Effect of SiC-reinforcement on thermo-mechanical fatigue of a dispersion-strengthened high-temperature aluminum alloy

Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

Authors

External Research Organisations

  • University of Siegen
  • Paderborn University
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Details

Original languageEnglish
Title of host publicationASTM Special Technical Publication
PublisherASTM International
Pages167-185
Number of pages19
Edition1371
ISBN (print)0803128533
Publication statusPublished - 2000
Externally publishedYes
EventThe Symposium of 'Thermo-Mechanical Fatigue Behavior of Materials: Third Volume' - Norfolk, VA, USA
Duration: 4 Nov 19985 Nov 1998

Publication series

NameASTM Special Technical Publication
Number1371
ISSN (Print)1040-3094

Abstract

Isothermal and thermo-mechanical fatigue (TMF) behavior of a dispersion-strengthened aluminum alloy has been studied between room temperature and 350°C. Cyclic stress-strain (CSS) response was found to be dominated by dispersoid-dislocation interactions, and thus, the effect of an additional SiC reinforcement on CSS behavior was only minor. As the dispersoids are thermally very stable, identical microstructures were observed to form independent of the actual loading conditions. Consequently, CSS response under TMF conditions could be accurately predicted from isothermal tests only. Damage evolution, by contrast, was found to depend drastically on the type of test. A microcrack propagation model could be successfully used to correlate all tests performed on the unreinforced alloy. In the SiC-reinforced material, however, both creep damage and oxidation damage were more severe under TMF conditions than predicted from isothermal tests, and life prediction is nonconservative, if only based on isothermal tests.

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Cite this

Effect of SiC-reinforcement on thermo-mechanical fatigue of a dispersion-strengthened high-temperature aluminum alloy. / Jung, Arnd; Maier, Hans J.; Christ, Hans Jürgen.
ASTM Special Technical Publication. 1371. ed. ASTM International, 2000. p. 167-185 (ASTM Special Technical Publication; No. 1371).

Research output: Chapter in book/report/conference proceedingConference contributionResearchpeer review

Jung, A, Maier, HJ & Christ, HJ 2000, Effect of SiC-reinforcement on thermo-mechanical fatigue of a dispersion-strengthened high-temperature aluminum alloy. in ASTM Special Technical Publication. 1371 edn, ASTM Special Technical Publication, no. 1371, ASTM International, pp. 167-185, The Symposium of 'Thermo-Mechanical Fatigue Behavior of Materials: Third Volume', Norfolk, VA, USA, 4 Nov 1998.
Jung, A., Maier, H. J., & Christ, H. J. (2000). Effect of SiC-reinforcement on thermo-mechanical fatigue of a dispersion-strengthened high-temperature aluminum alloy. In ASTM Special Technical Publication (1371 ed., pp. 167-185). (ASTM Special Technical Publication; No. 1371). ASTM International.
Jung A, Maier HJ, Christ HJ. Effect of SiC-reinforcement on thermo-mechanical fatigue of a dispersion-strengthened high-temperature aluminum alloy. In ASTM Special Technical Publication. 1371 ed. ASTM International. 2000. p. 167-185. (ASTM Special Technical Publication; 1371).
Jung, Arnd ; Maier, Hans J. ; Christ, Hans Jürgen. / Effect of SiC-reinforcement on thermo-mechanical fatigue of a dispersion-strengthened high-temperature aluminum alloy. ASTM Special Technical Publication. 1371. ed. ASTM International, 2000. pp. 167-185 (ASTM Special Technical Publication; 1371).
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