Quality of self-piercing riveting (SPR) joints from cross-sectional perspective: A review

• Autorzy: Haque R.

Identyfikatory

DOI

10.1016/j.acme.2017.06.003

• Języki publikacji: EN

Abstrakty

EN

Self-piercing riveting (SPR) is a method used for joining sheet materials by creating a mechanical interlock between the sheets. SPR is of increasing interest in automobile industries due to its suitability for joining lightweight, high strength and dissimilar materials. The quality of an SPR joint from cross-sectional perspective is primarily characterized by the amount of mechanical interlock known as rivet flaring. Other parameters, such as rivet head height, bottom thickness and effective length of the rivet in the bottom sheet are also considered as quality parameters. However, the many factors that determine the quality of an SPR joint are poorly described in the literature and, as a consequence, the opportunities to develop new product and optimize the process are limited. In this paper, several of the key parameters that affect the quality of an SPR joint are described and some assistive technologies that have the potential of improving the quality of a joint are discussed. This is a zone in the field of SPR joining which has plenty of research opportunities. Innovative progress will be achieved by a combination of techniques, together with industrial trials and laboratory simulations.

Słowa kluczowe

EN

self-piercing riveting; SPR; rivet; flaring; mechanical interlock; joining

PL

nit; blokada mechaniczna; złącze; przemysł motoryzacyjny

• Wydawca: Springer ; Wrocław University of Science and Technology
• Czasopismo: Archives of Civil and Mechanical Engineering
• Rocznik: 2018
• Tom: Vol. 18, no. 1
• Strony: 83--93
• Opis fizyczny: Bibliogr. 70 poz., rys., tab.

Twórcy

autor

Haque R.

• Faculty of Science, Health, Education and Engineering, University of the Sunshine Coast, Sippy Downs, QLD 4556, Australia

