordance with instructions from a CAD/CAM program, the laser beam, or an additional beam, is deployed as a localized heat treatment tool instead of a deposition tool. The use of laser energy during the process can minimize, if not eliminate, the periodic heat treatments now required for stress alleviation, thereby compressing the DMD fabrication cycle. In the preferred embodiment, every deposition run may be followed by a dry (i.e., without powder) run of one or more intensities to manipulate the stress magnitude and location. Since it is well known that residual stress is a function of cooling rate, a plurality of laser beams may alternatively be used to control the cooling rate of the deposited layer. Examples of stress reduction using H13 tool steel are provided.
64 Citations
9 Claims
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1. A method of controlling residual stress in conjunction with an additive manufacturing process, comprising the steps of:
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providing a substrate; providing a deposition head including a laser outputting a laser beam surrounded by a metal powder feed; heating a localized region of the substrate with the laser beam to create a melt pool while feeding metal powder into the melt pool to achieve the build-up of material in a deposition zone; directing the beam of one or more lasers into the zone following the deposition of the material at a temperature less than the melting point of the material as a means of controlling residual stress; and adjusting the location or intensity of the laser beam(s) used to control the stress to adjust the location and/or magnitude of the residual stress. - View Dependent Claims (2, 3, 4)
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5. In a direct-metal deposition (DMD) process wherein a laser beam is used to melt a powder feed to deposit a material on a substrate, a method of controlling the build-up of residual stress, comprising the steps of:
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providing a substrate; providing a deposition head including a laser outputting a laser beam surrounded by a metal powder feed; heating a localized region of the substrate with the laser beam to create a melt pool while feeding metal powder into the melt pool to achieve the build-up of material in a deposition zone; and following the deposition path with a laser beam incapable of remelting the material as a means of controlling the build-up of residual stress. - View Dependent Claims (6, 7, 8, 9)
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Specification
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- Resources
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Current AssigneeDM3D Technology, LLC
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Original AssigneeJyoti Mazumder
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InventorsMazumder, Jyoti
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Primary Examiner(s)Picard; Leo
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Assistant Examiner(s)Garland; Steven R.
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Application NumberUS09/608,874Time in Patent Office2,671 DaysField of Search700/123, 700/118, 700/119, 700/120, 700/145, 700/166, 700/212, 700/207, 228/158, 427/555, 419/45, 419/25, 219/121.6, 219/121.76, 219/121.65, 219/121.66, 219/121.85, 294/021.8US Class Current700/145CPC Class CodesB23K 2103/50 Inorganic material, e.g. me...B23K 26/32 taking account of the prope...B23K 26/34 Laser welding for purposes ...B33Y 40/00 Auxiliary operations or equ...C21D 9/50 for welded jointsY10T 29/49746 by applying fluent material...
