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Translated from Problemy Prochnosti, No. 4, pp. 6 – 18, July – August, 2017.
The clinching joining of three steel sheets (DC06, DX53D, and H220PD type) was studied by utilization of the finite element method. Clinched joints were also prepared experimentally by joining the above-mentioned steels with the thickness of 0.8 mm (DC06 and DX53D) and 1.0 mm (H220PD). The experimental tool works as single stroke tool, while prepared joints have circular axisymmetric shape, and the rigid die has no flexible segments. Finite element calculations were carried out in ANSYS software under simplified-axisymmetric conditions. Metallographic sections were also prepared from experimentally developed joints to make possible to directly compare the results of simulated and experimental approach. The results of computational approach are discussed and compared to the experimental ones.
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F. Lambiase and A. Di Ilio, “Damage analysis in mechanical clinching: Experimental and numerical study,” J. Mater. Process. Tech., 230, 203–210 (2016). CrossRef
C. Chen, S. Zhao, M. Cui, et al., “An experimental study on the compressing forces for joining Al6061 sheets,” Thin Wall. Struct., 108, 56–63 (2016). CrossRef
T. Jiang, Z.-X. Liu, and P.-Ch. Wang, “Effect of aluminum pre-straining on strength of clinched galvanized SAE1004 steel-to-AA6111-T4 aluminum,” J. Mater. Process. Tech., 215, 193–204 (2015). CrossRef
F. Lambiase, A. Paoletti, and A. Di Ilio, “Advances in mechanical clinching: employment of a rotating tool,” in: Proc. of the 17th Int. Conf. on Sheet Metal (SHEMET17), Vol. 183 (2017), pp. 200–205.
K. Mori, N. Bay, L. Fratini, et al., “Joining by plastic deformation,” CIRP Annals, 62, No. 2, 673–694 (2013). CrossRef
A. A. de Paula, M. T. P. Aguilar, A. E. M. Pertence, and P. R. Cetlin, “Finite element simulations of the clinch joining of metallic sheets,” J. Mater. Process. Tech., 182, 352–357 (2007). CrossRef
Y. Zhou, F. Lan, and J. Chen, “Influence of tooling geometric parameters on clinching joint properties for steel-aluminum hybrid car-body structures,” in: Proc. of the Computer Science and Information Technology (ICCSIT), Vol. 5 (2010), pp. 441–445.
J. Mucha, “The analysis of lock forming mechanism in the clinching joint,” Mater. Design, 32, No. 10, 4943–4954 (2011). CrossRef
T. Sadowski, T. Balawender, and P. Golewski, Technological Aspects of Manufacturing and Numerical Modeling of Clinch-Adhesive Joints, Springer, New York (2015). CrossRef
T. Sadowski, P. Golewski, and E. Zarzeka-Raczkowska, “Damage and failure processes of hybrid joints: Adhesive bonded aluminum plates reinforced by rivets,” Comp. Mater. Sci., 50, No. 4, 1256–1262 (2011). CrossRef
P. Kamble and R. Mahale, “Simulation and parametric study of clinched joint,” Int. Res. J. Eng. Technol., 3, 2730–2734 (2016).
ANSYS 17.0 Documentation, ANSYS Mechanical APDL Element Reference, ANSYS Inc., Canonsburg, PA (2013).
V. Hamel, J. M. Roelandt, J. N. Gacel, and F. Schmit, “Finite element modeling of clinch forming with automatic remeshing,” Comput. Struct., 77, No. 2, 185–200 (2000). CrossRef
P. Siedlaczek, “Numerical analysis and test simulation of clinch forming,” in: Research and Development Directions of Cold Clinch Joints [in Polish], Oficyna Wydawnicza Politechniki Rzeszowskie, Rzeszów (2015).
C. J. Lee, J. M. Lee, H. Y. Ryu, et al., “Design of hole-clinching process for joining of dissimilar materials-A16061-T4 alloy with DP780 steel, hot-pressed 22MnB5 steel, and carbon fiber-reinforced plastic,” J. Mater. Process. Tech., 214, No. 10, 2169 – 2178 (2014). CrossRef
- Finite Element Calculation of Clinching with Rigid Die of Three Steel Sheets
- Springer US
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