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2021 | OriginalPaper | Chapter

Inline Measurement of Process Forces and Development of a Friction Model in Abrasive Flow Machining

Authors : S. Roßkamp, E. Uhlmann

Published in: Production at the leading edge of technology

Publisher: Springer Berlin Heidelberg

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Abstract

Abrasive flow machining is widely used for finishing applications. For every workpiece material, chips are formed by the relative movement between abrasive grains and workpiece surface. Thus, the friction in between is an important parameter to describe these mechanisms. A method for inline measuring of process forces in abrasive flow machining is presented. A sealed, technical device for measuring tangential forces and a device for measuring the static pressure were successfully developed. The results show a strong dependence on processing parameters. The data is used for developing a friction model that takes processing parameters into account. Moreover, the friction model is utilized to implement the local slip of the abrasive media on the workpiece surface in flow simulations. Consequently, process designs of machining tasks will be improved and will contribute to an enhanced quality and process stability. By process simulations, time consuming experiments are reduced in order to reduce costs.

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Balman, C.: Honing apparatus. U.S. Patent 3,039,234 (1962)

Luckey, G.: Method of oliving jewels. U.S. Patent 2,419,687 (1945)

Uhlmann, E., Mihotović, V., Roßkamp, S., Dethlefs, A.: A pragmatic modeling approach in abrasive flow machining for complex-shaped automotive components. Procedia CIRP 5(46), 51–54 (2016)CrossRef

Dong, Z., Ya, G., Liu, J.: Study on machining mechanism of high viscoelastic abrasive flow machining for surface finishing. Proc. Inst. Mech. Eng. Part B J. Eng. IMechE 231(4), 608–617 (2017)CrossRef

Mahalik, N.: Micromanufacturing and Nanotechnology. Springer, Berlin (2006)CrossRef

Jain, V., Kumar, R., Dixit, P., Sidpara, A.: Investigations into abrasive flow finishing of complex workpieces using FEM. Wear 267(1–4), 71–80 (2009)CrossRef

Roßkamp, S., Uhlmann, E., Hofmann, R., Gröger, S.: Shape alterations and their holistic geometrical representation in abrasive flow machining. In: Wulfsberg, J., Hintze, W., Behrens, B. (eds.) Production at the Leading Edge of Technology, pp. 249–258. Springer, Berlin (2019)

Tzeng, H., Yan, B., Hsu, R., Chow, H.: Finishing effect of abrasive flow machining on micro slit fabricated by wire-EDM. Int. J. Adv. Manuf. Technol. 34(7–8), 649–656 (2007)CrossRef

Hashimoto, F., Yamaguchi, H., Krajnik, P., Wegener, K., Chaudhari, R., Hoffmeister, H., Kuster, F.: Abrasive fine-finishing technology. CIRP Ann. 65(2), 597–620 (2016)CrossRef

10.

Gorana, V., Jain, V., Lal, G.: Forces prediction during material deformation in abrasive flow machining. Wear 260(1–2), 128–139 (2006)CrossRef

11.

Li, J., Su, N., Wei, L., Zhang, X., Yin, Y., Zhao, W.: Study on the surface forming mechanism of the solid-liquid two-phase grinding fluid polishing pipe based on large eddy simulation. Proc. Inst. Mech. Eng. Part B J. Eng. Manuf. 233(14), 2505–2514 (2019)CrossRef

12.

Fang, L., Sun, K., Cen, Q.: Particle movement patterns and their prediction in abrasive flow machining. Tribotest 13(4), 195–206 (2007)CrossRef

13.

Murali, K., Raju, H.: Extrusion honed surface characteristics of inconel 625 fabricated by EDM for square shape. Int. J. Eng. Res. Appl. 4(6), 68–72 (2014)

14.

Fang, L., Zhao, J., Li, B., Sun, K.: Movement patterns of ellipsoidal particle in abrasive flow machining. J. Mater. Process. Technol. 209(20), 6048–6056 (2009)CrossRef

15.

Sankar, M., Jain, V., Ramkumar, J.: Experimental investigations into rotating workpiece abrasive flow finishing. Wear 267(1–4), 43–51 (2009)CrossRef

16.

M’Saoubi, R., Outeiro, J., Chandrasekaran, H., Dillon, O., Jawahir, I.: A review of surface integrity in machining and its impact on functional performance and life of machined products. Int. J. Sustain. Manuf. 1(1/2), 203–236 (2008)

17.

Gorana, V., Jain, V., Lal, G.: Experimental investigation into cutting forces and active grain density during abrasive flow machining. Int. J. Mach. Tools Manuf. 44(2–3), 201–211 (2004)CrossRef

18.

Cozza, R., Tanaka, D., Souza, R.: Friction coefficient and abrasive wear modes in ball-cratering tests conducted at constant normal force and constant pressure—preliminary results. Wear 267(1–4), 61–70 (2009)CrossRef

19.

Coulomb, C.: Théorie des machines simples. Memoire de Mathematique et de Physics de l’Academie Royal, 161–342 (1785)

20.

Neto, C., Evans, D., Bonaccurso, E., Butt, H., Craig, V.: Boundary slip in Newtonian liquids: a review of experimental studies. Rep. Prog. Phys. 68(12), 2859–2897 (2005)CrossRef

21.

DIN 53019-1: Viskosimetrie: Messung von Viskositäten und Fließkurven mit Rotationsviskosimetern. Grundlagen und Messgeometrie. Beuth, Berlin (2008)

22.

Krieger, I., Dougherty, T.: A mechanism for non-Newtonian flow in suspensions of rigid spheres. Trans. Soc. Rheo. 3(1), 137–152 (1959)CrossRef

23.

Metzner, A., Reed, J.: Flow of non-Newtonian fluids—correlation of the laminar, transition, and turbulent-flow regions. Am. Inst. Chem. Eng. J. 1(4), 434–440 (1955)CrossRef

24.

Kistler Gruppe: SlimLine Sensoren (SLS). Messen von dynamischen und quasistatischen Druckkräften, 0 … 3 kN bis 0 … 80 kN. Winterthur, Schweiz (2020)

25.

Jain, R., Jain, V.: Specific energy and temperature determination in abrasive flow machining process. Int. J. Mach. Tools Manuf. 12(41), 1689–1704 (2001)CrossRef

26.

Fang, L., Zhao, J., Sun, K., Zheng, D., Ma, D.: Temperature as sensitive monitor for efficiency of work in abrasive flow machining. Wear 266(7–8), 678–687 (2009)CrossRef

27.

Böhme, G.: Strömungsmechanik nicht-newtonischer Fluide, 2nd edn. Vieweg, Wiesbaden (2000)CrossRef

Title: Inline Measurement of Process Forces and Development of a Friction Model in Abrasive Flow Machining
Authors: S. Roßkamp
E. Uhlmann
Publisher: Springer Berlin Heidelberg
Book: Production at the leading edge of technology
Print ISBN: 978-3-662-62137-0

Electronic ISBN: 978-3-662-62138-7

Copyright Year: 2021
DOI: https://doi.org/10.1007/978-3-662-62138-7_34

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