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Creep Crack Growth Properties of Low Pressure Turbine Rotor Steel under Constant Load and Ct  

Jeong, Soon-Uk (School of transport vehicle engineering, Gyeongsang National University)
Publication Information
International Journal of Precision Engineering and Manufacturing / v.3, no.2, 2002 , pp. 95-101 More about this Journal
Abstract
The propagation rate(da/dt) prediction parameter and the microstructure properties of creep crack in domestic 3.3NiCrMov steel were investigated at 550$\^{C}$ by using 0.5" CT specimen under constant load(4090N) and constant Ct(300∼4000N/mhr) condition that was maintained during crack growth of 1mm distance. C* usually increased with crack length though load was reduced in order to maintain constant Ct value as crack growth and considerably showed the scatter band, but Ct depended on load line displacement rate and represented a good relation with da/dt. At constant toad and Ct region, crack growth slope was 0.900 and 0.844 each, in the other hand C* slope was 0.480. Fully coalesced area(FCA) ahead of crack tip was increased as Ct value increase to the critical value, and after that value FCA decreased. The average diameter ditribution of cavity in FCA showed the greatest value about 1.5 ㎛ when Ct=2000N/mhr. The increasing of Ct in FCA view point enlarged the size of damage area and the size reached to maximum 800 ㎛ when Ct=2000N/mhr.
Keywords
Fully Coalesced Area; Creep Crack Growth Rate; Load Line Displacement Rate; Creep-induced Displacement;
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