Bibliografia

• [1] Profast, 2017, www.profast.com.au (accessed 23.02.17).
• [2] R. Haque, J.H. Beynon, Y. Durandet, O. Kirstein, S. Blacket, Feasibility of measuring residual stress profile in different self-pierce riveted joints, Science & Technology of Welding & Joining 17 (2012) 60–68.
• [3] R.P. King, Analysis and quality monitoring of a self-pierce riveting process, (Ph.D. thesis), University of Hertfordshire, Hertfordshire, UK, 1997.
• [4] S.P. Sunday, Self-piercing rivets for aluminum components, in: SAE Technical Paper 830526, 1983, http://dx.doi.org/ 10.4271/830526.
• [5] D. Monday, Joining through thick and thin, appliance design, Australia, 2008.
• [6] Emhart, 2017, www.emhart.com (accessed 24.02.17)
• [7] S. Blacket, Self-pierce riveting technology. a joining solution for light metals, in: Proceedings of the 1st International Light Metals Technology Conference, Brisbane, Qld, Australia, September, (2003) 383–388.
• [8] X. He, C. Deng, X. Zhang, Fretting behavior of SPR joining dissimilar sheets of titanium and copper alloys, Metals 6 (2016).
• [9] P. Briskham, N. Blundell, L. Han, R. Hewitt, K. Young, Comparison of Self-pierce Riveting, Resistance Spot Welding and Spot Friction Joining for Aluminium Automotive Sheet, SAE International, 2006-01-0774, 2006.
• [10] Bollohoff, 2017, www.boellhoff.de (accessed 24.02.17)
• [11] G. Di Franco, L. Fratini, A. Pasta, V.F. Ruisi, On the self-piercing riveting of aluminium blanks and carbon fibre composite panels, International Journal of Material Forming 6 (2013) 137–144.
• [12] X. Zhang, X. He, B. Xing, L. Zhao, Y. Lu, F. Gu, A. Ball, Influence of heat treatment on fatigue performances for self-piercing riveting similar and dissimilar titanium, aluminium and copper alloys, Materials and Design 97 (2016) 108–117.
• [13] L. Zhao, X. He, B. Xing, Y. Lu, F. Gu, A. Ball, Influence of sheet thickness on fatigue behavior and fretting of self-piercing riveted joints in aluminum alloy 5052, Materials and Design 87 (2015) 1010–1017.
• [14] R. Haque, Residual stress and deformation in SPR joints of high strength materials, (Ph.D. thesis), Faculty of Science, Engineering and Technology, Swinburne University of Technology, 2014.
• [15] R. Haque, Y.C. Wong, A. Paradowska, S. Blacket, Y. Durandet, SPR characteristics curve and distribution of residual stress in self-piercing riveted joints of steel sheets, Advances in Materials Science and Engineering 2017 (2017) 14.
• [16] S. Cheraghi, Effect of variations in the riveting process on the quality of riveted joints, The International Journal of Advanced Manufacturing Technology 39 (2008) 1144–1155.
• [17] X. He, I. Pearson, K. Young, Self-pierce riveting for sheet materials: state of the art, Journal of Materials Processing Technology 199 (2008) 27–36.
• [18] Scopus, 2017, www.scopus.com (accessed 24.02.17)
• [19] Y. Xu, Characterization of self-piercing riveted joint, (Ph.D. dissertation, in Engineering Science), The University of Toledo, 2005.
• [20] L. Han, A. Chrysanthou, Evaluation of quality and behaviour of self-piercing riveted aluminium to high strength low alloy sheets with different surface coatings, Materials and Design 29 (2008) 458–468.
• [21] Y. Xu, Effects of factors on physical attributes of self-piercing riveted joints, Science & Technology of Welding & Joining 11 (2006) 666–671.
• [22] X. Sun, M.A. Khaleel, Performance optimization of self-piercing rivets through analytical rivet strength estimation, Journal of Manufacturing Processes 7 (2005) 83–93.
• [23] C.G. Pickin, K. Young, I. Tuersley, Joining of lightweight sandwich sheets to aluminium using self-pierce riveting, Materials and Design 28 (2007) 2361–2365.
• [24] K. Mori, T. Kato, Y. Abe, Y. Ravshanbek, Plastic joining of ultra high strength steel and aluminium alloy sheets by self piercing rivet, CIRP Annals – Manufacturing Technology 55 (2006) 283–286.
• [25] R. Haque, J.H. Beynon, Y. Durandet, Characterisation of force– displacement curve in self-pierce riveting, Science and Technology of Welding and joining 17 (2012) 476–488.
• [26] R. Haque, N.S. Williams, S.E. Blacket, Y. Durandet, A simple but effective model for characterizing SPR joints in steel sheet, Journal of Materials Processing Technology 223 (2015) 225–231.
