|
[1] M.D. Vijayakumar , V. Dhinakaran , T. Sathish , G. Muthu , P.M. Bupathi ram ,Experimental study of chemical composition of aluminium alloys ,Materials Today: Proceedings , 2(37) , 2021, P 1790-1793. [2] Rajesh P. Verma,Manish Kumar Lila, A short review on aluminium alloys and welding in structural applications ,Materials Today: Proceedings ,20(37), 2021, P 10687-10691. [3] Md. Tanwir Alam , Akhter Husain Ansari, Review on aluminium and its alloys for automotive applications , International Journal of Advanced Technology in Engineering and Science,5(5) ,2017. [4] Tolga Dursun , Costas Soutis , Recent developments in advanced aircraft aluminium alloys, Materials and Design , 56 , 2014, P862-871. [5] E.A. Starke Jr , J.T. Staley , Application of modern aluminum alloys to aircraft, Progress in Aerospace Sciences, 2-3(32) , 1996, P131-172. [6] James C. Williams , Edgar A. Starke, Jr. , Progress in structural materials for aerospace systems, Acta Materialia, 19(51) ,2003, P5775-5799. [7] Zhongxing Wang , Mengyu Li , Qinghua Han, Structural fire behaviour of aluminium alloy structures: Review and outlook, Engineering Structures, 268 , 2022, 114746. [8] Omid Ferdowsi Hosseinabadi, Mohammad Reza Khedmati , A review on ultimate strength of aluminium structural elements and systems for marine applications, Ocean Engineering, 232 , 2021, 109153. [9] Yao Sun, The use of aluminum alloys in structures: Review and outlook, Structures , 57 ,2023, 105290. [10] Gürel Çam1 , Güven İpekoğlu1, Recent developments in joining of aluminum alloys, The International Journal of Advanced Manufacturing Technology, 91 , 2017, P 1851–1866. [11] J. Chen, C.S. Wu, M.A. Chen, ” Improvement of welding heat source models for TIG-MIG hybrid welding process, Journal of Manufacturing Processes, 4(46) ,2014, P485-493. [12] Ying Lianga, Shengsun Hua, Junqi Shena, Heng Zhanga, Peng Wanga , Geometrical and microstructural characteristics of the TIG-CMT hybrid welding in 6061 aluminum alloy cladding, Journal of Materials Processing Technology, 239 ,2017, P18-30. [13] Xiangyang Wu , Xinyu Zhao , Ji Chen , Zhiyi Zhang , Chuansong Wu , Simulation of the influence of welding parameters on weld pool behavior during a TIG-MIG hybrid welding process, Journal of Manufacturing Processes , 79 , 2022 , P 460-475. [14] Xuefei Cui , Ji Chen , Chunyang Xia, Xiaohui Han , Hao Su , Chuansong Wu , The mechanism study of TIG-MIG hybrid welding process basedon simulation, Vacuum , 215 , 2023 , 112341. [15] R.S. Vidyarthy , D.K. Dwivedi, Activating flux tungsten inert gas welding for enhanced weld penetration, Journal of Manufacturing Processes , 22 , 2016 , P 211-228. [16] Naishadh P. Patel , Jay J. Vora , Vishvesh J. Badheka , Gautam H.Upadhyay, Review on the use of activated flux in arc and beam welding processes , Materials Today: Proceedings , 2 43 , 2021 , P 916-920. [17] P. Vasantharaja, M. Vasudevan, Studies on A-TIG welding of Low Activation Ferritic/Martensitic (LAFM) steel, Journal of Nuclear Materials, 1-3(421) , 2012 , P 117-123. [18] Her-Yueh Huang, Research on the Activating Flux Gas Tungsten Arc Welding and Plasma Arc Welding for Stainless Steel, Metals and Materials International, Volume 16 , 2010 , P 819–825. [19] Balázs