Please use this identifier to cite or link to this item: http://ena.lp.edu.ua:8080/handle/ntb/49621
Title: Elements of the theory of closed-loop mechanisms formed by rolling bodies without kinematic sliding
Authors: Vorobyov, Mykola
Prokopenko, Denis
Affiliation: Ivano-Frankivsk National University of Oil and Gas
Bibliographic description (Ukraine): Vorobyov M. Elements of the theory of closed-loop mechanisms formed by rolling bodies without kinematic sliding / Mykola Vorobyov, Denis Prokopenko // Ukrainian Journal of Mechanical Engineering and Materials Science. — Lviv : Lviv Politechnic Publishing House, 2019. — Vol 5. — No 1. — P. 73–84.
Bibliographic description (International): Vorobyov M. Elements of the theory of closed-loop mechanisms formed by rolling bodies without kinematic sliding / Mykola Vorobyov, Denis Prokopenko // Ukrainian Journal of Mechanical Engineering and Materials Science. — Lviv : Lviv Politechnic Publishing House, 2019. — Vol 5. — No 1. — P. 73–84.
Is part of: Український журнал із машинобудування і матеріалознавства, 1 (5), 2019
Ukrainian Journal of Mechanical Engineering and Materials Science, 1 (5), 2019
Journal/Collection: Український журнал із машинобудування і матеріалознавства
Issue: 1
Volume: 5
Issue Date: 20-Mar-2019
Publisher: Видавництво Львівської політехніки
Lviv Politechnic Publishing House
Place of the edition/event: Львів
Lviv
Keywords: mechanism
rolling bodies
bearing
kinematic sliding
sliding friction
bearing
Number of pages: 12
Page range: 73-84
Start page: 73
End page: 84
Abstract: In the modern industry, it is impossible to do without high-tech equipment, for the designing of which the practical experience and experience of scientists are used. The main principles of engineering mechanics are based on the improvement of technical processes that promote creating certain conditions for the development of the manufacturing industry. An innovative approach to solving the problems of designing and creating any equipment makes it possible to combine new technologies and scientific and technical studies. When designing process equipment, there is a need not only to improve the existing types but also to search for new principles for connecting the supporting elements. It is important to create the right conditions for the effective functioning of reliable mechanisms. The main elements of the process equipment are the supporting ones. Among them, the bearings are the most important elements. Their reliable and long-term operation depends on the structural features of the supports. When designing the bearing units, they take into account the purpose of the mechanism, its operating conditions, the magnitude and direction of the loadings applied to the bearings, the required resource, the rotation frequency, the temperature and the state of the environment. In real bearings, there are no two fixed guides, and the separation is ensured by an intermediate element, which is connected by sliding friction. Besides, modern oil and gas equipment also usesradial supports through which a working fluid circulates with impurities of abrasive particles, which quickly destroys this element. Therefore, there is a need to create a scientific basis for the design of fundamentally new modern bearings. The purpose of the work is to find the optimum range of existence of closed-loop mechanisms formed by rolling bodies without kinematic sliding and to obtain the analytical dependences that relate the geometric parameters of the bearings to the separation by the rolling bodies in the absence of sliding. In this case, all three drive types are considered: from the outer or inner clip or the two clips together. To ensure the workability of all types of radial bearings, a range of specific basic conditions should be met. Given the significant advantages of these types of mechanisms, the challenge arises for their further study, with a view to wide implementation and practical application. The results can be useful for designing support elements for equipment used in many manufacturing fields.
URI: http://ena.lp.edu.ua:8080/handle/ntb/49621
Copyright owner: © Національний університет “Львівська політехніка”, 2019
© Vorobyov M., Prokopenko D., 2019
References (Ukraine): 1. A. V. Haidamaka, “Udoskonalennia konstruktcii separatoriv dlia pidshypnykiv pidvyshchenoho tekhnichnoho rivnia” [“Improvement of design of separators for bearings of high technical level”], Vostochnojevropejskij zhurnal peredovykh technologij [Eastern-European Journal of Enterprise Technologies], vol. 1, no. 6 (84), pp. 53–62, 2016. [in Ukrainian].
2. E. Simson, V. Ovcharenko, and M. Trokhman, “Modelirovanije i optimizacija iznosa v zone tortcevoho kontakta skol’zhenija rolikovykh podshipnikov” [“Modeling and optimization of wear in the face contact zone of roller bearings during sliding”], MicroCA: Sektcija – Matematychne modeliuvannia v mekhanitci i systemakh [MicroCA: Section – Mathematical modeling in mechanics and systems], vol. 2, pp. 35–36, 2009. [in Russian].
3. H. Fujiwara, T. Tsujimoto, and K. Yamauchi, “Optimized radius of roller large end face in tapered roller bearings”, NTN Technical review, vol. 77, pp. 96–104, 2009.
