[1] 冯小军. 快速制造技术[M]. 北京: 机械工业出版社, 2004.
Feng Xiaojun. Rapid manufacturing technology[M]. Beijing: China Machine Press, 2004.
[2] Meng X C, Huang Y X, Cao J, et al. Recent progress on control strategies for inherent issues in friction stir welding[J]. Progress in Materials Science, 2020, 115: 100706.
[3] Kandasamy K. Solid state joining using additive friction stir processing: US10105790B2[P]. 2018.
[4] Palanivel S, Sidhar H, Mishra R S. Friction stir additive manufacturing: Route to high structural performance[J]. Jom, 2015, 67(3): 616 ? 621.
[5] Troysi F D, Brito P P. Development and characterization of an iron aluminide coating on mild steel substrate obtained by friction surfacing and heat treatment[J]. The International Journal of Advanced Manufacturing Technology, 2020, 111(9-10): 1 ? 8.
[6] Rathee S, Srivastava M, Maheshwari S, et al. Friction based additive manufacturing technologies: principles for building in solid state, benefits, limitations, and applications[M]. Florida: CRC Press, 2018.
[7] Yu H Z, Mishra R S. Additive friction stir deposition: a deformation processing route to metal additive manufacturing[J]. Materials Research Letters, 2021, 9(2): 71 ? 83.
[8] 王红军. 增材制造的研究现状与发展趋势[J]. 北京信息科技大学学报(自然科学版), 2014, 29(3): 20 ? 24
Wang Hongjun. Research status and development tendency of additive manufacturing[J]. Journal of Beijing Information Science and Technology University, 2014, 29(3): 20 ? 24
[9] 朱雪岩. 基于电磁感应加热技术的高温金属3D打印设备研制与工艺研究[D]. 宁波: 宁波大学, 2018.
Zhu Xueyan. Development of equipment and process of high temperature metal 3D printing based on electromagnetic induction heating technology[D]. Ningbo: Ningbo University, 2018.
[10] Zhao C, Parab N D, Li X, et al. Critical instability at moving keyhole tip generates porosity in laser melting[J]. Science, 2020, 370(6520): 1080 ? 1086.
[11] White D. Object consolidation employing friction joining: US 6457629[P]. 2002.
[12] Thomas W M, Norris I M, Staines D. G. et al. Friction stir welding-process developments and variant techniques[R]. The SME Summit. Oconomowoc, USA, 2005.
[13] Lequeu R M, Ehrstrom J. C, Bron F, et al. High-Performance friction stir welded structures using advanced alloys[C]//Aeromat Conference. WA, Seattle, 2006: 85 − 91.
[14] Threadgill P, Russell M. Friction welding of near net shape preforms in Ti-6Al-4V[C]//Proceedings of the 11th World Conference on Titanium. Japan, 2007: 3 − 7.
[15] Dilip J, Rafi H K, Ram G. A new additive manufacturing process based on friction deposition[J]. Transactions of the Indian Institute of Metals, 2011, 64(1-2): 27 ? 30.
[16] Baumann J A. Production of energy efficient preform structures (PEEPS)[R]. The Boeing Company, Chiago, USA, 2012.
[17] Kandasamy K. Solid state joining using additive friction stir processing: US10105790[P]. 2018.
[18] Griffiths R J, Perry M E J, Sietins J M, et al. A Perspective on solid-state additive manufacturing of aluminum matrix composites using meld[J]. Journal of Materials Engineering and Performance, 2018, 28(2): 648 ? 656.
[19] 柯黎明, 邢丽, 刘鸽平. 搅拌摩擦焊工艺及其应用[J]. 焊接技术, 2000(2): 7 ? 8
Ke Liming, Xing Li, Liu Geping. Friction stir welding process and its applications[J]. Welding Technology, 2000(2): 7 ? 8
[20] Su J Q, Nelson T W, Mishra R, et al. Microstructural investigation of friction stir welded 7050-T651 aluminium[J]. Acta Materialia, 2003, 51(3): 713 ? 729.
[21] Barenj R V. Influence of heat input conditions on microstructure evolution and mechanical properties of friction stir welded pure copper joints[J]. Transactions of the Indian Institute of Metals, 2016, 69(5): 1077 ? 1085.
[22] Li J C, Huang Y X, Wang F F, et al. Enhanced strength and ductility of friction-stir-processed Mg-6Zn alloys via Y and Zr co-alloying[J]. Materials Science and Engineering, 2020, 773: 138877.1 ? 138877.7.
[23] Huang Y X, Huang T F, Wan L, et al. Material flow and mechanical properties of aluminum-to-steel self-riveting friction stir lap joints[J]. Journal of Materials Processing Technology, 2018, 263: 129 ? 137.
[24] Palanivel S, Nelaturu P, Glass B, et al. Friction stir additive manufacturing for high structural performance through microstructural control in an Mg based WE43 alloy[J]. Materials & Design, 2015, 65: 934 ? 952.
[25] Mao Y Q, Ke L M, Huang C P, et al. Formation characteristic, microstructure, and mechanical performances of aluminum-based components by friction stir additive manufacturing[J]. The International Journal of Advanced Manufacturing Technology, 2016, 83(9): 1637 ? 1647.