Varbai, Rita Kormos, Kornél Májlinger, Effects of Active Fluxes in Gas Metal Arc Welding, Periodica Polytechnica Mechanical Engineering, 61(1) , 2017, P 68–73. [20] M. Kuo,Z. Sun &D. Pan, Laser welding with activating flux, Science and Technology of Welding and Joining , 6 , 2013 , P 17–22. [21] ZHANG Ruihua , FAN Ding , KATAYAMA Seiji, Electron Beam Welding with Activating Flux, Transactions of JWR , Vol.3 , 2006 , No.2. [22]黃振賢,”機械材料”,二版,新文京開發,新北,2017 [23] aluminum associatetion, et al. Aluminum: properties and physical metallurgy. ASM international, 1984,p66-82. [24] Y.J. Li , A.M.F. Muggerud , A. Olsen , T. Furu , Precipitation of partially coherent α-Al(Mn,Fe)Si dispersoids and their strengthening effect in AA 3003 alloy , Acta Materialia , 60 , 2012 , P 1004-1014. [25] Y. Liu, G.Z. Menga, Y.F. Cheng , Electronic structure and pitting behavior of 3003 aluminum alloy passivated under various conditions , Electrochimica Acta , 54 , 2009 , P 4155-4163. [26] Y.B. Tan , X.M. Wang , M. Ma , J.X. Zhang , W.C. Liu , R.D. Fu , S. Xiang, A study on microstructure and mechanical properties of AA 3003 aluminum alloy joints by underwater friction stir welding,Materials Characterization , 127 , 2017, P 41-52. [27] D. Scotto D'Antuono , J. Gaies , W. Golumbfskie , M.L. Taheri , Direct measurement of the effect of cold rolling on β phase precipitation kinetics in 5xxx series aluminum alloys, Acta Materialia , 123 , 2017, P 264-271. [28] R. Dubey , R. Jayaganthan , D. Ruan , N.K. Gupta , N. Jones , R. Velmurugan, Energy absorption and dynamic behaviour of 6xxx series aluminium alloys:A review, International Journal of Impact Engineering , 172 , 2023, 104397. [29] Ming Yang , Lei Lei , Yun Jiang , Fahong Xu , Cunhong Yin, Simultaneously improving tensile properties and stress corrosion cracking resistance of 7075-T6 aluminum alloy by USRP treatment, Corrosion Science , 218 , 2023 , 111211. [30] Rui Fu , Yaojian Liang , Qifei Han, Yueling Guo , Hongshuai Lei , Changmeng Liu, Strengthening and fracturing mechanisms of laser-directed energy deposited Al-7075 alloy , Materials Science & Engineering A ,881 , 2023 , 145433. [31] kora t sunny, joby joseph, georgekutty s mangalathu & jeeno mathew, a review on mechanical & microstructural property evaluation of aluminium 5083 alloy weldment , International Journal of Mechanical and Production Engineering Research and Development , 3 , 2013 , 119-128. [32] H.B. Cary, 1994, Modern Welding Technology, 3rd ed, Prentice-Hall, Englewood Cliffs [33] Peter Hidnert ,H.S. Krider, Thermal Expansion of Aluminum and Some Aluminum Alloys , Journal of Research of the National Bureau of Standards , 48(3) , 1952 , 3208. [34] J.M. Fortain , S. Gadrey, How to select a suitable shielding gas to improve the performance of MIG and TIG welding ofaluminium alloys , Welding International, 27 , 2013 , Pages 936–947 [35] Yiwen Li , Wenfeng Zou, Boyoung Lee , Aleksandr Babkin , Yunlong Chang, Research progress of aluminum alloy welding technology, The International Journal of Advanced Manufacturing Technology , 109 , 2020, P 1207–1218. [36] Rizki Dwi Ardika, Teguh Triyono, Nurul Muhayat, Triyono, A review porosity in aluminum welding, Procedia Structural Integrity , 33 , 2022, P 