Your search keyword '"strain-induced precipitation"' showing total 98 results

1. Unraveling the effects of strain‒induced precipitation on continuous cooling ferrite transformation in titanium‒molybdenum microalloyed steel

Author

Qifan Zhang, Liejun Li, Jixiang Gao, Zhuoran Li, Songjun Chen, Zhengwu Peng, and Xiangdong Huo

Subjects

Strain‒induced precipitation, Stress relaxation method, Ferrite transformation, Strengthening mechanism, Mining engineering. Metallurgy, TN1-997

Abstract

Strain‒induced precipitation is a characteristic physical‒metallurgical phenomenon during hot‒rolling in microalloyed steel production that strongly affects the overallthermomechanical control process. In this study, the strain‒induced precipitation behavior in titanium‒molybdenum microalloyed steel was comprehensively investigated, and its complex effects on the austenite/ferrite transformation during continuous cooling were analyzed for the first time, based on stress relaxation and multi‒aspect characterization methods. The stress relaxation results revealed that the fastest strain‒induced precipitation occurred at 900 °C. The precipitates were identified as FCC structured (Ti, Mo)C particles with a coherent or semi‒coherent cubic‒cubic orientation relationship to the austenite matrix. The strain‒induced precipitation proved to increase the ferrite transformation temperature and proportion, significantly refine and homogenize the transformed grains. The intermittent quenching at 0.5 C/s further revealed that the (Ti, Mo)C particles with cubic‒cubic orientation relationship to austenite matrix exerted a dual pinning effect: by pinning dislocations, these particles facilitated diffusion‒controlled ferrite nucleation and growth both at austenite grain boundaries and within grains; by pinning migrating phase interfaces, the particles inhibited the coarsening of ferrite grains. Coupled with compressive testing and strengthening contribution analysis, the strain‒induced precipitation was shown to weaken precipitation strengthening but enhance grain refinement strengthening, thereby providing a novel approach to achieving an optimal balance between microstructural homogeneity and mechanical properties.

Published

2024

2. Investigation of deformation behavior and strain-induced precipitations in Al–Zn–Mg–Cu alloys across a wide temperature range

Author

Qingdong Zhang, Jinrong Zuo, Chen Yang, Yingxiang Xia, Xuedao Shu, Bizhou Mei, Ying Wang, and Long Cui

Subjects

Al–Zn–Mg–Cu alloy, Arrhenius constitutive model, Hot deformation, Strain-induced precipitation, Microstructure, Medicine, Science

Abstract

Abstract This study explores the hot deformation behavior of Al–Zn–Mg–Cu alloy through uniaxial hot compression (200 °C–450°C) using the Gleeble-1500. True stress–strain curves were corrected, and three models were established: the Arrhenius model, strain compensated (SC) Arrhenius model, and strain compensated recrystallization temperature (RT) segmentation-based (TS-SC) Arrhenius model. Comparative analysis revealed the limited predictive accuracy of the SC Arrhenius model, with a 25.12% average absolute relative error (AARE), while the TS-SC Arrhenius model exhibited a significantly improved to 9.901% AARE. Material parameter calculations displayed variations across the temperature range. The SC Arrhenius model, utilizing an average slope method for parameter computation, failed to consider temperature-induced disparities, limiting its predictive capability. Hot processing map, utilizing the Murty improved Dynamic Materials Model (DMM), indicated optimal conditions for stable forming of the Al–Zn–Mg–Cu alloy. Microstructural analysis revealed MgZn2 precipitation induced by hot deformation, with crystallographic defects enhancing nucleation rates and precipitate refinement.

Published

2024

3. Effect of Zr on static recrystallization of deformed austenite and strain-induced precipitation in Ti microalloyed steel.

Author

Luo, Hanyu, Liu, Xing, Lu, Chao, Cao, Jianchun, Yang, Yinghui, Xiong, Xuegang, and Wang, Chuangwei

Abstract

The static recrystallization and strain-induced precipitation behavior of Ti and Ti-Zr low carbon microalloyed steels were studied through isothermal stress relaxation experiments at different deformation temperatures (875–1025 °C). The precipitation kinetic curves of microalloyed carbides were obtained, and the effect of Zr on the precipitation kinetics of microalloyed carbides was analyzed. Two static recrystallization kinetic models were established, and the activation energies for static recrystallization of Ti steel and Ti-Zr steel were calculated to be 312.44 and 246.59 kJ/mol, respectively. The results indicate that the addition of Zr lowers the nose point temperature of the precipitation–time–temperature curve, shortens the incubation period for the nucleation of precipitates, promotes the nucleation of strain-induced precipitates in Ti microalloyed steel, and reduces the coarsening rate of precipitates particles by an order of magnitude. In addition, the addition of Zr also advances the end time of static recrystallization of deformed austenite, inhibits the growth of static recrystallization austenite grains in Ti steel during the isothermal process, and makes the austenite grains finer and more uniform. [ABSTRACT FROM AUTHOR]

Published

2024

4. Investigation of deformation behavior and strain-induced precipitations in Al–Zn–Mg–Cu alloys across a wide temperature range.

Author

Zhang, Qingdong, Zuo, Jinrong, Yang, Chen, Xia, Yingxiang, Shu, Xuedao, Mei, Bizhou, Wang, Ying, and Cui, Long

Subjects

*PRECIPITATION (Chemistry), *CRYSTAL defects, *DEFORMATIONS (Mechanics), *ALLOYS, *RATE of nucleation

Abstract

This study explores the hot deformation behavior of Al–Zn–Mg–Cu alloy through uniaxial hot compression (200 °C–450°C) using the Gleeble-1500. True stress–strain curves were corrected, and three models were established: the Arrhenius model, strain compensated (SC) Arrhenius model, and strain compensated recrystallization temperature (RT) segmentation-based (TS-SC) Arrhenius model. Comparative analysis revealed the limited predictive accuracy of the SC Arrhenius model, with a 25.12% average absolute relative error (AARE), while the TS-SC Arrhenius model exhibited a significantly improved to 9.901% AARE. Material parameter calculations displayed variations across the temperature range. The SC Arrhenius model, utilizing an average slope method for parameter computation, failed to consider temperature-induced disparities, limiting its predictive capability. Hot processing map, utilizing the Murty improved Dynamic Materials Model (DMM), indicated optimal conditions for stable forming of the Al–Zn–Mg–Cu alloy. Microstructural analysis revealed MgZn2 precipitation induced by hot deformation, with crystallographic defects enhancing nucleation rates and precipitate refinement. [ABSTRACT FROM AUTHOR]

Published

2024

5. Thermal Mechanical Behavior and Microstructure Characteristics of As‐Cast FeCrNiAl Steel.

Author

Cui, Haotian, Wang, Kui, Lv, Jingyan, and Tian, Qingchao

Subjects

*LIGHTWEIGHT steel, *MICROSTRUCTURE, *STRAINS & stresses (Mechanics), *STEEL, *DENDRITES

Abstract

To find the suitable deformation temperature range for the as‐cast Fe–5.5Cr–5.5Ni–3.0Al–0.27C high‐strength lightweight steel, the thermal mechanical behavior and the dependent microstructure characteristics are studied to investigate the high‐temperature mechanical response of the steel. In the results, it is shown that the microstructure of the steel owns a dendrite framework consisting of the martensite dendrite and the interdendritic austenite, among which precipitations of NiAl, Ni3Al, and δ‐Fe are induced by high‐temperature deformation. The flow stress dependence of deformation temperature shows two different variation tendencies, corresponding to the varied deformation mechanisms of strain‐induced precipitation of second phases and δ‐Fe nucleation, and then resulting in different variation of dislocation density. It is found that a periodical fluctuation of flow stress appears as the alternative occurrence of first rise and then drop followed by drop and rise, and the phenomenon is inferred to be caused by local dynamic recrystallization in the dendrites and the neighboring interdendritic spacings. [ABSTRACT FROM AUTHOR]

Published

2024

6. Strain-induced precipitation behaviors of 7Mo super-austenitic stainless steel

Author

Shiguang Xu, Jinshan He, Runze Zhang, Fucheng Zhang, and Xitao Wang

Subjects

Super-austenitic stainless steel, Strain-induced precipitation, Stress relaxation test, Dynamic precipitation, σ phase, Mining engineering. Metallurgy, TN1-997

Abstract

Strain-induced precipitation (SIP) behaviors of 7Mo super-austenitic stainless steel (SASS) were studied by strain relaxation test at 850 °C. Our results reveal that sigma (σ) phases are the predominant SIP of 7Mo SASS, with the chemical formula of (FeNi) (CrMo). SIP first precipitates in granular shape at HAGBs, such as deformed grain boundaries (SIP-GBs), interfaces between deformation twin layers and matrix (SIP-TW), and HAGBs inside deformed grains (SIP-HAGBs). This is attributed to the ability of HAGBs for providing high deformation stored energy, nucleation sites, and efficient element diffusion channels. When the nucleation sites at HAGBs become saturated with increasing holding time, needle-like SIPs (SIP-NL) are precipitated along closely packed planes of γ-Fe matrix. The specific orientation relationships between SIP-NL and matrix, namely (−111)γ-Fe//(00–1)σ, [0–11]γ-Fe//[-110]σ or (-1-1-1)γ-Fe//(00–1)σ, [0–11]γ-Fe//[-110]σ, and the needle-like shape are contribute to minimizing interfacial energy and elastic strain energy of SIP, respectively, thereby promoting SIP-NL. The absence of SIP on dislocations can be attributed to the large critical nucleus size of σ phase (about 4.87 nm), which poses challenges for SIP nucleation through dislocation distortion energy. Mo is the controlling element for the nucleation and growth of SIP. SIP can promote cDRX through particle-induced nucleation (PSN) mechanism during the deformation process, while residual high-density dislocations around SIP can also promote cSRX during the holding process. During holding process, the boundaries of recrystallized grains can also serve as nucleation sites for SIP, thereby promoting SIP, and finally form a multi-layer structure of “σ phase/Recrystallization/σ phase”.

