How to cite this paper
Abishkenov, M., Ashkeyev, Z., Nogaev, K., Bestembek, Y., Azimbayev, K & Tavshanov, I. (2023). On the possibility of implementing a simple shear in the cross-section of metal materials during caliber rolling.Engineering Solid Mechanics, 11(3), 253-262.
Refrences
Abishkenov, M., Ashkeyev, Z., & Nogaev, K. (2022). Investigation of the shape rolling process implementing intense shear strains in special diamond passes. Materialia, 26, 101573.
Afifeh, M., Hosseinipour, S.J., & Jamaati, R. (2019). Nanostructured copper matrix composite with extraordinary strength and high electrical conductivity produced by asymmetric cryorolling. Materials Science and Engineering: A, 763, 138146.
Ashkeyev Zh. A., Andreyachshenko VA, & Bukanov Zh. U. (2020). Research of the asymmetric rolling of workpieces. PNRPU Mechanics Bulletin, 4, 27–35.
Ashkeyev, Z., Abishkenov, M., & Nogaev, K. (2023). Stress state of workpieces during upsetting with additional shear. Engineering Solid Mechanics, 11(1), 41-46.
Ashkeyev, Z., Abishkenov, M., Mashekov, S., & Kawałek, A. (2021). Stress state and power parameters during pulling workpieces through a special die with an inclined working surface. Engineering Solid Mechanics, 9(2), 161–176.
Ashkeyev, Z., Abishkenov, M., Mashekov, S., Kawałek, A., & Nogaev, K. (2021). Study of the deformation state during the pulling of the workpiece in a special die. Metalurgija, 60(3-4), 335–338.
Bagherpour, E., Pardis, N., Reihanian, M., & Ebrahimi, R. (2019). An overview on severe plastic deformation: research status, techniques classification, microstructure evolution, and applications. The International Journal of Advanced Manufacturing Technology, 100, 1647–1694.
Beausir, B., Scharnweber, J., Jaschinski, J., Brokmeier, H.-G., Oertel, C.-G., & Skrotzki, W. (2010). Plastic anisotropy of ultrafine grained aluminum alloys produced by accumulative roll bonding. Materials Science and Engineering: A, 527(13-14), 3271–3278.
Beygelzimer, Y., Varyukhin, V., Synkov, S., & Orlov, D. (2009). Useful properties of twist extrusion. Materials Science and Engineering: A, 503(1-2), 14–17.
Bridgman, P. W. (1935). Effects of High Shearing Stress Combined with High Hydrostatic Pressure. Physical Review, 48(10), 825–847.
Camilo Magalhães, D.C., Cintho, O.M., Rubert, J.B., Sordi, V.L., & Kliauga, A.M. (2020). The role of shear strain during Accumulative Roll-Bonding of multilayered composite sheets: Pattern formation, microstructure and texture evolution. Materials Science and Engineering: A, 796, 140055.
Cao, Y., Ni, S., Liao, X., Song, M., & Zhu, Y. (2018). Structural evolutions of metallic materials processed by severe plastic deformation. Materials Science and Engineering: R: Reports, 133, 1–59.
Cheng, Y.Q., Chen, Z.H., & Xia, W.J. (2007). Drawability of AZ31 magnesium alloy sheet produced by equal channel angular rolling at room temperature. Materials Characterization, 58(7), 617–622.
Cui, Q., & Ohori, K. (2000). Grain refinement of high purity aluminum by asymmetric rolling. Materials Science and Technology, 16(10), 1095–1101.
Derakhshan, J.F., Parsa, M.H., & Jafarian, H.R. (2019). Microstructure and mechanical properties variations of pure aluminum subjected to one pass of ECAP-Conform process. Materials Science and Engineering: A, 747, 120–129.
Edalati, K., Matsuda, J., Yanagida, A., Akiba, E., & Horita, Z. (2014). Activation of TiFe for hydrogen storage by plastic deformation using groove rolling and high-pressure torsion: Similarities and differences. International Journal of Hydrogen Energy, 39(28), 15589–15594.
Huang, J.Y., Zhu, Y.T., Jiang, H., & Lowe, T.C. (2001). Microstructures and dislocation configurations in nanostructured Cu processed by repetitive corrugation and straightening. Acta Materialia, 49(9), 1497-1505.
