Single Piece Vehicle Control Surface and Associated Systems and Methods of Manufacture

Content Provider	The Lens
Abstract	A method of manufacturing a vehicle control surface includes generating, using an electronic controller, a three-dimensional plan for the vehicle control surface. The three-dimensional plan includes, at least, non-vehicular support structure dimensions, for a non-vehicular support structure, and skin dimensions for a skin. The method further includes configuring the dimensions of the non-vehicular support structure based on build environment characteristics associated with an additive manufacturing process of the control surface. The additive manufacturing process is based on the three-dimensional plan. The method further includes fabricating the vehicle control surface, using the additive manufacturing process, based on the three-dimensional plan.
Related Links	https://www.lens.org/lens/patent/012-484-624-089-39X/frontpage
Language	English
Publisher Date	2019-01-24
Access Restriction	Open
Content Type	Text
Resource Type	Patent
Jurisdiction	United States of America
Date Applied	2017-07-18
Applicant	Boeing Co
Application No.	201715652689
Claim	A method ( 100 ) of manufacturing a vehicle control surface ( 200 ), the vehicle control surface including, at least, a non-vehicular support structure ( 220 ) and a skin ( 210 ), the method comprising: generating ( 120 ), using an electronic controller ( 20 ), a three-dimensional plan ( 22 ) for the vehicle control surface, the three-dimensional plan including, at least, non-vehicular support structure dimensions ( 26 ), for the non-vehicular support structure, and skin dimensions ( 24 ) for the skin; configuring ( 130 ) the dimensions of the non-vehicular support structure based on build environment characteristics associated with an additive manufacturing process of the control surface, the additive manufacturing process based on the three-dimensional plan; and fabricating ( 150 ) the vehicle control surface, using the additive manufacturing process, based on the three-dimensional plan. The method of claim 1 , further comprising detaching ( 160 ) the non-vehicular support structure from the vehicle control surface and any components thereof The method of claim 1 , wherein configuring the dimensions of the non-vehicular support structure includes designing the non-vehicular support structure as a rigid body mount ( 222 ), existing between a base plate, used in the additive manufacturing process, and the skin and any additional components of the vehicle control surface, the rigid body mount configured to conduct heat away from manufactured portions of the skin during the additive manufacturing process. The method of claim 3 , wherein configuring the dimensions of the non-vehicular support structure includes configuring filleting in the rigid body mount for manufacturing stress relief. The method of claim 1 , wherein configuring the dimensions of the non-vehicular support structure includes designing the support structure to include a plurality of tabs ( 228 ) at a first end of the vehicle control surface, the plurality of tabs conducting heat to distribute heat from the vehicle control surface during fabrication via the additive manufacturing process. The method of claim 5 , wherein configuring the dimensions of the support structure includes configuring the plurality of tabs for flexible strain relief. The method of claim 1 , wherein the vehicle control surface further includes internal ribbing ( 230 ) operatively coupled with the skin and configured as structural support for the skin, wherein the three-dimensional plan further includes internal ribbing characteristics ( 28 ) for the internal ribbing, and the method further comprising configuring the dimensions of the internal ribbing for providing structural support for the skin and based on the build environment characteristics associated with the additive manufacturing process. The method of claim 7 , wherein configuring the dimensions of the internal ribbing includes designing the internal ribbing to include egress passages ( 234 ) for removing excess powder during or after fabrication of the vehicle control surface, via the additive manufacturing process. The method of claim 8 , wherein configuring the dimensions of the non-vehicular support structure includes configuring the non-vehicular support structure to receive the excess powder, from the egress passages, for powder removal during or after fabrication via the additive manufacturing. The method of claim 7 , wherein configuring the dimensions