• [27] R. Haque, Y. Durandet, Strength prediction of self-pierce riveted joint in cross-tension and lap-shear, Materials & Design 108 (2016) 666–678.
• [28] G. Casalino, DOE analysis of the effects of geometrical parameters on the self-pierci ng riveting of aluminium alloy AA6060T4, Key Engineering Materials 473 (2011) 733–738. [29] J. Mucha, A study of quality parameters and behaviour of self-piercing riveted aluminium sheets with different joining conditions, Strojniski Vestnik/Journal of Mechanical Engineering 57 (2011) 323–333.
• [30] W. Hou, E. Mangialardi, S.J. Hu, P.C. Wang, R. Menassa, Characterization for quality monitoring of a self-piercing riveting process, in: Proceedings of the Sheet Metal Welding conference XI, Sterling Heights, MI, 2004.
• [31] A. Chrysanthou, X. Sun, Self-piercing riveting: properties, Processes and Applications (2014).
• [32] Z. Huang, S. Kang, J. Lai, Numerical simulation and experiment of self-piercing riveting with flat-bottom die, in: Proceedings of the 2nd International Conference on Transportation Engineering, ICTE 2009, 2009, 1359–1364.
• [33] L. Huang, J.V. Lasecki, H. Guo, X. Su, Finite element modeling of dissimilar metal self-piercing riveting process, SAE International Journal of Materials and Manufacturing 7 (2014).
• [34] R. Cacko, Review of different material separation criteria in numerical modeling of the self-piercing riveting process – SPR, Archives of Civil and Mechanical Engineering 8 (2008) 21–30.
• [35] R. Haque, Y.C. Wong, A. Paradowska, Y. Durandet, Residual stress profiles in riveted joints of steel sheets, Science and Technology of Welding and Joining 20 (2015) 199–207.
• [36] R. Haque, Y. Durandet, Y.C. Wong, A. Paradowska, J.H. Beynon, S. Blacket, Optimising parameters for meaningful measurement of residual strain by neutron diffraction in self- pierce riveted joints, Science and Technology of Welding and Joining 18 (2013) 492–499.
• [37] Z. Jin, P.K. Mallick, Enhancement of fatigue life of self- piercing riveted joints by coining, in: ASME 2002 International Mechanical Engineering Congress and Exposition, IMECE2002, New Orleans, LA, United States, 17 November 2002 through 22 November 2002, (2002) 417–429, Code 82313.
• [38] J. Gårdstam, Simulation and Verification of Strength of Self Pierced Rivet Joints of Stainless Sheet Steels, Swedish Institute for Metals Research, 2004 IM-2004-547.
• [39] E. Sjöström, J. Gårdstam, R. Trinick, Development of Martensitic Stainless Steel Rivets for Applications of Self Piercing Riveting of Stainless Steel Sheets, Swedish Institute for Metals Research, 2004 IM-2004-536.
• [40] R.P. King, J.M. Osullivan, D. Spurgeon, P. Bentley, Setting load requirements and fastening strength in the self-pierce riveting process, Advances in Manufacturing Technology (1995) 57–61.
• [41] P.O. Bouchard, T. Laurenta, L. Tollier, Numerical modeling of self-pierce riveting—from riveting process modeling down to structural analysis, Journal of Materials Processing Technology 202 (2008) 290–300.
• [42] X. He, L. Zhao, C. Deng, B. Xing, F. Gu, A. Ball, Self-piercing riveting of similar and dissimilar metal sheets of aluminum alloy and copper alloy, Materials and Design 65 (2015) 923–933.
• [43] X. He, Y. Wang, Y. Lu, K. Zeng, F. Gu, A. Ball, Self-piercing riveting of similar and dissimilar titanium sheet materials, International Journal of Advanced Manufacturing Technology 80 (2015) 2105–2115.
• [44] R. Haque, J.H. Beynon, Y.C. Wong, O. Kirstein, Y. Durandet, Evaluation of residual stress in SPR joint by neutron diffraction, Advanced Materials Research 409 (2011) 575.
• [45] X. Liu, Y.C. Lim, Y. Li, W. Tang, Y. Ma, Z. Feng, J. Ni, Effects of process parameters on friction self-piercing riveting of dissimilar materials, Journal of Materials Processing Technology 237 (2016) 19–30. [46] O. Hahn, R. Neugebauer, G. Leuschen, C. Kraus, R. Mauermann, Research in impulse joining of self pierce riveting, in: 3rd International Conference on High Speed Forming – 2008, Dortmund, Germany, 2008.
• [47] B. Wang, C. Hao, J. Zhang, A new self-piercing riveting process and strength evaluation, Journal of Manufacturing Science and Engineering 128 (2006) 580–587.
