Your search keyword '"cryogenic rolling"' showing total 67 results

1. High density dislocations enhance creep ageing response and mechanical properties in 2195 alloy sheet.

Author

Wei, Shuo, Ma, Pei-pei, Chen, Long-hui, Yang, Jian-shi, Zhan, Li-hua, and Liu, Chun-hui

Abstract

Copyright of Journal of Central South University is the property of Springer Nature and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2024

2. Effect of Deep-Cooling Rolling Deformation on the Microstructure and Mechanical Properties of an Al-4.5Cu-1.5Mg-0.6Mn-0.2Ti Alloy

Author

Liu, Xinyu, Sun, Youping, Li, Wangzhen, Xie, Shangheng, He, Jiangmei, and Pei, Mengyu

Published

2024

3. High strength and electrical conductivity of nanostructured Cu–1Cr–0.1Zr alloy processed by multi–stage deformation and aging

Author

Zhuqi Chu, Xuhao Pan, Wei Wei, Kunxia Wei, Igor V. Alexandrov, Xulong An, Dandan Wang, and Xiangkui Liu

Subjects

Cu–1Cr–0.1Zr alloy, ECAP, Cryogenic rolling, Electrical conductivity, Nanostructure, Mining engineering. Metallurgy, TN1-997

Abstract

The effects of equal channel angular pressing (ECAP), multiple cryogenic rolling and aging treatment on the microstructure, mechanical properties, and electrical conductivity of Cu–1Cr–0.1Zr alloy were investigated. The results showed that multi-stage deformation and aging (ECAP at ambient temperature + primary cryogenic rolling 50 % + 450 °C aging for 1h + secondary cryogenic rolling 80 % + 150 °C aging for 1h) can lead to the rational comprehensive performance of Cu–1Cr–0.1Zr alloy with tensile strength of 730 MPa and electrical conductivity of 75.5 % IACS. The microstructure characterization revealed that in the Cu–1Cr–0.1Zr alloy a subject to the multistage deformation and aging, there ultrafine grains, nanotwins, nanoprecipitates and micrometer precipitates constituted the nanostructured state. The increase in tensile strength was mainly attributed to fine grain strengthening and precipitation strengthening, followed by dislocation strengthening due to low temperature deformation. The ECAP resulted in the refinement of grain, and the increased dislocation density. The following primary cryogenic rolling refined the grains up to ultrafine-grained (UFG) size and created nanotwins. The introduction of nano-precipitated phases by intermediate aging pinned dislocations and impeded the motion of dislocation entanglements, allowing the alloy to achieve higher strength. Multi-stage deformation and aging resulted in a higher density of twin boundaries in the nanostructure and dilute solid solution in comparison with one stage treatment. These microstructural features were responsible for the excellent electrical conductivity.

Published

2024

4. Combination of cryogenic deformation and electropulse processing as a way to produce ultrafine-grain metals

Author

Mikhail V. Markushev, Elena V. Avtokratova, Aigul Kh. Valeeva, Irshat Sh. Valeev, Rafis R. Ilyasov, Stanislav V. Krymsky, and Oleg Sh. Sitdikov

Subjects

fcc metals, cryogenic deformation, cryogenic rolling, electric pulse treatment, ultrafine-grain structure, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

The data of a comparative analysis of the structure and hardness of pure metals with a face-centered cubic lattice – aluminum, nickel and copper, subjected to complex thermomechanical treatment (TMT), including isothermal cryogenic rolling at liquid nitrogen temperature and subsequent high-density electropulse treatment (EPT) were presented. The main stages, features and advantages of TMT, which first ensure strong work hardening of the processed material due to deformation at low temperatures and then its ultra-fast contact electropulse heating up to a specified temperature, were considered. A multi-level analysis of the metals structure evolution due to TMT was carried out using modern methods of scanning electron microscopy and X-ray diffractometry, recording a wide range of its linear and angular parameters. The kinetics and nature of the processes of the metals structure evolution under cryogenic rolling and EPT, their driving forces and controlling factors, as well as general patterns and temperature intervals of activation of the deformation structure recovery and recrystallization influenced by an electric pulse are identified and discussed. Based on the results of the analysis of the structural and mechanical behaviour of metals, it was concluded that the combination of severe plastic cryogenic deformation and a single-step treatment with ultrashort alternating current pulses is an effective way to obtain semi-finished products with controlled parameters of their structure and properties, including high-strength ultrafine-grain rolled products. At that the phenomenology and nature of the strengthening/softening of metals during cryogenic rolling and subsequent electropulsing are similar to those observed under cold rolling and furnace annealing.

Published

2023

5. Influence of bimodal non-basal texture on microstructure characteristics, texture evolution and deformation mechanisms of AZ31 magnesium alloy sheet rolled at liquid-nitrogen temperature

Author

Shouzuo Zhang, Li Hu, Yutao Ruan, Tao Zhou, Qiang Chen, Yang Zhong, Laixin Shi, Mingao Li, Mingbo Yang, and Shuyong Jiang

Subjects

AZ31 Mg alloy, Bimodal non-basal texture, Cryogenic rolling, Microstructure evolution, Deformation mechanism, Mining engineering. Metallurgy, TN1-997

Abstract

Cryogenic rolling experiments have been conducted on the AZ31 magnesium (Mg) alloy sheet with bimodal non-basal texture, which is fabricated via the newly developed equal channel angular rolling and continuous bending process with subsequent annealing (ECAR-CB-A) process. Results demonstrate that this sheet shows no edge cracks until the accumulated thickness reduction reaches about 18.5%, which is about 105.6% larger than that of the sheet with traditional basal texture. Characterization experiments including optical microstructure (OM), X-ray diffractometer (XRD), and electron backscatter diffraction (EBSD) measurements are then performed to explore the microstructure characteristics, texture evolution and deformation mechanisms during cryogenic rolling. Experimental observations confirm the occurrence of abundant {10–12} extension twins (ETs), twin-twin interactions among {10–12} ET variants and {10–12}-{10–12} double twins (DTs). The twinning behaviors as for {10–12} ETs are responsible for the concentration of c-axes of grains towards normal direction (ND) and the formation of transverse direction (TD)-component texture at the beginning of cryogenic rolling. The twinning behaviors with respect to {10–12}-{10–12} DTs are responsible for the disappearance of TD-component texture at the later stage of cryogenic rolling. The involved deformation mechanisms can be summarized as follows: Firstly {10–12} ETs dominate the plastic deformation. Subsequently, dislocation slip, especially basal slip, starts to sustain more plastic strain, while {10–12} ETs occur more frequently and enlarge continuously, resulting in the formation of twin-twin interaction among {10–12} ET variants. With the increasing rolling passes, {10–12}-{10–12} DTs incorporate in the plastic deformation and dislocation slip serves as the major one to sustain plastic strain. The activities of basal slip, {10–12} ETs and {10–12}-{10–12} DTs benefit in accommodating the plastic strain in sheet thickness, which contributes to the improved rolling formability in AZ31 Mg alloy sheet with bimodal non-basal texture during cryogenic rolling.

Published

2023

6. Influence of substructures on precipitation behavior and mechanical properties of cryogenic rolled Al–Mg–Si alloys during aging treatment

Author

Xucheng Wang, Yongxing Zhao, Yu Liu, and Yuanchun Huang

Subjects

AA6016 sheet, Cryogenic rolling, Aging treatment, Substructures, Precipitation strengthening, Mining engineering. Metallurgy, TN1-997

Abstract

Cryogenic rolling is a promising method to improve the mechanical properties of Al–Mg–Si alloys. In this paper, the effect of artificial aging treatment on the mechanical properties and microstructures of cryogenic rolled Al–Mg–Si sheet is investigated. The hardness and yield strength of cryogenic rolled alloys decrease at the early aging stage, but the hardness and yield strength of room temperature rolled alloys increase at the early aging stage. Besides, substructures (such as dislocations) are observed in cryogenic rolled alloys but not in room temperature rolled alloys after solution treatment, the degree of recrystallization in the cryogenic rolled alloy is inferior to that in room temperature rolled alloy. The differences lead to the difference in strength between cryogenic rolled alloys and room temperature rolled alloys at the early aging stage. A precipitation mechanism is proposed to explain how these substructures promote precipitate nucleation and growth during artificial aging treatment. Based on the precipitation strengthening theory, a precipitation model is used to explain the strengthening contribution from precipitation during aging treatment, the capacity of precipitation strengthening in cryogenic rolled alloy is much higher than that in room temperature rolled alloy.

Published

2023

7. Hierarchical Multiple Precursors Induced Heterogeneous Structures in Super Austenitic Stainless Steels by Cryogenic Rolling and Annealing.

Author

Tan, Duo, Fu, Bin, Guan, Wei, Li, Yu, Guo, Yanhui, Wei, Liqun, and Ding, Yi

Subjects

*AUSTENITIC stainless steel, *ROLLING (Metalwork), *STRAIN hardening, *COLD rolling, *MARTENSITE, *CARBON foams

Abstract

Multiple deformed substructures including dislocation cells, nanotwins (NTs) and martensite were introduced in super austenitic stainless steels (SASSs) by cryogenic rolling (Cryo-R, 77 K/22.1 mJ·m−2). With the reduction increasing, a low stacking fault energy (SFE) and increased flow stress led to the activation of secondary slip and the occurrence of NTs and martensite nano-laths, while only dislocation tangles were observed under a heavy reduction by cold-rolling (Cold-R, 293 K/49.2 mJ·m−2). The multiple precursors not only possess variable deformation stored energy, but also experience competition between recrystallization and reverse transformation during subsequent annealing, thus contributing to the formation of a heterogeneous structure (HS). The HS, which consists of bimodal-grained austenite and retained martensite simultaneously, showed a higher yield strength (~1032 MPa) and a larger tensile elongation (~9.1%) than the annealed coarse-grained Cold-R sample. The superior strength–ductility and strain hardening originate from the synergistic effects of grain refinement, dislocation and hetero-deformation-induced hardening. [ABSTRACT FROM AUTHOR]

Published

2023

8. CHARACTERIZATION OF CRYO-ROLLED LOW CARBON STEEL USING FERRITE-MARTENSITE STARTING MICROSTRUCTURE.

Author

Zakaria, S. A., Ahmad, M. S., Anasyida, A. S., Zuhailawati, H., Dhindaw, B. K., and Abioye, T. E.