Published

2023

7. Effect of Deformation Conditions on Strain-Induced Precipitation of 7Mo Super-Austenitic Stainless Steel.

Author

Xu, Shiguang, He, Jinshan, Zhang, Runze, Zhang, Fucheng, and Wang, Xitao

Subjects

*STRESS relaxation tests, *DEFORMATIONS (Mechanics), *STRAIN rate, *CRYSTAL grain boundaries, *RECRYSTALLIZATION (Metallurgy), *STRESS relaxation (Mechanics)

Abstract

Strain-induced precipitation (SIP) behaviors of 7Mo super-austenitic stainless steel (SASS) under various deformation conditions were studied by stress relaxation tests. The research demonstrates that sigma phases are the primary SIP phases of 7Mo SASS. Generally, SIP is mainly distributed in granular shape at the boundaries of deformed grains or recrystallized grains, as well as around the deformed microstructure, such as deformation twin layers/matrix interfaces. The variation of deformation parameters can lead to changes in microstructure, therefore influencing the distribution of SIP. For instance, with the temperature increases, the SIP distribution gradually evolves from deformed grain boundaries to recrystallized grain boundaries. The average size of SIP increases with increasing temperature and strain, as well as decreasing strain rate. The SIP content also increases with increasing strain and decreasing strain rate, while exhibiting an initial rise followed by a decline with increasing temperature, reaching its maximum value at 850 °C. The presence of SIP can promote recrystallization by particle-induced nucleation (PSN) mechanism during the hot deformation process. Moreover, the boundaries of these recrystallized grains can also serve as nucleation sites for SIP, therefore promoting SIP. This process can be simplified as S I P → P S N R e c r y s t a l l i z a t i o n → N u c l e a t i o n   s i t e s S I P . With the increase in holding time and the consumption of stored energy, the process gradually slows down, leading to the formation of a multi-layer structure, namely SIPs/Recrystallized grains/SIPs structure. Moreover, SIP at recrystallized grain boundaries can hinder the growth of recrystallized grains. Through this study, a comprehensive understanding of the SIP behaviors in 7Mo SASS under different deformation conditions has been achieved, as well as the interaction between SIP and recrystallization. This finding provides valuable insights for effective control or regulation of SIP and optimizing the hot working processes of 7Mo SASS. [ABSTRACT FROM AUTHOR]

Published

2023

8. Physical Metallurgy Guided Machine Learning for Strain‐Induced Precipitation of Nb (C, N) Based on the Orthogonalized Small Data.

Author

Li, Xin, Jiang, Qiming, Cui, Chunyuan, Zhou, Xiaoguang, Cao, Guangming, and Liu, Zhenyu

Subjects

*PHYSICAL metallurgy, *MACHINE learning, *PRECIPITATION (Chemistry) kinetics, *TRANSMISSION electron microscopes, *HOT rolling

Abstract

Strain‐induced precipitation (SIP) plays an important role in controlling the microstructure and properties of micro‐alloyed steels during hot rolling. However, due to lack of systematic experiments, the existing precipitation data are scarce and insufficient for accurate modeling of SIP behavior with good extrapolation. Herein, the data space of Niobium Carbonitride (Nb(C,N)) SIP kinetics is analyzed based on principle of orthogonal design, and the missing points in the orthogonal space are identified and supplemented in addition to the available data. The parameters in models for precipitation start and finish times are optimized by using the precipitation–time–temperature curves through genetic algorithm, and their relationships with compositions and processing conditions are established by support vector machine. Based on the orthogonally modified dataset, the machine learning (ML) models outperform the classical and ML models with the original data in terms of accuracy and are in good agreement with theoretical expectations. By using the new ML modeling, the evolution behavior of Nb (C, N) during hot deformation is predicted and verified with transmission electron microscope, and the influences of Nb content in steel, strain, strain rate, and the sensitivity of compositions and processing conditions on precipitation kinetics are quantitatively analyzed. [ABSTRACT FROM AUTHOR]

Published

2023

9. Static recrystallization behaviors and mechanisms of 7Mo super-austenitic stainless steel with undissolved sigma precipitates during double-stage hot deformation

Author

Xu, Shi-guang, He, Jin-shan, Zhang, Run-ze, Zhang, Fu-cheng, and Wang, Xi-tao

Published

2024

10. Study of austenite grain growth and recrystallization behavior in pipeline steels containing niobium

Author

Fengliang Tan, Jinbiao Cui, Ning Liu, Li Wang, Jiansheng Chen, Shiwei Tian, and Yantao Li

Subjects

Austenitising, strain-induced precipitation, Nb element, sub-dynamic recrystallization, Materials of engineering and construction. Mechanics of materials, TA401-492, Chemical technology, TP1-1185

Abstract

The austenite grain growth and recrystallization behaviors of three pipeline steels with different Nb contents were investigated through reheating and thermal simulation compression experiments. The initiation conditions for dynamic and sub-dynamic recrystallization of austenite were analyzed, and sub-dynamic recrystallization equations in Avrami form were established. The influences of Nb content and deformation conditions on the evolution of grain size during austenite recrystallization was examined. The findings indicate that the austenite grain size of the three steels increases gradually with higher reheating temperatures, while the average grain size decreases with increasing Nb content. Sub-dynamic recrystallization initiation temperatures for the B150-steel, B145-steel, and 73-steel were found to be 920 °C for 10 s, 940 °C for 30 s, and 960 °C for 30 s, respectively. During high-temperature deformation, Nb in solid solution hindered recrystallization by impeding grain boundary and dislocation movement. At lower deformation temperatures, Nb(C, N) precipitation pinned grain boundaries and dislocations and consumed substantial free energy, thus competing with recrystallization. As Nb content increased, strain-induced precipitation became more pronounced, resulting in more effective inhibition of recrystallized grain growth.

Published

2024

11. Analysis of the Microstructure Development of Nb-Microalloyed Steel during Rolling on a Heavy-Section Mill.

Author

Sauer, Michal, Fabík, Richard, Schindler, Ivo, Kawulok, Petr, Opěla, Petr, Kawulok, Rostislav, Vodárek, Vlastimil, and Rusz, Stanislav

Subjects

*ROLLING (Metalwork), *ROLLING-mills, *RECRYSTALLIZATION (Metallurgy), *MICROSTRUCTURE, *HOT rolling

Abstract

It is not realistic to optimize the roll pass design of profile rolling mills, which typically roll hundreds of profiles, using physical modelling or operational rolling. The use of reliable models of microstructure evolution is preferable here. Based on the mathematical equations describing the microstructure evolution during hot rolling, a modified microstructure evolution model was presented that better accounts for the influence of strain-induced precipitation (SIP) on the kinetics of static recrystallization. The time required for half of the structure to soften, t0.5, by static recrystallization was calculated separately for both situations in which strain-induced precipitation occurred or did not occur. On this basis, the resulting model was more sensitive to the description of grain coarsening in the high-rolling-temperature region, which is a consequence of the rapid progress of static recrystallization and the larger interpass times during rolling on cross-country and continuous mills. The modified model was verified using a plain strain compression test (PSCT) simulation of rolling a 100-mm-diameter round bar performed on the Hydrawedge II hot deformation simulator (HDS-20). Four variants of simulations were performed, differing in the rolling temperature in the last four passes. For comparison with the outputs of the modified model, an analysis of the austenite grain size after rolling was performed using optical metallography. For indirect comparison with the model outputs, the SIP initiation time was determined based on the NbX precipitate size distribution obtained by TEM. Using the PSCT and the outputs from the modified microstructure evolution model, it was found that during conventional rolling, strain-induced precipitation occurs after the last pass and thus does not affect the austenite grain size. By lowering the rolling temperature, it was possible to reduce the grain size by up to 56 μm, while increasing the mean flow stress by a maximum of 74%. The resulting grain size for all four modes was consistent with the operating results. [ABSTRACT FROM AUTHOR]

Published

2023

12. Strain-Induced Precipitation Behavior and Microstructure Evolution of Ti-V-Mo Complex Microalloyed Steel

Author

Liu, Wensheng, Wei, Hongyu, Zhang, Ke, Zhang, Mingya, Li, Jinghui, Zhao, Shiyu, Zhao, Peilin, Ye, Xiaoyu, Li, Zhaodong, and Ma, Yuxi

Published

2023

13. Effect of Deformation Conditions on Strain-Induced Precipitation of 7Mo Super-Austenitic Stainless Steel

Author

Shiguang Xu, Jinshan He, Runze Zhang, Fucheng Zhang, and Xitao Wang

Subjects

7Mo super-austenitic stainless steel, strain-induced precipitation, stress relaxation test, deformation parameters, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Strain-induced precipitation (SIP) behaviors of 7Mo super-austenitic stainless steel (SASS) under various deformation conditions were studied by stress relaxation tests. The research demonstrates that sigma phases are the primary SIP phases of 7Mo SASS. Generally, SIP is mainly distributed in granular shape at the boundaries of deformed grains or recrystallized grains, as well as around the deformed microstructure, such as deformation twin layers/matrix interfaces. The variation of deformation parameters can lead to changes in microstructure, therefore influencing the distribution of SIP. For instance, with the temperature increases, the SIP distribution gradually evolves from deformed grain boundaries to recrystallized grain boundaries. The average size of SIP increases with increasing temperature and strain, as well as decreasing strain rate. The SIP content also increases with increasing strain and decreasing strain rate, while exhibiting an initial rise followed by a decline with increasing temperature, reaching its maximum value at 850 °C. The presence of SIP can promote recrystallization by particle-induced nucleation (PSN) mechanism during the hot deformation process. Moreover, the boundaries of these recrystallized grains can also serve as nucleation sites for SIP, therefore promoting SIP. This process can be simplified as SIP→PSNRecrystallization→Nucleation sitesSIP. With the increase in holding time and the consumption of stored energy, the process gradually slows down, leading to the formation of a multi-layer structure, namely SIPs/Recrystallized grains/SIPs structure. Moreover, SIP at recrystallized grain boundaries can hinder the growth of recrystallized grains. Through this study, a comprehensive understanding of the SIP behaviors in 7Mo SASS under different deformation conditions has been achieved, as well as the interaction between SIP and recrystallization. This finding provides valuable insights for effective control or regulation of SIP and optimizing the hot working processes of 7Mo SASS.