• [48] Y. Abe, T. Kato, K. Mori, Joinability of aluminium alloy and mild steel sheets by self piercing rivet, Journal of Materials Processing Technology 177 (2006) 417–421.
• [49] Y. Abe, T. Kato, K. Mori, Self-piercing riveting of high tensile strength steel and aluminium alloy sheets using conventional rivet and die, Journal of Materials Processing Technology 209 (2009) 3914–3922.
• [50] K. Mori, Y. Abe, T. Kato, Self-pierce riveting of multiple steel and aluminium alloy sheets, Journal of Materials Processing Technology 214 (2014) 2002–2008.
• [51] D. Li, L. Han, M. Thornton, M. Shergold, Influence of rivet to sheet edge distance on fatigue strength of self-piercing riveted aluminium joints, Materials Science and Engineering A 558 (2012) 242–252.
• [52] R. Liu, Y. Chu, X. Dang, X. Wang, Connection strength of self-piercing riveted with different surface treatment, Information (Japan) 15 (2012) 5403–5410.
• [53] R.M. Howard, S.P. Sunday, The Corrosion Performance of Steel Self-Piercing Rivets When Used with Aluminum Components, SAE International, 1983 SAE-831816.
• [54] L. Han, A. Chrysanthou, J.M. O'Sullivan, Fretting behaviour of self-piercing riveted aluminium alloy joints under different interfacial conditions, Materials and Design 27 (2006) 200–208.
• [55] L. Han, Mechanical behaviour of self-piercing riveted aluminium joints, (Ph.D. thesis), University of Hertfordshire, UK, 2003.
• [56] O. Hahn, T.M. Wibbeke, Application of low-heat hybrid joining technologies for the joining of thin-walled sheet materials, Welding and Cutting 4 (2005) 208–214.
• [57] L. Fratini, V.F. Ruisi, Self-piercing riveting for aluminium alloys – composites hybrid joints, International Journal of Advanced Manufacturing Technology 43 (2009) 61–66.
• [58] X. He, B. Xing, Y. Ding, Y. Hu, K. Zeng, Strength and Energy Absorption of Self-piercing Riveted Joints, 2013, 1783–1786.
• [59] L. Han, K.W. Young, A. Chrysanthou, J.M. O'Sullivan, The effect of pre-straining on the mechanical behaviour of self-piercing riveted aluminium alloy sheets, Materials and Design 27 (2006) 1108–1113.
• [60] H. Huang, D. Du, B.H. Chang, B. Sui, Q. Chen, Distortion analysis for self-piercing riveting of aluminium alloy sheets, Science and Technology of Welding and Joining 12 (2007) 73–78.
• [61] Z. Huang, Q. Yao, J. Lai, J. Zhao, Z. Jiang, Developing a self-piercing riveting with flange pipe rivet joining aluminum sheets, International Journal of Advanced Manufacturing Technology (2017) 1–14.
• [62] Z.X. Liu, P.C. Wang, J.W. Wang, Investigation to self-piercing riveting of wrought magnesium AZ31 sheets, Advanced Materials Research 472–475 (2012) 1188–1191.
• [63] M. Easton, A. Beer, M. Barnett, C. Davies, G. Dunlop, Y. Durandet, S. Blacket, T. Hilditch, P. Beggs, Magnesium alloy applications in automotive structures, JOM Journal of the Minerals, Metals and Materials Society 60 (2008) 57–62.
• [64] Y. Durandet, R. Deam, A. Beer, W. Song, S. Blacket, Laser assisted self-pierce riveting of AZ31 magnesium alloy strips, Materials and Design 31 (2010) S13–S16.
• [65] J.W. Wang, Z.X. Liu, Y. Shang, A.L. Liu, M.X. Wang, R.N. Sun, P.-C. Wang, Self-piercing riveting of wrought magnesium AZ31 sheets, Journal of Manufacturing Science & Engineering 133 (2011), 031009-031001-031009-031009.
• [66] M. Lou, Y. Li, Y. Wang, B. Wang, X. Lai, Influence of resistance heating on self-piercing riveted dissimilar joints of AA6061- T6 and galvanized DP590, Journal of Materials Processing Technology 214 (2014) 2119–2126.
• [67] M. Lou, Y. Li, Y. Li, G. Chen, Behavior and quality evaluation of electroplastic self-piercing riveting of aluminum alloy and advanced high strength steel, Journal of Manufacturing Science and Engineering, Transactions of the ASME 135 (2013).
• [68] R. Neugebauer, R. Mauermann, R. Grützner, Combination of hydroforming and joining, Steel Research International 76 (2005) 939–944.
• [69] W.G. Drossel, M. Jäckel, New die concept for self-pierce riveting materials with limited ductility, Key Engineering Materials 611–612 (2014) 1452–1459.
• [70] V. Fiore, F. Alagna, G. Di Bella, A. Valenza, On the mechanical behavior of BFRP to aluminum AA6086 mixed joints, Composites Part B: Engineering 48 (2013) 79–87.

Uwagi

PL

Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2018)