Subjects

*MILD steel, *LIQUID nitrogen, *CARBON steel, *MICROSTRUCTURE, *MATERIAL plasticity, *DISLOCATION density, *CRYOGENIC liquids

Abstract

Cryo-rolling, a technique of severe plastic deformation (SPD) performed at cryogenic temperatures, has proven to be a promising technique for improving the microstructure and mechanical properties of low-carbon steels. Low carbon steel with a two-phase ferrite-martensite starting microstructure was subjected to cryogenic rolling at liquid nitrogen temperature to produce sheets with different deformation rates: 50%, 70%, and 90%. The microstructure, mechanical properties, and corrosion resistance were investigated. The results show that cryo-rolling effectively refines the microstructure and leads to a higher dislocation density and smaller grain size as the deformation rate increases. The cryorolled sample deformed at 90% has the highest grain aspect ratio (35.5), the smallest crystallite size (13.70 nm), the highest lattice strain (74.6 x 10-3), and the highest dislocation density compared to the samples deformed at 50% and 70%. This refined microstructure significantly improves the mechanical properties, with the cryo-rolled sample deformed at 90% exhibiting the highest hardness (152 HV), tensile strength (1020 MPa), and yield strength (950 MPa), corresponding to an increase of 175.6%, 344.0%, and 466.5%, respectively. In addition, cryo-rolling at 90% showed a decrease in corrosion resistance, with the lowest corrosion rate observed at 90% deformation (5.97 mm/year). [ABSTRACT FROM AUTHOR]

Published

2023

9. Influence of bimodal non-basal texture on microstructure characteristics, texture evolution and deformation mechanisms of AZ31 magnesium alloy sheet rolled at liquid-nitrogen temperature.

Author

Zhang, Shouzuo, Hu, Li, Ruan, Yutao, Zhou, Tao, Chen, Qiang, Zhong, Yang, Shi, Laixin, Li, Mingao, Yang, Mingbo, and Jiang, Shuyong

Subjects

MAGNESIUM alloys, LIQUID nitrogen, MICROSTRUCTURE, MATERIAL plasticity, DEFORMATIONS (Mechanics), X-ray diffraction, X-ray diffractometers

Abstract

Cryogenic rolling experiments have been conducted on the AZ31 magnesium (Mg) alloy sheet with bimodal non-basal texture, which is fabricated via the newly developed equal channel angular rolling and continuous bending process with subsequent annealing (ECAR-CB-A) process. Results demonstrate that this sheet shows no edge cracks until the accumulated thickness reduction reaches about 18.5%, which is about 105.6% larger than that of the sheet with traditional basal texture. Characterization experiments including optical microstructure (OM), X-ray diffractometer (XRD), and electron backscatter diffraction (EBSD) measurements are then performed to explore the microstructure characteristics, texture evolution and deformation mechanisms during cryogenic rolling. Experimental observations confirm the occurrence of abundant {10–12} extension twins (ETs), twin-twin interactions among {10–12} ET variants and {10–12}-{10–12} double twins (DTs). The twinning behaviors as for {10–12} ETs are responsible for the concentration of c-axes of grains towards normal direction (ND) and the formation of transverse direction (TD)-component texture at the beginning of cryogenic rolling. The twinning behaviors with respect to {10–12}-{10–12} DTs are responsible for the disappearance of TD-component texture at the later stage of cryogenic rolling. The involved deformation mechanisms can be summarized as follows: Firstly {10–12} ETs dominate the plastic deformation. Subsequently, dislocation slip, especially basal slip, starts to sustain more plastic strain, while {10–12} ETs occur more frequently and enlarge continuously, resulting in the formation of twin-twin interaction among {10–12} ET variants. With the increasing rolling passes, {10–12}-{10–12} DTs incorporate in the plastic deformation and dislocation slip serves as the major one to sustain plastic strain. The activities of basal slip, {10–12} ETs and {10–12}-{10–12} DTs benefit in accommodating the plastic strain in sheet thickness, which contributes to the improved rolling formability in AZ31 Mg alloy sheet with bimodal non-basal texture during cryogenic rolling. [ABSTRACT FROM AUTHOR]

Published

2023

10. Improving Precipitation in Cryogenic Rolling 6016 Aluminum Alloys during Aging Treatment.

Author

Wang, Xucheng, Liu, Yu, and Huang, Yuanchun

Subjects

*ALUMINUM alloys, *RECRYSTALLIZATION (Metallurgy), *SOLID solutions, *ALLOYS, *PRECIPITATION hardening

Abstract

This study systematically investigated the performance and microstructure characterization of cryogenic rolling (CR) and room-temperature rolling (RTR) Al–Mg–Si alloys. The result showed that the hardness of the CR alloys decreased at the early aging stage, but that the hardness of the RTR alloys increased at the early aging stage. Retrogression phenomena were apparent in the CR alloys at the early aging stage. Despite undergoing the same solid solution treatment, a few substructures were still observed in the CR alloys, and the degree of recrystallization in the CR alloys was significantly inferior to that in the RTR alloys. After aging for 50 h, the strength and precipitates' density in the CR 75 alloy were higher than that in the other alloys; this indicated that the substructures were beneficial to precipitation and precipitate growth. A precipitation strength model was employed to illustrate the precipitation contribution at different aging stages. The results showed that the CR 75 alloy obtained the strongest precipitation strengthening. [ABSTRACT FROM AUTHOR]

Published

2023

11. Investigation of the Formability of Cryogenic Rolled AA6061 and Its Improvement Using Artificial Aging Treatment.

Author

Sadeghi, Abbas, Kozeschnik, Ernst, and Biglari, Farid R.

Subjects

ALUMINUM sheets, MANUFACTURING processes, MATERIAL plasticity

Abstract

Cryogenic rolling is one of the essential severe plastic deformation processes to manufacture high-strength aluminum sheets with excellent formability limits. The present work characterizes the formability of AA6061 for cryogenic rolling before and after artificial aging. Nakajima method based on ISO standard is used to measure formability. Samples are aged in the range of 100 °C to 150 °C. Artificial aging at 150 °C is found to be the optimum temperature for achieving a good combination of strength and formability. Over the course of artificial aging, strength improved up to 40%, where the original value of 250 MPa for cryo-rolled condition increased to 350 MPa after 50 h of aging at 150 °C, and the formability of the cryo-rolled sample improved especially for multi-axial forming condition. [ABSTRACT FROM AUTHOR]

Published

2023

12. Effect of Rolling Process and Aging on the Microstructure and Properties of Cu-1.0Cr-0.1Zr Alloy.

Author

Zha, Jun, Zhao, Yu, Qiao, Yihui, Zou, Haohao, Hua, Zeen, Zhu, Weiwei, Han, Ying, Zu, Guoqing, and Ran, Xu

Subjects

*ALLOY plating, *MECHANICAL behavior of materials, *TENSILE strength, *FRETTING corrosion, *MICROSTRUCTURE, *ADHESIVE wear, *ALLOYS

Abstract

In order to study the effect of the rolling process and aging on the microstructure evolution and mechanical and tribological properties of the material, room-temperature rolling (RTR), cryogenic rolling (CR), and deep cryogenic treatment after rolling (RTR + DCT) experiments were carried out on a Cu-1.0Cr-0.1Zr alloy by a large plastic deformation process. Alloy plates were aged at 550 °C for 60 min. Different rolling processes and aging treatments have different effects on the microstructure and properties of alloy plates. The alloy plate is rolled and deformed, and the grains change from equiaxed to layered. Compared with RTR and RTR + DCT treatment, CR can promote the precipitation of the Cr phase and the degree of grain fragmentation is greater. After aging treatment, the Cu-Zr mesophase compounds in the microstructure increased, the alloys treated with CR and RTR + DCT appeared to be partially recrystallized, and the number of twins in the CR alloy plate was significantly more than that of RTR + DCT. The ultimate tensile strength of the alloy plate reached 553 MPa and the hardness reached 170 HV after cryogenic rolling with 90% deformation, which indicates that CR treatment can further improve the physical properties of the alloy plate. After aging at 550 °C for 60 min, the RTR 90% + DCT alloy plate has a tensile strength of 498 MPa and an elongation of 47.9%, which is three times that of the as-rolled alloy plate. From the research on the tribological properties of alloy plates, we learned that the main wear mechanisms in the wear forms of CR and RTR + DCT alloy plates are adhesive wear and abrasive wear. Adhesive wear is dominant in the early stage, while abrasive wear is the dominant mechanism in the later stage of wear. The friction coefficient of the CR 90% alloy plate in the TD direction is close to 0.55, and the wear rate is 2.9 × 10−4 mm3/Nm, indicating that the CR treatment further improves the wear resistance of the alloy plates. [ABSTRACT FROM AUTHOR]

Published

2023

13. Work Hardening Behavior and Microstructure Evolution of a Cu-Ti-Cr-Mg Alloy during Room Temperature and Cryogenic Rolling.