[26] Klopstock H, Neelands A R. An improved method of joining or welding metals: British patent specification 572789[P]. 1945-10-24.
[27] Kalvala P R, Akram J, Tshibind A I, et al. Friction spot welding and friction seam welding: US20150360317A1 [P]. 2015-12-17.
[28] Dilip J, Babu S, Rajan S V, et al. Use of friction surfacing for additive manufacturing[J]. Materials and Manufacturing Processes, 2013, 28(2): 189 ? 194.
[29] 刘雪梅, 姚君山, 张彦华. 摩擦堆焊工艺参数的优化选择[J]. 焊接学报, 2004, 25(6): 99 ? 102
Liu Xuemei, Yao Junshan, Zhang Yanhua. Optimization for friction surfacing parameters[J]. Transactions of The China Welding Institution, 2004, 25(6): 99 ? 102
[30] Fitseva V, Krohn H, Hanke S, et al. Friction surfacing of Ti-6Al-4V: Process characteristics and deposition behaviour at various rotational speeds[J]. Surface & Coatings Technology, 2015, 278: 56 ? 63.
[31] Seidi E, Miller S F. A novel approach to friction surfacing: experimental analysis of deposition from radial surface of a consumable tool[J]. Coatings, 2020, 10(11): 17.
[32] Kramer D E, Pinheiro G A, Santos J F, et al. Deposit by friction surfacing and its applications[J]. Welding International, 2010, 24(6): 422 ? 431.
[33] Suhuddin U, Mironov S, Krohn H, et al. Microstructural evolution during friction surfacing of dissimilar aluminum alloys[J]. Metallurgical and Materials Transactions A, 2012, 43(13): 5224 ? 5231.
[34] Dilip J J S, Janaki Ram G D. Microstructures and properties of friction freeform fabricated borated stainless steel[J]. Journal of Materials Engineering and Performance, 2013, 22(10): 3034 ? 3042.
[35] Gandra J, Pereira D, Miranda R, et al. Deposition of AA6082-T6 over AA2024-T3 by friction surfacing-Mechanical and wear characterization[J]. Surface and Coatings Technology, 2013, 223: 32 ? 40.
[36] Vitanov V, Voutchkov I, Bedford G. Neurofuzzy approach to process parameter selection for friction surfacing applications[J]. Surface and Coatings Technology, 2001, 140(3): 256 ? 262.
[37] Rahmati Z, Aval H J, Nourouzi S, et al. Microstructural, tribological, and texture analysis of friction surfaced Al-Mg-Cu clad on AA1050 alloy[J]. Surface & Coatings Technology, 2020, 397: 125980.
[38] Nanci H, Kumar K, Jianqing S, et al. Additive friction stir deposition of Mg alloys using powder filler materials[C]//TMS Annual Meeting & Exhibition. Gewerbestrasse, Switzerland, 2016: 215-222.
[39] Calvert J R. Microstructure and mechanical properties of WE43 alloy produced via additive friction stir technology[D]. Virginia: Virginia Polytechnic Institute and State University, 2015.
[40] Rivera O, Allison P, Jordon J, et al. Microstructures and mechanical behavior of Inconel 625 fabricated by solid-state additive manufacturing[J]. Materials Science and Engineering:A, 2017, 69: 1 ? 9.
[41] Mukhopadhyay A, Saha P. Mechanical and microstructural characterization of aluminium powder deposit made by friction stir based additive manufacturing[J]. Journal of Materials Processing Technology, 2020, 281: 116648.
[42] Rivera O G, Allison P G, Jordon J B, et al. Microstructures and mechanical behavior of Inconel 625 fabricated by solid-state additive manufacturing[J]. Materials Science & Engineering, 2017, 694(10): 1 ? 9.
[43] Patel V, Li W, Xu Y. Stationary shoulder tool in friction stir processing: a novel low heat input tooling system for magnesium alloy[J]. Materials & Manufacturing Processes, 2019, 34(2): 177 ? 182.
[44] 吴宝生. 增材式径向搅拌摩擦修复工艺研究[D]. 沈阳: 沈阳航空航天大学, 2019.
Wu Baosheng. Radial-additive friction stir repairing for exceeded tolerance hole[D]. Shenyang: Shenyang Aerospace University, 2019.
[45] Mendes N, Neto P, Loureiro A, et al. Machines and control systems for friction stir welding: A review[J]. Materials & Design, 2016, 90: 256 ? 65.
[46] Franke D, Rudraraju S, Zinn M, et al. Understanding process force transients with application towards defect detection during friction stir welding of aluminum alloys[J]. Journal of Manufacturing Processes, 2020, 54: 251 ? 261.
[47] Meng X C, Huang Y X, Cao J, et al. Recent progress on control strategies for inherent issues in friction stir welding[J]. Progress in Materials Science, 2020: 100706.
[48] Akram J, Puli R, Kalvala P R, et al. A novel weld transition joint by friction surfacing[J]. Manufacturing Letters, 2014, 2(4): 104 ? 107.
[49] Garcia D, Hartley W D, Rauch H A, et al. In situ investigation into temperature evolution and heat generation during additive friction stir deposition: A comparative study of Cu and Al-Mg-Si[J]. Additive Manufacturing, 2020, 34: 101386.