Published

2023

14. Correlation between Precipitation and Recrystallisation during Stress Relaxation in Titanium Microalloyed Steel.

Author

Zhang, Qifan, Huo, Xiangdong, Li, Liejun, Chen, Songjun, and Lu, Chao

Subjects

TITANIUM, STEEL, AUSTENITE, GRAIN, RECRYSTALLIZATION (Metallurgy), NOSE

Abstract

This study investigated the correlation between strain-induced precipitation (SIP) and static recrystallisation (SRX) in Ti microalloyed steel during stress relaxation after controlled compression. The final compression temperature strongly influenced the order of SIP and SRX and thus the evolution of the austenite structure. Precipitation-time-temperature (PTT) curve obtained for the experimental steel exhibited an inverted "S" shape. A recrystallisation kinetics model revealed that SRX, which occurs preferentially above 940 °C, resulted in delayed subsequent SIP, thus causing deviation in the PTT curve from the typical 'C' shape. Below 940 °C, the fastest nose temperature for precipitation was located at 900 °C, and the precipitate was constituted by TiC particles with a NaCl-type FCC structure. The dynamic competition between SIP and SRX processes were evaluated by comparing the relative magnitude of the recrystallisation driving force and precipitation pinning force during stress relaxation, combined with the evolution of precipitate and austenitic structure. The results indicated that the plateau period occurred because of the precipitation pinning effect inhibited recrystallisation-induced austenite softening. However, the non-uniform distribution of SIP restricted the mobility of the boundaries to a portion of the austenite grains, resulting in abnormal grain growth during the plateau period. [ABSTRACT FROM AUTHOR]

Published

2022

15. Static Recrystallization Behavior of Low-Carbon Nb-V-Microalloyed Forging Steel.

Author

Zhao, Yang, Zheng, Jiahao, Chen, Liqing, and Liu, Xianghua

Subjects

RECRYSTALLIZATION (Metallurgy), AVRAMI equation, CRITICAL temperature, ACTIVATION energy

Abstract

Static recrystallization is a method of tailoring the microstructure and mechanical properties of steels, which is important for microalloyed forging steels as the hot deformation process significantly affects their mechanical properties. In this paper, the static recrystallization behavior of a low-carbon Nb-V-microalloyed forging steel was investigated by double-pass hot compression tests at deformation temperature of 800–1100 °C and interruption time of 1–1000 s. The static recrystallization fractions were determined using the 2% offset method. The static recrystallization activation energy and the static recrystallization critical temperature (SRCT) of the experimental steel were determined. When the deformation temperature was higher than the SRCT, the recrystallization fraction curve conformed to the Avrami equation. When the deformation temperature was below the SRCT, the recrystallization curve appeared to plateau, which was caused by strain-induced precipitation. Before and after the plateau, the static recrystallization kinetics still obeyed the Avrami equation. [ABSTRACT FROM AUTHOR]

Published

2022

16. Investigation of Strain-Induced Precipitation of Niobium Carbide in Niobium Micro-Alloyed Steels at Elevated Temperatures.

Author

Tsao, Tzu-Ching, Chiu, Po-Han, Tseng, Chien-Yu, Tai, Cheng-Lin, Chen, Hsueh-Ren, Chung, Tsai-Fu, Chen, Chih-Yuan, Wang, Shing-Hoa, Tsai, Yu-Ting, and Yang, Jer-Ren

Subjects

NIOBIUM, HIGH temperatures, STEEL, STRAIN rate, RECRYSTALLIZATION (Metallurgy)

Abstract

Two steels with a base composition of Fe-0.2C-0.8Mn-1.2Cr (wt%) but with different niobium (Nb) contents (0.02 and 0.03 wt%) were employed to study the effect of precipitate evolution on the softening resistance in the austenite region under elevated temperature deformation. The thermomechanical procedure was executed by a deformation-dilatometer and involved double deformation processes with 25% strain at a 0.25 s−1 strain rate at 900, 925, 950, and 1000 °C. The softening ratios, reflecting the competition between recrystallization and precipitation, were evaluated. The results indicated that both steels showed better softening resistance at 900 °C than at other temperatures. However, the softening ratio of 0.03 wt% Nb-containing steel (Steel 3N) rose after 100 s at 900 °C, while 0.02 wt% Nb-containing steel (Steel 2N) maintained a low softening ratio within 300 s at 900 °C, indicating that Steel 3N was relatively non-durable. A microstructural characterization showed that in the Steel 3N sample deformed at 900 °C, recrystallization occurred more strongly than for Steel 2N after a 1000 s holding time. A follow-up analysis then showed that Steel 3N treated at 900 °C revealed a faster coarsening of the carbides than Steel 2N even in the early stage of precipitation, evidencing that Steel 2N exhibited a lower softening resistance at 900 °C. [ABSTRACT FROM AUTHOR]

Published

2022

17. Microstructure and Superplastic Behavior of Ni-Modified Ti-Al-Mo-V Alloys.

Author

Kotov, Anton D., Postnikova, Maria N., Mosleh, Ahmed O., Cheverikin, Vladimir V., and Mikhaylovskaya, Anastasia V.

Subjects

ALLOYS, TENSILE strength, INTERMETALLIC compounds, MICROSTRUCTURE, TITANIUM alloys

Abstract

The paper studies the influence of 0.5–1.8 wt.% Ni alloying on the superplasticity, microstructural evolution, and dynamic grain growth effect in a temperature range of 625–775 °C and room temperature mechanical properties of two-phase Ti-Al-Mo-V alloys. Due to a decrease in β transus and an enhancement in the alloy diffusivity, an increase in Ni content significantly improved superplasticity. The Ni-modified alloys exhibited 1.5–3-fold lower flow stress, a 2.5–3-fold greater elongation to failure, and 1.4–1.7-fold higher strain rate sensitivity m coefficient compared to the Ni-free alloy. An intermetallic Ti2Ni compound precipitated in the 1.8 wt.% Ni-modified alloy during low-temperature deformation at 700 °C and decreased superplastic properties. The Ti-4Al-3Mo-1V-0.1B alloy with 0.9 wt.% Ni exhibited a good combination of the superplastic behavior and room-temperature mechanical properties: an elongation to failure of 500–900% at a low-temperature range of 625–775 °C and constant strain rate of 1 × 10−3 s−1 and a yield strength of 885 MPa and ultimate tensile strength of 1020 MPa after pre-straining for 100% in a superplastic regime and strengthening heat treatment. [ABSTRACT FROM AUTHOR]

Published

2022

18. Strain-induced precipitation in Ti microalloyed steel by two-stage controlled rolling process

Author

Songjun Chen, Liejun Li, Zhengwu Peng, Xiangdong Huo, and Jixiang Gao

Subjects

Ti microalloyed steel, Strain-induced precipitation, TiC, PTT curves, TEM, Mining engineering. Metallurgy, TN1-997

Abstract

Strain-induced precipitation kinetics and precipitates' characteristics in a Ti microalloyed steel subjected to a two-stage controlled rolling process, simulating rough and finish rolling process of industrial production, were quantitatively investigated by stress relaxation experiments and transmission electron microscopy (TEM), as well as inductively coupled plasma-atomic emission spectroscopy (ICP-AES). In the present work, precipitation during the cooling stage after rough rolling was taken into consideration for the first time. It was found that a small amount of Ti-bearing precipitates, consuming about 10% of the elemental Ti, were formed on dislocations after rough rolling and cooling to 900 °C. The obtained precipitation-time-temperature (PTT) curves exhibited a classic C shape with a nose temperature of 900 °C and the shortest incubation time of 60 s. The PTT curves moved to the lower left by the introduction of 20% deformation at 1050 °C, which was attributed to more nucleation sites for strain-induced precipitation and the decrease of Ti concentration in deformed austenite. During the stress relaxation stage, strain-induced precipitates preferentially nucleated on dislocations and sub-boundaries and were identified as TiC particles. The mean size of precipitated TiC particles increased from 10.2 ± 2.1 to 25.2 ± 2.8 nm, as the holding time was increased from 100 to 1800 s at 900 °C. When the holding time exceeded 600 s the migration of austenite grain boundaries could not be completely inhibited due to the coarsening of precipitates. Isothermal treatment at 900 °C with a holding time of 60–100 s is suggested here as a viable combination for the processing of the 0.05C-0.21Si-1.05Mn-0.13Ti (wt. %) steel due to the shortest incubation time period and effective pinning of grain boundaries by strain-induced precipitates.

Published

2020

19. Analysis of the Microstructure Development of Nb-Microalloyed Steel during Rolling on a Heavy-Section Mill

Author

Michal Sauer, Richard Fabík, Ivo Schindler, Petr Kawulok, Petr Opěla, Rostislav Kawulok, Vlastimil Vodárek, and Stanislav Rusz

Subjects

static recrystallization, strain-induced precipitation, microstructure evolution, PSCT, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

It is not realistic to optimize the roll pass design of profile rolling mills, which typically roll hundreds of profiles, using physical modelling or operational rolling. The use of reliable models of microstructure evolution is preferable here. Based on the mathematical equations describing the microstructure evolution during hot rolling, a modified microstructure evolution model was presented that better accounts for the influence of strain-induced precipitation (SIP) on the kinetics of static recrystallization. The time required for half of the structure to soften, t0.5, by static recrystallization was calculated separately for both situations in which strain-induced precipitation occurred or did not occur. On this basis, the resulting model was more sensitive to the description of grain coarsening in the high-rolling-temperature region, which is a consequence of the rapid progress of static recrystallization and the larger interpass times during rolling on cross-country and continuous mills. The modified model was verified using a plain strain compression test (PSCT) simulation of rolling a 100-mm-diameter round bar performed on the Hydrawedge II hot deformation simulator (HDS-20). Four variants of simulations were performed, differing in the rolling temperature in the last four passes. For comparison with the outputs of the modified model, an analysis of the austenite grain size after rolling was performed using optical metallography. For indirect comparison with the model outputs, the SIP initiation time was determined based on the NbX precipitate size distribution obtained by TEM. Using the PSCT and the outputs from the modified microstructure evolution model, it was found that during conventional rolling, strain-induced precipitation occurs after the last pass and thus does not affect the austenite grain size. By lowering the rolling temperature, it was possible to reduce the grain size by up to 56 μm, while increasing the mean flow stress by a maximum of 74%. The resulting grain size for all four modes was consistent with the operating results.