Author

Li, Rong, Xiao, Zhu, Li, Zhou, Meng, Xiangpeng, and Wang, Xu

Subjects

*STRAIN hardening, *JOB performance, *MICROSTRUCTURE, *MECHANICAL alloying, *TENSILE strength

Abstract

A Cu-1.79Ti-0.39Cr-0.1Mg (wt.%) alloy was prepared by a vacuum induction melting furnace in a high-purity argon atmosphere. The effects of room temperature rolling and cryogenic rolling on the microstructure, textures, and mechanical properties of the alloy were investigated by means of electron backscatter diffraction, transmission electron microscopy, and X-ray diffraction. The results show that the hardness of the cryogenically rolled alloy is 18–30 HV higher than that of the room temperature rolled alloy at any tested rolling reduction. The yield strength and tensile strength of the alloy cryogenically rolled by 90% reduction are 723 MPa and 796 MPa, respectively. With the increase of rolling reduction, the orientation density of the Cube texture decreases, while the Brass texture increases. The Brass texture is preferred especially during the cryogenic rolling, suggesting that the cross-slip is inhibited at the cryogenic temperature. The dislocation densities of Cu-Ti-Cr-Mg alloy increase significantly during the deformation, finally reaching 23.03 × 10−14 m−2 and 29.98 × 10−14 m−2 after a 90% reduction for the room temperature rolled and cryogenically rolled alloys, respectively. This difference could be attributed to the impediment effect of cryogenic temperature on dynamic recovery and dynamic recrystallization. The cryogenic temperature promotes the formation of the dislocation and the nano-twins, leading to the improvement of the mechanical properties of the alloy. [ABSTRACT FROM AUTHOR]

Published

2023

14. Recrystallization behavior and texture evolution during annealing of cryogenic-rolled 3003 aluminum alloy.

Author

Zhou, Y.L., Yang, Y., Tan, Y.B., Xiang, S., Ma, M., Zhao, F., and Yang, M.

Subjects

*ALUMINUM alloys, *RECRYSTALLIZATION (Metallurgy), *ELECTRICAL steel, *ELECTRON diffraction, *X-ray diffraction, *LEAD time (Supply chain management)

Abstract

Heterostructure materials have attracted much attention owing to their excellent strength-ductility synchronization. In this work, a heterogeneous structure consisting of coarse grains and ultrafine grains was developed in 3003 aluminum alloy by cryogenic rolling and short-time annealing. The recrystallization behavior and texture evolution in cryogenic-rolled 3003 aluminum alloy were investigated by using X-ray diffraction and Electron Back-Scatter Diffraction. The results show that various annealing temperatures and time led to a significant difference in the microstructure and texture evolution. As annealing progressed, the recrystallized volume fraction raised with the increment of annealing time, and the β-fiber rolling texture gradually developed to recrystallization texture including R, Cube and R-Cube ND. Recrystallization kinetics were constructed based on the Johnson-Mehl-Avrami-Kolmogorov model. An excellent strength-ductility balance can be obtained for cryogenic-rolled samples annealed at 390°C/45 s owing to the formation of a heterogeneous structure comprising coarse grains and ultrafine grains. • A heterogeneous structure was produced by cryogenic rolling and short-time annealing. • The recrystallization kinetics of cryogenic-rolled 3003 aluminum alloy were constructed. • Microstructure and texture evolution during cryogenic rolling and annealing was investigated. [ABSTRACT FROM AUTHOR]

Published

2024

15. Hierarchical Multiple Precursors Induced Heterogeneous Structures in Super Austenitic Stainless Steels by Cryogenic Rolling and Annealing

Author

Duo Tan, Bin Fu, Wei Guan, Yu Li, Yanhui Guo, Liqun Wei, and Yi Ding

Subjects

super austenitic stainless steel, cryogenic rolling, heterogeneous structure, microstructure, mechanical properties, 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

Multiple deformed substructures including dislocation cells, nanotwins (NTs) and martensite were introduced in super austenitic stainless steels (SASSs) by cryogenic rolling (Cryo-R, 77 K/22.1 mJ·m−2). With the reduction increasing, a low stacking fault energy (SFE) and increased flow stress led to the activation of secondary slip and the occurrence of NTs and martensite nano-laths, while only dislocation tangles were observed under a heavy reduction by cold-rolling (Cold-R, 293 K/49.2 mJ·m−2). The multiple precursors not only possess variable deformation stored energy, but also experience competition between recrystallization and reverse transformation during subsequent annealing, thus contributing to the formation of a heterogeneous structure (HS). The HS, which consists of bimodal-grained austenite and retained martensite simultaneously, showed a higher yield strength (~1032 MPa) and a larger tensile elongation (~9.1%) than the annealed coarse-grained Cold-R sample. The superior strength–ductility and strain hardening originate from the synergistic effects of grain refinement, dislocation and hetero-deformation-induced hardening.

Published

2023

16. EFFECT OF INITIAL TEMPERATURE ON THE MICROSTRUCTURE AND PROPERTIES OF CRYOGENIC ROLLED AZ31 MAGNESIUM ALLOY.

Author

Zhenyu Wu, Chenchen Zhi, Lifeng Ma, Zebang Zheng, Yanchun Zhu, and Weitao Jia

Subjects

MAGNESIUM alloys, MICROSTRUCTURE, YIELD strength (Engineering), HARDNESS, TEMPERATURE measurements

Abstract

Copyright of Materials & Technologies / Materiali in Tehnologije is the property of Institute of Metals & Technology and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

17. Improving Precipitation in Cryogenic Rolling 6016 Aluminum Alloys during Aging Treatment

Author

Xucheng Wang, Yu Liu, and Yuanchun Huang

Subjects

AA6016 plate, cryogenic rolling, aging treatment, substructures, precipitation strengthening, 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

This study systematically investigated the performance and microstructure characterization of cryogenic rolling (CR) and room-temperature rolling (RTR) Al–Mg–Si alloys. The result showed that the hardness of the CR alloys decreased at the early aging stage, but that the hardness of the RTR alloys increased at the early aging stage. Retrogression phenomena were apparent in the CR alloys at the early aging stage. Despite undergoing the same solid solution treatment, a few substructures were still observed in the CR alloys, and the degree of recrystallization in the CR alloys was significantly inferior to that in the RTR alloys. After aging for 50 h, the strength and precipitates’ density in the CR 75 alloy were higher than that in the other alloys; this indicated that the substructures were beneficial to precipitation and precipitate growth. A precipitation strength model was employed to illustrate the precipitation contribution at different aging stages. The results showed that the CR 75 alloy obtained the strongest precipitation strengthening.

Published

2023

18. Investigation of the Formability of Cryogenic Rolled AA6061 and Its Improvement Using Artificial Aging Treatment

Author

Abbas Sadeghi, Ernst Kozeschnik, and Farid R. Biglari

Subjects

cryogenic rolling, AA6061, forming limit diagram, artificial aging, mechanical properties, Production capacity. Manufacturing capacity, T58.7-58.8

Abstract

Cryogenic rolling is one of the essential severe plastic deformation processes to manufacture high-strength aluminum sheets with excellent formability limits. The present work characterizes the formability of AA6061 for cryogenic rolling before and after artificial aging. Nakajima method based on ISO standard is used to measure formability. Samples are aged in the range of 100 °C to 150 °C. Artificial aging at 150 °C is found to be the optimum temperature for achieving a good combination of strength and formability. Over the course of artificial aging, strength improved up to 40%, where the original value of 250 MPa for cryo-rolled condition increased to 350 MPa after 50 h of aging at 150 °C, and the formability of the cryo-rolled sample improved especially for multi-axial forming condition.

Published

2023

19. Effect of Rolling Process and Aging on the Microstructure and Properties of Cu-1.0Cr-0.1Zr Alloy

Author

Jun Zha, Yu Zhao, Yihui Qiao, Haohao Zou, Zeen Hua, Weiwei Zhu, Ying Han, Guoqing Zu, and Xu Ran

Subjects

Cu-1.0Cr-0.1Zr alloy, cryogenic rolling, microstructure, mechanical properties, friction and wear, 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 order to study the effect of the rolling process and aging on the microstructure evolution and mechanical and tribological properties of the material, room-temperature rolling (RTR), cryogenic rolling (CR), and deep cryogenic treatment after rolling (RTR + DCT) experiments were carried out on a Cu-1.0Cr-0.1Zr alloy by a large plastic deformation process. Alloy plates were aged at 550 °C for 60 min. Different rolling processes and aging treatments have different effects on the microstructure and properties of alloy plates. The alloy plate is rolled and deformed, and the grains change from equiaxed to layered. Compared with RTR and RTR + DCT treatment, CR can promote the precipitation of the Cr phase and the degree of grain fragmentation is greater. After aging treatment, the Cu-Zr mesophase compounds in the microstructure increased, the alloys treated with CR and RTR + DCT appeared to be partially recrystallized, and the number of twins in the CR alloy plate was significantly more than that of RTR + DCT. The ultimate tensile strength of the alloy plate reached 553 MPa and the hardness reached 170 HV after cryogenic rolling with 90% deformation, which indicates that CR treatment can further improve the physical properties of the alloy plate. After aging at 550 °C for 60 min, the RTR 90% + DCT alloy plate has a tensile strength of 498 MPa and an elongation of 47.9%, which is three times that of the as-rolled alloy plate. From the research on the tribological properties of alloy plates, we learned that the main wear mechanisms in the wear forms of CR and RTR + DCT alloy plates are adhesive wear and abrasive wear. Adhesive wear is dominant in the early stage, while abrasive wear is the dominant mechanism in the later stage of wear. The friction coefficient of the CR 90% alloy plate in the TD direction is close to 0.55, and the wear rate is 2.9 × 10−4 mm3/Nm, indicating that the CR treatment further improves the wear resistance of the alloy plates.