171–180. [37] J.F.Rudy, E.J.Rupert, Effects of Porosity on Mechanical Properties of Aluminum Welds, Welding Journal, 1970 , p322-336 [38] 周長彬、蔡丕樁、郭央諶,”銲接學” ,初版,全華科技圖書,臺北,2001 [39] C. C. Chang, C. L. Chen, J. Y. Wen, C. M. Cheng, and C. P. Chou,Characterization of Hot Cracking Due to Welding of High-Strength Aluminum Alloys, Materials and Manufacturing Processes, 27 , 2012, P658–663. [40] Chun-Jung Huang , Chang-Pin Chou, The Influence of Aluminum Content on Hot Cracking and Post-Weld Heat Treatment of Magnesium Alloys, National Chiao Tung University, Ph.D.,2011. [41] Jia-Cing Yan, Chang-Ping Chou, Effect of Flux on MIG Welding Process for 6061 Aluminum Alloy , National Chiao Tung University , Ph.D.,2012. [42] S. Kou, Welding Metallurgy, 2nd ed, John Wiley & Sons, 2003 [43]N.Jeyaprakash, Adisu Haile, M.Arunprasath, The Parameters and Equipments Used in TIG Welding: A Review, The International Journal Of Engineering And Science, 4 , 2015 , PP.11-20. [44]王振欽,銲接學,初版,高立圖書,臺北,1999. [45] Ravel F. Ammerman,P.K. Sen, Modeling High-Current Electrical Arcs: A Volt-Ampere Characteristic Perspective for AC and DC Systems, IEEE , 2007. [46] Prachya Peasura , Anucha Watanapa, Influence of Shielding Gas on Aluminum Alloy 5083 in Gas Tungsten Arc Welding, Procedia Engineering , 29 , 2012, PP. 2465-2469. [47] Jyoti Prakash,S.P.Tewari, Bipin Kumar Srivastava, Shielding Gas for Welding of Aluminium Alloys by TIG/MIG Welding-A Review, International Journal of Modern Engineering Research (IJMER), 1 , 2011 , PP. 690-699. [48] ji long ma, metal transfer in mig welding, cranfield institute of technology school of industrial science, ph.d.,1982 [49] larry jeffus, Principles and Applications, 3rd ed, International Thomson, New York , 1999 [50] Yu Han, Ji Chen , Haijun Ma, Xinyu Zhao, Chuansong Wu , Jinqiang Gao, Numerical Simulation of Arc and Droplet Behaviors in TIG-MIG Hybrid Welding, Materials, 13 (20) , 2020 [51] P.F. Mendez, T.W. Eagar, Penetration and defect formation in high-current arc welding, WELDING RESEARCH, 82 (10) , 2003 , pp. 296-306 [52] J. Tusek, M. Suban, Hybrid welding with arc and laser beam, Science and Technology of Welding and Joining, 4 (5) , 1999 , pp. 308-311. [53] KAIERLE, S., et al, Innovative hybrid welding process in an industrial application, International Congress on Applications of Lasers & Electro-Optics, AIP Publishing , 2000 , pp C91-C98. [54]ONO, Moriaki, et al, Development of laser-arc hybrid welding , technical report-japanese edition , 2002 , pp. 70-74. [55] Wang, J, Feng, J.C, Zhang, H.T, TIG-MIG Indirect arc welding process , transactions of the china welding institution , 30 , 2009 , 145–148. [56] Yang, T ,Zhang, S.H, Gao, H.M.; Wu, L.; Xu, K.W.; Liu, Y.Z, Analysis on the characteristic mechanism of TIG-MIG hybrid welding , TRANSACTIONS OF THE CHINA WELDING INSTITUTION , 33 , 2012 , 25–28. [57] Kanemaru, S.; Sasaki, T.; Sato, T.; Era, T.; Tanaka, M, Study for the mechanism of TIG-MIG hybrid welding process , Weld. World , 59 , 2015 , 261–268. [58] Xiangmeng Meng, Guoliang Qin, Yuqi Zhang, Banglong Fu, Zengda Zou, High speed TIG–MAG hybrid arc welding of mild steel plate, Journal of Materials Processing Technology, 214(11), 2014 , Pages 2417-2424. [59] J. Chen, C.S. Wu, M.A. Chen, Improvement