Your search keyword '"Cai, Yifan"' showing total 6 results

1. Dependence on Manufacturing Directions of Tensile Behavior and Microstructure Evolution of Selective Laser Melting Manufactured Inconel 625

Author

Liu, Meng, Wang, Quanyi, Cai, Yifan, Lu, Dong, Pei, Yubing, Zhang, Hong, Liu, Yongjie, and Wang, Qingyuan

Published

2023

2. The Low-Cycle Fatigue Behavior, Microstructure Evolution, and Life Prediction of SS304: Influence of Temperature.

Author

Mei, Ting, Wang, Quanyi, Liu, Meng, Jiang, Yunqing, Zou, Tongfei, and Cai, Yifan

Subjects

CRACK initiation (Fracture mechanics), FATIGUE life, MICROSTRUCTURE, HIGH cycle fatigue, FORECASTING, HIGH temperatures

Abstract

To study the fatigue failure and microstructure evolution behavior of SS304, low-cycle fatigue tests are conducted at room temperature (RT), 300 °C, and 650 °C. The results indicate that, because of the influence of the dislocation walls, carbon-containing precipitates, and deformation twins, the cyclic hardening behavior is presented at RT. However, different from the cyclic hardening behavior at RT, the cyclic softening behavior of SS304 can be observed due to the dynamic recovery and recrystallization containing dislocation rearrangement and annihilation at 300 °C and 650 °C. In addition, two fatigue crack initiation modes are observed. At RT, the single fatigue crack initiation mode is observed. At high temperatures, multiple crack initiation modes are presented, resulting from the degradation of material properties. Furthermore, a new fatigue life prediction model considering the temperature is conducted as a reference for industrial applications. [ABSTRACT FROM AUTHOR]

Published

2023

3. Analysis of the Tensile Deformation Behaviors and Microstructure Characterization under Various Temperatures of MarBN Steel by EBSD.

Author

Zou, Tongfei, Liu, Meng, Cai, Yifan, Wang, Quanyi, Jiang, Yunqing, Wang, Yunru, Pei, Yubing, Zhang, Hong, Liu, Yongjie, and Wang, Qingyuan

Subjects

MICROSTRUCTURE, TENSILE strength, STRAIN rate, CRYSTAL grain boundaries, STEEL, ROCK mechanics

Abstract

The uniaxial tensile behavior of MarBN steel with a constant strain rate of 5 × 10−5 s−1 under various temperatures ranging from room temperature to 630 °C was analyzed. This study aimed to identify the effect of the temperature on the tensile behavior and to understand the microstructure deformation by electron backscatter diffraction. The tensile results showed that the yield and ultimate tensile strength decreased with increasing temperature. Serrated flow was observed from 430 °C to 630 °C. The electron backscatter diffraction analysis showed that the low-angle grain boundaries decreased at the medium deformation and increased at the maximum deformation. In contrast, they decreased with increasing temperatures. In addition, the number of voids increased with the increasing plastic strain. As the strain increased, the voids joined together, and the tiny cracks became larger and failed. Three mechanisms were responsible for the tensile deformation failure at various temperatures: grain rotation, the formation and rearrangement of low angle grain boundaries, and void nucleation and propagation. Finally, the formation of the low-angle grain boundaries and voids under different degrees of deformation is discussed. [ABSTRACT FROM AUTHOR]

Published

2023

4. Tensile Behavior, Constitutive Model, and Deformation Mechanisms of MarBN Steel at Various Temperatures and Strain Rates.

Author

Cai, Yifan, Wang, Quanyi, Liu, Meng, Jiang, Yunqing, Zou, Tongfei, Wang, Yunru, Li, Qingsong, Pei, Yubing, Zhang, Hong, Liu, Yongjie, and Wang, Qingyuan

Subjects

*MECHANICAL behavior of materials, *STRAIN rate, *DEFORMATIONS (Mechanics), *STEEL, *DISLOCATION density, *HIGH temperatures

