Additive Manufacturing for the Aerospace Industry
eBook - ePub

Additive Manufacturing for the Aerospace Industry

  1. 482 pages
  2. English
  3. ePUB (mobile friendly)
  4. Available on iOS & Android
eBook - ePub

Additive Manufacturing for the Aerospace Industry

About this book

Additive Manufacturing for the Aerospace Industry explores the design, processing, metallurgy and applications of additive manufacturing (AM) within the aerospace industry. The book's editors have assembled an international team of experts who discuss recent developments and the future prospects of additive manufacturing. The work includes a review of the advantages of AM over conventionally subtractive fabrication, including cost considerations. Microstructures and mechanical properties are also presented, along with examples of components fabricated by AM. Readers will find information on a broad range of materials and processes used in additive manufacturing.It is ideal reading for those in academia, government labs, component fabricators, and research institutes, but will also appeal to all sectors of the aerospace industry.- Provides information on a broad range of materials and processes used in additive manufacturing- Presents recent developments in the design and applications of additive manufacturing specific to the aerospace industry- Covers a wide array of materials for use in the additive manufacturing of aerospace parts- Discusses current standards in the area of aerospace AM parts

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Yes, you can access Additive Manufacturing for the Aerospace Industry by Francis H. Froes,Rodney Boyer in PDF and/or ePUB format, as well as other popular books in Technology & Engineering & Materials Science. We have over one million books available in our catalogue for you to explore.
1

Introduction to aerospace materials requirements and the role of additive manufacturing

Francis Froes1, Rodney Boyer2,3 and B. Dutta4, 1Advanced Materials Industries, Tacoma, WA, United States, 2School of Materials Science and Engineering, University of Shanghai for Science and Technology, Shanghai, P.R. China, 3RBTi Consulting, Bellevue, WA, United States, 4DM3D Technology, Auburn Hills, MI, United States

Abstract

The requirements for Aerospace Materials are presented including Specification details. The Additive Manufacturing (AM) techniques are described along with examples of parts fabricated by this method. Consideration is then given to different materials fabricated by AM including Metals, Ceramics and Polymers.

Keywords

Aerospace materials; additive manufacturing; metals; ceramics; polymers

1.1 Aerospace materials and their requirements

Aerospace materials are frequently metal alloys, although they also include polymeric based materials, that have either been developed for, or have come to prominence through, their use for aerospace purposes. Aerospace uses often require exceptional performance, strength or heat resistance, even at the cost of considerable expense in their fabrication or conventional machining. Others are chosen for their long-term reliability in this safety-conscious field, particularly for their resistance to fatigue loading. The field of materials engineering is an important one within aerospace engineering. Its practice is defined by the international standards bodies that maintain standards for the materials and processes involved, such as ASTM, AMS or company specifications (Table 1.1 shows specifications for additive manufacturing [AM]). Generally, not a lot of information is contained in company specs, but with the controls required, a company spec will be mandatory due to the complexity of the process, where the customer will want to know a lot more details than will ever get into a public spec due to protection of proprietary information. A further requirement is observer observation of fabrication of acceptable quality, including microstructures (Fig. 1.1).
Table 1.1
Specifications released and in-work for additive manufacturing (AM) components
Specification no.Specification titleStatus
AMS 4998Titanium alloy powder, Ti–6Al–4VReleased—1977
AMS 4999Titanium alloy laser deposited products, Ti–6Al–4V, annealedReleased—2002
AMS 7000Additive manufacture of aerospace parts from Ni-base superalloy 625 via laser powder bed processIn work
AMS 7001Ni base 625 superalloy powder for use in laser powder bed manufacturing of aerospace partsIn work
AMS 7002Process requirements for production of powder feedstock for use in laser powder bed additive manufacturing of aerospace partsIn work
AMS 7003Laser powder bed fusion processIn work
AMS 7004Titanium alloy preforms from high deposition rate additive manufacturing on substrate Ti–6Al–4V stress relievedIn work
AS9100Quality management systems—requirements for aviation, space, and defense organizationsIssued 1997, Current Rev. D, 2016
The AS (Aerospace Standards) are utilized for details with regard to quality management systems. They do not cover specific material requirements such as properties, inspection, etc.
image

Figure 1.1 Schematic showing powder bed fusion technology.