4. T. Ozu, “High load capacity cylindrical roller bearings”, NTN Technical review, vol. 74, pp. 90–95, 2006.
5. T. Ueno, and T. Matsushita, “Extremely high load capacity tapered roller bearings”, NTN Technical review, vol. 77, pp. 73–80, 2009.
6. N. Carlisle, “The Amazing Rolamite – It Opens the Door for 1000 Inventions,” Popular Mechanics, vol. 129, no. 2, pp. 92–95, February 1968.
7. M. S. Vorobyov, and D. P. Prokopenko, Suchasne pidhruntia vdoskonalennia teorii mekhanismiv [The modern basis for improving the theory of mechanisms]. Ivano-Frankivsk, Ukraine: IFNTUNG Publ., 2019. [in Ukrainian].
8. D. F. Wilkes, “Roller-band devices”, U.S. Patent 3 452 175, June 24, 1969.
9. “Rolomite reduces friction in devices,” Tribology, vol. 1, issue 2, pp. 71–73, March 1968.
10. M. S. Vorobyov, and D. P. Prokopenko, “Elektromahnitnyi hidronasos kotchennia” [“A hydraulic roller pump with electromagnetic actuator”], UA Patent 108050, March 10, 2015. [in Ukrainian].
11. M. S. Vorobyov, V. I. Vekeryk, and O. A. Vorobyov, “Rolykovyi litchyl’nyk” [“Roller counter”], UA Patent 68800А, August 16, 2004. [in Ukrainian].
12. M. S. Vorobyov, Perspektyvni napriamky vdoskonalennia teorii mashyn [Promising directions for improving the theory of machines]. Ivano-Frankivsk: IFNTUNG Publ., 2015. [in Ukrainian].
13. K. Ragulskis, et. al., Mekhanismy tipa rolamajt [Rolamite-type mechanisms]. Vilnius, Lithuania: Mokslas Publ., 1990. [in Russian].
References (International): 1. A. V. Haidamaka, "Udoskonalennia konstruktcii separatoriv dlia pidshypnykiv pidvyshchenoho tekhnichnoho rivnia" ["Improvement of design of separators for bearings of high technical level"], Vostochnojevropejskij zhurnal peredovykh technologij [Eastern-European Journal of Enterprise Technologies], vol. 1, no. 6 (84), pp. 53–62, 2016. [in Ukrainian].
2. E. Simson, V. Ovcharenko, and M. Trokhman, "Modelirovanije i optimizacija iznosa v zone tortcevoho kontakta skol’zhenija rolikovykh podshipnikov" ["Modeling and optimization of wear in the face contact zone of roller bearings during sliding"], MicroCA: Sektcija – Matematychne modeliuvannia v mekhanitci i systemakh [MicroCA: Section – Mathematical modeling in mechanics and systems], vol. 2, pp. 35–36, 2009. [in Russian].
3. H. Fujiwara, T. Tsujimoto, and K. Yamauchi, "Optimized radius of roller large end face in tapered roller bearings", NTN Technical review, vol. 77, pp. 96–104, 2009.
4. T. Ozu, "High load capacity cylindrical roller bearings", NTN Technical review, vol. 74, pp. 90–95, 2006.
5. T. Ueno, and T. Matsushita, "Extremely high load capacity tapered roller bearings", NTN Technical review, vol. 77, pp. 73–80, 2009.
6. N. Carlisle, "The Amazing Rolamite – It Opens the Door for 1000 Inventions," Popular Mechanics, vol. 129, no. 2, pp. 92–95, February 1968.
7. M. S. Vorobyov, and D. P. Prokopenko, Suchasne pidhruntia vdoskonalennia teorii mekhanismiv [The modern basis for improving the theory of mechanisms]. Ivano-Frankivsk, Ukraine: IFNTUNG Publ., 2019. [in Ukrainian].
8. D. F. Wilkes, "Roller-band devices", U.S. Patent 3 452 175, June 24, 1969.
9. "Rolomite reduces friction in devices," Tribology, vol. 1, issue 2, pp. 71–73, March 1968.
10. M. S. Vorobyov, and D. P. Prokopenko, "Elektromahnitnyi hidronasos kotchennia" ["A hydraulic roller pump with electromagnetic actuator"], UA Patent 108050, March 10, 2015. [in Ukrainian].
11. M. S. Vorobyov, V. I. Vekeryk, and O. A. Vorobyov, "Rolykovyi litchyl’nyk" ["Roller counter"], UA Patent 68800A, August 16, 2004. [in Ukrainian].
12. M. S. Vorobyov, Perspektyvni napriamky vdoskonalennia teorii mashyn [Promising directions for improving the theory of machines]. Ivano-Frankivsk: IFNTUNG Publ., 2015. [in Ukrainian].
13. K. Ragulskis, et. al., Mekhanismy tipa rolamajt [Rolamite-type mechanisms]. Vilnius, Lithuania: Mokslas Publ., 1990. [in Russian].
Content type: Article
Appears in Collections:Ukrainian Journal of Mechanical Engineering And Materials Science. – 2019. – Vol. 5, No. 1



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