Kavli Affiliate: Xiang Zhang
| First 5 Authors: Weichen Kong, Yanwei Dai, Xiang Zhang, Yinghua Liu,
| Summary:
Creep failure under high temperatures is a complex multiscale and
multi-mechanism issue involving inherent microstructural randomness. To
investigate the effect of microstructures on the uniaxial/multiaxial creep
failure, a dual-scale stochastic analysis framework is established to introduce
the grain boundary (GB) characteristics into the macroscopic analysis. The
nickel-base superalloy Inconel 617 is considered in this study. Firstly, the
damage mechanisms of GBs are investigated based on the crystal plasticity
finite element (CPFE) method and cohesive zone model (CZM). Subsequently, based
on the obtained GB damage evolution, a novel Monte Carlo (MC) approach is
proposed to establish the relationship between the GB orientation and area
distribution and macroscopic creep damage. Finally, a dual-scale stochastic
multiaxial creep damage model is established to incorporate the influence of
the random GB orientation and area distribution. With the numerical application
of the proposed creep damage model, the random initiation and growth of creep
cracks in the uniaxial tensile specimen and the pressurized tube are captured
and analyzed. The proposed stochastic framework effectively considers the
inherent randomness introduced by GB characteristics and efficiently realizes
full-field multiscale calculations. It also shows its potential applications in
safety evaluation and life prediction of creep components and structures under
high temperatures.
| Search Query: ArXiv Query: search_query=au:”Xiang Zhang”&id_list=&start=0&max_results=3