Huang, Y., & Prangnell, P.B. (2007). Continuous frictional angular extrusion and its application in the production of ultrafine-grained sheet metals. Scripta Materialia, 56(5), 333-336.
Jamaati, R., & Toroghinejad, M. R. (2014). Effect of stacking fault energy on deformation texture development of nanostructured materials produced by the ARB process. Materials Science and Engineering: A, 598, 263–276.
Langdon, T.G. (2010). Processing by severe plastic deformation: historical developments and current impact. Materials Science Forum, 667–669, 9–14.
Lee, HH, Yoon, JI, & Kim, HS (2018). Single-roll angular-rolling: A new continuous severe plastic deformation process for metal sheets. Scripta Materialia, 146, 204-207.
Lee, J.-C., Seok, H.-K., Han, J.-H., Chung, & Y.-H. (2001). Controlling the textures of the metal strips via the continuous confined strip shearing(C2S2) process. Materials Research Bulletin, 36(5-6), 997–1004.
Lee, SH, Saito, Y., Sakai, T., & Utsunomiya, H. (2002). Microstructures and mechanical properties of 6061 aluminum alloy processed by accumulative roll-bonding. Materials Science and Engineering: A, 325(1-2), 228–235.
Li, J., Gao, H., Kong, C., Tandon, P., Pesin, A., & Yu, H. (2021). Mechanical properties and thermal stability of gradient structured Zr via cyclic skin-pass cryorolling. Materials Letters, 302, 130406.
Mashekov, S., Nurtazaev, E., Mashekova, A., & Abishkenov, M. (2021). Extruding aluminum bars on a new structure radial shear mill. Metalurgija, 60(3-4). 427–430.
Mirsepasi, A., Nili-Ahmadabadi, M., Habibi-Parsa, M., Ghasemi-Nanesa, H., & Dizaji, A.F. (2012). Microstructure and mechanical behavior of martensitic steel severely deformed by the novel technique of repetitive corrugation and straightening by rolling. Materials Science and Engineering: A, 551, 32–39.
Naizabekov, A.B., & Ashkeev, Z.A. (1995). Analysis of forming and closing of an internal axial defect of a billet. Steel in Translation, 25(2), 51–54.
Naizabekov, A.B., & Ashkeev, Zh. A. (1998). Billet state and quality during deformation in special appliance. Steel in Translation, 28(8), 52–55.
Naizabekov, A.B., Ashkeev, Zh. A., & Lezhnev, S.N. (1999). Role of shear strains in closing internal defects. Steel in Translation, 29(10), 64–66.
Naizabekov, A.B., Bykhin, MB, Nogaev, KA, & Bykhin, BB (2010). Study of the process of realization of high-rate plastic deformation in lengthwise rolling. METAL 2010 - 19th International Conference on Metallurgy and Materials, 192–202.
Najzabekov, A.B., Nogaev, KA, & Ashkeev, Zh. A. (2004). Deformation of billets with plane block heads with imposing the additional shears of deformation. Izvestiya Ferrous Metallurgy, 6, 24–26.
Peng, J., Zhang, Z., Yang, P., Li, Y., Guo, P., Zhou, W., & Wu, Y. (2018). The effect of continuous confined strip shearing deformation on the mechanical properties of AZ31 magnesium alloys. Materials Science and Engineering: A, 743, 397–403.
Rahimi Goloujeh, M., & Soltanpour, M. (2021). Simple shear forging as a method for severe plastic deformation. International Journal of Lightweight Materials and Manufacture, 4(2), 165–178.
Rees, DWA (2006). Basic Engineering Plasticity: An Introduction to Engineering and Manufacturing Applications. Oxford: Butterworth-Heinemann.
Saito, Y., Utsunomiya, H., Suzuki, H., & Sakai, T. (2000). Improvement in the r-value of aluminum strip by a continuous shear deformation process. Scripta Materialia, 42(12), 1139-1144.
Saito, Y., Utsunomiya, H., Tsuji, N., & Sakai, T. (1999). Novel ultra-high straining process for bulk materials—development of the accumulative roll-bonding (ARB) process. Acta Materialia, 47(2), 579-583.
Song, D., Zhou, T., Tu, J., Shi, L., Song, B., Hu, L., Yang, M., Chen, Q., & Lu, L. (2018). Improved stretch formability of AZ31 sheet via texture control by introducing a continuous bending channel into equal channel angular rolling. Journal of Materials Processing Technology, 259, 380–386.