Published

2023

20. Work Hardening Behavior and Microstructure Evolution of a Cu-Ti-Cr-Mg Alloy during Room Temperature and Cryogenic Rolling

Author

Rong Li, Zhu Xiao, Zhou Li, Xiangpeng Meng, and Xu Wang

Subjects

Cu-Ti-Cr-Mg alloy, cryogenic rolling, hardness, texture, twins, 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

A Cu-1.79Ti-0.39Cr-0.1Mg (wt.%) alloy was prepared by a vacuum induction melting furnace in a high-purity argon atmosphere. The effects of room temperature rolling and cryogenic rolling on the microstructure, textures, and mechanical properties of the alloy were investigated by means of electron backscatter diffraction, transmission electron microscopy, and X-ray diffraction. The results show that the hardness of the cryogenically rolled alloy is 18–30 HV higher than that of the room temperature rolled alloy at any tested rolling reduction. The yield strength and tensile strength of the alloy cryogenically rolled by 90% reduction are 723 MPa and 796 MPa, respectively. With the increase of rolling reduction, the orientation density of the Cube texture decreases, while the Brass texture increases. The Brass texture is preferred especially during the cryogenic rolling, suggesting that the cross-slip is inhibited at the cryogenic temperature. The dislocation densities of Cu-Ti-Cr-Mg alloy increase significantly during the deformation, finally reaching 23.03 × 10−14 m−2 and 29.98 × 10−14 m−2 after a 90% reduction for the room temperature rolled and cryogenically rolled alloys, respectively. This difference could be attributed to the impediment effect of cryogenic temperature on dynamic recovery and dynamic recrystallization. The cryogenic temperature promotes the formation of the dislocation and the nano-twins, leading to the improvement of the mechanical properties of the alloy.

Published

2023

21. High strength high conductivity copper prepared by C-ECAP and Cryo-rolling.

Author

Gao, Yang, Guo, Tingbiao, Feng, Rui, Qian, Danchen, Huang, Dawei, Zhang, Guoqing, Ling, Dekui, and Ding, Yutian

Subjects

*COPPER, *MATERIALS texture, *TRANSMISSION electron microscopes, *SHEAR (Mechanics), *MATERIAL plasticity

Abstract

Shear deformation through severe plastic deformation (SPD) is an effective method for achieving material refinement and twinning. In this study, T2 copper was subjected to contnuous equal channel angular pressing (C-ECAP) and liquid nitrogen cooled cryogenic rolling (CR) processes. The microstructure and texture evolution of the material were detected by X-ray diffraction (XRD), electron back-scattered diffraction (EBSD) and transmission electron microscope (TEM). The study shows that utilizing C-ECAP continuous directional shear can enhance the continuous directional twinning of T2 copper structure. Additionally, cryogenic rolling can promote the material structure to be dominated by twinning segmentation. During the deformation, the texture experiences significant fluctuations, after C-ECAP the initial {111}〈110〉 texture is rapidly transformed into a strong {110}〈112〉 Brass texture. Among various combinatons of C-ECAP and cryogenic rolling, it was noted that, after 2 passes and cryogenic rolling at 75% total thickness reducton yields, the tensile strength, hardness and conductivity reached of 462 MPa, 120 HV and 95% IACS. • In this study, the C-ECAP method was used to quickly and consistently prepare bulk ultrafine grained materials of pure copper. • Five possible modes of lattice evolution under shear action are proposed. • C-ECAP Combined with cryogenic rolling can easily form nanocrystals and induce continuous directional twinning of materials. [ABSTRACT FROM AUTHOR]

Published

2024

22. Preparation of high strength Mg–Li–Zn–Y alloy by MgLi2Zn precipitation.

Author

Wei, Zhen, Dong, Hao, Zhang, Jinghuai, Wu, Ruizhi, He, Yuying, Bao, Rirong, Zhang, Xiaobo, and Wang, Jiahao

Subjects

*ALLOYS, *ALUMINUM-lithium alloys, *QUANTITATIVE research

Abstract

For ultralight Mg–Li alloys, the improvement of strength is the most concerned issue. In this work, we successfully realize the incredible enhancement of strength in the Mg-8.5Li-7.5Zn-1.5Y alloy via a series of preparation processes, and the excellent tensile properties containing high yield strength of 312.4 MPa and good elongation of 14.2 % are obtained. Yield strength increment is as high as 213 MPa through deformation processing, which is rarely reported in Mg–Li alloys. Qualitative and quantitative studies reveal that the dislocation cutting of semi-coherent MgLi 2 Zn nano-precipitates is mainly responsible for such a high yield strength. The new finding for strengthening way is expected to contribute to the design of high-performance Mg–Li alloys. [ABSTRACT FROM AUTHOR]

Published

2024

23. Effect of cryogenic rolling and multistage thermo-mechanical treatment on the microstructure and properties of the Cu-0.4Cr-0.39Zn-0.1Mg-0.07Zr alloy.

Author

Xin, Zhao, Jiang, Yan-Bin, Wu, Zi-Xiao, Tan, Fei, Qiu, Wen-Ting, Li, Jia-Hao, Xia, Zhuo-Ran, Dai, Wen, Li, Lin-Han, and Xiao, Zhu

Subjects

*LEAD alloys, *MICROSTRUCTURE, *HEAT treatment, *ALLOYS, *MICROALLOYING, *DISLOCATION density, *COPPER alloys, *TOOL-steel

Abstract

A Cu-0.4Cr-0.39Zn-0.1Mg-0.07Zr (wt%) alloy was prepared using cryogenic rolling process and multistage thermo-mechanical treatment to achieve excellent comprehensive properties with tensile strength of 635 MPa, yield strength of 620 MPa and electrical conductivity of 75.3% IACS. A large number of nano deformation twins appeared in the alloy after cryogenic rolling, and the width of the nano twins decreased with the deformation, and the average width of nano twins decreased by 8.4% and 11.8% after the second and the third cryogenic rolling, respectively. The high density of dislocations introduced by cryogenic rolling provided more nucleation sites for Cr phase precipitation, which promoted the diffusive precipitation of Cr phase. With the synergy of microalloying of Mg and Zn elements, cryogenic rolling and multistage thermo-mechanical treatment, the copper alloy with high density of nano deformed twins, fine and diffuse precipitation phases and excellent performance was prepared, which can be used as high-performance copper alloys for lead frames of large-scale integrated circuits. • Designed alloy achieved excellent properties by cryogenic rolling and heat treatment. • Cryogenic rolling introduced nanotwins. [ABSTRACT FROM AUTHOR]

Published

2024

24. Microstructural Evolution Induced Mechanical Property Enhancement in Cryogenically Rolled Ce‐Modified SAF2507 Super Duplex Stainless Steel.

Author

Zhou, Tian, Xiong, Yi, Zha, Xiao-qin, Lu, Yan, He, Tian-tian, Ren, Feng-zhang, Rani, Ekta, Singh, Harishchandra, Kömi, Jukka, Huttula, Marko, and Cao, Wei

Subjects

DUPLEX stainless steel, STAINLESS steel, DUAL-phase steel, MECHANICAL behavior of materials, STRAIN hardening, DEFORMATIONS (Mechanics), TENSILE strength

Abstract

Thermomechanical deformation is one of the most efficient and facile routes to tailor microstructure in structural materials for mechanical property enhancement. Herein, the Ce‐modified SAF2507 super duplex stainless steel (Ce‐SAF2507) is deformed at different levels from 30% to 90% at a cryogenic temperature (–196 °C) to achieve superior mechanical performances. Cryogenic rolling increase fiber texture and induce ultra‐fine grain refinement which brings grains to ≈10 nm in the selected steel. The high‐density dislocations and deformation twins in the cryogenically rolled Ce‐SAF2507 lead to the nucleation and growth of martensite. Increases in the martensite volume fraction and nanoscale grain refinement occur at higher deformation levels. Cryogenically rolled deformation results in the overall increase in the Ce‐SAF2507 hardness. A higher hardness increment of austenite–martensite dual‐phase compared to that of ferrite is attributed to the austenite–martensite's higher work hardening ability. Furthermore, the ultimate tensile strength and yield strength increase with the deformation level, but the elongation decrease. Observed microstructural evolutions induced by cryogenic rolling enunciate the superiority of the present method over conventional ones to promote steel' mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2020

25. Effects of twin-twin interactions and deformation bands on the nucleation of recrystallization in AZ31 magnesium alloy

Author

Kai Zhang, Zhutao Shao, and Jun Jiang

Subjects

Magnesium alloys, Recrystallization, Twin-twin interactions, Texture evolution, Cryogenic rolling, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Investigating recrystallization is essential to optimize the microstructure including texture weakening and grain refinement in the rolling of magnesium alloys, thus to improve the mechanical properties of magnesium sheets for industrial applications. This research has gained an in-depth understanding of the effects of deformation bands and twin-twin interactions on recrystallization, which will potentially lead to improved manufacturing processes and mechanical properties of magnesium alloys. To study their individual effects, the recrystallization mechanisms of the room-temperature (RT)-rolled and liquid-nitrogen-temperature (LNT)-rolled samples during the annealing process were analysed with the quasi-in-situ electron backscatter diffraction method, respectively. It is found that recrystallization mainly occurred in deformation bands in the RT-rolled sample, which enhanced the initially formed texture, due to oriented and inhomogeneous grain growth. However, it is of great interest to see that the recrystallized sites were mainly located around the (101¯2)-(011¯2) twin-twin interactions with high kernel average misorientation (KAM) values in the LNT-rolled samples, resulting in rather weaker texture, finer grain size and more homogeneous microstructure, because of the randomized orientations of recrystallized grains and uniform grain growth, while almost no recrystallization was observed around the single tension twin variant.

