STUDY AND DEVELOPMENT OF THE TECHNOLOGY FOR HARDENING ROPE BLOCKS BY REELING
Creators
- 1. Khmelnytskyi National University
- 2. Mykolaiv National Agrarian University
Description
The study of the efficiency of hardening the parts working in spalling conditions through reeling with rollers were performed with the help of physical simulation and showed the high effect of hardening cast steels (a 10- to 14-fold increase in durability). The depth and degree of work hardening during plastic deformation of the surface layer were studied by the method of regression analysis. It was found that the 95-% confidence intervals for the depth of work hardening calculated from the results of measurements of yield strength make up 11‒36 % of the hardening depth and 32‒75 % by the hardness measurements. Electrography examination has shown that an increase in the degree of work hardening when reeling with a needle roller manifests itself in a higher dislocation density and cell size decrease in the substructure of ferrite grains. Diffusion of chemical elements in the surface layer in the process of surface deformation was studied with an analysis of the change of the surface microhardness. It was established that the content of Cr and C decreased by 20‒30 % in the transition zone and increased to 10‒15 % in the hardened layer. The main mechanism of diffusion during SFW is the dislocation density gradient. The process of the contact friction surface wear during reeling with consideration of slippage was investigated. It was proved that roughness of the friction surfaces affects the coefficient of friction and the rate of tribo-contact wear during reeling with slippage. For example, with a decrease in surface roughness after reeling with rollers, coefficient of friction for the lubricated surfaces decreases.
A procedure for determining conditions of reeling with a wedge roller was developed. A method, technology, and a device for reeling the rope blocks with a wedge roller were developed to provide low roughness and high degree of work hardening of the surface. Optimal reeling conditions were found due to experiment planning using the steep convergence method.
The obtained results of calculations will serve as initial data in designing working elements of the reeling devices and developing technological processes for strengthening parts. The conducted studies will find their future use in evaluation of the wear processes taking into account slippage of the «rope block – rope» friction couple
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Study and development of the technology for hardening rope blocks by reeling.pdf
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Additional details
References
- Babei, Y. I., Butakov, B. I., Sysoev, V. G. (1995). Surface hardening of metals. Kyiv: Scientific Opinion, 256.
- Kuzmenko, A. G., Lyubin, A. G. (2008). Contact mechanics and calculations on the wear of sliding supports. Khmelnytsky: KhNU, 550.
- Kindrachuk, M. V., Labunets, V. F., Pasheechko, M. I., Korbut, Y. V. (2009). Tribology. Kyiv: NAU-druk, 392.
- Kindrachuk, M. V., Kornienko, A. O., Fedorchuk, S. V., Tisov, O. V. (2006). Stress-deformed state of composite material loaded with friction and temperature. Problems of tribology, 1, 153–157.
- Aulin, V., Warouma, A., Lysenko, S., Kuzyk, A. (2016). Improving of the wear resistance of working parts agricultural machinery by the implementation of the effect of self-sharpening. International Journal of Engineering & Technology, 5 (4), 126–130. doi: 10.14419/ijet.v5i4.6386
- Kuzmenko, A. G., Dicha, O. V. (2007). Contact, friction and wear of oiled surfaces. Khmelnitsky: KhNU, 344.
- Braude, В. I., Gohberg, M. M., Zvyagin, I. E. et. al.; Gohberg, M. M. (Ed.) (1988). Handbook for cranes. Vol. 1. Characteristics of materials and loads. Basics of calculation of cranes, their drives and metal constructions. Moscow: Mechanical Engineering, 536.
- Voloshin, V. I. (1986). Influence of wear of the blocks on the work of lifting ropes. Pod'emno-transportnoe oborudovanie, 17, 65–66.
- Chernets, M. V. (2015). Prediction of the life of a sliding bearing based on a cumulative wear model taking into account the lobing of the shaft contour. Journal of Friction and Wear, 36 (2), 163–169. doi: 10.3103/s1068366615020038
- Soldatenkov, I. A. (2010). Evolution of contact pressure during wear of the coating in a thrust sliding bearing. Journal of Friction and Wear, 31 (2), 102–106. doi: 10.3103/s1068366610020029
- Mezrin, A. M. (2009). Determining local wear equation based on friction and wear testing using a pin-on-disk scheme. Journal of Friction and Wear, 30 (4), 242–245. doi: 10.3103/s1068366609040035
- Togawa, K., Arai, S., Uwatoko, M. (2012). 104 Influence of Traction Sheave P.C.D. Difference on Sheave and Rope. The Proceedings of the Elevator, Escalator and Amusement Rides Conference, 2011, 31–34. doi: 10.1299/jsmeearc.2011.31
- Ryu, J. B., Chae, Y. H., Kim, S. S. (2005). A Fundamental Study of the Tribological Characteristics of Sheave Steel against a Wire Rope. Advances in Fracture and Strength, 1382–1387. doi: 10.4028/0-87849-978-4.1382
- Dykha, A. V., Kuzmenko, A. G. (2015). Solution to the problem of contact wear for a four-ball wear-testing scheme. Journal of Friction and Wear, 36 (2), 138–143. doi: 10.3103/s1068366615020051
- Dykha, A., Aulin, V., Makovkin, O., Posonskiy, S. (2017). Determining the characteristics of viscous friction in the sliding supports using the method of pendulum. Eastern-European Journal of Enterprise Technologies, 3 (7 (87)), 4–10. doi: 10.15587/1729-4061.2017.99823
- Butakov, B. I., Shebanin, V. S., Butakova, G. S., Marchenko, D. D. (2008). Pat. No. 93252 UA. A method of finishing and strengthening the processing of surfaces of the bodies of rotation of a complex profile and a device for its implementation. IPC V 24 V 39/04. No. a200815098; declareted: 29.12.2008; published: 25.01.2011, Bul. No. 2.
- Butakov, B. I., Shebanin, V. S., Butakova, G. S., Marchenko, D. D. (2010). Pat. No. 2493954 RF. A device for finishing and strengthening the surfaces of bodies of rotation of a complex profile. IPC V 39/04, B 21 N 1/22. No. 2010147733/02; declareted: 22.11.2010; published: 27.09.2013, Bul. No. 27.
- Butakov, B. I., Marchenko, D. D. (2013). Promoting contact strength of steel by rolling. Journal of Friction and Wear, 34 (4), 308–316. doi: 10.3103/s106836661304003x
- Erdonmez, C., Imrak, C. (2009). Modeling and numerical analysis of the wire strand. Journal of Naval Science and Engineering, 5 (1), 30–38.