COMPARISON OF CREEP BEHAVIOR UNDER VARYING LOAD/TEMPERATURE CONDITIONS BETWEEN HASTELLOY XR ALLOYS WITH DIFFERENT BORON CONTENT LEVELS

摘要

In the design of the high-temperature components, it is often required to predict the creep rupture life under the conditions in which the stress and/or temperature may vary by using the data obtained with the constant load and temperature creep rupture tests. Some conventional creep damage rules have been proposed to meet the above-mentioned requirement. The applicability of the proposed creep damage rules seems to depend strongly on materials. Currently only limited data are ivailable on the behavior of Hastelloy XR, which is a developed alloy as the structural material for high-temperature components of the High-Temperature Engineering Test Reactor (HTTR), under varying stress and/or temperature creep conditions.rnHence a series of constant load and temperature creep rupture tests as well as varying load and temperature creep rupture tests was carried out on two kinds of Hastelloy XR alloys whose boron content levels are different, i.e., below 10 and 60 mass ppm, in order to examine the behavior of the alloy under varying load and temperature conditions.rnThe life fraction rule completely fails in the prediction of the creep rupture life of Hastelloy XR with 60 mass ppm boron under varying load and temperature conditions though the rule shows good applicability for Hastelloy XR with below 10 mass ppm boron. The change of boron content level of the material during the tests is the most probable source of impairing the applicability of the life fraction rule to Hastelloy XR whose boron content level is 60 mass ppm. The modified life fraction rule has been proposed based on the dependence of the creep rupture strength on the boron content level of the alloy. The modified rule successfully predicts the creep rupture life under the two stage creep test conditions from 1000 to 900℃. The trend observed in the two stage creep tests from 900 to 1000℃ can be qualitatively explained by the mechanism that the oxide film which is formed during the prior exposure to 900℃ plays the role of the protective barrier against the boron dissipation into the environment.