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International Journal of Material Forming

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12-07-2018 | Original Research

End flare of linear flow split profiles

Published in: International Journal of Material Forming | Issue 3/2019

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Abstract

One approach to design load optimized structures is the use of bifurcations. Linear flow splitting is a continuous sheet-bulk metal forming process, whereby bifurcated profiles are manufactured without joining or external heat supply. By roll forming linear flow split profiles, a wide spectrum of profile geometries can be realized, e.g. multi-chamber-profiles. Those profiles often require high dimensional accuracy to ensure their functionality. During roll forming, process related residual stresses are induced, which are released when the profiles are cut to length. Thereby increased deformation at the profile ends occurs, also known as end flare. End flare of bifurcated profiles has not been investigated so far. The aim of this research is to investigate end flare after roll forming of linear flow split profiles. Therefore, end flare after roll forming of a conventional sheet metal and a linear flow split profile is compared. The effect of residual stresses induced by linear flow splitting as well as the effect of additional geometrical stiffness due to the bifurcations on the development of end flare are examined. It is found that the residual stresses induced by linear flow splitting have no significant effect on end flare. However, the geometrical bifurcation affects the roll forming process, leading to higher residual stresses in the flange, which significantly affect the magnitude and the direction of end flare.

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Groche P, Bruder E, Gramlich S (2017) Manufacturing integrated design – sheet metal product and process innovation, Springer international publishing AG

Groche P, Ringler J, Vucic D (2007) New forming processes for sheet metal with large plastic deformation. Key Eng Mater 344:251–258CrossRef

Groche P, Vucic D, Jöckel M (2006) Basics of linear flow splitting. J Mater Process Technol 183:249–255CrossRef

Groche P, Vucic D (2006) Multi-chambered profiles made from high-strength sheets. Production Engineering, Annals of the WGP 3:67–70

Halmos G (2005) Roll forming handbook. CRC Press, Boca RatonCrossRef

Sweeney K, Grunewald U (2003) The application of roll forming for automotive structural parts. J Mater Process Technol 132(1-3):9–15CrossRef

Moneke M, Groche P (2017) Counter measures to effectively reduce end flare, AIP Conference Proceedings 1896, pp. 020006–1 – 020006–6

Lange K (1990) Handbook of metal forming – volume 3, Society of Manufacturing Engineers

Zhu S, Panton S, Duncan J (1996) The effects of geometric variables in roll forming a channel section. Proceedings of The Institution of Mechanical Engineers Part B-journal of Engineering Manufacture - PROC INST MECH ENG B-J ENG MA 210(2):127–134CrossRef

10.

Abeyrathna B, Rolfe B, Hodgson P, Weiss M (2017) Local deformation in roll forming. Int J Adv Manuf Technol 88(9–12):2405–2415CrossRef

11.

Bhattacharyya D, Smith P, Yee C, Collins I (1984) The prediction of deformation length in cold roll-forming. J Mech Work Technol 9(2):181–191CrossRef

12.

Abeyrathna B, Rolfe B, Weiss M (2017) The effect of process and geometric parameters on longitudinal edge strain and product defects in cold roll forming. Int J Adv Manuf Technol 92(1–4):746–754

13.

Paralikas J, Salonitis K, Chrydssolouris G (2009) Investigation of the effects of main roll forming process parameters on quality for a V-section profile from AHSS. Int J Adv Manuf Technol 44(3–4):223–237CrossRef

14.

Han Z, Liu C, Lu W, Ren L (2001) The effects of forming parameters in the roll-forming of a channel section with an outer edge. J Mater Process Technol 116(2-3):205–210CrossRef

15.

Saffe S, Nagamachi T, Ona H (2015) Mechanism of end deformation after cutting of light Gauge Channel steel formed by roll forming. Mater Trans 56(2):187–192CrossRef

16.

Quach W, Teng J, Chung K (2004) Residual stresses in steel sheets due to coiling and uncoiling - a closed-form analytical solution. Eng Struct 26(9):1249–1259CrossRef

17.

Weiss M, Abeyrathna B, Rolfe B, Abee A, Wolfkamp H (2017) Effect of coil set on shape defects in roll forming steel strip. J Manuf Process 25:8–15CrossRef

18.

Weiss M, Rolfe B, Hodgson P, Yang C (2012) Effect of residual stress on the bending of aluminium. J Mater Process Technol 212(4):877–883CrossRef

19.

Abvabi RB, Hodgson P, Weiss M (2015) The influence of residual stress on a roll forming process. Int J Mech Sci 101-102:124–136CrossRef

20.

Ludwig C, Hammen V, Groche P, Kaune V, Müller C (2013) Manufacturing of quality optimized linear flow split parts by variation of fast modifiable process parameters and their influence on material characteristics. Mat-wiss u Werkstofftech 44(7):601–611CrossRef

21.

Groche P, Monnerjahn V, Özel M, Yu Y (2017) Remote joining by plastic deformation in the process of linear flow splitting. J Mater Process Technol 246:262–266CrossRef

22.

Görtan M, Vucic D, Groche P, Livatyali H (2009) Roll forming of branched profiles. J Mater Process Technol 209(17):5837–5844CrossRef

23.

Bruder E, Ahmels L, Niehuesbernd J, Müller C (2017) Manufacturing-induced material properties of linear flow split and linear bend split profiles. Mat-wiss u Werkstofftech 48(1):41–52CrossRef

24.

Liu C, Zhou W, Fu X, Chen G (2015) A new mathematical model for determining the longitudinal strain in cold roll forming process. Int J Adv Manuf Technol 79(5–8):1055–1061CrossRef

25.

Görtan O, Ludwig C, Groche P, Livatyali H (2009) Finite Element Simulation of Roll Forming Process of Branched Profiles, 5^th International Conference and Exhibition on Design and Production of Machines and Dies/Molds, 18–21 June 2009, Kusadasi, Aydin, Turkey

26.

Wagner C, Gramlich S, Monnerjahn V, Groche P, Kloberdanz H (2015) Technology pushed process and product innovation – joining by linear flow splitting. Procedia CIRP 37:83–88CrossRef

27.

Monnerjahn V, Lobers M, Groche P (2017) Simultaneous Forming and Joining by Linear Flow Splitting – From Basic Mechanisms to the Continuous Manufacturing Line, Procedia Engineering, Vol. 207, pp. 962–967

28.

Rullmann F, Abrass A, Kruse M, Groche P (2012) The Cut-Expand-Method for the FE-simulation of steady-state rolling processes, Metal Forming. Wiley-VCH Verlag GmbH & Co., Weinheim, Germany

29.

Rullmann F, Bauer O, Landersheim V, Groche P, Hanselka H (2012) Numerische durchgängige Prozessketten- bewertung mittels FEM, in 4. Zwischenkolloquium des Sonderforschungsbereich 666:109–120

30.

Müller C, Bohn T, Bruder E, Bruder T, Landersheim V, Dsoki C, Groche P, Veleva D (2007) Severe plastic deformation by linear flow splitting. Mat-wiss u Werkstofftech 38(10):842–854CrossRef

31.

Bruder E, Bohn T, Müller C (2008) Properties of UFG HSLA Steel Profiles Produced by Linear Flow Splitting. Mater Sci Forum 584–586:661–666CrossRef

Title: End flare of linear flow split profiles
Publication date: 12-07-2018
Published in: International Journal of Material Forming / Issue 3/2019
Print ISSN: 1960-6206
Electronic ISSN: 1960-6214
DOI: https://doi.org/10.1007/s12289-018-1426-3

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