Thiel, C., Voss, J., Martin, RJ, & Neff, P. (2018). Shear, pure and simple. International Journal of Non-Linear Mechanics, 112, 57–72.
Utsunomiya, H., Hatsuda, K., Sakai, T., & Saito, Y. (2004). Continuous grain refinement of aluminum strip by conshearing. Materials Science and Engineering: A, 372(1-2), 199–206.
Valiev, RZ, Islamgaliev, RK, & Alexandrov, IV (2000). Bulk nanostructured materials from severe plastic deformation. Progress in Materials Science, 45(2), 103–189.
Verma, R., Jayaganthan, R., Nath, SK, & Srinivasan, A. (2020). Effect of multiaxial forging followed by hot rolling on non-basal planes and its influence on tensile and fracture toughness behavior of Mg–4Zn–4Gd alloy. Materials Science and Engineering: A, 774, 138890.
Xu, C., Schroeder, S., Berbon, PB, & Langdon, T. G. (2010). Principles of ECAP–Conform as a continuous process for achieving grain refinement: Application to an aluminum alloy. Acta Materialia, 58(4), 1379-1386.
Xu, Q., Li, Y., Ding, H., M, A., Jiang, J., Chen, G., & Chen, Y. (2021). Microstructure and mechanical properties of SiCp/AZ91 composites processed by a combined processing method of equal channel angular pressing and rolling. Journal of Materials Research and Technology, 15, 5244–5251.
Yu, H., Wang, L., Chai, L., Li, J., Lu, C., Godbole, A., Wang, H., & Kong, C. (2019). High thermal stability and excellent mechanical properties of ultrafine-grained high-purity copper sheets subjected to asymmetric cryorolling. Materials Characterization, 153, 34–45.
Zherebtsov, SV, Dyakonov, GS, Salem, AA, Sokolenko, VI, Salishchev, GA, & Semiatin, SL (2013). Formation of nanostructures in commercial-purity titanium via cryorolling. Acta Materialia, 61(4), 1167-1178.
Zhu, XD, Xu, XJ, Zhao, ZH, Chong, K., Cheng, C., & Cheng, XN (2010). The Novel Continuous Large Deformation Technology Integrating Conventional Rolling with Equal-Channel Angular Technology. Materials Science Forum, 667-669, 127-132.
Afifeh, M., Hosseinipour, S.J., & Jamaati, R. (2019). Nanostructured copper matrix composite with extraordinary strength and high electrical conductivity produced by asymmetric cryorolling. Materials Science and Engineering: A, 763, 138146.
Ashkeyev Zh. A., Andreyachshenko VA, & Bukanov Zh. U. (2020). Research of the asymmetric rolling of workpieces. PNRPU Mechanics Bulletin, 4, 27–35.
Ashkeyev, Z., Abishkenov, M., & Nogaev, K. (2023). Stress state of workpieces during upsetting with additional shear. Engineering Solid Mechanics, 11(1), 41-46.
Ashkeyev, Z., Abishkenov, M., Mashekov, S., & Kawałek, A. (2021). Stress state and power parameters during pulling workpieces through a special die with an inclined working surface. Engineering Solid Mechanics, 9(2), 161–176.
Ashkeyev, Z., Abishkenov, M., Mashekov, S., Kawałek, A., & Nogaev, K. (2021). Study of the deformation state during the pulling of the workpiece in a special die. Metalurgija, 60(3-4), 335–338.
Bagherpour, E., Pardis, N., Reihanian, M., & Ebrahimi, R. (2019). An overview on severe plastic deformation: research status, techniques classification, microstructure evolution, and applications. The International Journal of Advanced Manufacturing Technology, 100, 1647–1694.
Beausir, B., Scharnweber, J., Jaschinski, J., Brokmeier, H.-G., Oertel, C.-G., & Skrotzki, W. (2010). Plastic anisotropy of ultrafine grained aluminum alloys produced by accumulative roll bonding. Materials Science and Engineering: A, 527(13-14), 3271–3278.
Beygelzimer, Y., Varyukhin, V., Synkov, S., & Orlov, D. (2009). Useful properties of twist extrusion. Materials Science and Engineering: A, 503(1-2), 14–17.
