Principles of design of specialized technological equipment
 
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VOLODYMYR DAHL EAST UKRAINIAN NATIONAL UNIVERSITY
 
 
Submission date: 2021-12-19
 
 
Final revision date: 2022-02-15
 
 
Acceptance date: 2022-02-17
 
 
Online publication date: 2022-02-18
 
 
Publication date: 2022-02-18
 
 
Corresponding author
Oleksiy Romanchenko   

VOLODYMYR DAHL EAST UKRAINIAN NATIONAL UNIVERSITY
 
 
Diagnostyka 2022;23(1):2022109
 
KEYWORDS
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ABSTRACT
The paper presents a universal principle of design of flexible schemes of specialized technological equipment and a modular principle of design of construction and elements of special technological equipment. The construction elements of equipment, which allow changing the linear dimensions of this equipment in a wide range are designed. The application of designed elements for changing one or several linear dimensions of the equipment is possible in a complex and independently of each other. The possibility of application of proposed design changes of equipment with the preservation of the required strength characteristics is substantiated. Three-dimensional models of construction elements and equipment in general are developed. Researches by changing of reservoir design by using a replaceable construction element are carried out. An analysis of the strength characteristics of integral reservoir and reservoir with a replaceable end wall from various materials is presented.
REFERENCES (28)
1.
Babichev AP. Fundamentals of vibration technology. Rostov-on-Don: DSTU Publishing Center; 2008.
 
2.
Kartashov IN, et al. Treatment of parts by free abrasives in vibrating reservoirs. Kiev: Highest school; 1975.
 
3.
Romanchenko OV. Technological process of manufacturing of reservoir of vibrational machine-tool from composite materials. International scientific journal Technological audit and production reserves. 2015; 6/3 (26): 31–37.
 
4.
Sankov NN, Zibenberg AN. Mechanization and automation of abrasive treatment of castings. Moscow: Mechanical Engineering; 1972.
 
5.
Ventskevich G. Zh. The influence of some parameters of an abrasive filler on the efficiency of the grinding process in vibrating reservoirs [dissertation]. Odessa, SU; 1986.
 
6.
Mitsyk V.Ya. Intensification of parts treatment in vibrating reservoirs by counter-moving flows of the working medium [dissertation]. Voroshilovgrad; SU; 1986.
 
7.
Romanchenko ОV. Expansion of technological capabilities of vibration equipment by creating conditions for treatment of long parts: [dissertation]. Chernigіv; UA; 2011.
 
8.
Blekhman II, Janelidze G.Yu. Vibration displacement. Moscow: Nauka; 1964.
 
9.
Kopylov Yu.R. Vibration impact hardening. Voronezh: Voronezh Institute of the Ministry of Internal Affairs of Russia; 1999.
 
10.
Lubenskaya LM. Features of energy processes in deformable working medium when treatment of parts in vibrating reservoirs: [dissertation]. Lugansk; UA; 1992.
 
11.
Ciampini D, Papini M, Spelt JK. Impact velocity measurement of media in a vibratory finisher. Journal of Materials Processing Technology. 2007;183:347–357. https://doi.org/10.1016/j.jmat....
 
12.
Barletta M, Rubino G, Valentini PP. Experimental investigation and modeling of fluidized bed assisted drag finishing according to the theory of localization of plastic deformation and energy absorption. Int J Adv Manuf Technol. 2015;77: 2165–2180. https://doi.org/10.1007/s00170....
 
13.
Kang YS, Hashimoto F, Johnson SP, Rhodes JP. Discrete element modeling of 3D media motion in vibratory finishing process. CIRP Annals – Manufacturing Technology. 2017;66(1):313–316. https://doi.org/10.1016/j.cirp....
 
14.
Mitsyk AV, Fedorovich VA. A new type of finishing and stripping method and an aggregated vibrating machine of vibration and centrifugal dynamic action. Cutting and tools in technological systems. 2016; 86: 96–102.
 
15.
Babichev AP, Pastukhov FA, Motrenko PD, Chuchukalov AP. Analysis of technological schemes of vibration impact hardening treatment of long parts. Hardening technologies and coatings. Mechanical hardening treatment. 2006;5:3–5.
 
16.
Davidson DA. Surface finishing reaches new heights: Mass media finishing techniques can improve aircraft part performance and service life. Metal finishing. 2005;103(3): 25–28.
 
17.
Sangid MD, Stori JA, Ferriera PM. Process characterization of vibrostrengthening and application to fatigue enhancement of aluminum aerospace components – part I: Experimental study of process parameters. Int J Adv Manuf. Technol. 2011;53: 545–560.
 
18.
Babichev AP. editor. The use of vibration technologies in the operations of finishing and cleaning treatment of parts (cleaning, washing, removal of burrs, edge treatment). Rostov-on-Don: DSTU; 2010.
 
19.
Romancheno OV, Romanchenko Yu.A. Review of devices for auxiliary operations of vibration Treatment. Vinyk of Volodymyr Dahl East Ukrainian National University. 2016; (226): 76–86.
 
20.
Krol O, Sokolov V, Tsankov P. Modeling of vertical spindle head for machining center. Journal of Physics: Conference Series. 2020;1553:012012. https://doi.org/10.1088/1742-6....
 
21.
Krol O, Sokolov V. Modeling of spindle node dynamics sing the spectral analysis method. In: Advances in Design, Simulation and Manufacturing III. DSMIE 2020. Lecture Notes in Mechanical Engineering. 2020;1:35–44. https://doi.org/10.1007/978-3-....
 
22.
Krol O, Porkuian O, Sokolov V, Tsankov P. Vibration stability of spindle nodes in the zone of tool equipment optimal parameters. Comptes rendus de l’Acade'mie bulgare des Sciences. 2019; 72(11): 1546–1556. https://doi.org/10.7546/CRABS.....
 
23.
Sokolov V, Porkuian O, Krol O, Baturin Y. Design calculation of electrohydraulic servo drive for technological equipment. In: Advances in Design, Simulation and Manufacturing III. DSMIE 2020. Lecture Notes in Mechanical Engineering. 2020;1: 75–84. https://doi.org/10.1007/978-3-....
 
24.
Sokolov V, Porkuian O, Krol O, Stepanova O. Design calculation of automatic rotary motion electrohydraulic drive for technological equipment. in: advances in design. Simulation and Manufacturing IV. DSMIE 2021. Lecture Notes in Mechanical Engineering. 2021;1:133–142. https://doi.org/10.1007/978-3-....
 
25.
Mitsyk AV, Fedorovich VA. Analytics, comments and classification of finishing and cleaning vibration treatment technologies, created by combining various schemes of energy impact. Modern technologies in machinery. NTU "KhPI". 2016;1: 175–179.
 
26.
Kotliar A, Basova Y, Ivanov V. et all. Ensuring the economic efficiency of enterprises by multi-criteria selection of the optimal manufacturing process. Management and Production Engineering Review. 2020;11(1):52–61. https://doi.org/10.24425/mper.....
 
27.
Mitsyk AV. Multi-energy technologies and modular equipment in the practice of finishing and cleaning vibration treatment of parts with free abrasive mediim. Vinyk of Volodymyr Dahl East Ukrainian National University. 2015; 5(222): 64–72.
 
28.
Kalmykov MA, Romanchenko OV. Determination of the functional dependence between the amplitude of the container and its length. Eastern-European Journal of enterprise technologies. 2011; 3/7:19–23.
 
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