Abstract

To reduce harmful gas emission and improve the operational efficiency, advanced ultra-supercritical power plants put forward higher requirements on the high temperature mechanical properties of applied materials. In this paper, the tensile behavior and deformation mechanisms of MarBN steel are discussed at different strain rates (5 × 10−3 s−1, 5 × 10−4 s−1, and 5 × 10−5 s−1) under room temperature and 630 °C. The results show that the tensile behavior of the alloy is dependent on temperature and strain rate, which derived from the balance between the average dislocation velocity and dislocation density. Furthermore, observed dynamic recrystallized grains under severe deformation reveal the existence of dynamic recovery at 630 °C, which increases the elongation compared to room temperature. Finally, three typical constitutive equations are used to quantitatively describe the tensile deformation behavior of MarBN steel under different strain rates and temperatures. Meanwhile, the constitutive model of flow stress for MarBN steel is developed based on the hyperbolic sine law. [ABSTRACT FROM AUTHOR]

Published

2022

5. Comparison in Deformation Behavior, Microstructure, and Failure Mechanism of Nickel Base Alloy 625 under Two Strain Rates.

Author

Liu, Meng, Wang, Quanyi, Cai, Yifan, Lu, Dong, Wang, Tianjian, Pei, Yubing, Zhang, Hong, Liu, Yongjie, Wang, Qingyuan, and Hosoda, Hideki

Subjects

SURFACE strains, TENSILE strength, NICKEL alloys, STRAIN hardening, MICROSTRUCTURE, DEFORMATIONS (Mechanics), STRAIN rate

Abstract

Tensile deformation behavior and microstructure of nickel-base superalloy Inconel 625 are investigated under different strain rates of 5 × 10−4 s−1 and 5 × 10−5 s−1. According to the experimental results, yield strength and ultimate tensile strength of the alloy increase with the increase in strain rate in room temperature. Microstructure results indicate that the size of dimples is smaller in the tensile fracture surface at low strain rate than the high strain rate, and the number of dimples is also related to the strain rates and twins appear earlier in the specimens with higher strain rates. Apart from Hollomon and Ludwik functions, a new formula considering the variation trend of strength in different deformation stages is deduced and introduced, which fit closer to the tensile curves of the 625 alloy used in the present work at both strain rates. Furthermore, the Schmid factors of tensile samples under two strain rates are calculated and discussed. In the end, typical work hardening behavior resulting from the dislocations slip behavior under different strain rates is observed, and a shearing phenomenon of slip lines cross through the δ precipitates due to the movement of dislocations is also be note. [ABSTRACT FROM AUTHOR]

Published

2021

6. Effect of temperature on tensile behavior, fracture morphology, and deformation mechanisms of Nickel-based additive manufacturing 939 superalloy.

Author

Zou, Tongfei, Liu, Meng, Cai, Yifan, Wang, Quanyi, Jiang, Yunqing, Wang, Yunru, Gao, Zhenheng, Pei, Yubing, Zhang, Hong, Liu, Yongjie, and Wang, Qingyuan

Subjects

*TEMPERATURE effect, *DEFORMATIONS (Mechanics), *HEAT resistant alloys, *TRANSMISSION electron microscopy, *TENSILE tests

Abstract

In the current work, uniaxial tensile tests, including interrupted tests at room temperature, intermediate temperatures (650 ℃ and 700 ℃), and high temperatures (850 ℃ and 950 ℃), were conducted on the additive manufacturing 939 superalloy to investigate the mechanical properties, fracture behaviors, and deformation mechanisms. According to the experimental results, the tensile mechanical properties exhibit a significant temperature sensitivity, as the yield, tensile strength, and elongation decrease with the increase in temperature. The fracture surfaces show that the material exhibits obvious plastic fracture characteristics at room temperature. Moreover, many multi-slip system steps can be observed when the temperature rises. Furthermore, according to the result of the transmission electron microscopy, the deformation mechanism at room temperature is primarily controlled by the single slip system. As temperature rises to the intermediate temperature region, more slip systems are activated by thermal energy, which promotes the movement of dislocations. The deformation mechanism is mainly dominated by dislocation shearing γ'. When the temperature reaches the high temperature region, the deformation mechanism firstly demonstrates large-scale stacking faults, and then transforms into the dislocation by-passing and climbing mechanism. Finally, the relationship between temperature and the deformation mechanism is discussed and deduced. [Display omitted] • Tensile behavior and flow stress are sensitive to temperature and evaluated by the Hollomon model. • Dislocation shearing of γ' exhibits a complex process, with the dominant mechanism evolving with temperature. • The critical shear stress was calculated to illustrate the competition among the dominant mechanism. [ABSTRACT FROM AUTHOR]

Published

2023