Production of Energy Efficient Preform Structures (PEEPS)
Due to its low density, good structural characteristics, excellent fabrication properties, and attractive appearance, aluminum metal and its alloys continue to be widely utilized. The transportation industry continues to be the largest consumer of aluminum products, with aerospace as the principal driver for this use. Boeing has long been the largest single company consumer of heat-treated aluminum in the U.S. The extensive use of aluminum to build aircraft and launch vehicles has been sustained, despite the growing reliance on more structurally efficient carbon fiber reinforced composite materials. The trend in the aerospace industry over the past several decades has been to rely extensively on large, complex, thin-walled, monolithic machined structural components, which are fabricated from heavy billets and thick plate using high speed machining. The use of these high buy-to-fly ratio starting product forms, while currently cost effective, is energy inefficient, with a high environmental impact. The widespread implementation of Solid State Joining (SSJ) technologies, to produce lower buy-to-fly ratio starting forms, tailored to each specific application, offers the potential for a more sustainable manufacturing strategy, which would consume less energy, require less material, and reduce material and manufacturing costs. One objective of this project was to project the energy benefits of using SSJ techniques to produce high-performance aluminum structures if implemented in the production of the world fleet of commercial aircraft. A further objective was to produce an energy consumption prediction model, capable of calculating the total energy consumption, solid waste burden, acidification potential, and CO2 burden in producing a starting product form - whether by conventional or SSJ processes - and machining that to a final part configuration. The model needed to be capable of computing and comparing, on an individual part/geometry basis, multiple possible manufacturing pathways, to identify the best balance of energy consumption and environmental impact. This model has been created and populated with energy consumption data for individual SSJ processes and process platforms. Technology feasibility cases studies were executed, to validate the model, and confirm the ability to create lower buy-to-fly ratio performs and machine these to final configuration aircraft components. This model can now be used as a tool to select manufacturing pathways that offer significant energy savings and, when coupled with a cost model, drive implementation of the SSJ processes.
- Research Organization:
- The Boeing Company
- Sponsoring Organization:
- USDOE
- DOE Contract Number:
- EE0003483
- OSTI ID:
- 1042703
- Report Number(s):
- Final Technical Report- Production of Energy Efficient Preform Structures (PEEPS); TRN: US201213%%194
- Country of Publication:
- United States
- Language:
- English
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Related Subjects
36 MATERIALS SCIENCE
ACIDIFICATION
AEROSPACE INDUSTRY
AIRCRAFT
ALLOYS
ALUMINIUM
CARBON FIBERS
COMPOSITE MATERIALS
CONFIGURATION
ENERGY CONSUMPTION
ENVIRONMENTAL IMPACTS
FABRICATION
IMPLEMENTATION
MACHINING
MANUFACTURING
PRODUCTION
SOLID WASTES
ENERGY EFFICIENCY
Aluminum
Aluminum Preforms
Energy Consumption
Energy Consumption Model
Friction Stir Welding
Machining
Linear Friction Welding
Corner Angle Welding
buy-to-fly
Environmental Impact
Solid State Joining