Bridgman, P. W. (1935). Effects of High Shearing Stress Combined with High Hydrostatic Pressure. Physical Review, 48(10), 825–847.
Camilo Magalhães, D.C., Cintho, O.M., Rubert, J.B., Sordi, V.L., & Kliauga, A.M. (2020). The role of shear strain during Accumulative Roll-Bonding of multilayered composite sheets: Pattern formation, microstructure and texture evolution. Materials Science and Engineering: A, 796, 140055.
Cao, Y., Ni, S., Liao, X., Song, M., & Zhu, Y. (2018). Structural evolutions of metallic materials processed by severe plastic deformation. Materials Science and Engineering: R: Reports, 133, 1–59.
Cheng, Y.Q., Chen, Z.H., & Xia, W.J. (2007). Drawability of AZ31 magnesium alloy sheet produced by equal channel angular rolling at room temperature. Materials Characterization, 58(7), 617–622.
Cui, Q., & Ohori, K. (2000). Grain refinement of high purity aluminum by asymmetric rolling. Materials Science and Technology, 16(10), 1095–1101.
Derakhshan, J.F., Parsa, M.H., & Jafarian, H.R. (2019). Microstructure and mechanical properties variations of pure aluminum subjected to one pass of ECAP-Conform process. Materials Science and Engineering: A, 747, 120–129.
Edalati, K., Matsuda, J., Yanagida, A., Akiba, E., & Horita, Z. (2014). Activation of TiFe for hydrogen storage by plastic deformation using groove rolling and high-pressure torsion: Similarities and differences. International Journal of Hydrogen Energy, 39(28), 15589–15594.
Huang, J.Y., Zhu, Y.T., Jiang, H., & Lowe, T.C. (2001). Microstructures and dislocation configurations in nanostructured Cu processed by repetitive corrugation and straightening. Acta Materialia, 49(9), 1497-1505.
Huang, Y., & Prangnell, P.B. (2007). Continuous frictional angular extrusion and its application in the production of ultrafine-grained sheet metals. Scripta Materialia, 56(5), 333-336.
Jamaati, R., & Toroghinejad, M. R. (2014). Effect of stacking fault energy on deformation texture development of nanostructured materials produced by the ARB process. Materials Science and Engineering: A, 598, 263–276.
Langdon, T.G. (2010). Processing by severe plastic deformation: historical developments and current impact. Materials Science Forum, 667–669, 9–14.
Lee, HH, Yoon, JI, & Kim, HS (2018). Single-roll angular-rolling: A new continuous severe plastic deformation process for metal sheets. Scripta Materialia, 146, 204-207.
Lee, J.-C., Seok, H.-K., Han, J.-H., Chung, & Y.-H. (2001). Controlling the textures of the metal strips via the continuous confined strip shearing(C2S2) process. Materials Research Bulletin, 36(5-6), 997–1004.
Lee, SH, Saito, Y., Sakai, T., & Utsunomiya, H. (2002). Microstructures and mechanical properties of 6061 aluminum alloy processed by accumulative roll-bonding. Materials Science and Engineering: A, 325(1-2), 228–235.
Li, J., Gao, H., Kong, C., Tandon, P., Pesin, A., & Yu, H. (2021). Mechanical properties and thermal stability of gradient structured Zr via cyclic skin-pass cryorolling. Materials Letters, 302, 130406.
Mashekov, S., Nurtazaev, E., Mashekova, A., & Abishkenov, M. (2021). Extruding aluminum bars on a new structure radial shear mill. Metalurgija, 60(3-4). 427–430.
Mirsepasi, A., Nili-Ahmadabadi, M., Habibi-Parsa, M., Ghasemi-Nanesa, H., & Dizaji, A.F. (2012). Microstructure and mechanical behavior of martensitic steel severely deformed by the novel technique of repetitive corrugation and straightening by rolling. Materials Science and Engineering: A, 551, 32–39.
Naizabekov, A.B., & Ashkeev, Z.A. (1995). Analysis of forming and closing of an internal axial defect of a billet. Steel in Translation, 25(2), 51–54.
Naizabekov, A.B., & Ashkeev, Zh. A. (1998). Billet state and quality during deformation in special appliance. Steel in Translation, 28(8), 52–55.
