Type : Bid Notification
Department of Energy National Energy Technology Laboratory Sources Sought 89243324NFE000154 Directed Energy Deposition Additive Manufacturing Machine ISSUE DATE: 10 April 2024 The U.S.
Department of Energy National Energy Technology Laboratory Sources Sought 89243324NFE000154 Directed Energy Deposition Additive Manufacturing Machine ISSUE DATE: 10 April 2024 The U.S.
The Colorado School of Mines (“Mines”) seeks bids for a Directed Energy Deposition (“DED”) Additive Manufacturing (“AM”) machine (“Machine”) on a “FOB Destination, prepay and add” basis. Mines requires a blown powder Directed Energy Deposition (“DED”) Additive Manufacturing (“AM”) machine (“Machine”) capable of fabricating...
NASA/NSSC has a requirement for Provide C103 Powder for Directed Energy Deposition (DED) Additive Manufacturing. NASA/NSSC intends to issue a sole source contract to ATI Special Alloys & Components under the authority of FAR 13.106-1(b)(1)(i). It has been determined that ATI Special Alloys & Components is the sole provider of C103 Powder for Directed Energy Deposition (DED) Additive Manufacturing.
THIS PURCHASE ORDER IS FOR PROVIDE C103 POWDER FOR DIRECTED ENERGY DEPOSITION (DED) ADDITIVE MANUFACTURING AS PER ATTACHED QUOTE 150592-3 08/17/2021..DELIVERY DATE 10/01/2021 Solicitation ID/Procurement Identifier: 80NSSC21P2519 Ultimate Completion Date: Fri Oct 01 17:00:00 GMT 2021
TECHNOLOGY LICENSING OPPORTUNITYIn-House Laser Atomization Solution for Directed Energy Deposition MachinesRevolutionize additive manufacturing capabilities with an innovative in-house laser atomization solution, allowing the creation of custom powder feedstock from various alloys within existing DED machines.
The Naval Nuclear Laboratory (NNL) is seeking methods capable of producing fine-grained, isotropic microstructures in gas metal arc-directed energy deposition (GMA-DED) additive manufacturing (AM) builds. This capability is of interest to enhance material properties and ultrasonic inspection ability.
The Naval Nuclear Laboratory (NNL) is seeking methods capable of producing fine-grained, isotropic microstructures in gas metal arc-directed energy deposition (GMA-DED) additive manufacturing (AM) builds. This capability is of interest to enhance material properties and ultrasonic inspection ability.