Skip to main content
SpringerLink
Log in

The Case for Physical Experiments in a Digital Age

  • Conference paper
  • First Online:
Proceedings of the 9th International Symposium on Superalloy 718 & Derivatives: Energy, Aerospace, and Industrial Applications

Part of the book series: The Minerals, Metals & Materials Series ((MMMS))

Abstract

Casting and solidification simulations, heat transfer models, hot isostatic press consolidation simulations, hot working simulations, phase equilibrium calculations… the list is quite long of digital technologies embraced by ATI and other producers of specialty materials and components. Through virtual experimentation, product development cycle time and cost is reduced, the potential impact of process upsets can be determined without testing, and sensitivity to process variation can be assessed prior to ever making any metal, among other efficiency and cost benefits. Nevertheless, effective, efficient development of superalloys manufacturing processes requires that these digital experiments are complemented by careful physical experiments at the pilot scale in order to manage risk and expense of scale-up. Pilot scale development provides critical insight into factors not easily computed, such as the integrity of a VIM cast electrode, the variation in segregation during VAR melting , and cracking due to grain structure or surface condition during hot working. ATI integrates use of physical experiments conducted in pilot research facilities and computational methods to facilitate both new product development and development of the manufacturing method. Such an approach has been instrumental in the development of ATI 718Plus® alloy and René 65 alloy and an array of new products including cast-and-wrought, powder , and titanium alloys and components. This paper will discuss the advantages of using physical experiments to streamline the development of new products and manufacturing methods and some of the ways ATI capitalizes on the combined approach.

This is a preview of subscription content, log in via an institution to check access.

Access this chapter

Log in via an institution
Chapter
USD 29.95
Price excludes VAT (USA)
  • Available as PDF
  • Read on any device
  • Instant download
  • Own it forever
eBook
USD 169.00
Price excludes VAT (USA)
  • Available as EPUB and PDF
  • Read on any device
  • Instant download
  • Own it forever
Softcover Book
USD 219.99
Price excludes VAT (USA)
  • Compact, lightweight edition
  • Dispatched in 3 to 5 business days
  • Free shipping worldwide - see info
Hardcover Book
USD 219.99
Price excludes VAT (USA)
  • Durable hardcover edition
  • Dispatched in 3 to 5 business days
  • Free shipping worldwide - see info

Tax calculation will be finalised at checkout

Purchases are for personal use only

Institutional subscriptions

References

  1. Kuehmann CJ, Olson GB (2009) Computational materials design and engineering. Mater Sci Technol 25(4):472–478

    Article  CAS  Google Scholar 

  2. Rae C (2009) Alloys by design: modelling next generation superalloys. Mater Sci Technol 25(4):479–487

    Article  CAS  Google Scholar 

  3. Thomas M, Murray S, Furrer D (2010) Introducing new materials into aero engines—risks and rewards, a user’s perspective. In: Paper presented at the 7th international symposium on superalloy 718 and derivatives, pp 3–11

    Google Scholar 

  4. Kermanpur A, Tin S, Lee PD, McLean M (2004) Integrated modeling for the manufacture of aerospace discs: grain structure evolution. JOM 56(3):72–78

    Article  CAS  Google Scholar 

  5. Minisandram RS, Srivatsa SK (2001) Deformation modeling applications in the aircraft engine industry. In: Mori K (ed) Simulation of materials processing: theory, methods and applications—Proceedings of the 7th international conference on numerical methods in industrial forming processes—NUMIFORM 2001, Toyohashi, Japan, 18–20 June 2001. AA Balkema Publishers

    Google Scholar 

  6. Bratberg J, Mao H, Kjellqvist L, Engström A, Mason P, Chen Q (2012) The development and validation of a new thermodynamic database for Ni-based alloys. In: Paper presented at the proceedings of the international symposium on superalloys, pp 803–812

    Chapter  Google Scholar 

  7. Patel AD, Minisandram RS, Evans DG (2004) Modeling of vacuum ARC remelting of alloy 718 ingots. In: Paper presented at the proceedings of the international symposium on superalloys, pp 917–924

    Google Scholar 

  8. Kelkar KM, Patankar SV, Srivatsa SK, Minisandram RS, Evans DG, Debarbadillo JJ, Sizek HA (2013) Computational modeling of electroslag remelting (ESR) process used for the production of high-performance alloys. In: Paper presented at the international symposium on liquid metal processing and casting 2013, LMPC 2013, pp 3–12

    Chapter  Google Scholar 

  9. Walters J, Wu W, Arvind A, Li G, Lambert D, Tang J (2000) Recent development of process simulation for industrial applications. J Mater Process Technol 98(2):205–211

    Article  Google Scholar 

  10. Bramley AN, Mynors DJ (2000) The use of forging simulation tools. Mater Des 21(4):279–286

    Article  Google Scholar 

  11. White House Office of Science and Technology Policy: Materials Genome Initiative for Global Competitiveness White Paper, June 2011

    Google Scholar 

  12. Thomas JP, Montheillet F, Semiatin SL (2007) A geometric framework for mesoscale models of recrystallization. Metall Mater Trans A 38 A(9):2095–2109

    Article  Google Scholar 

  13. Xie X, Wang G, Dong J, Xu C, Cao W, Kennedy R (2005) Structure stability study on a newly developed nickel-base superalloy—Allvac® 718Plus™. In: Paper presented at the proceedings of the international symposium on superalloys and various derivatives, pp 179–191