Naizabekov, A.B., Ashkeev, Zh. A., & Lezhnev, S.N. (1999). Role of shear strains in closing internal defects. Steel in Translation, 29(10), 64–66.
Naizabekov, A.B., Bykhin, MB, Nogaev, KA, & Bykhin, BB (2010). Study of the process of realization of high-rate plastic deformation in lengthwise rolling. METAL 2010 - 19th International Conference on Metallurgy and Materials, 192–202.
Najzabekov, A.B., Nogaev, KA, & Ashkeev, Zh. A. (2004). Deformation of billets with plane block heads with imposing the additional shears of deformation. Izvestiya Ferrous Metallurgy, 6, 24–26.
Peng, J., Zhang, Z., Yang, P., Li, Y., Guo, P., Zhou, W., & Wu, Y. (2018). The effect of continuous confined strip shearing deformation on the mechanical properties of AZ31 magnesium alloys. Materials Science and Engineering: A, 743, 397–403.
Rahimi Goloujeh, M., & Soltanpour, M. (2021). Simple shear forging as a method for severe plastic deformation. International Journal of Lightweight Materials and Manufacture, 4(2), 165–178.
Rees, DWA (2006). Basic Engineering Plasticity: An Introduction to Engineering and Manufacturing Applications. Oxford: Butterworth-Heinemann.
Saito, Y., Utsunomiya, H., Suzuki, H., & Sakai, T. (2000). Improvement in the r-value of aluminum strip by a continuous shear deformation process. Scripta Materialia, 42(12), 1139-1144.
Saito, Y., Utsunomiya, H., Tsuji, N., & Sakai, T. (1999). Novel ultra-high straining process for bulk materials—development of the accumulative roll-bonding (ARB) process. Acta Materialia, 47(2), 579-583.
Song, D., Zhou, T., Tu, J., Shi, L., Song, B., Hu, L., Yang, M., Chen, Q., & Lu, L. (2018). Improved stretch formability of AZ31 sheet via texture control by introducing a continuous bending channel into equal channel angular rolling. Journal of Materials Processing Technology, 259, 380–386.
Thiel, C., Voss, J., Martin, RJ, & Neff, P. (2018). Shear, pure and simple. International Journal of Non-Linear Mechanics, 112, 57–72.
Utsunomiya, H., Hatsuda, K., Sakai, T., & Saito, Y. (2004). Continuous grain refinement of aluminum strip by conshearing. Materials Science and Engineering: A, 372(1-2), 199–206.
Valiev, RZ, Islamgaliev, RK, & Alexandrov, IV (2000). Bulk nanostructured materials from severe plastic deformation. Progress in Materials Science, 45(2), 103–189.
Verma, R., Jayaganthan, R., Nath, SK, & Srinivasan, A. (2020). Effect of multiaxial forging followed by hot rolling on non-basal planes and its influence on tensile and fracture toughness behavior of Mg–4Zn–4Gd alloy. Materials Science and Engineering: A, 774, 138890.
Xu, C., Schroeder, S., Berbon, PB, & Langdon, T. G. (2010). Principles of ECAP–Conform as a continuous process for achieving grain refinement: Application to an aluminum alloy. Acta Materialia, 58(4), 1379-1386.
Xu, Q., Li, Y., Ding, H., M, A., Jiang, J., Chen, G., & Chen, Y. (2021). Microstructure and mechanical properties of SiCp/AZ91 composites processed by a combined processing method of equal channel angular pressing and rolling. Journal of Materials Research and Technology, 15, 5244–5251.
Yu, H., Wang, L., Chai, L., Li, J., Lu, C., Godbole, A., Wang, H., & Kong, C. (2019). High thermal stability and excellent mechanical properties of ultrafine-grained high-purity copper sheets subjected to asymmetric cryorolling. Materials Characterization, 153, 34–45.
Zherebtsov, SV, Dyakonov, GS, Salem, AA, Sokolenko, VI, Salishchev, GA, & Semiatin, SL (2013). Formation of nanostructures in commercial-purity titanium via cryorolling. Acta Materialia, 61(4), 1167-1178.
Zhu, XD, Xu, XJ, Zhao, ZH, Chong, K., Cheng, C., & Cheng, XN (2010). The Novel Continuous Large Deformation Technology Integrating Conventional Rolling with Equal-Channel Angular Technology. Materials Science Forum, 667-669, 127-132.