of the support structure further includes altering a height of one or more of ribs of the internal in accordance with a gradual rate of cross sectional change, per a given distance, the gradual rate of cross sectional change being based on characteristics of the additive manufacturing process. The method of claim 10 , wherein the gradual rate of cross sectional change is a substantially linear function of the height of the one or more ribs versus the length of the one or more ribs. The method of claim 1 , further comprising controlling ( 152 ) cooling of the vehicle control surface within an additive manufacturing environment wherein the additive manufacturing process is performed, during one or both of a completed build state for the vehicle control surface and a partially complete build state for the vehicle control surface, the cooling is configured to control residual stresses caused by the additive manufacturing process. The method of claim 12 , wherein the additive manufacturing process is a selective laser sintering process including a series of layer-wise iterations, and wherein controlling cooling of the vehicle control surface includes controlling cooling after each of the series of layer-wise iterations to control residual stresses. The method of claim 1 , further comprising performing hot isostatic pressing ( 154 ) on the vehicle control surface within an additive manufacturing environment, wherein the additive manufacturing process is performed, during or after one or both of a completed build state for the vehicle control surface and a partially complete build state for the vehicle control surface. An airfoil ( 200 ) manufactured as a single workpiece in an additive manufacturing process, the airfoil comprising: a skin ( 210 ), the skin manufactured, via the additive manufacturing process, based on skin dimensions ( 24 ) for the skin, the skin dimensions being included in a three-dimensional plan ( 22 ) for the airfoil that is used in the additive manufacturing process; and a non-vehicular support structure ( 220 ), the support structure manufactured, via the additive manufacturing process, based on support structure dimensions ( 26 ) for the non-vehicular support structure, the non-vehicular support structure dimensions being included in the three-dimensional plan and configured based on build environment characteristics associated with the additive manufacturing process of the airfoil, the non-vehicular support structure being removable from airfoil upon completion of the additive manufacturing process. The airfoil of claim 15 , wherein the non-vehicular support structure includes a rigid body mount ( 222 ), the rigid body mount existing between a base plate ( 52 ), used in the additive manufacturing process, and the skin and any additional components of the airfoil, the rigid body mount being configured to conduct heat away from manufactured portions of the skin and any additional components of the airfoil, during the additive manufacturing process. The airfoil of claim 16 , wherein the non-vehicular support structure includes filleting in the rigid body mount for manufacturing stress relief. The airfoil of claim 15 , wherein the support structure includes a plurality of slits ( 226 ), the plurality of slits for conducting heat to distribute heat amongst the airfoil during fabrication via the additive manufacturing process. The airfoil of claim 18 , wherein the plurality of slits are configured for flexible strain relief during manufacture of the airfoil via the additive manufacturing process. The airfoil of claim 15 , further comprising internal ribbing ( 230 ) operatively coupled with the skin and configured as structural support for the skin, when the airfoil is in use, and configured based on build environment characteristics associated with the additive manufacturing process of the airfoi The airfoil of claim 20 , wherein the internal ribbing defines egress passages ( 232 ) for removing excess powder during or after fabrication of the airfoil via the additive manufacturing process. The airfoil of claim 21 , wherein the non-vehicular support structure is configured to receive the excess powder from the egress passages, for powder removal during or after fabrication via the additive manufacturing process. A system ( 10 ) for manufacturing a vehicle control surface ( 200 ) via an additive manufacturing process, the vehicle control surface including, at least, a non-vehicular support structure ( 220 ) and a skin ( 210 ), the system comprising: a controller ( 20 ), including a processor ( 