of welding heat source models for TIG-MIG hybrid welding process, Journal of Manufacturing Processes,16( 4),2014,Pages 485-493, [60] Ji Chen, Ran Zong, Chuansong Wu, Girish Kumar Padhy, Qingxian Hu, Influence of low current auxiliary TIG arc on high speed TIG-MIG hybrid welding, Journal of Materials Processing Technology, 243, 2017, Pages 131-142, [61] T. Rodríguez-Hernández, V.L. Cruz-Hernández, M.A. García-Rentería, R. Torres-Gonzalez, S. García-Villarreal, F.F. Curiel-López, L.A. Falcón-Franco, First assessment on the microstructure and mechanical properties of gtaw-gmaw hybrid welding of 6061-t6 AA, Journal of Manufacturing Processes,59,2020,Pages 658-667, [62] roslan, Rose Alifah Ellyana, et al. , Observation of arc behaviour in TIG/MIG hybrid welding process. , In: IOP Conference Series: Earth and Environmental Science. ,596(1) , 2020. p. 012025. [63] Rose Alifah Ellyana Roslan et al. , Numerical Simulation of Arc Behaviour in TIG/MIG Hybrid Welding Process of Aluminium Alloy , AIP Conference, 2454(1), 2022. [64]xiu, qingpeng; liu, zuming; zhao, xingchuan. , KTIG–MIG hybrid arc welding process. , Science and Technology of Welding and Joining, 28(8), 2023 , 728-737. [65] C.R. Heiple and J.R. Roper, Mechanism for Minor Element Effect on GTA Fusion Zone Geometry, Welding Journal (Miami, Fla), 61(4), pp. 97 - 102,1982. [66] K.C. MILLS, B.J. Keene , Factors affecting variable weld penetration , Int Mater Rev, 35, 1990, pp. 185-216, [67] Mills, k. c., et al. , Marangoni effects in welding. Philosophical Transactions of the Royal Societyof London., Series A : Mathematical , Physical and Engineering Sciences , 356(1739) , 1998 , pp 911-925. [68] S. Lu, H. Fujii , H. Sugiyama, M. Tanaka, K. Nogi, Weld penetration and Marangoni convection with oxide fluxes in GTA welding , Mater Trans, 43 ,2002, pp. 2926-2931. [69]C. Li, Y. Shi, Y. Gu, F. Yang, Effect of oxide on surface tension pf molten metal , RSC Adv, 7 , 2017, pp. 53941-53950, [70]C. Li, Y. Shi, D. Fan, M. Zhu , Effects of different activating fluxes on the surface tension of molten metal in gas tungsten arc welding , J Manuf Process, 32, 2018, pp. 395-402, [71]Sudhanshu Ranjan Singh, Pradeep Khanna, A-TIG (activated flux tungsten inert gas) welding: – A review, Materials Today: Proceedings, 44( 1),2021,Pages 808-820 [72]A.G. Simonik, Effect of Contraction of the Arc Discharge Upon theIntroduction of Electro-Negative Elements, Welding Production (Englishtranslation of Svarochnoe Proizvodstvo), 23(3), pp. 68-71, 1976. [73]S. Sire, G. Ruckert, and S. Marya, Flux Optimisation for Enhanced Weld Penetration in ALUMINIUM Contribution to FBTIG Process, pp.207-217,Copenhagen, Denmark, Institut International de la Soudure,2002. [74]S.W. Shyu, H.Y. Huang, K.H. Tseng, C.P. Chou, Study of the Performance of Stainless Steel A-TIG Welds, J. Mater. Eng. Perform., 17 (2) (2008), pp. 193-201, [75]M. Tanaka, T. Shimizu, T. Terasaki, M. Ushio, F. Koshiishi, Effects of activating flux on arc phenomena in gas tungsten arc welding, Sci Technol Weld Join, 5 , 2000, pp. 397-402, [76]M. Tanaka, H. Terasaki, H. Fujii, M. Ushio, R. Narita, K. Kobayashi, Anode heat transfer in TIG welding and its effect on the cross-sectional area of weld