Published

2022

20. Correlation between Precipitation and Recrystallisation during Stress Relaxation in Titanium Microalloyed Steel

Author

Qifan Zhang, Xiangdong Huo, Liejun Li, Songjun Chen, and Chao Lu

Subjects

thermo-mechanical control process, stress relaxation method, titanium microalloyed steel, strain-induced precipitation, austenite recrystallization, Mining engineering. Metallurgy, TN1-997

Abstract

This study investigated the correlation between strain-induced precipitation (SIP) and static recrystallisation (SRX) in Ti microalloyed steel during stress relaxation after controlled compression. The final compression temperature strongly influenced the order of SIP and SRX and thus the evolution of the austenite structure. Precipitation-time-temperature (PTT) curve obtained for the experimental steel exhibited an inverted “S” shape. A recrystallisation kinetics model revealed that SRX, which occurs preferentially above 940 °C, resulted in delayed subsequent SIP, thus causing deviation in the PTT curve from the typical ‘C’ shape. Below 940 °C, the fastest nose temperature for precipitation was located at 900 °C, and the precipitate was constituted by TiC particles with a NaCl-type FCC structure. The dynamic competition between SIP and SRX processes were evaluated by comparing the relative magnitude of the recrystallisation driving force and precipitation pinning force during stress relaxation, combined with the evolution of precipitate and austenitic structure. The results indicated that the plateau period occurred because of the precipitation pinning effect inhibited recrystallisation-induced austenite softening. However, the non-uniform distribution of SIP restricted the mobility of the boundaries to a portion of the austenite grains, resulting in abnormal grain growth during the plateau period.

Published

2022

21. Static Recrystallization Behavior of Low-Carbon Nb-V-Microalloyed Forging Steel

Author

Yang Zhao, Jiahao Zheng, Liqing Chen, and Xianghua Liu

Subjects

Nb-V-microalloyed forging steel, static recrystallization, static recrystallization critical temperature, strain-induced precipitation, Mining engineering. Metallurgy, TN1-997

Abstract

Static recrystallization is a method of tailoring the microstructure and mechanical properties of steels, which is important for microalloyed forging steels as the hot deformation process significantly affects their mechanical properties. In this paper, the static recrystallization behavior of a low-carbon Nb-V-microalloyed forging steel was investigated by double-pass hot compression tests at deformation temperature of 800–1100 °C and interruption time of 1–1000 s. The static recrystallization fractions were determined using the 2% offset method. The static recrystallization activation energy and the static recrystallization critical temperature (SRCT) of the experimental steel were determined. When the deformation temperature was higher than the SRCT, the recrystallization fraction curve conformed to the Avrami equation. When the deformation temperature was below the SRCT, the recrystallization curve appeared to plateau, which was caused by strain-induced precipitation. Before and after the plateau, the static recrystallization kinetics still obeyed the Avrami equation.

Published

2022

22. Investigation of Strain-Induced Precipitation of Niobium Carbide in Niobium Micro-Alloyed Steels at Elevated Temperatures

Author

Tzu-Ching Tsao, Po-Han Chiu, Chien-Yu Tseng, Cheng-Lin Tai, Hsueh-Ren Chen, Tsai-Fu Chung, Chih-Yuan Chen, Shing-Hoa Wang, Yu-Ting Tsai, and Jer-Ren Yang

Subjects

niobium micro-alloyed steel, dilatometer, strain-induced precipitation, recrystallization, softening resistance, Mining engineering. Metallurgy, TN1-997

Abstract

Two steels with a base composition of Fe-0.2C-0.8Mn-1.2Cr (wt%) but with different niobium (Nb) contents (0.02 and 0.03 wt%) were employed to study the effect of precipitate evolution on the softening resistance in the austenite region under elevated temperature deformation. The thermomechanical procedure was executed by a deformation-dilatometer and involved double deformation processes with 25% strain at a 0.25 s−1 strain rate at 900, 925, 950, and 1000 °C. The softening ratios, reflecting the competition between recrystallization and precipitation, were evaluated. The results indicated that both steels showed better softening resistance at 900 °C than at other temperatures. However, the softening ratio of 0.03 wt% Nb-containing steel (Steel 3N) rose after 100 s at 900 °C, while 0.02 wt% Nb-containing steel (Steel 2N) maintained a low softening ratio within 300 s at 900 °C, indicating that Steel 3N was relatively non-durable. A microstructural characterization showed that in the Steel 3N sample deformed at 900 °C, recrystallization occurred more strongly than for Steel 2N after a 1000 s holding time. A follow-up analysis then showed that Steel 3N treated at 900 °C revealed a faster coarsening of the carbides than Steel 2N even in the early stage of precipitation, evidencing that Steel 2N exhibited a lower softening resistance at 900 °C.

Published

2022

23. Microstructure and Superplastic Behavior of Ni-Modified Ti-Al-Mo-V Alloys

Author

Anton D. Kotov, Maria N. Postnikova, Ahmed O. Mosleh, Vladimir V. Cheverikin, and Anastasia V. Mikhaylovskaya

Subjects

titanium alloys, superplasticity, microstructural evolution, dynamic grain growth kinetics, strain-induced precipitation, mechanical properties, Mining engineering. Metallurgy, TN1-997

Abstract

The paper studies the influence of 0.5–1.8 wt.% Ni alloying on the superplasticity, microstructural evolution, and dynamic grain growth effect in a temperature range of 625–775 °C and room temperature mechanical properties of two-phase Ti-Al-Mo-V alloys. Due to a decrease in β transus and an enhancement in the alloy diffusivity, an increase in Ni content significantly improved superplasticity. The Ni-modified alloys exhibited 1.5–3-fold lower flow stress, a 2.5–3-fold greater elongation to failure, and 1.4–1.7-fold higher strain rate sensitivity m coefficient compared to the Ni-free alloy. An intermetallic Ti2Ni compound precipitated in the 1.8 wt.% Ni-modified alloy during low-temperature deformation at 700 °C and decreased superplastic properties. The Ti-4Al-3Mo-1V-0.1B alloy with 0.9 wt.% Ni exhibited a good combination of the superplastic behavior and room-temperature mechanical properties: an elongation to failure of 500–900% at a low-temperature range of 625–775 °C and constant strain rate of 1 × 10−3 s−1 and a yield strength of 885 MPa and ultimate tensile strength of 1020 MPa after pre-straining for 100% in a superplastic regime and strengthening heat treatment.

Published

2022

24. Effect of strain-induced precipitation on microstructure and properties of titanium micro-alloyed steels

Author

Huo, Xiang-dong, Lv, Zhi-wei, Ao, Chen, Li, Lie-jun, Xia, Ji-nian, and Chen, Song-jun

Published

2022

25. The Use of Model Systems Based on Fe-30 wt%Ni for Investigating the Precipitation and Transformation Behaviour of Microalloyed Austenite

Author

Palmiere, E. J.

Published

2016

26. Dynamic recrystallization behavior and interfacial bonding mechanism of 14Cr ferrite steel during hot deformation bonding.

Author

Zhou, Liying, Chen, Wenxiong, Feng, Shaobo, Sun, Mingyue, Xu, Bin, and Li, Dianzhong

Subjects

INTERFACIAL bonding, FERRITES, CRYSTAL grain boundaries, TENSILE tests, STEEL

Abstract

In this study, hot compression bonding was first applied to join 14Cr ferrite steel at temperatures of 950–1200 °C and strains of 0.11–0.51 under strain rates of 0.01–30 s−1. Subsequently, tensile tests were performed on the joints to evaluate the reliability of the joints formed. Detailed microstructural analyses suggest that two different competing dynamic recrystallization (DRX) mechanisms occur during the bonding process depending on the strain rate, and the joints obtained at different strain rate exhibits distinct healing effect. At a low strain rate (0.01 s−1), continuous DRX occurs, as expected in high-stacking-fault-energy materials, and is characterized by the progressive conversion of the sub-boundaries into larger-angle boundaries, which involves very limited grain boundaries migration. In addition, strain-induced precipitation (SIP) is sufficient under this condition, further impeding the healing of bonding interface. Hence, the joints obtained at low strain rate fractured at the bonding interface easily. Whereas discontinuous DRX is activated at high strain rates (10 and 30 s−1). Under this condition, the formation of sub-boundaries is severely suppressed, resulting in the piling-up of dislocations and hence the storage of a greater amount of stored energy for nucleation and subsequent nuclei growth via the long-distance grain boundaries migration. Meanwhile, the SIP process is sluggish, making the conditions much more favorable for grain boundaries migration which plays a key role in the healing of the original bonding interface. Thus, the joints can be successfully bonded when a high strain rate is applied, with the joints exhibiting tensile properties similar to that of the base material. [ABSTRACT FROM AUTHOR]

Published

2020

27. The effect of strain on interphase precipitation characteristics in a Ti-Mo steel.

Author

Bikmukhametov, Ilias, Beladi, Hossein, Wang, Jiangting, Hodgson, Peter D., and Timokhina, Ilana

Subjects

*METEOROLOGICAL precipitation, *DISLOCATION density, *ATOM-probe tomography, *STEEL