Published

2020

26. Evolution of twinning and shear bands in magnesium alloys during rolling at room and cryogenic temperature

Author

Kai Zhang, Jing-Hua Zheng, Yan Huang, Catalin Pruncu, and Jun Jiang

Subjects

Twinning, Shear bands, Cryogenic rolling, EBSD, Magnesium alloys, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Twinning and shear bands are two main deformation structures in magnesium alloys at low temperatures, however, the relationship between these two deformation structures is still under debate. To clarify their relationship and behaviours at low temperatures, rolling tests to various thickness reductions at room temperature (RT) and liquid nitrogen temperature (LNT) were conducted for AZ31 magnesium alloys. The evolutions of shear bands and twinning, and their interactions with geometrically necessary dislocation (GND), were observed during the RT- and LNT-rolling process. Abundant shear bands, evolving from {101¯1}-{101¯2} double twins (DTWs), were observed in the RT-rolled samples, while a high quantity of twins, including {101¯2} tension twins (TTWs), twin-twin interactions and twinning sequence, were observed in the LNT-rolled samples. More importantly, a rarely observed twinning sequence behaviour, namely primary TTW-TTW interactions→ secondary TTW-TTW interactions, creating a 45° misorientation peak, was studied. Abundant GNDs accumulated around these twin-twin interactions, twinning sequence, DTWs and shear bands, while the GND density was low around TTWs. This research delivers a systematic investigation into the deformation structures in Mg alloys during the rolling process from RT to cryogenic temperature and provides insights into the newly discovered twinning sequence and twin-twin interactions.

Published

2020

27. Study of Cryogenic Rolling of FCC Metals with Different Stacking Fault Energies

Author

Milene Yumi Maeda, John Jairo Hoyos Quintero, Marcel Tadashi Izumi, Márcio Ferreira Hupalo, and Osvaldo Mitsuyuki Cintho

Subjects

Cryogenic Deformation, Cryogenic Rolling, Stacking Fault Energy, Recovery, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Aluminum, copper and silver samples, all of them face-centered cubic (FCC) metals, were rolled at room and cryogenic temperatures until equivalent strains (ε) were between 3.23 and 4.13. The cryogenic temperature (CT) and room temperature (RT) rolled samples were evaluated by hardness tests and X-ray diffraction (XRD), which indicate influence of stacking fault energy (SFE) on process. Lower SFE metals tend to exhibit dislocation densities significantly increased and as consequence, hardness too. It was also noted that after sometime exposed to RT, the materials rolled at CT present hardness decrease.

Published

2017

28. Improving the Mechanical and Tribological Properties of NiTi Alloys by Combining Cryo-Rolling and Post-Annealing

Author

Wen, Yong, Wang, Yan-Fei, Ran, Hao, Wei, Wei, Zhang, Jun-Ming, and Huang, Chong-Xiang

Published

2022

29. The deformation behavior and strain rate sensitivity of ultra-fine grained CoNiFeCrMn high-entropy alloys at temperatures ranging from 77 K to 573 K.

Author

Han, Zhenhua, Ren, Weining, Yang, Jun, Du, Yuzhou, Wei, Ran, Zhang, Changjun, Chen, Yuanqing, and Zhang, Guojun

Subjects

*STRAIN rate, *ALLOYS, *CRYSTAL grain boundaries, *TENSILE tests, *LIQUID nitrogen

Abstract

In this study, CoCrFeMnNi (Cantor alloy) high-entropy alloy (HEA) with ultra-fine grained (UFG) structure were prepared using cryogenic (liquid nitrogen, 77 K) rolling followed by short time annealing. The deformation behavior and strain rate sensitivity (SRS) of processed material were investigated by tensile test at temperatures ranging from 77 K to 573 K. It was found that the critical twinning stress of the UFG alloy decreased at 77 K, which was attributed to the decrease of stacking fault energy with the temperature. In addition, the UFG alloy exhibited plastic instability and was prominently strengthened with increasing testing temperature from 293 K to 473 K, which was related to obviously grain boundaries relaxation in HEAs. The strain rate jump test revealed that the SRS change of UFG specimen with the decrease of grain size was inversely proportional to the associated strength enhancement, and exhibited a stronger temperature dependence than that of CG specimens especially from 293 K to 473 K. The stronger temperature dependence of SRS of UFG Cantor alloys was due to the increased grain boundary relaxation, which was a thermal activation process and depended on strain rate and temperature. • UFG Cantor alloy was prepared using cryo-rolling and short time annealing. • Tensile and strain rate jump tensile test were conducted from 77 K to 573 K. • UFG alloy exhibited a prominent strengthening from 293 K to 473 K. • Change of SRS in UFG alloy displayed a strong temperature dependence. [ABSTRACT FROM AUTHOR]

Published

2019

30. Altered microstructural evolution and mechanical properties of CoCrFeNiMo0.15 high-entropy alloy by cryogenic rolling.

Author

Wu, Wenqian, Guo, Lin, Guo, Baisong, Liu, Yong, and Song, Min

Subjects

*ALLOYS, *BIOLOGICAL evolution, *TEMPERATURE, *LIQUID nitrogen

Abstract

In this paper, the microstructural characteristics and deformation behaviors of a CoCrFeNiMo 0.15 high-entropy alloy (HEA) with a low volume fraction of σ precipitates during rolling deformation at cryogenic temperature and room temperature were investigated. The stacking fault energy of the HEA was experimentally estimated via measuring the widths of the dissociated dislocations. Deformations at two temperature conditions were both characterized by dislocation activities and extensive nano-twinning, while the rate of these microstructural evolution was accelerated with the aid of the cryogenic temperature. Abundant microbands, nanotwins and stacking faults were detected during deformation under both temperature conditions. Moreover, the hexagonal close-packed structure can only be observed in the cryogenic rolled sample, which was produced via the glide of Shockley partials on every other {111} FCC plane. At the late deformation stage of cryogenic rolling, the nanotwins were markedly distorted or even fractured, and shear bands were also formed. The contributions of different strengthening mechanisms of cryogenic rolling were discussed. [ABSTRACT FROM AUTHOR]

Published

2019

31. Effects of annealing treatment on mechanical properties of 8011 aluminum alloy after cryogenic rolling.

Author

Cui, Junjun, Chen, Liqing, Li, Yanfei, Liu, Jiahua, and Xie, Jiaqi

Subjects

ALUMINUM alloys

Abstract

In order to improve mechanical properties of roll cast 8011 aluminum alloy (AA 8011) by grain strengthening, and expand its application field, the effect of different annealing treating processes on mechanical properties and microstructures of cryogenic rolled AA 8011 was investigated. The roll cast AA 8011 was cryogenic rolled for six passes and then annealed. The annealing treatment was adopted at 100–300 °C for 1 h, and then the annealing treatment was adopted at 220 °C for 10–80 min. The microstructures of AA 8011 under roll cast and cryogenic rolled states were studied by using OM. The grain size was calculated by the Image-pro-plus 5.0. The microstructures of AA 8011 under annealing states were observed by using TEM and energy dispersive spectrum analysis. The results show that the second phase Al8Fe2Si appears in the cryogenic rolled AA 8011 after annealing treatment. When the dislocation moves in the grain, the dislocation plays a pinning role, which is conducive to grain refinement. The optical annealing treatment was treated at 220 °C for 40 min with optimal thermal stability. The ideal grain size is 1 μm, hardness is 65 HV, and tensile strength is 202 MPa. It is about 1.5 times of the roll cast AA 8011. [ABSTRACT FROM AUTHOR]

Published

2019

32. Microstructural evolution and strengthening mechanisms operating during cryogenic rolling of solutionized Al-Cu-Mg alloy.

Author

Zuiko, Ivan S., Mironov, Sergey, and Kaibyshev, Rustam

Subjects

*MICROSTRUCTURE, *CRYOGENICS, *ALUMINUM-copper-magnesium alloys, *LIQUID nitrogen, *GRAIN refinement

Abstract

Abstract In this work, microstructural evolution of a solutionized Al-Cu-Mg alloy during rolling at liquid-nitrogen temperature was studied and concomitant strengthening effect was elucidated. It was found that a prior solid-solution treatment as well as a lowering of deformation temperature to the cryogenic range essentially suppressed dislocation mobility. This promoted an abrupt increase of dislocation density but considerably retarded microstructural processes, particularly texture evolution and development of deformation-induced boundaries, thus suppressing grain refinement. Hence, the strengthening effect of the cryogenic rolling was mainly contributed by the work hardening mechanism. [ABSTRACT FROM AUTHOR]

Published

2019

33. Effects of Co and Si additions and cryogenic rolling on structure and properties of Cu–Cr alloys.

Author

Sun, Xinglong, Jie, Jinchuan, Wang, Pengfei, Qin, Bailiang, Ma, Xiaodong, Wang, Tongmin, and Li, Tingju

Subjects

*CRYOGENICS, *ROLLING (Metalwork), *CHROMIUM copper alloys, *MECHANICAL properties of metals, *INDUSTRIAL applications, *ELECTRIC conductivity