1.2 Additive manufacturing

In publications over the past few years [15], the cost of fabricating various titanium precursors and mill products has been discussed (very recently the price of TiO2 has risen to $2.00 per pound and TiCl4 to $0.55 per pound) and it has been pointed out that the cost of extraction is a small fraction of the total cost of a component fabricated by the cast and wrought (ingot metallurgy) approach. To reach a final component, the mill products must be machined, often with very high buy-to-fly ratios (which can reach as high as 40:1). The generally accepted cost of machining a component is that it doubles the cost of the component. The feedstock for AM can be a wire or a powder. Using powder, there are two basic approaches to AM: powder bed fusion (PBF) and direct energy deposition (DED), Figs. 1.1 and 1.2. The PBF technique allows the fabrication of complex features, hollow cooling passages, high precision parts, and single metal builds. The DED approach allows large build envelopes, high deposition rates, multiple materials, and addition of material to existing components. Mechanical properties are at least at ingot metallurgy levels (including fracture toughness). Examples of AM manufactured parts and parts which could be AM fabricated in an advanced engine are shown in Fig. 1.3.
image

Figure 1.2 Schematic showing DMD technology. DMD, Direct metal deposition.
image

Figure 1.3 (A) Examples of metallic parts fabricated by additive manufacturing. (B) The propulsion system for the F-35 lightening, which contains a substantial number of components that can be fabricated by additive manufacturing.

1.3 Additive manufacturing fabrication of various types of materials

The AM technique has been applied to metals, ceramics, and polymeric materials (Figs. 1.31.5)
image

Figure 1.4 Examples of ceramic parts fabricated by the additive manufacturing technique.
image

Figure 1.5 Examples of polymeric materials fabricated by additive manufacturing.
After the AM build, ceramic parts are porous and, if desired, can be infiltrated or fired in a postprocess step. This method is used for fine art ceramics. The primary advantages for 3-D printing, especially binder jetting (binder jetting is an AM process in which a liquid binding agent is selectively deposited to join powder particles. Layers of material are then bonded to form an object, for example by hot isostatic pressing) are low cost, high speed, scalability, ease of building parts in multiple materials, and versatility for use with ceramic materials. Originally evol...

Table of contents

  1. Cover image
  2. Title page
  3. Table of Contents
  4. Copyright
  5. List of Contributors
  6. 1. Introduction to aerospace materials requirements and the role of additive manufacturing
  7. 2. Review of additive manufacturing technologies and applications in the aerospace industry
  8. 3. Qualification and certification of metal additive manufactured hardware for aerospace applications
  9. 4. Design for metal additive manufacturing for aerospace applications
  10. 5. Structure formation in A.M. processes of Titanium and Ni-base alloys
  11. 6. Measurement of powder characteristics and quality for additive manufacturing in aerospace alloys
  12. 7. The processing and heat treatment of selective laser melted Al-7Si-0.6Mg alloy
  13. 8. Superalloys, powders, process monitoring in additive manufacturing
  14. 9. Fusion and/or solid state additive manufacturing for aerospace applications
  15. 10. Profile electron beam 3D metal printing
  16. 11. Additive manufacturing of titanium aluminides
  17. 12. Aerospace applications of the SLM process of functional and functional graded metal matrix composites based on NiCr superalloys
  18. 13. Surface roughness and fatigue properties of selective laser melted Ti–6Al–4V alloy
  19. 14. Aluminum alloys for selective laser melting – towards improved performance
  20. 15. Additive aerospace considered as a business
  21. 16. Surface texture characterization and optimization of metal additive manufacturing-produced components for aerospace applications
  22. 17. Developing and applying ICME + modeling tools to predict performance of additively manufactured aerospace parts
  23. 18. Nondestructive evaluation of additively manufactured metallic parts: In situ and post deposition
  24. 19. Combining additive manufacturing with conventional casting and reduced density materials to greatly reduce the weight of airplane components such as passenger seat frames
  25. 20. Synergetic technologies of direct layer deposition in aerospace additive manufacturing
  26. Index