Abstract

In the current study, the effect of deformation in the non-recrystallization region on the characteristics of interphase precipitation was extensively studied in a Ti-Mo steel. The present observation revealed a novel mechanism affecting the interphase precipitation characteristics during an austenite-to-ferrite transformation, as a result of the thermomechanical processing. The hot deformation primarily led to the fragmentation of an austenite grain interior through the formation of elongated dislocation walls, locally deviating the orientation within a grain. Relatively coarse strain-induced precipitates were initially formed on the dislocation walls upon cooling. During the isothermal austenite to ferrite transformation, the interphase precipitation took place on the advancing austenite-ferrite interface front. This was similar to the strain-free condition, though the alignment of planar rows was abruptly altered while encountering the microband walls due to local orientation change at either side of a given microband. In addition, the deformation reduced the planar spacing of interphase precipitates up to a given strain (i.e., ∼0.3), beyond which it became nearly constant. This was due to the saturation of dislocation density within austenite above a certain strain and/or the consumption of alloying elements through the strain-induced precipitation formed on the microbands prior to the austenite to ferrite transformation. Image 1 [ABSTRACT FROM AUTHOR]

Published

2019

28. Analysis of the Microstructure Development of Nb-Microalloyed Steel during Rolling on a Heavy-Section Mill

Author

Rusz, Michal Sauer, Richard Fabík, Ivo Schindler, Petr Kawulok, Petr Opěla, Rostislav Kawulok, Vlastimil Vodárek, and Stanislav

Subjects

static recrystallization, strain-induced precipitation, microstructure evolution, PSCT

Abstract

It is not realistic to optimize the roll pass design of profile rolling mills, which typically roll hundreds of profiles, using physical modelling or operational rolling. The use of reliable models of microstructure evolution is preferable here. Based on the mathematical equations describing the microstructure evolution during hot rolling, a modified microstructure evolution model was presented that better accounts for the influence of strain-induced precipitation (SIP) on the kinetics of static recrystallization. The time required for half of the structure to soften, t0.5, by static recrystallization was calculated separately for both situations in which strain-induced precipitation occurred or did not occur. On this basis, the resulting model was more sensitive to the description of grain coarsening in the high-rolling-temperature region, which is a consequence of the rapid progress of static recrystallization and the larger interpass times during rolling on cross-country and continuous mills. The modified model was verified using a plain strain compression test (PSCT) simulation of rolling a 100-mm-diameter round bar performed on the Hydrawedge II hot deformation simulator (HDS-20). Four variants of simulations were performed, differing in the rolling temperature in the last four passes. For comparison with the outputs of the modified model, an analysis of the austenite grain size after rolling was performed using optical metallography. For indirect comparison with the model outputs, the SIP initiation time was determined based on the NbX precipitate size distribution obtained by TEM. Using the PSCT and the outputs from the modified microstructure evolution model, it was found that during conventional rolling, strain-induced precipitation occurs after the last pass and thus does not affect the austenite grain size. By lowering the rolling temperature, it was possible to reduce the grain size by up to 56 μm, while increasing the mean flow stress by a maximum of 74%. The resulting grain size for all four modes was consistent with the operating results.

Published

2022

29. Effect of High Ti Contents on Austenite Microstructural Evolution During Hot Deformation in Low Carbon Nb Microalloyed Steels

Author

Leire García-Sesma, Beatriz López, and Beatriz Pereda

Subjects

high ti steels, nb microalloying, recrystallization kinetics, strain-induced precipitation, Mining engineering. Metallurgy, TN1-997

Abstract

This work has focused on the study of hot working behavior of Ti-Nb microalloyed steels with high Ti contents (> 0.05%). The role of Nb during the hot deformation of low carbon steels is well known: it mainly retards austenite recrystallization, leading to pancaked austenite microstructures before phase transformation and to refined room temperature microstructures. However, to design rolling schedules that result in properly conditioned austenite microstructures, it is necessary to develop models that take into account the effect of high Ti concentrations on the microstructural evolution of austenite. To that end, in this work torsion tests were performed to investigate the microstructural evolution during hot deformation of steels microalloyed with 0.03% Nb and different high Ti concentrations (0.05%, 0.1%, 0.15%). It was observed that the 0.1% and 0.15% Ti additions resulted in retarded softening kinetics at all the temperatures. This retardation can be mainly attributed to the solute drag effect exerted by Ti in solid solution. The precipitation state of the steels after reheating and after deformation was characterized and the applicability of existing microstructural evolution models was also evaluated. Determined recrystallization kinetics and recrystallized grain sizes reasonably agree with those predicted by equations previously developed for Nb-Ti microalloyed steels with lower Ti concentrations (

Published

2020

30. Thermomechanical Processing of Steels.

Author

María Rodríguez-Ibabe, José, María Rodríguez-Ibabe, José, and Uranga, Pello

Subjects

Research & information: general, Bs temperature, EBSD, EELS, HEXRD, Nb microalloying, advanced high-strength steels (AHSS), atom probe tomography, austenite stability, bainite, carbon segregation, defect reduction, dynamic recrystallization, dynamic strain-induced transformation, electrical resistivity, ferritic heat resistant stainless steel, ferritic stainless steel, flow behavior, high Ti steels, high-aluminum steel, hot tensile deformation, hot torsion testing, intercritical rolling, low carbon steel, low-carbon steel, medium-Mn steel, microalloyed, microalloying, microstructural and mechanical coupling, microstructure, n/a, niobium-titanium microalloyed steel, phase equilibrium, phase transition, plastic deformation, polygonal ferrite, prior austenite, prior austenite grain boundary, recrystallization kinetics, rheological law modeling, rolling, scanning electron microscopy, second phase, strain-induced precipitation, tensile property, thermodynamic calculation, vanadium microalloying

Abstract

Summary: This book gathers a collection of papers summarizing some of the latest developments in the thermomechanical processing of steels. The replacement of conventional rolling plus post-rolling heat treatments by integrated controlled forming and cooling strategies implies important reductions in energy consumption, increases in productivity and more compact facilities in the steel industry. The metallurgical challenges that this integration implies, though, are relevant and impressive developments that have been achieved over the last 40 years. The frequency of the development of new steel grades and processing technologies devoted to thermomechanically processed products is increasing, and their implementation is being expended to higher value added products and applications. In addition to the metallurgical peculiarities and relationships between chemical composition, process and final properties, the relevance impact of advanced characterization techniques and innovative modelling strategies provides new tools to achieve the further deployment of the TMCP technologies. The contents of the book cover low carbon microalloyed grades, ferritic stainless steels and Fe-Al-Cr alloys, medium-Mn steels, and medium carbon grades. Authors of the chapters of this "Thermomechanical Processing of Steels" book represent some of the most relevant research groups from both the steel industry and academia.

31. Hot Deformation and Microstructure Evolution of Metallic Materials.

Author

Schindler, Ivo and Schindler, Ivo

Subjects

History of engineering & technology, Materials science, Technology: general issues, 47Zr-45Ti-5Al-3V alloy, Al-Cu alloys, Al6061, Barkhausen noise, CA, CCT diagram, DRX behavior, FE, FEM, FEM modelling, KoBo extrusion, LPSO phase, Mg-6.8Y-2.5Zn-0.4Zr, Nb-Mo-microalloyed steels, PSCT, SEM-EBSD microstructural analysis, activation energy at hot forming, activation energy maps, aircraft mounts, aluminium, aluminium alloys, aluminum alloy, artificial neural networks, austenite conditioning, austenite grain size, austenite to ferrite transformation, austenitization temperature, bonding strength, brake disk, car bodies, carbon steels, cellular automaton, closure of discontinuities, compression, constitutive equations, constitutive model, critical strain for induce of dynamic recrystallization, deformation, deformation characteristics, deformation mechanism, dynamic and post-dynamic softening, dynamic recrystallisation, dynamic recrystallization, extrusion, ferrite grain size, final microstructure and mechanical properties, finite element method (FEM), flat anvils, flow behavior, flow curve, flow stress maps, flow stress model, forging, forging metal specimens, forming, hammer forging, hidden defects, high-carbon bainitic steel, hot deformation behavior, hot flow stress curves, hot rolling, hot-rolling, hot-working, industrial research, low carbon and low alloy steel, low-alloy steel, magnesium alloy AZ91, magnesium alloys, mechanical properties, meshless methods, metal matrix composite, microstructure, microstructure and superplastic deformation, microstructure evolution, multipass torsion tests, n/a, open die forging, peak flow stress, peak strain, phase transformations, physical modeling, physical modelling, plastic deformation, plastometric tests, processing map, processing maps, radial basis functions, recrystallization, rheological properties, semi-solid isothermal compression, shaped anvils, static recrystallization, steel, strain-induced precipitation, stress correction, structure, super-duplex stainless steel (SDSS), tensile deformation, texture, thermal stability, thermomechanical processing, twin-roll casting, ultrasonic investigation, warm deformation, β titanium alloy

Abstract

Summary: Hot deformation is a key method of processing metallic materials and controlling their final properties through structure-forming processes. The ability to exploit the structural potentiality of both traditional alloys and new progressive materials is crucial in terms of sustainable development and economic growth. This reprint focuses not only on conventional technologies (e.g., rolling or forging) but also on modern procedures, such as various types of complex thermomechanical processing and controlled cooling. Most papers are based on the application of advanced hot deformation simulators and structural analysis methods, as well as computer simulations of bulk-forming processes.

32. Interaction of precipitation, recovery and recrystallization in the Mo-Hf-C alloy MHC studied by multipass compression tests.

Author

Siller, M., Clemens, H., Maier-Kiener, V., Lang, D., Schatte, J., and Knabl, W.