Abstract

Abstract Cu–Cr alloys have been widely used in industrial applications owing to their good combination of mechanical properties and electrical conductivity. However, the comprehensive performance of the alloy needs to be further improved to meet the harsh working environment. Hence, in this study, a new type of Cu–Cr alloy with Co and Si additions together with cryogenic rolling (CR) was designed and investigated. Microstructure analysis confirms that the Cr 15 Co 9 Si 6 and Co 2 Si phases are formed with Co and Si additions into the Cu–Cr alloy. For the more, partial Cr 15 Co 9 Si 6 phase decomposes during heat treatment process, and the Co 2 Si and Cr precipitates are precipitated from matrix during aging process. The improvement of tensile properties of the Cu–1Cr–1Co–0.6Si alloy is mainly attributed to the precipitation strengthening and grain boundary strengthening, and is also benefited from dislocation density strengthening, twin boundary strengthening, and solid solution strengthening. The electrical conductivity of the Cu–1Cr–1Co–0.6Si alloy decreases dramatically mainly due to the increase of impurity scattering caused by surplus Si atoms. CR deformation is helpful for more solute atoms precipitated from the supersaturated solid solution during aging process, and thus the electrical conductivity of the Cu–1Cr–1Co–0.6Si alloy increases with increasing deformation amount. After homogenizing treatment at 900 °C for 2 h, hot rolling by 60% at 900 °C, solution treating at 990 °C for 4 h, cold rolling by 90%, and aging at 440 °C for 1 h, the hardness, yield strength (YS), ultimate tensile strength (UTS), and electrical conductivity of the Cu–1Cr–1Co–0.6Si alloy are 214.6 HV, 663.7 MPa, 745.9 MPa and 41.6%IACS, respectively, which exhibit good mechanical properties with a proper electrical conductivity. These results provide a feasible route for developing high performance Cu–Cr alloys. [ABSTRACT FROM AUTHOR]

Published

2019

34. Unraveling the self-annealing behavior of cryo-rolled Cu-Fe-P alloy sheets: Evidence and implications.

Author

Gupta, Aman, Park, Ki-Seong, Yoo, Tae-Hyeon, Singh, Abhishek Kumar, Lee, Dongwon, Heo, Yoon-Uk, and Choi, Shi-Hoon

Subjects

*RECRYSTALLIZATION (Metallurgy), *ALLOYS, *FINITE element method, *CRYSTAL grain boundaries, *TRANSMISSION electron microscopy

Abstract

• Strain localizations (SLs) were observed preferentially in Copper-type grains in the CR Cu-Fe-P specimens. • Self-annealing at room temperature was observed at the deformed GBs and at SLs in the CR specimens. • TEM and TKD confirms that DSRX and CSRX were responsible for the self-annealing phenomena in the CR specimens. • CPFEM simulation was showing the nearby predictions for average grain size (GS avg) and texture fraction. • Activation of single-slip system in the Copper and S oriented grains was the primary cause of SLs formations. Deformation of Cu-Fe-P alloys at cryogenic temperature (CT) leads to the evolution of a complex microstructure, which includes deformed and recrystallized grains, strain localizations (SLs), and heterogeneous deformation. In this study, specimens of Cu-Fe-P alloy were subjected to cryogenic rolling (CR) at reduction ratios (RR) of 20, 40, 60, and 80%. The microstructural evolution of the CR specimens was characterized using electron back-scattered diffraction (EBSD) and high-resolution transmission electron microscopy (HR-TEM). Severely deformed CR specimens showed SLs, which formed predominantly in the Copper and S oriented grains. After deformation, the CR specimens exhibited self-annealing behavior, which is also referred to as static recrystallization (SRX). Self-annealing at room temperature (RT) caused grain nucleation at the deformed grain boundaries (GBs) and at the SLs. The nucleation of new grains was attributed to both discontinuous SRX (DSRX) and continuous SRX (CSRX) phenomena. The characteristics of DSRX and CSRX grains were analyzed based on transmission Kikuchi diffraction (TKD) and HR-TEM investigations. DSRX grains were surrounded by high-angle GBs, whereas CSRX grains showed sub-boundaries with no dislocations inside. The as-received Cu-Fe-P specimen showed a weak plane-strain texture that intensity increased with an increase in the RR. The CR-80 specimen showed the highest-intensity for plane-strain texture components. SRX at the SLs showed preferential formations of Copper, Brass and S-nucleated grains in the CR-80 specimen. In this study, crystal plasticity finite element method (CPFEM) was used to calculate the stored energy, relative slip activity and texture fractions for the CR specimens. Copper and S oriented grains showed the occurrence of predominant single-slip systems near the severely deformed regions which was the primary cause of SLs formation. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

35. Effect and mechanism of room temperature rolling, cryogenic rolling and heat treatment on mechanical properties and electrical conductivity of Cu-Ni-Si alloy with continuous directional solidification.

Author

Liao, Wanneng, Qiang, Hui, Song, Weifei, Hu, Yangyang, and Zhang, Chenxing

Subjects

*MECHANICAL heat treatment, *ELECTRIC conductivity, *DIRECTIONAL solidification, *COPPER alloys, *ELECTRICAL steel, *ALLOYS

Abstract

Simultaneously improving the mechanical and electrical conductivity of copper alloys has become an important challenge. In this paper, columnar crystal Cu-Ni-Si alloy materials were prepared using continuous unidirectional solidification method, and the effects of room temperature rolling (RTR), cryogenic rolling (CR) and subsequent aging treatment on the microstructure, mechanical and electrical properties of C70250 copper alloy were investigated. The results show that the material has good tensile strength (886 MPa), elongation after break (5.2%) and electrical conductivity (42.4% IACS) when the columnar crystal C70250 copper alloy is cryogenic rolled with 95% depression rate and aged at 450 °C for 1 h. After severe rolling deformation, both RTR and CR C70250 copper alloy produce uniform fibrous structure. Large deformation CR can exhibit higher dislocation density compared with RTR C70250 copper alloy, high lattice distortion results in the transformation of the matrix into an amorphous structure, which has a very strong promotion effect on solute atom diffusion and recrystallization. The precipitation of the fine Ni 2 Si cluster phase with average size of ∼3.2 nm can be accelerated in a shorter aging time compared to RTR, while the uniform fibrous structure after CR can rapidly recrystallize to produce uniform ultra-fine grains with diameter of ∼550 nm. The strength of the cryogenic rolling alloy can significantly increase through precipitation strengthening, fine grain strengthening and dislocation strengthening. This provides a feasible strategy to improve the overall performance of Cu-Ni-Si alloys. • A new process is developed to prepare C70250 copper alloys with high strength and electrical conductivity. • Ultra-fine grains and uniform Ni 2 Si phases are produced by cryogenic rolling with large deformation and peak aging. • Synergies of ultra-fine grains and Ni 2 Si are exploited to achieve a high comprehensive property. [ABSTRACT FROM AUTHOR]

Published

2023

36. The dependence of the strain path on the microstructure, texture and mechanical properties of cryogenic rolled Al-Cu alloy

Author

C Chinthanai Selvan, C Sathiya Narayanan, B Ravisankar, R Narayanasamy, and C Thillaiyadi Valliammai

Subjects

cryogenic rolling, cross rolling, goss to brass ratio, EBSD, TEM, Materials of engineering and construction. Mechanics of materials, TA401-492, Chemical technology, TP1-1185

Abstract

An investigation was conducted on Al-4%Cu alloy sheets to study the role of deformation path on the strength properties, evolution of microstructure and crystallographic texture during cryogenic rolling. Samples were rolled to two distinct thickness strains (50% and 75%) by unidirectional and cross rolling (bidirectional) routes. The strength and hardness properties were found to be more efficient in the cross rolled samples at 50% reduction than their counterparts rolled unidirectionally. Dynamic recovery was observed at higher rolling reductions on cross rolling. Microscopic features observed by EBSD revealed the occurrence of significant grain refinement on the samples rolled with a change of strain path. Also, the alteration of the rolling route resulted in distinct deformation textures and microstructures. TEM studies pointed out the scattered diffusion of the disintegrated dislocation cores and the redistribution of the second phase particles on higher rolling reductions with the change of strain path. Furthermore, the texture results showed a threefold increase on the Goss/Brass ratio which indicated the good fracture toughness behaviour of the cross rolled samples at lower reductions.

Published

2020

37. An effective method to obtain Cu-35Zn alloy with a good combination of strength and ductility through cryogenic rolling.

Author

Wang, Pengfei, Jie, Jinchuan, Liu, Chenbin, Li, Tingju, and Guo, Lijuan

Subjects

*ALPHA brass, *LOW temperature techniques, *DEFORMATIONS (Mechanics), *STRENGTHENING mechanisms in solids, *DUCTILITY, *TRANSMISSION electron microscopy, *X-ray diffraction

Abstract

In the present study, commercial Cu-35Zn α-brass sheets were subjected to cryogenic rolling (CR) to obtain samples with different amounts of deformation in the thickness direction. A self-designed liquid nitrogen cooling system that can simultaneously cool the work rollers and samples was used to ensure an ultra-low temperature condition during the rolling process. The grains, deformation twins, and dislocation density of the samples were studied by optical microscopy, transmission electron microscopy (TEM), and X-ray diffraction (XRD). Uniaxial tensile tests and Vickers hardness measurements were conducted to measure the mechanical properties of the samples. The microstructures and mechanical properties of CR samples were apparently improved compared to the room temperature rolling (RTR) samples with increasing deformation amount. As a typical example, when the deformation amount is 90%, the CR sample possesses ultrafine microstructures and demonstrates extraordinary mechanical properties. The average tensile and yield strengths of a 90% deformation CR sample can be improved to 835.3 MPa and 711.5 MPa, while those of a 90% deformation RTR sample are 718.6 MPa and 481.2 MPa. The average elongation of the CR sample is 2.9%, which is acceptable compared with the RTR sample whose average elongation is 3.1%. The ultrafine microstructures containing ultrafine grains, high density dislocation, and nanometer scale deformation twins in the 90% deformation CR sample may be the main reason for its extraordinary mechanical properties. Therefore, samples with a good combination of strength and ductility were obtained in the present study. This may be a valuable exploration to fabricate Cu-35Zn alloy sheets with excellent microstructures and mechanical properties. [ABSTRACT FROM AUTHOR]

Published

2018

38. Effect of cryogenic deformation on microstructure and mechanical properties of 304 austenitic stainless steel.

Author

Mallick, P., Tewary, N.K., Ghosh, S.K., and Chattopadhyay, P.P.