penetration” ,Weld Int, 20, 2006, pp. 268-274, [77]Kuang-Hung Tseng, Chih-Yu Hsu, Performance of activated TIG process in austenitic stainless steel welds, Journal of Materials Processing Technology, 211( 3),2011,Pages 503-512, [78]K-H. Tseng, K-L. Chen, Comparisons between TiO2- and SiO2-flux assisted TIG welding processes, J Nanosci Nanotechnol, 12 , 2012, pp. 6359-6367, [79]J.J. Lowke, M. Tanaka, and M. Ushio, Mechanisms giving increased weld depth due to a flux, Journal of Physics D: Applied Physics, 38(18), pp.3438-3445, 2005. [80]Her-Yueh Huang, Effects of activating flux on the welded joint characteristics in gas metal arc welding , Materials & Design (1980-2015), 31(5), 2010, Pages 2488-2495. [81]R.S. Vidyarthy, P. Sivateja, Influence of activating flux tungsten inert gas welding on mechanical and metallurgical properties of the mild steel , Materials Today: Proceedings, 28(2), 2020, Pages 977-981. [82]Tathgir, S., Bhattacharya, A., & Bera, T. K. (2015) , Influence of current and shielding gas in TiO2 flux activated TIG welding on different graded steels , Materials and Manufacturing Processes, 30(9), 1115-1123. [83]Tathgir, Surinder; Bhattacharya, Anirban. , Activated-TIG welding of different steels: influence of various flux and shielding gas. , Materials and Manufacturing Processes, 31(3) , 2016, 335-342. [84]H.-Y. Huang , Research on the activating flux gas tungsten arc welding and plasma arc welding for stainless steel, Met Mater Int, 16, 2010, pp. 819-825. [85] Paulo J Modenesi, Eustáquio R Apolinário, Iaci M Pereira , TIG welding with single-component fluxes , Journal of Materials Processing Technology, 99( 1–3), 2000, Pages 260-265. [86]M. Marya, G.R. Edwards, Chloride contributions in flux-assisted GTA welding of magnesium alloys,Weld J,2002, pp. 291-298 [87]Anup Kulkarni, D.K. Dwivedi, M. Vasudevan, Study of mechanism, microstructure and mechanical properties of activated flux TIG welded P91 Steel-P22 steel dissimilar metal joint, Materials Science and Engineering: A, 731, 2018, Pages 309-323. [88]Sanjay G. Nayee, Vishvesh J. Badheka, Effect of oxide-based fluxes on mechanical and metallurgical properties of Dissimilar Activating Flux Assisted-Tungsten Inert Gas Welds , Journal of Manufacturing Processes, 16(1), 2014, Pages 137-143. [89]Yiming Huang, Yuxue Yuan, Yingchao Feng, Jinping Liu, Lijun Yang, Lei Cui, Effect of activating flux Cr2O3 on microstructure and properties of laser welded 5083 aluminum alloys , Optics & Laser Technology, 150, 2022, 107930. [90]Guo-liang QIN, Guo-gang WANG, Zeng-da ZOU, ” Effects of activating flux on CO2 laser welding process of 6013 Al alloy” , Transactions of Nonferrous Metals Society of China, 22(1), 2012, Pages 23-29. [91]Zhao, Yong, et al. , Effect on formation of 5083 aluminum alloy of activating flux in FBTIG welding , Advanced Materials Research, , 311, 2011, 2385-2388. [92]Ajezi-sardroud, r., et al. , Effect of Active Flux on Aluminum 6061 and its Mechanical Properties by Gas Tungsten Arc Welding Process , International Journal of Engineering, 35(8) , 2022, 1501-1508. [93]Varshney, Deekshant, and Kaushal Kumar , Effects of activating flux on aluminum 6061 using TIG welding (GTAW) , AIP Conference Proceedings, 2341(1), 2021.
|