Subjects

*ALLOYS, *MOLYBDENUM, *HAFNIUM, *CARBON, *PRECIPITATION (Chemistry)

Abstract

The interaction between strain-induced precipitation, recovery and recrystallization governs the properties of the particle strengthened Mo-Hf-C alloy MHC. Complex, multi-staged thermomechanical processes have become the key approach for further improvement of the high temperature properties of MHC products within recent years. An investigation of those processes, including a wide field of parameters, usually turns out to be both difficult and time consuming. With multi-pass compression tests it is possible to analyze complex thermomechanical processes on small scale samples in a straightforward manner. The evaluation of the gathered information is demonstrated and the results are compared to microstructural investigations, conventional mechanical tests as well as relevant literature. Furthermore, the influence of different particle size distributions in MHC is interpreted. Precipitation between individual deformation steps resulted in minor additional hardening of the final material. Intermediate recrystallization during the thermomechanical processing showed high softening and ductilization of the final condition. [ABSTRACT FROM AUTHOR]

Published

2018

33. Enhanced elevated-temperature mechanical properties of Al-Mn-Mg containing TiC nano-particles by pre-strain and concurrent precipitation.

Author

Zhao, Qinglong, Zhang, Huidi, Zhang, Xiaoxian, Qiu, Feng, and Jiang, Qichuan

Subjects

*TITANIUM carbide, *PRECIPITATION (Chemistry), *DUCTILITY, *ALUMINUM alloys, *THERMAL stability

Abstract

The influence of pre-strain on the tension and creep behavior of Al-Mn-Mg containing nano-sized TiC particles at elevated temperatures was investigated. Introduction of TiC nano-particles and the application of pre-strain significantly increase the strength at the ambient temperature and at 473 K, even though the strengthening effect diminishes at 573 K due to the more activated dislocation climb. Small pre-strain (von Mises strain of 0.2) could increase the yield strength at 573 K from 72 MPa to 96 MPa. Larger pre-strain promotes the precipitation during hot deformation at 573 K, and concurrent precipitation suppresses work softening by the pinning effect, leading to a significantly enhanced ductility and creep rupture life. [ABSTRACT FROM AUTHOR]

Published

2018

34. Strain-Induced Precipitation Kinetics of Vanadium Carbonitride Precipitates with the Cubic Structure in High-Strength Weathering Steels.

Author

Cheng, J., Qing, J., and Shen, H. F.

Subjects

*PRECIPITATION (Chemistry), *VANADIUM compounds, *HEAT resistant alloys, *AUSTENITE, *HEAT resistant steel

Abstract

The strain-induced precipitation kinetic model of vanadium carbonitride [V(C, N)] precipitates with the cubic structure in vanadium-nitrogen (V-N) microalloyed high-strength weathering steels was constructed and validated. The V(C, N) precipitates possess an fcc structure with the lattice sites and octahedral interstitial sites (O-sites) being occupied with V atoms, and C and N atoms, respectively. The model is based on the cubic structure for V(C, N) precipitates instead of the spherical one, since recent experimental results clearly demonstrate that the strain-induced precipitation of V(C, N) in austenite is of the cubic structure. The nitrogen content effect on precipitation-temperature-time (PTT) curve pattwerns was also studied. With the nitrogen content, the PTT curve nose temperature increased, and the curves shifted left. When the nitrogen content in steels was dropped, PTT curves of V(C, N) precipitates in austenite acquired an S-shape, since free energy conversion is nonlinear. Additionally, thermodynamic software was employed to calculate the phase equilibrium of V(C, N) precipitates in the new high-strength weathering steels. The N site fraction of N during the V(C, N) precipitation was much larger for steels with high N contents, compared to those with low ones. [ABSTRACT FROM AUTHOR]

Published

2018

35. Control of Laves Precipitation in a FeCrAl-based Alloy Through Severe Thermomechanical Processing

Author

Jiyun Zheng, Yuzhen Jia, Peinan Du, Hui Wang, Qianfu Pan, Yiyong Zhang, Chaohong Liu, Ruiqian Zhang, and Shaoyu Qiu

Subjects

FeCrAl alloy, Laves phase, precipitation particle, strain-induced precipitation, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

In recent years, the development of nuclear grade FeCrAl-based alloys with enhanced accident tolerance has been carried out for light water reactor (LWR) fuel cladding to serve as a substitute for zirconium-based alloys. To achieve excellent microstructure stability and mechanical properties, the control of precipitation particles is critical for application of FeCrAl-based alloys. In this paper, the effect of thermomechanical processing on the microstructure and precipitation behavior of hot-rolled FeCrAl alloy plates was examined. After hot rolling, the FeCrAl alloy plates had typical deformation textures. The rolling direction (RD) orientation gradually rotated from to along with increasing reduction. Shear bands and cell structures were formed in the matrix, and the former acted as preferable nucleation sites for crystallization. Improved deformation helped to produce strain-induced precipitation. The plate with 83% reduction had the most homogeneous and finest precipitation particles. Identification results by TEM indicated that the Laves precipitation was of the Fe2Nb-type crystal structure type, with impurities including Mo, Cr, and Si. The plate with uniform Laves particles displayed favorable heat stability after a long period of aging at 800 °C. The microstructure evolution of the aged sample was also observed. The deformation microstructure and the strain-induced precipitation mechanism of FeCrAl alloys are discussed.

Published

2019

36. Suppression of strain-induced precipitation of NbC by epitaxial growth of NbC on pre-existing TiN in Nb-Ti microalloyed steel.

Author

Ma, Xiaoping, Miao, Chengliang, Langelier, Brian, and Subramanian, Sundaresa

Subjects

*STRAINS & stresses (Mechanics), *PRECIPITATION (Chemistry), *NIOBIUM compound synthesis, *TITANIUM nitride, *TITANIUM alloys, *STEEL manufacture

Abstract

Absence of strain-induced precipitation of NbC is observed in a conventional hot rolled Nb-Ti microalloyed X90 strip. Quantitative analysis using transmission electron microscopy and 3D atom probe tomography indicates that epitaxial growth of NbC on pre-existing TiN particles with a short inter-particle spacing of 300 ± 65 nm suppresses the occurrence of strain-induced precipitation of NbC on dislocations. The model for predicting kinetics of strain-induced precipitation of NbC on dislocations is incorporated into a criterion for the end of nucleation of strain-induced precipitation to estimate the effects of process parameters on suppression of strain-induced precipitation of NbC. TiN particle inter-spacing is identified as a key parameter influencing the precipitation behavior of NbC during thermomechanical controlled processing. TiN-NbC composite precipitates offer an alternative approach to strain-induced precipitation of NbC for high temperature processing of Nb microalloyed steels with high toughness. The significance and possible implication of the TiN-NbC composite precipitate engineering are discussed. [ABSTRACT FROM AUTHOR]

Published

2017

37. Thermomechanical controlled processing to achieve very fine grains in the ISO 5832-9 austenitic stainless steel biomaterial.

Author

Silva, Mariana Beatriz dos Reis, Cabrera, Jose Maria, Balancin, Oscar, and JrJorge, Alberto Moreira

Subjects

*METALS, *AUSTENITIC stainless steel, *ORTHOPEDIC implants, *DEFORMATIONS (Mechanics), *THERMOMECHANICAL treatment

Abstract

Simulations of thermomechanical processing of a high niobium- and nitrogen-bearing austenitic stainless steel for orthopedic implants (ISO 5832-9) were conducted using hot torsion test with multiple deformations under continuous cooling conditions. Samples were reheated to 1250 °C and subjected to deformation schedules with pass strain of 0.3, strain rate of 1 s − 1 and interpass times of 5, 20 and 50 s. Optical microscopy, TEM, EDS and EBSD were used to characterize the samples. Characterization of precipitates indicated that only TiNbN was undissolved after soaking, while Z-phase and NbN precipitated during on cooling deformation schedules. The evolution of grain and precipitate sizes with deformation conditions were studied and related to both grain refinement, and mechanical behavior observed. The critical grain size limited by precipitates was calculated using the values obtained for size and volume fraction of precipitates. Differences observed between calculated and measured values were discussed. [ABSTRACT FROM AUTHOR]

Published

2017

38. Evolution of strain-induced hafnium carbides in a molybdenum base Mo–Hf–C alloy studied by small-angle neutron scattering and complementary methods.

Author

Lang, D., Karge, L., Schatte, J., Gilles, R., Dallinger, R., Weißensteiner, I., Staron, P., Knabl, W., Primig, S., and Clemens, H.

Subjects

*MOLYBDENUM alloys, *HAFNIUM compounds, *STRAINS & stresses (Mechanics), *SMALL-angle neutron scattering, *POWDER metallurgy, *HIGH temperature metallurgy

Abstract

The powder metallurgically processed molybdenum base alloy MHC (Mo–Hf–C), with a nominal content of 0.65 at.% Hf and 0.65 at.% C, is of considerable interest for high temperature applications. After uniaxial deformation and subsequent aging of the as-sintered material, plate-like, nm-sized hafnium carbides are formed by heterogeneous nucleation at dislocations. The main focus of this work was to study the evolution of the size distribution of these small hafnium carbides and to gain statistically reliable data from a large volume regarding the morphology and the volume fractions using small-angle neutron scattering (SANS) experiments for samples aged at 1600 °C for different times. Additionally, complementary methods were used to support the SANS results. Hardness testing, two-stage interrupted compression tests, optical light microscopy, electron backscatter diffraction, scanning and transmission electron microscopy were used for further characterization of the aged MHC microstructures and as complementary methods to the SANS measurements. The small-angle neutron scattering investigations revealed anisotropic 2D patterns in relation to the loading direction of the deformed samples which were assigned to not fully compressed pores. It was possible to analyze the thickness distribution of the fine hafnium carbides due to streak formation of the scattering patterns caused by an orientation relationship between face centered cubic hafnium carbides and the body centered cubic molybdenum matrix. The evolution of the microstructure and hardness are in good agreement with the results of the small-angle neutron scattering measurements. The highest hardness was revealed after aging for 1 min at 1600 °C exhibiting small hafnium carbides with a mean diameter of ∼13 nm, a mean plate-thickness of ∼3 nm and a volume fraction of 0.05 vol%. Although, the volume fraction of these carbides was increasing with progressing aging time the hardness dropped due to recovery, recrystallization as well as increasing particle size. [ABSTRACT FROM AUTHOR]