Subjects

*MARTENSITE, *STAINLESS steel, *MICROSTRUCTURE, *IRON & steel plates, *LOW temperature engineering

Abstract

304 austenitic stainless steel plates have been deformed (10 to 40%) by multi-pass cold rolling incorporating soaking at 0 °C and − 196 °C after each pass with an aim to correlate the microstructure and mechanical properties under cold/cryogenically deformed conditions. Characterisation of phase constituents, microstructure and mechanical properties of such steel specimens has been conducted after processing under different schedules. Rolling of the investigated steel at near cryogenic temperature results into the formation of extended stacking faults, ε-martensite and α′-martensite in contrast to the formation of homogeneous dislocation structure along with α′-martensite in the samples rolled at 0 °C, which can be correlated with temperature dependent stacking fault energy. EBSD phase analysis reveals 46.3% and 69.2% α′-martensite in the austenitic matrix for 10% and 20% deformation at − 196 °C, respectively. Deformation twins are evident in all the samples rolled at 0 °C as well as − 196 °C. 40% cold deformation at 0 °C leads to high strength (1225 MPa) and 13% total elongation, whereas comparatively lower 10–20% deformation at − 196 °C leads to higher level of strength (1306–1589 MPa) with 15–9% elongation due to the formation of the higher volume fraction of strain induced martensite (ε/α′). [ABSTRACT FROM AUTHOR]

Published

2017

39. Cryogenic rolling-enhanced mechanical properties and microstructural evolution of 5052 Al-Mg alloy.

Author

Shi, Jintao, Hou, Longgang, Zuo, Jinrong, Zhuang, Linzhong, and Zhang, Jishan

Subjects

*ALUMINUM-magnesium alloys, *MECHANICAL behavior of materials, *MICROSTRUCTURE, *ROLLING (Metalwork), *LOW temperature engineering, *ANNEALING of metals, *METAL recrystallization kinetics

Abstract

The microstructure/mechanical properties, annealing behavior, and post-annealed microstructure/property relationship of 5052 Al alloy processed by cryogenic rolling (CR) and room-temperature rolling (RTR) have been investigated. It was observed that the CR-processed 5052 Al alloy exhibits a refined crystallite size along with higher-density dislocations than that of the RTR-processed sample. As a result, the tensile strength of the CR-processed alloy increased significantly to 345 MPa because of the enhanced dislocation strengthening and grain-boundary strengthening. The effective suppression of dynamic recovery and accumulation of high-density dislocations caused by CR help accelerate recrystallization kinetics and refine the grain size, gaining higher yield strength for the post-annealed CR 5052 Al alloy compared to that of other commercial 5052-O Al alloys. [ABSTRACT FROM AUTHOR]

Published

2017

40. Effect of cryogenic rolling and annealing on the microstructure evolution and mechanical properties of 304 stainless steel.

Author

Shi, Jin-tao, Hou, Long-gang, Zuo, Jin-rong, Zhuang, Lin-zhong, and Zhang, Ji-shan

Abstract

Metastable 304 austenitic stainless steel was subjected to rolling at cryogenic and room temperatures, followed by annealing at different temperatures from 500 to 950°C. Phase transition during annealing was studied using X-ray diffractometry. Transmission electron microscopy and electron backscattered diffraction were used to characterize the martensite transformation and the distribution of austenite grain size after annealing. The recrystallization mechanism during cryogenic rolling was a reversal of martensite into austenite and austenite growth. Cryogenic rolling followed by annealing refined grains to 4.7 μm compared with 8.7 μm achieved under room-temperature rolling, as shown by the electron backscattered diffraction images. Tensile tests showed significantly improved mechanical properties after cryogenic rolling as the yield strength was enhanced by 47% compared with room-temperature rolling. [ABSTRACT FROM AUTHOR]

Published

2017

41. The comprehensive performance and strengthening mechanism of the columnar crystal Cu-Ni-Si alloy after two large deformation rates of cryogenic rolling-aging.

Author

Liao, Wanneng, Zhang, Chenxing, Qiang, Hui, Song, Weifei, and Hu, Yangyang

Subjects

*COPPER alloys, *PRECIPITATION (Chemistry), *ELECTRIC conductivity, *DEFORMATIONS (Mechanics), *ALLOYS, *PRECIPITATION hardening

Abstract

In order to improve the strength and electrical conductivity of Cu-Ni-Si alloy, the columnar crystalline C70250 copper alloy strip suffer from two deep cryogenic rolling-aging treatments with large deformation, and the relationship between the cryogenic rolling-aging process and microscopic structure, mechanical, conductive properties is studied, and the precipitation behavior is analyzed. The research findings show that the columnar crystalline C70250 copper alloy produced by continuous directional solidification can be directly processed by two cryogenic rolling-aging treatment with large deformation, eliminating the traditional solution treatment process and obtaining a fibrous tissue structures containing high-density dislocations and multi-scale precipitates, the yield strength, tensile strength and electrical conductivity of the alloy reached 879 MPa, 923 MPa and 38.7 % IACS respectively, combination of strength and electrical conductivity is excellent. Two deep cryogenic rolling with large deformation can force the matrix to change to amorphous, favorable to atomic diffusion. Solute atoms are continuously transformed into Ni 2 Si phase and Cu atoms are continuously expelled, forming large-sized pure Ni 2 Si precipitated phase and small-sized NiSi cluster phase containing Cu atoms, which together impede dislocation movement and reinforce alloy. With the uniform precipitation of multi-scale nano-precipitation phases and reduction of grain boundary density, the electrical conductivity along the rolling direction is significantly reduced. • A new process is developed to prepare C70250 copper alloys with high strength and electrical conductivity. • The high diffusion rate channel of elements is driven by two deep cryogenic rolling with large deformation. • Synergies of NiSi and Ni 2 Si are exploited to achieve a high comprehensive property. [ABSTRACT FROM AUTHOR]

Published

2023

42. Thermal stability of deformation twins in cryogenic rolled CP-Ti.

Author

Chen, Cai, Han, Dongsheng, Song, Yutao, Wang, Mingchuan, Li, Yusheng, and Xu, Shun

Subjects

*THERMAL stability, *RECRYSTALLIZATION (Metallurgy), *CRYSTAL texture

Abstract

In this work, abundant types of deformation twins were introduced in CP-Ti by cryogenic rolling. The stability of the twins under the annealing process and their contribution to texture were investigated. The EBSD results revealed that {11 2 ¯ 2} compression twins as the primary twin result in the texture with c-axis near ND and RD, while {10 1 ¯ 2}and {11 2 ¯ 1} tension twins as the primary twin induce the texture with c-axis nearly parallel to TD. Besides, the asymmetric texture intensity of the as-received sheet will be improved by the reorientation induced by deformation twins during the annealing process. Most twins show good thermal stability during the annealing process at 550 °C, however, all twins rapidly disappeared at 650 °C. The {10 1 ¯ 2} twins are the most thermally stable during annealing treatment at 600 °C. After full recrystallization, the texture induced by matrix reorientation maintains, while the texture associated with primary twins recovers. • Abundant deformation twins are activated in cryogenic rolled CP-Ti. Different twin interactions are investigated. • All twins show good thermal stability at 550℃ while they rapidly disappear at 650℃. {10 1 ¯ 2 } twins show the best thermal stability at 600℃. • The texture components induced by primary twins recover while those by secondary twins maintain after annealing. [ABSTRACT FROM AUTHOR]

Published

2023

43. Microstructure and mechanical properties of a basal textured AZ31 magnesium alloy cryorolled at liquid-nitrogen temperature.

Author

Luo, Jinru, Yan, Yaqiong, Zhang, Jishan, and Zhuang, Linzhong

Abstract

A strongly basal textured AZ31 magnesium alloy were cryorolled at liquid-nitrogen temperature at various strains. The microstructure and texture of the rolled sheets have been investigated using electron backscatter diffraction (EBSD) and X-ray diffraction. The microstructural and textural evolutions of the AZ31 magnesium alloy during cryorolling have been discussed. A lot of twins were observed in the rolled sheets. The influence of strain on the twin types and variant selection during cryorolling for the magnesium alloy has been discussed quantitatively based on the orientation data collected using EBSD. The influence of the twins on the microstructural and textural evolutions for the AZ31 magnesium alloy during cryorolling has also been discussed. The mechanical properties of the cryorolled sheets were tested by uniaxial tensile tests at the ambient temperature with a strain rate 10s in the tensile direction respectively along the rolling and transverse directions of the rolled sheets. The relationships between the mechanical properties and microstructure of the cryorolled sheets have been discussed in the present work. The active twinning during rolling at that cryogenic temperature has been found to play an important role in influencing the microstructure, texture, as well as the mechanical properties of the AZ31 magnesium alloy. [ABSTRACT FROM AUTHOR]

Published

2016

44. Unveiling the room-temperature softening phenomenon and texture evolution in room-temperature- and cryogenic-rolled ETP copper.