    Google Scholar 

  14. Bockenstedt KJ, O’Brien CM, Minisandram RS, Smith GJ, Bryant DJ (2016) Conventionally forged RR1000 billet for forged turbine components. In: Paper presented at the proceedings of the international symposium on superalloys, January 2016, pp 479–486

    Chapter  Google Scholar 

  15. Minisandram RS, Jackman LA, Russell JL, Lasonde ML, Heaney JA, Powell AM (2014) Recrystallization response during thermo-mechanical processing of alloy rené 65 billet. In: Paper presented at the 8th international symposium on superalloy 718 and derivatives, pp 95–105

    Google Scholar 

  16. Cao W, Kennedy R (2004) Role of chemistry in 718-type alloys—Allvac® 718Plus™ alloy development. In: Paper presented at the proceedings of the international symposium on superalloys, pp 91–99

    Google Scholar 

  17. McDevitt E (2010) Effect of temperature and strain during forging on subsequent delta phase precipitation during solution annealing in ATI 718plus® alloy. In: Paper presented at the 7th international symposium on superalloy 718 and derivatives, pp 307–319

    Google Scholar 

  18. Casanova A, Loehnert K, Huenert D, Hardy M, Rae C (2016) Systematic evaluation of microstructural and thermo-mechanical effects on the as-forged condition of alloy ATI 718Plus®. In: Paper presented at the proceedings of the international symposium on superalloys, January 2016, pp 427–436

    Chapter  Google Scholar 

  19. Shima S, Oyane M (1976) Plasticity theory for porous metals. Int J Mech Sci 18(6):285–291

    Article  Google Scholar 

  20. Svoboda A, Bjork L, Haggblad H (1995) Determination of material parameters for simulation of hot isostatic pressing. Trans Model Simul 10:29–39

    Google Scholar 

  21. Svoboda A, Häggblad H, Näsström M (1996) Simulation of hot isostatic pressing of metal powder components to near net shape. Eng Comput (Swansea, Wales), 13(5):13–37

    Article  Google Scholar 

  22. Svoboda A, Lindgren L, Oddy AS (1998) The effective stress function algorithm for pressure-dependent plasticity applied to hot isostatic pressing. Int J Numer Methods Eng 43(4):587–606

    Article  Google Scholar 

  23. Svoboda A, Häggblad H, Karlsson L (1997) Simulation of hot isostatic pressing of a powder metal component with an internal core. Comput Methods Appl Mech Eng 148(3–4):299–314

    Article  Google Scholar 

  24. Wikman B, Svoboda A, Häggblad H (2000) A combined material model for numerical simulation of hot isostatic pressing. Comput Methods Appl Mech Eng 189(3):901–913

    Article  Google Scholar 

  25. Van Nguyen C, Deng Y, Bezold A, Broeckmann C (2017) A combined model to simulate the powder densification and shape changes during hot isostatic pressing. Comput Methods Appl Mech Eng 315:302–315

    Article  Google Scholar 

  26. Xue Y, Lang LH, Bu GL, Li L (2011) Densification modeling of titanium alloy powder during hot isostatic pressing. Sci Sinter 43(3):247–260

    Article  CAS  Google Scholar 

Download references

Author information

Authors and Affiliations

  1. ATI Specialty Materials, Monroe, NC, 28110, USA

    Erin McDevitt, Ramesh Minisandram & Matias Garcia-Avila

Authors
  1. Erin McDevitt
    View author publications

    You can also search for this author in PubMed Google Scholar

  2. Ramesh Minisandram
    View author publications

    You can also search for this author in PubMed Google Scholar

  3. Matias Garcia-Avila
    View author publications

    You can also search for this author in PubMed Google Scholar

Corresponding author

Correspondence to Erin McDevitt .

Editor information

Editors and Affiliations

  1. General Electric, Cincinnati, Ohio, USA

    Eric Ott

  2. West Virginia University, Morgantown, West Virginia, USA

    Xingbo Liu

  3. University West, Trollhättan, Sweden

    Joel Andersson

  4. China Iron and Steel Research Institute, Beijing, China

    Zhongnan Bi

  5. ‎ATI Specialty Materials, Monroe, North Carolina, USA

    Kevin Bockenstedt

  6. Wyman Gordon Forgings Inc., Houston, Texas, USA

    Ian Dempster

  7. General Electric, Cincinnati, Ohio, USA

    Jon Groh

  8. Carpenter Technology, Philadelphia, Pennsylvania, USA

    Karl Heck

  9. United States Department of Energy, Albany, New York, USA

    Paul Jablonski

  10. Pratt & Whitney, East Hartford, Connecticut, USA

    Max Kaplan

  11. Honda Motor Co. Ltd., Saitama, Japan

    Daisuke Nagahama

  12. QuesTek Innovations, Evanston, Illinois, USA

    Chantal Sudbrack

Rights and permissions

Reprints and permissions

Copyright information

© 2018 The Minerals, Metals & Materials Society

About this paper

Check for updates. Verify currency and authenticity via CrossMark

Cite this paper

McDevitt, E., Minisandram, R., Garcia-Avila, M. (2018). The Case for Physical Experiments in a Digital Age. In: Ott, E., et al. Proceedings of the 9th International Symposium on Superalloy 718 & Derivatives: Energy, Aerospace, and Industrial Applications. The Minerals, Metals & Materials Series. Springer, Cham. https://doi.org/10.1007/978-3-319-89480-5_63

Download citation

Publish with us

Policies and ethics

Search

Navigation