Abstract
Various aspects of the use of a fracture mechanics approach to steam turbine rotor design are covered in this chapter. The importance of using proper operational procedure to prevent brittle fracture is reviewed, and various methods of estimating toughness properties from small amounts of material are discussed. Some practical aspects of disc bursting are covered, and a probabilistic approach to design is introduced by way of an example problem.
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Yukawa, S., Timo, D.P. and Rubio, A., “Fracture Design Practices for Rotating Equipment”, in Fracture, Vol. 5, ed. by H. Liebowitz. New York: Academic Press (1969), 65–157.
Greenberg, H.D., Wessel, E.T., Clark, W.C. and Pryle, W.H., “Critical Flaw Sizes for Brittle Fracture of Large Turbine Generator Rotor Forgings”, paper presented at the Fifth International Forgemasters Conference, Terni, Italy, 1970.
Curran, R.M., “Progress in the Development of Large Rotor Forgings”, paper presented at the Fifth International Forgemasters Conference, Terni, Italy, 1970.
Sully, A.H., “Progress in the Manufacture of Large Forgings”, Proc. Inst. Mech. Eng., London, Pt. 1, 181 (1966–67), 877–99.
Begley, J.A. and Logsdon, W.A., “Correlation of Fracture Toughness and Charpy Properties for Rotor Steels”, unpublished research, Westinghouse Research Laboratories.
Begley, J.A. and Landes, J.D., “The J Integral as a Fracture Criterion”, in Fracture Toughness, Special Technical Publication 514. Philadelphia: Am. Soc. for Testing and Materials (1972), 1–20.
Kalderon, D., “Steam Turbine Failure at Hinckley Point”, Proc. Inst. Mech. Eng., London, 186 (1972), 341–77.
Gray, J.L., “Investigation into the Consequences of the Failure of a Turbine — Generator at Hinckley Point ‘A’ Power Station”, Proc. Inst. Mech. Eng., London, 186 (1972), 379–90.
Leven, M.M., Sankey, G.O. and Bitzer, J.H., “Experimentally Determined Stress Intensity Factors for Notched Rotors”, unpublished research, Westinghouse Research Laboratories.
Griffith, A.A., “Phenomena of Rupture and Flow in Solids”, Phil. Trans. Roy. Soc. London, Ser. A, 221 (1920), 163–98.
Irwin, G.R., “Analysis of Stresses and Strains Near the End of a Crack Transversing a Plate”, J. Appl. Mech., 24 (1957), 361–64.
Bowie, O.L., “Analysis of an Infinite Plate Containing Radial Cracks Originating at the Boundary of an Internal Circular Hole”, J. Math. Phys., 25 (1956), 60–71.
Bueckner, H.F. and Giaever, I., “The Stress Concentration in a Notched Rotor Subjected to Centrifugal Forces”, Z. Angew. Math. Mech., 46 (1966), 265–73.
Wessel, E.T., Clark, W.G. and Wilson, W.K., “Engineering Methods for the Design and Selection of Materials Against Fracture”, Westinghouse Research Labs., Pittsburgh, Pa., Army Tank-Automotive Center Contract Report No. 66–9B4–315-R1, June 1966. (AD 801 005)
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Sherlock, T.P. (1979). Practical Aspects of Fracture Mechanics for Steam Turbine Rotors. In: Burke, J.J., Weiss, V. (eds) Application of Fracture Mechanics to Design. Sagamore Army Materials Research Conference Proceedings. Springer, Boston, MA. https://doi.org/10.1007/978-1-4899-6588-2_11
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DOI: https://doi.org/10.1007/978-1-4899-6588-2_11
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