Author

Gupta, Aman, Yoo, Tae-Hyeon, Kaushik, Lalit, Lee, Jin Woo, Kim, Young-Kil, and Choi, Shi-Hoon

Subjects

*CRYSTAL texture, *RECRYSTALLIZATION (Metallurgy), *HARDNESS, *MICROSTRUCTURE

Abstract

• Microstructural and crystallographic texture evolution in the RTR and CR ETP copper were investigated systematically. • CR-processed specimens showed higher hardening and softening rate than RTR-processed specimens. • SRX at room temperature was the main softening phenomena observed in the severely deformed specimens. • DSRX and CSRX were responsible for the nucleation of small grains at room temperature in the severely deformed RTR and CR-processed specimens. • Time-dependent decay in the hardness values for the RTR and CR specimens, attributed to the SRV and SRX. The present study addresses the evolution of microstructural and crystallographic texture in room-temperature-rolled (RTR) and cryogenic-rolled (CR) electrolytic tough-pitch (ETP) copper. Copper specimens were subjected to 20, 40, 60, and 80% reductions via RTR and CR processing. The microstructure evolution of the severely deformed RTR and CR specimens revealed deformed and recrystallized grains. Static recrystallization (SRX) at room temperature (RT) was observed in the severely deformed RTR and CR specimens. Both discontinuous SRX (DSRX) and continuous SRX (CSRX) were responsible for the nucleation of small grains at RT. Particle-stimulated nucleation (PSN) was also responsible for small-grain formations around the Cu 2 O particles. The initial ETP copper specimen showed a weak texture whose intensity increased after the RTR and CR deformation. The texture intensity of the severely deformed specimens was affected by both deformation and the SRX phenomena. The CR specimens showed texture that was stronger than that of the RTR specimens up to the point of an intermediate reduction (60%), whereas at higher deformation (80%), the RTR specimens showed stronger texture intensity compared with that of the CR specimens. The texture weakening in the CR80 specimen was due to the formation of strain localizations (SLs) and to the nucleation at SLs. Large amounts of stored energy and SL formation in severely deformed CR specimens led to a different recrystallization texture compared with that of RTR specimens. A Cube component was dominant in the RTR80, whereas Goss, Copper and S components were observed in the CR80 specimen for SRX grains. The CR specimen showed a relatively high hardness value compared with the RTR specimen. Time-dependent decay in the hardness values for both the RTR and the CR specimens were attributed to room-temperature recovery (SRV) and recrystallization (SRX). [ABSTRACT FROM AUTHOR]

Published

2022

45. Texture comparison between room temperature rolled and cryogenically rolled pure copper.

Author

Lapeire, L., Sidor, J., Verleysen, P., Verbeken, K., De Graeve, I., Terryn, H., and Kestens, L.A.I.

Subjects

*TEMPERATURE effect, *CRYSTAL texture, *COPPER, *MECHANICAL behavior of materials, *ROLLING (Metalwork), *MICROSTRUCTURE

Abstract

Nowadays, due to their potential for superior mechanical properties, a considerable interest in bulk ultrafine grained metals exists. One of the possible formation methods for this ultrafine grained material is cryogenic rolling. In this work, the influence of cryogenic rolling on the texture and the microstructure of pure copper is investigated by electron backscatter diffraction (EBSD), both in the deformed and the annealed state. This is done by comparing cryogenically rolled copper with room temperature rolled copper, rolled to the same thickness reductions. A texture difference between the room temperature rolled and cryogenically rolled copper is seen in the deformed state, although the largest texture difference is observed after annealing. These texture differences are mainly attributed to the presence of shear bands in the microstructure of the cryogenically rolled copper. In order to obtain a better understanding of the influence of shear bands on the texture evolution, the grain orientations inside the shear bands are analyzed both experimentally and numerically by applying the visco plastic self-consistent (VPSC) model. A number of shear band specific orientations, which are not observed in the conventional rolling texture of fcc materials, could be identified both in the experimental observations and in the simulations. [ABSTRACT FROM AUTHOR]

Published

2015

46. Significant Increase in Tensile Strength and Hardness in 2024 Aluminum Alloy by Cryogenic Rolling.

Author

Shahsavari, A., Karimzadeh, F., Rezaeian, A., and Heydari, H.

Abstract

Because of high strength to weight ratio and good resistance to corrosion, 2024Al alloy has attracted a high attention in the aerospace and shipbuilding industries. Most of the research activities to grain refinement lead to decrease in ductility. In this article, the researchers have developed a novel approach in achieving both high strength and good ductility in 2024 Al alloy. The approach involves Solid solution-treating, rolling at cryogenic temperature (containing a high density of dislocations) and artificial aging treatment to generate bimodal structure and nanosized S’ precipitates (Al 2 CuMg). Under optimal processing conditions, tensile strength (653 MPa), ductility (11% tensile elongation) and hardness (170 HV) were obtained. [ABSTRACT FROM AUTHOR]

Published

2015

47. Natural aging behavior of AA7050 Al alloy after cryogenic rolling.

Author

Magalhães, Danielle Cristina Camilo, Hupalo, Marcio Ferreira, and Cintho, Osvaldo Mitsuyuki

Subjects

*ALUMINUM alloys, *DETERIORATION of materials, *CRYOGENICS, *ROLLING (Metalwork), *SOLUTION (Chemistry), *SCANNING electron microscopy

Abstract

Abstract: The effect of cryogenic rolling on the natural aging behavior of a commercial AA7050 aluminum alloy was investigated. Solutionized 10mm-thick sheets were cryo-rolled to true strains of 0.5, 0.9, 1.1 and 1.4 followed by natural aging (T4 temper) at times ranging from 10 to 1000h. Light optical microscopy (LOM), scanning electron microscopy (SEM) and differential scanning calorimetry (DSC) were used to follow the microstructural changes upon processing. Mechanical properties were assessed by Vickers hardness measurements and tensile tests. During natural aging the hardness values increased from 100 HV to approximately 145 HV after 100h. The strength of the undeformed specimen, naturally aged for 100h, was much higher than that in the as-quenched state. The yield strength (YS) increased from 130 to 375MPa (188% increase) and the increment of ultimate tensile strength (UTS) was almost 47% (321–470MPa). A superior combination of mechanical properties was achieved for the specimen cryo-rolled to a true strain of 0.5 followed by natural aging for 1000h (YS=611MPa and 15% total elongation). These results suggest that a combination of cryogenic rolling with natural aging is a useful method for achieving optimized mechanical properties for the AA7050 alloy. [Copyright &y& Elsevier]

Published

2014

48. On the Plasticity of Interstitial-Free Steel Subjected to Cryogenic Rolling Followed by Annealing.

Author

Anand, Gautam, Sinha, Arijit, and Chattopadhyay, ParthaProtim

Subjects

HEAT treatment of steel, ANNEALING of metals, LOW temperature engineering, MICROSTRUCTURE, TENSILE strength

Abstract

Microstructure and tensile deformation behavior of interstitial-free (IF) steel subjected to near-cryogenic (−150°C to −100°C) rolling followed by annealing have been investigated. Twining has been found to be the dominant mode of deformation during rolling. Both the rolled and annealed sample exhibited limited work hardening due to high matrix resistance. In the rolled sample cleavage, nuclei acted as potential fracture initiation site. Annealing has resulted in effective blunting of cleavage nuclei giving rise to large total elongation due to prolonged damage growth process. [ABSTRACT FROM PUBLISHER]

Published

2013

49. Effects of microstructure, texture evolution and strengthening mechanisms on mechanical properties of 3003 aluminum alloy during cryogenic rolling.

Author

Yang, Q.Y., Zhou, Y.L., Tan, Y.B., Xiang, S., Ma, M., and Zhao, F.

Subjects

*ALUMINUM alloys, *TENSILE strength, *MICROSTRUCTURE, *DISLOCATION density, *ALLOY texture, *TRANSMISSION electron microscopy

Abstract

The effects of microstructure, texture evolution and strengthening mechanisms on mechanical properties of 3003 aluminum alloy during cryogenic rolling (CR) and room temperature rolling (RTR) processing were investigated by electron backscatter diffraction, transmission electron microscopy and X-ray diffraction. The results show that the CR processing can significantly decrease the size of sub-grains and second-phase particles, and increase the dislocation density of the 3003 aluminum alloy. During the CR and RTR processing, the initial Cube and R-Cube textures are gradually rotated into the β -fiber texture. The CR processing can obviously delay the texture evolution from initial Cube texture to β -fiber texture during rolling. A significant enhancement in the yield strength, ultimate tensile strength and elongation of the 3003 aluminum alloy after the CR processing is obtained comparing with the RTR processing. This can be explained by the contribution of dislocation strengthening and grain refinement strengthening. • Microstructure, texture evolution and strengthening mechanisms in 3003 aluminum alloy during CR and RTR were investigated. • CR processing can refine the size of sub-grains grains and increase the dislocation density. • CR processing can delay the texture evolution from initial cube texture to β-fiber texture. • CR processing can enhanced the YS, UTS and EL of CR samples compared with the RTR samples. [ABSTRACT FROM AUTHOR]

Published

2021

50. Mechanical properties of ultrafine grained 5052 Al alloy produced by accumulative roll-bonding and cryogenic rolling.

Author

Song, H., Kim, Y., and Nam, W.

Abstract

Mechanical properties in conjunction with microstructural evolution during annealing of 5052 Al alloy deformed at cryogenic temperature were investigated and compared with those yielded by the ARB process. ARB was conducted up to 7 cycles under conditions where the reduction in thickness per cycle was 50% and the rolling temperature was 300°C. To investigate the effect of annealing temperature, cryo-rolled sheets with 85% reduction were annealed in a temperature range of 150≈300°C for one hour. Strengths of 5052 Al alloy ARB processed at 300°C increased with increasing number of cycles and decreased rapidly after 6 or 7 cycles. This indicated that, during the ARB process, work hardening proceeded at low strains and subdivision of grains and dynamic recovery occurred at high strains. Tensile strength and yield strength of cryo-rolled 5052 Al alloy decreased as the annealing temperature increased. The volume fraction of recrystallized and coarsened grains appeared to have the most significant influence on strength and ductility in sheets annealed at 250°C. [ABSTRACT FROM AUTHOR]

Published

2006