Published

2016

39. Strain-induced precipitation in Ti microalloyed steel by two-stage controlled rolling process

Author

Gao Jixiang, Zhengwu Peng, Xiangdong Huo, Chen Songjun, and Liejun Li

Subjects

lcsh:TN1-997, TiC, Materials science, Nucleation, 02 engineering and technology, engineering.material, 01 natural sciences, Isothermal process, Biomaterials, 0103 physical sciences, Ti microalloyed steel, Stress relaxation, PTT curves, lcsh:Mining engineering. Metallurgy, 010302 applied physics, Austenite, Precipitation (chemistry), Metallurgy, Metals and Alloys, 021001 nanoscience & nanotechnology, Surfaces, Coatings and Films, TEM, Ceramics and Composites, engineering, Strain-induced precipitation, Grain boundary, Microalloyed steel, Deformation (engineering), 0210 nano-technology

Abstract

Strain-induced precipitation kinetics and precipitates' characteristics in a Ti microalloyed steel subjected to a two-stage controlled rolling process, simulating rough and finish rolling process of industrial production, were quantitatively investigated by stress relaxation experiments and transmission electron microscopy (TEM), as well as inductively coupled plasma-atomic emission spectroscopy (ICP-AES). In the present work, precipitation during the cooling stage after rough rolling was taken into consideration for the first time. It was found that a small amount of Ti-bearing precipitates, consuming about 10% of the elemental Ti, were formed on dislocations after rough rolling and cooling to 900 °C. The obtained precipitation-time-temperature (PTT) curves exhibited a classic C shape with a nose temperature of 900 °C and the shortest incubation time of 60 s. The PTT curves moved to the lower left by the introduction of 20% deformation at 1050 °C, which was attributed to more nucleation sites for strain-induced precipitation and the decrease of Ti concentration in deformed austenite. During the stress relaxation stage, strain-induced precipitates preferentially nucleated on dislocations and sub-boundaries and were identified as TiC particles. The mean size of precipitated TiC particles increased from 10.2 ± 2.1 to 25.2 ± 2.8 nm, as the holding time was increased from 100 to 1800 s at 900 °C. When the holding time exceeded 600 s the migration of austenite grain boundaries could not be completely inhibited due to the coarsening of precipitates. Isothermal treatment at 900 °C with a holding time of 60–100 s is suggested here as a viable combination for the processing of the 0.05C-0.21Si-1.05Mn-0.13Ti (wt. %) steel due to the shortest incubation time period and effective pinning of grain boundaries by strain-induced precipitates.

Published

2020

40. Effect of deformation sequence and coiling conditions on precipitation strengthening in high Ti-Nb-microalloyed steels

Author

L. G. Sesma, B. Lopez, and B. Pereda

Subjects

Niobium, Metals and Alloys, Mechanical-properties, Temperature, Recrystallization, Ferrite, Condensed Matter Physics, Austenite, Mechanics of Materials, Strain-induced precipitation, Low-carbon, Interphase precipitation, Área de Ciencia y Tecnología de Materiales, Microstructure

Abstract

In this work, multipass torsion tests followed by coiling simulations under different conditions have been performed with a reference Nb (0.03 pct) and a high Ti (0.1 pct)–Nb-microalloyed (0.03 pct) steel. In the case of the high Ti steel, estimated yield strengths close to or over 700 MPa were obtained for some of the conditions researched. However, a very significant effect of previous austenite grain size and strain accumulation on precipitation strengthening has also been observed. As a result, depending on deformation sequence and final cooling conditions, the coiling simulation temperatures that lead to the highest mechanical strength varied from 600 °C to 500 °C. The effect of increasing strain accumulation was mainly related to higher phase transformation temperatures, which led to a lower driving force for precipitation and higher microalloying element diffusivity, resulting in the formation of less and coarser precipitates.

Published

2022

41. Improving Elevated-Temperature Strength of an Al–Mn–Si Alloy by Strain-Induced Precipitation

Author

Yangyang Zhang, Wei Jin, Xuanzhang Hao, Feng Qiu, and Qinglong Zhao

Subjects

aluminum alloys, high temperature mechanical properties, strain-induced precipitation, Mining engineering. Metallurgy, TN1-997

Abstract

The coupled effect of strain-induced precipitation and stabilized substructure on the elevated-temperature strength of an Al–Mn–Si alloy and its thermal stability have been investigated. Prestrain significantly promotes the nucleation of nano-sized dispersoids, and strain-induced precipitation suppresses recrystallization, stabilizing substructure at elevated temperatures. Compared with the dispersoids formed during the heat treatment of as-cast alloy, substructure does not increase the coarsening rate of strain-induced precipitates. The strain-induced precipitation and stabilized substructure profoundly strengthen the aluminum alloy at the elevated temperature (300 °C).

Published

2018

42. Thermomechanical processing route to achieve ultrafine grains in low carbon microalloyed steels.

Author

Gong, P., Palmiere, E.J., and Rainforth, W.M.

Subjects

*MILD steel, *THERMOMECHANICAL properties of metals, *MICROALLOYING, *RECRYSTALLIZATION (Metallurgy), *MECHANICAL properties of metals, *EFFECT of temperature on metals

Abstract

A new thermomechanical processing route is described for a microalloyed steel, with roughing deformation below the recrystallisation-stop temperature (T 5% ), followed by a rapid reheat to 1200 °C for 10s, and then finish deformation at the same temperature as the rough deformation. The new route focused on optimising the kinetics of strain-induced precipitation (SIP) and the formation of deformation-induced ferrite transformation (DITF). For comparative purposes, two experimental 0.06 wt% C steels were studied: one with 0.03 wt% Nb (Nb steel), and a second with both 0.03 wt% Nb and 0.02 wt% Ti (Nb Ti steel). Two processing routes were studied. The first was a conventional route, which consisted of a simulated rough deformation schedule with the final roughing pass taking place at 850 °C, which produced fully unrecrystallised austenite grains during deformation with no strain-induced ferrite formation. The second, new, thermomechanical processing route used the same roughing step, after which the steels were reheated at 10 °C/s to a temperature of 1200 °C, isothermally held for 10s allowing for precipitate dissolution, prior to air cooling to a finishing deformation temperature of 850 °C. This route resulted in DIFT primarily on the prior-austenite grain boundaries. The precipitate solution during the reheat treatment increased the supersaturation of Nb and Ti in the austenite matrix on subsequent cooling, which therefore increased the undercooling due to the increased A e3 . The observation of nanoscale cementite in the DIFT supports the view that it formed through a massive transformation mechanism. The volume fraction of SIP after finish deformation was influenced by the supersaturation of microalloy elements in solution during heat treatment. The new process route led to a significant refinement of the final ferrite grain size. [ABSTRACT FROM AUTHOR]

Published

2016

43. Effect of preexisting plastic deformation on the creep behavior of TP347 austenitic steel.

Author

Hong, Sung-Min, Min, Dong-Joon, Chung, Yong-keun, Kim, Ju-Heon, Kim, Dong-Ik, Suh, Jin-Yoo, Shim, Jae-Hyeok, Jung, Woo-Sang, and Choi, In-Suk

Subjects

*AUSTENITIC steel, *MATERIAL plasticity, *METAL creep, *METAL microstructure, *STRENGTH of materials

Abstract

We investigated the effect of preexisting plastic deformation with the strain of 30% on the creep behavior of TP347 austenitic steel at 650 °C with different applied stresses. The results showed that the creep rupture life of the prestrained sample increased more than that of the unstrained sample tested at 300, 250 and 200 MPa due to the strengthening of the mechanical twins induced by preexisting plastic deformation. Conversely, the prestrained samples were ruptured earlier than that of the unstrained sample tested when the lower creep stresses (150 and 125 MPa) were applied. The shorter creep rupture life of the prestrained sample was due to the reduced amount of time to a minimum creep rate and the shorter tertiary-stage creep time which can be related to the accelerated precipitation of sigma phase at the grain boundaries in the strained sample. [ABSTRACT FROM AUTHOR]

Published

2016

44. Hot deformation and static softening behavior of vanadium microalloyed high manganese austenitic steels.

Author

Llanos, L., Pereda, B., Lopez, B., and Rodriguez-Ibabe, J.M.

Subjects

*VANADIUM alloys, *DEFORMATIONS (Mechanics), *AUSTENITIC steel, *MANGANESE, *MICROALLOYING

Abstract

The hot deformation and static softening behavior of various high Mn (20–30 wt%) austenitic steels microalloyed with different V (0.1, 0.2 wt%), C (0.2, 0.6, 1 wt%) and N (0.005–0.025 wt%) contents were investigated. Double-hit torsion tests at temperatures in the range 700–1100 °C were carried out and specimens quenched at selected conditions were examined using advanced microscopy techniques (EBSD-TEM) to characterize the recrystallization and strain-induced precipitation behavior. The results show that precipitation of vanadium at the hot working temperature range is sluggish. It mainly occurs for the combinations of 20%Mn–0.6%C–0.2%V and 30%Mn–1%C–0.1%V. When the carbon content is reduced to 0.2%C, strain-induced precipitation is suppressed at typical hot working temperatures, independently of the N level. The flow stress behavior was affected by the amount of C and by modifying the base composition from 30%Mn to 20%Mn–1.5%Al. However, the effect is complex and depends on deformation conditions. In the absence of strain-induced precipitation, the static softening kinetics was accelerated by increasing C content. However, no effect of Mn or V in solid solution was observed. In those cases where strain-induced precipitation took place, static recrystallization was severely delayed, leading to a major contribution of recovery to softening kinetics. [ABSTRACT FROM AUTHOR]

Published

2016

45. Precipitation of homogeneous nanoscale HfRe2 in NiAl by strain-induced precipitation.

Author

Liu, Dekai, Lu, Zhen, Liu, Wei, Shi, Chengcheng, Xiao, Han, and Jiang, Shaosong

Subjects

*PRECIPITATION (Chemistry), *OSTWALD ripening, *STRAIN rate, *LATTICE theory, *HOT pressing, *PRECIPITATION hardening

Abstract

The precipitation of homogeneous nanoscale HfRe 2 in NiAl grains was achieved by strain-induced precipitation at 1000 °C with a strain rate of 0.001 s−1. HfRe 2 could not be precipitated under separate heating at 1000 °C, as the deformation increased, HfRe 2 began to precipitate and gradually increased in size due to Ostwald ripening. The increase in hardness confirmed the occurrence of precipitation processes. A detailed discussion of the phase composition of the precipitates and their orientation relationship with the matrix was performed. The lattice mismatch at the NiAl 111 / / HfRe 2 2 7 ¯ 5 5.36 ⊥ HfRe 2 2 7 ¯ 5 3 interface was calculated to be only 3.90% based on the Bramfitt two-dimensional lattice mismatch theory, which demonstrated that HfRe 2 could precipitate with NiAl as a heterogeneous nucleus. • NiAl-based network structural composites were prepared by hot press sintering. • Homogeneous nanoscale HfRe 2 was obtained by strain-induced precipitation. • The precipitation behaviour of HfRe 2 was studied by TEM. • NiAl could be a very effective heterogeneous nucleus for HfRe 2. [ABSTRACT FROM AUTHOR]

Published

2022

46. Dissolution and precipitation behaviour in steels microalloyed with niobium during thermomechanical processing.

Author

Gong, P., Palmiere, E.J., and Rainforth, W.M.

