10.22190/FUME171002020F

367

381

New constructive solutions of the winches for single-row radial multi-layered cable smooth winding/unwinding are described. Two new structural solutions of winches are defined. The nonlinear phenomenon of a cable smooth winding/unwinding process on the winch by using one of the two proposed constructive solutions is defined and analyzed. To facilitate understanding of this concept, the cable winding/unwinding process on only one winch is analyzed. The obtained variables which characterize the kinematics of the cable smooth winding/unwinding process are nonlinear and smooth. This result is important because the systems for the smooth cable winding/unwinding process on the winch could be parts of any cable driven mechanism. These systems can be used in various fields of human activity. For the verification of the presented theoretical contributions, a novel software package named SMOWIND – OW has been developed using MATLAB.

Analysis, Kinematics, Cable Winding/unwinding, Winch Construction, Simulation

United Nations, 1981, Cable Logging Systems, FOOD AND AGRICULTURE ORGANIZATION OF THE UNITED NATIONS, Roma.

Samset, I., 1985, Winch and cable systems, Series Forestry Sciences, Vol. 18, Springer Netherlands.

Abdel-Rahman, E.M., Nayfeh, A.H., Masoud, Z.N., 2003, Dynamics and Control of Cranes: A Review, Journal of Vibration and Control, 9, pp. 863-908.

Padfield, D.G., 1958, The motion and tension of an unwinding thread. I, Proc. R. Soc. Lond. A, 245(1242), pp. 382–407.

Fraser, W.B., Ghosh, T.K., Batra, S.K., 1992, On Unwinding Yarn from a Cylindrical Package, Proc. R. Soc. Lond. A, 436(1898), pp. 479-498.

Clark, J.D., Fraser, W.B., Stump, D.M., 2001, Modelling of tension in yarn package unwinding, Journal of Engineering Mathematics, 40, pp. 59–75.

Imanishi, E., Nanjo, T., Kobayashi, T., 2009, Dynamic simulation of wire rope with contact, Journal of Mechanical Science and Technology, 23, pp. 1083-1088.

Szczotka, M., Wojciech, S., Maczynski, A., 2007, Mathematical model of a pipelay spread, The Archive of Mechanical Engineering, 54(1), pp. 27-46.

Lee, J-W., Kim, K-W., Kim, H-R., Yoo, W-S., 2012, Prediction of unwinding behaviors and problems of cables from inner-winding spool dispensers, Nonlinear Dyn., 67, pp.1791–1809.

Filipovic, M., Djuric, A., Kevac, Lj., 2015, The significance of adopted Lagrange principle of virtual work used for modeling aerial robots, Applied Mathematical Modelling, 39(7), pp. 1804-1822.

von Zietzwitz, J., Fehlberg, L., Bruckmann, T., Vallery, H., 2013, Use of passively guided deflection units and energy-storing elements to increase the application range of wire robots, in Bruckmann, T., Pott, A. (Eds.), Cable-Driven Parallel Robots, Mechanisms and Machine Science, vol. 12, pp. 167-184.

Kevac, Lj., Filipovic, M., 2017, Mathematical Model of Cable Winding/Unwinding System, Journal of Mechanics, DOI: https://doi.org/10.1017/jmech.2017.59,

Kevac, Lj., Filipovic, M., Rakic, A., 2017, Dynamics of the process of the cable winding (unwinding) on the winch, Applied Mathematical Modelling 48, pp. 821-843.

Aref, M.M., Taghirad, H.D., 2008, Geometrical workspace analysis of a cable-driven redundant parallel manipulator: KNTU CDRPM. Proc. IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), pp. 1958-1963.