Abstract
This paper introduces an original, fully compliant universal joint design. Many mechanisms with different dimensions are investigated. The proposed design is a single-piece compliant mechanism. The number of flexible segments is a design parameter determined as a function of transferred torque. The mechanism can be produced by additive manufacturing from polylactic acid and polypropylene. It is possible to produce the proposed design as a single piece of polypropylene by additive manufacturing and injection molding methods; thus, it has the advantage of ease in manufacturing. The proposed design’s bending and torque transmission capacities are determined by applying analytical and numerical methods. Furthermore, a prototype was manufactured, and experiments were conducted. It is verified that the results of the experiments are consistent with theoretical approaches. The proposed fully compliant universal joint design has a great potential in the industry.
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References
F. Schmelz, C. H. Seherr-Thoss and E. Aucktor, Universal jointed driveshafts for transmitting rotational movements, In Universal Joints and Driveshafts, Springer (1992) 1–28.
C. H. Chiang, Kinematics of Spherical Mechanisms, United Kingdom: Cambridge University Press (1988).
D. F. Machekposhti, N. Tolou and J. L. Herder, A review on compliant joints and rigid-body constant velocity universal joints towards the design of compliant homokinetic couplings, J. of Mechanical Design, 137(3) (2015) 032301.
D. F. Machekposhti, N. Tolou and J. L. Herder, The scope for a compliant homokinetic coupling based on review of compliant joints and rigid-body constant velocity universal joints, Proceeding ASME IDETC/CIE 36th Mechanisms and Robotics Conference, Chicago, 45035 (2012) 379–392.
A. H. Rzeppa, Constant Velocity Universal Joint, United State Patent, 1665280 (1928).
I. H. Culver, Constant Velocity Universal Joint, United States Patent, 3477249 (1969) 51.
G. A. Thompson, Constant Velocity Coupling and Control System Therefor, United States Patent, 7144326 (2006).
H. Kocabas, Deisgn and analysis of a spherical constant velocity coupling mechanism, J. of Mechanical Design, 129 (2007) 991–998.
M. Yaghoubi and A. Sanaeifar, Design, manufacture and evaluation of a new flexible constant velocity mechanism for transmission of power between parallel shafts, Journal of Mechanical Science and Technology, 29 (2015) 3357–3361.
L. L. Howell and A. Midha, A method for the design of compliant mechnaisms with small length flexural pivots, ASME J. of Mechnaical Design, 1(116) (1994) 280–290.
L. L. Howell, Compliant Mechanisms, New York: John Wiley & Sons, Inc. (2001).
A. Midha, T. W. Norton and L. L. Howell, On the nomenclature, classification and abstractions of compliant mechanisms, ASME J. of Mechanical Design, 1(116) (1994) 270–279.
B. Trease, Y. Moon and S. Kota, Design of large-displacement joints, ASME J. of Mechanical Design, 127 (2005) 788–798.
L. Rubbert, S. Caro, J. Gangloff and P. Renaud, Using singulariities of parallel manipulators to enhance the rigid-body replacement, ASME J. of Mechanical Design, 136 (2014) 051010.
E. Tanık and V. Parlaktaş, Compliant cardan universal joint, J. of Mechanical Design, 134 (2012) 021011.
Ç. M. Tanık, V. Parlaktaş, E. Tanık and S. Kadıoğlu, Steel compliant cardan universal joint, Mechanism and Machine Theory, 92 (2015) 171–183.
D. F. Machekposhti, N. tolou and J. L. Herder, A fully compliat constant velocity universal joint, International Design Engineering Technical Conference & Computers and Information in Engineering Conference, Boston, Massachusetts, 57120 (2015) V05AT08A014.
D. F. Machekposhti, N. tolou and J. L. Herder, A fully compliant homokinetic coupling, ASME J. of Mechanical Design, 140(1) (2018) 012301.
V. Parlaktaş and E. Tanık, Single piece compliant spatial slider-crank mechanism, Mechanism and Machine Theory, 81 (2014) 1–10.
R. G. Budynas and J. K. Nisbett, Shigley’s Mechanical Engineering Design, New York: McGraw-Hill Education (2015).
BASF, Technical Data Sheet for Ultrafuse PP Version: 3.2 (2019).
M. Garcia, K. McFall and A. Tekes, Trajectory control of planar closed chain, Journal of Mechanical Science and Technology, 35(4) (2021) 1711–1719.
A. Tekes, H. Lin and K. McFall, Design, modelling and experimentation of a novel compliant translational dwell mechanism, Journal of Mechanical Science and Technology, 33(7) (2019) 3137–3145.
V. Vega, J. Clements, T. Lam, A. Abad, B. Fritz, N. Ula and O. S. Es-Said, The effect of layer orientation on the mechanical properties and microstructure of a polymer, J. of Materials Engineering and Performance, 20(6) (2011) 978–988.
V. Kovan, G. Altan and E. S. Topal, Effect of layer thickness and print orientation on strength of 3D printed and adhesively bonded single lap joints, J. of Mechanical Science and Technology, 31(5) (2016) 2197–2201.
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Appendix. Supplementary data https://www.youtube.com/watch?v=jRGxo9E9lpE
Raşit Karakuş works as a teaching assistant at Hacettepe University. He received his Ph.D. in Mechanical Engineering from Hacettepe University. His research interests include compliant mechanisms and electric vehicles.
Çağıl Merve Tanık works as an engineer in the Academic Relations Department at ASELSAN Academy. She received her Ph.D. in Mechanical Engineering from Middle East Technical University. Her research interests include compliant mechanisms and solid mechanics.
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Karakuş, R., Tanık, Ç.M. Compliant universal joint with preformed flexible segments. J Mech Sci Technol 36, 5639–5648 (2022). https://doi.org/10.1007/s12206-022-1026-5
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DOI: https://doi.org/10.1007/s12206-022-1026-5