Subjects

*DISSOLUTION (Chemistry), *PRECIPITATION (Chemistry), *STEEL analysis, *MICROALLOYING, *NIOBIUM, *LOW temperatures

Abstract

The thermomechanical processing of high strength low allow (HSLA) steels during low-temperature roughing, followed by rapid reheating to higher temperatures was investigated to better understand the Nb dissolution kinetics in austenite, and the subsequent precipitation behaviour during the final finishing passes. For comparative purposes, two experimental 0.06 wt% C steels were studied, one containing 0.03 wt% Nb (Nb steel), and the second containing both 0.03 wt% Nb and 0.02 wt% Ti (Nb–Ti steel). Processing of these steels consisted of a simulated roughing schedule, with the final roughing pass taking place at 850 °C. The strain-induced precipitation intensity in the steels subsequently quenched where characterised using transmission electron microscopy. Following this, the steels were rapidly reheated at a rate of 10 °C/s to a temperature of 1200 °C, held at temperature for various times, and water quenched to room temperature so that both the precipitate dissolution kinetics, together with the austenite grain coarsening kinetics could be established. [ABSTRACT FROM AUTHOR]

Published

2015

47. Softening Kinetics in High Al and High Al-Nb-Microalloyed Steels.

Author

Pereda, B., Aretxabaleta, Z., and López, B.

Subjects

ALUMINUM alloys, MICROALLOYING, TORSION, PHASE transitions, SOLID solutions

Abstract

Double-hit torsion tests were performed in order to study the effect of high Al levels (up to 2 wt.%) and Nb microalloying (up to 0.07 wt.%) on the static softening kinetics of 0.2%C-2%Mn steels. The addition of 1%Al leads to a delay in the softening kinetics due to solute-drag effect, equivalent to that exerted by 0.027%Nb. For the 2%Al steels, at temperatures below 1000 °C, γ → α phase transformation occurs after deformation, resulting in a larger retardation of the softening kinetics. At temperatures higher than 1000 °C, Nb in solid solution also contributes to the retardation of the static softening kinetics, and at lower temperatures NbC strain-induced precipitation leads to incomplete softening for the 1%Al steel, and to a complex interaction between softening, phase transformation, and NbC strain-induced precipitation for the 2%Al-Nb steels. The effect of Al on the static softening kinetics was quantified and introduced in a model developed in previous works for the prediction of the austenite microstructural evolution. In order to validate the results of the model, multipass torsion tests were carried out at conditions representative of hot strip and plate rolling mills. Model predictions show reasonable agreement with the results obtained at different deformation conditions. [ABSTRACT FROM AUTHOR]

Published

2015

48. Analysis of the Microstructure Development of Nb-Microalloyed Steel during Rolling on a Heavy-Section Mill.

Author

Sauer M, Fabík R, Schindler I, Kawulok P, Opěla P, Kawulok R, Vodárek V, and Rusz S

Abstract

It is not realistic to optimize the roll pass design of profile rolling mills, which typically roll hundreds of profiles, using physical modelling or operational rolling. The use of reliable models of microstructure evolution is preferable here. Based on the mathematical equations describing the microstructure evolution during hot rolling, a modified microstructure evolution model was presented that better accounts for the influence of strain-induced precipitation (SIP) on the kinetics of static recrystallization. The time required for half of the structure to soften, t , by static recrystallization was calculated separately for both situations in which strain-induced precipitation occurred or did not occur. On this basis, the resulting model was more sensitive to the description of grain coarsening in the high-rolling-temperature region, which is a consequence of the rapid progress of static recrystallization and the larger interpass times during rolling on cross-country and continuous mills. The modified model was verified using a plain strain compression test (PSCT) simulation of rolling a 100-mm-diameter round bar performed on the Hydrawedge II hot deformation simulator (HDS-20). Four variants of simulations were performed, differing in the rolling temperature in the last four passes. For comparison with the outputs of the modified model, an analysis of the austenite grain size after rolling was performed using optical metallography. For indirect comparison with the model outputs, the SIP initiation time was determined based on the NbX precipitate size distribution obtained by TEM. Using the PSCT and the outputs from the modified microstructure evolution model, it was found that during conventional rolling, strain-induced precipitation occurs after the last pass and thus does not affect the austenite grain size. By lowering the rolling temperature, it was possible to reduce the grain size by up to 56 μm, while increasing the mean flow stress by a maximum of 74%. The resulting grain size for all four modes was consistent with the operating results.0.5 , by static recrystallization was calculated separately for both situations in which strain-induced precipitation occurred or did not occur. On this basis, the resulting model was more sensitive to the description of grain coarsening in the high-rolling-temperature region, which is a consequence of the rapid progress of static recrystallization and the larger interpass times during rolling on cross-country and continuous mills. The modified model was verified using a plain strain compression test (PSCT) simulation of rolling a 100-mm-diameter round bar performed on the Hydrawedge II hot deformation simulator (HDS-20). Four variants of simulations were performed, differing in the rolling temperature in the last four passes. For comparison with the outputs of the modified model, an analysis of the austenite grain size after rolling was performed using optical metallography. For indirect comparison with the model outputs, the SIP initiation time was determined based on the NbX precipitate size distribution obtained by TEM. Using the PSCT and the outputs from the modified microstructure evolution model, it was found that during conventional rolling, strain-induced precipitation occurs after the last pass and thus does not affect the austenite grain size. By lowering the rolling temperature, it was possible to reduce the grain size by up to 56 μm, while increasing the mean flow stress by a maximum of 74%. The resulting grain size for all four modes was consistent with the operating results.

Published

2022

49. Microstructure and Superplastic Behavior of Ni-Modified Ti-Al-Mo-V Alloys

Author

Maria Postnikova, Anastasia Mikhaylovskaya, Vladimir Cheverikin, Ahmed Omar, and Anton Kotov

Subjects

titanium alloys, superplasticity, microstructural evolution, dynamic grain growth kinetics, strain-induced precipitation, mechanical properties, Metals and Alloys, General Materials Science

Abstract

The paper studies the influence of 0.5–1.8 wt.% Ni alloying on the superplasticity, microstructural evolution, and dynamic grain growth effect in a temperature range of 625–775 °C and room temperature mechanical properties of two-phase Ti-Al-Mo-V alloys. Due to a decrease in β transus and an enhancement in the alloy diffusivity, an increase in Ni content significantly improved superplasticity. The Ni-modified alloys exhibited 1.5–3-fold lower flow stress, a 2.5–3-fold greater elongation to failure, and 1.4–1.7-fold higher strain rate sensitivity m coefficient compared to the Ni-free alloy. An intermetallic Ti2Ni compound precipitated in the 1.8 wt.% Ni-modified alloy during low-temperature deformation at 700 °C and decreased superplastic properties. The Ti-4Al-3Mo-1V-0.1B alloy with 0.9 wt.% Ni exhibited a good combination of the superplastic behavior and room-temperature mechanical properties: an elongation to failure of 500–900% at a low-temperature range of 625–775 °C and constant strain rate of 1 × 10−3 s−1 and a yield strength of 885 MPa and ultimate tensile strength of 1020 MPa after pre-straining for 100% in a superplastic regime and strengthening heat treatment.

Published

2022

50. Evolution of strain-induced precipitates in a model austenitic Fe–30Ni–Nb steel and their effect on the flow behaviour.

Author

Poddar, Debasis, Cizek, Pavel, Beladi, Hossein, and Hodgson, Peter D.

Subjects

*STRAINS & stresses (Mechanics), *PRECIPITATION (Chemistry), *AUSTENITIC steel, *IRON-nickel alloys, *DISLOCATIONS in crystals, *TRANSMISSION electron microscopy

Abstract

The present work investigated the evolution of strain-induced NbC precipitates in a model austenitic Fe–30Ni–Nb steel deformed at 925 °C to a strain of 0.2 during post-deformation holding between 3 and 1000 s and their effect on the reloading flow stress. The precipitate particles preferentially nucleated on the nodes of the periodic dislocation networks constituting microband walls. Holding for 10 s resulted in the formation of fine, largely coherent NbC particles with a mean diameter of ∼5 nm, which displayed a cube-on-cube orientation relationship with austenite and caused the maximum increase in the reloading steady-state flow stress. A further increase in the holding time from 30 to 1000 s led to the formation of semi-coherent, gradually coarser and more widely spaced particles with a mean diameter of 8 nm and above, which led to a gradual decrease in the reloading steady-state flow stress. The holding time increase resulted in progressive disintegration of the dislocation substructure and dislocation annihilation through static recovery processes, which was also reflected by the measured softening fractions. The precipitate particle shape changed during post-deformation annealing from elliptical to faceted octahedral and subsequently to tetra-kai-decahedral. [ABSTRACT FROM AUTHOR]

Published

2014