21 ) and a memory ( 23 ), the controller configured to: generate ( 120 ) a three-dimensional plan ( 22 ) for the vehicle control surface ( 200 ), based on one or both of instructions stored on the memory and user input, the three-dimensional plan including, at least, non-vehicular support structure dimensions ( 26 ) for the support structure and skin dimensions ( 24 ) for the skin, configure ( 130 ) the dimensions of the non-vehicular support structure based on build environment characteristics associated with the additive manufacturing process, the additive manufacturing process based on the three-dimensional plan, and generate ( 140 ) fabrication instructions ( 40 ), based on the three-dimensional plan, for executing the additive manufacturing process; and a three-dimensional (3-D) printer ( 50 ) operatively associated with the controller, the 3-D printer including: a base plate ( 52 ) upon which a build ( 60 ) for the vehicle control surface rests during fabrication, a powder supply ( 66 ) for providing a powdered material to the base plate for each successive layer of the build, and a heat source ( 54 ) configured to selectively heat the powdered material to form the build, in a series of layer-wise iterations ( 62 ), and configured to operate in accordance with a toolpath for the heat source to selectively heat the powdered material, for each of the series of layer-wise iterations, the toolpath based, at least, on the fabrication instructions. The system of claim 23 , wherein the 3-D printer further includes a cooling device ( 70 ), configured to control cooling of the build within the 3-D printer during one or both of a completed build state for the build and a partially complete build state for the build, the cooling of the build configured to control residual stresses caused by the additive manufacturing process. The system of claim 24 , wherein controlling cooling of the build includes controlling cooling after each of the series of layer-wise iterations to control residual stresses. The system of claim 23 , wherein the 3-D printer further includes a system ( 72 ) for hot isostatic pressing for performing hot isostatic pressing on the build, during one or both of a completed build state for the vehicle control surface and a partially complete build state for the vehicle control surface, the hot isostatic pressing system including: a temperature control ( 74 ) for managing the temperature within the 3-D printer during hot isostatic pressing, a gas source ( 76 ) for providing gas for isostatic pressing; and a gas controller ( 78 ) for controlling flow of the gas into the 3-D printer for hot isostatic pressing. The system of claim 23 , further comprising an electric discharge machining (EDM) device, configured to detach ( 160 ) the non-vehicular support structure from the vehicle control surface, upon completion of the additive manufacturing process. The system of claim 23 , wherein the vehicle control surface is an airfoi
CPC Classification	CONTROL OR REGULATING SYSTEMS IN GENERAL;FUNCTIONAL ELEMENTS OF SUCH SYSTEMS;MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS WORKING METALLIC POWDER;MANUFACTURE OF ARTICLES FROM METALLIC POWDER;MAKING METALLIC POWDER ;APPARATUS OR DEVICES SPECIALLY ADAPTED FOR METALLIC POWDER ADDITIVE MANUFACTURING; i.e. MANUFACTURING OF THREE-DIMENSIONAL [3-D] OBJECTS BY ADDITIVE DEPOSITION; ADDITIVE AGGLOMERATION OR ADDITIVE LAYERING; e.g. BY 3-D PRINTING; STEREOLITHOGRAPHY OR SELECTIVE LASER SINTERING AEROPLANES;HELICOPTERS GROUND OR AIRCRAFT-CARRIER-DECK INSTALLATIONS SPECIALLY ADAPTED FOR USE IN CONNECTION WITH AIRCRAFT;DESIGNING; MANUFACTURING; ASSEMBLING; CLEANING; MAINTAINING OR REPAIRING AIRCRAFT; NOT OTHERWISE PROVIDED FOR;HANDLING; TRANSPORTING; TESTING OR INSPECTING AIRCRAFT COMPONENTS; NOT OTHERWISE PROVIDED FOR Climate Change Mitigation Technologies In The Production Or Processing Of Goods
Extended Family	012-484-624-089-39X 188-213-050-633-226
Patent ID	20190025797
Inventor/Author	Aston Richard W Langmack Michael J Herrmann Matthew J Cochran Russell W Munoz Philip R Hastings Nicole M
IPC	G05B19/4099 B33Y50/02 B64C3/18 B64C3/26 B64F5/00
Status	Active
Owner	The Boeing Company
Simple Family	012-484-624-089-39X 188-213-050-633-226
CPC (with Group)	G05B19/4099 B22F5/04 B22F10/28 B22F10/322 B22F10/64 B22F12/63 B22F12/70 B22F2998/10 B33Y10/00 B33Y40/20 B33Y50/02 B33Y80/00 B64C9/00 B64F5/10 G05B2219/35134 G05B2219/49007 Y02P10/25 Y02P90/02 B64C3/187 B64C3/26 B64F5/00
Issuing Authority	United States Patent and Trademark Office (USPTO)
Kind	Patent Application Publication