Development of Executive Equipment Design for Implementing the Process of Generating of Drops of Microand Nanoscale Range-Reference-Cited by-同舟云学术

Development of Executive Equipment Design for Implementing the Process of Generating of Drops of Microand Nanoscale Range

Published:2021-03-19 Issue:1 Volume:12 Page:38-45
ISSN:2414-0473
Container-title:Devices and Methods of Measurements
language:
Short-container-title:Prib. metody izmer.

Author:

Kuznetsov M. A.¹,Ilyaschenko D. P.¹,Kryukov A. V.¹,Solodsky S. A.¹,Lavrova E. V.²,Verkhoturova E. V.³

Affiliation:

1. Yurga Institute of Technology National Research Tomsk Polytechnic University

2. Priazovskyi State Technical University

3. Irkutsk National Research Technical University

Abstract

Modeling of velocities and temperatures processes distribution in the plasma-forming channel determining the design features and optimal parameters of the plasma torch nozzle is one of promising directions in development of plasma technologies. The aim of this work was to simulate the processes of velocities and temperature distribution in the plasma-forming channel and to determine the design features and optimal geometric parameters of the plasmatron nozzle which ensures the formation of necessary direction of plasma flows for generation of surface waves on the surface of a liquid metal droplet under the influence of the investigated instabilities.One of the main tasks is to consider the process of plasma jet formation and the flow of electric arc plasma. For obtaining small-sized particles one of the main parameters is the plasma flow velocity. It is necessary that the plasma outflow velocity be close to supersonic. An increase of the supersonic speed is possible due to design of the plasmatron nozzle especially the design feature and dimensions of the gas channel in which the plasma is formed. Also the modeling took into account dimensions of the plasma torch nozzle, i. e. the device should provide a supersonic plasma flow with the smallest possible geometric dimensions.As a result models of velocities and temperatures distribution in the plasma-forming channel at the minimum and maximum diameters of the channel were obtained. The design features and optimal geometric parameters of the plasmatron have been determined: the inlet diameter is 3 mm, the outlet diameter is 2 mm.The design of the executive equipment has been developed and designed which implements the investigated process of generating droplets of the micro- and nanoscale range. A plasmatron nozzle was manufactured which forms the necessary directions of plasma flows for the formation of surface waves on the metal droplet surface under the influence of instabilities. An algorithm has been developed for controlling of executive equipment that implements the process of generating drops of micro- and nanoscale range.

Publisher

Belarusian National Technical University

Subject

General Earth and Planetary Sciences,Water Science and Technology,Geography, Planning and Development

Reference15 articles.

1. Chinakhov D.A., Vorobjev A.V., Tomchik A.A. Simulation of Active Shielding Gas Impact on Heat Distribution in the Weld Zone. Materials Science Forum, 2013, no. 762, pp. 717‒721. DOI: 10.4028/www.scientific.net/MSF.762.717

2. Chinakhov D.A.,Vorobjev A.V.,Gotovshchik Y.M. Simulation of wind Influence on the thermal processes in gas-shielded welding. Applied Mechanics and Materials, 2014, no. 682, pp. 91‒95. DOI: 10.4028/www.scientific.net/AMM.682.91

3. Temlyancev M.V., Starikov V.S., Kondrat'ev V.G. [Modeling of temperature fields and the deformation resistance in cylindrical billets during heating from a hot fit for rolling]. Izvestiya vysshih uchebnyh zavedenij. CHernaya metallurgiya. [Proceedings of higher educational institutions. Ferrous metallurgy], 2000, no. 6, pp. 51‒54 (in Russian).

4. Tashev P, Koprinkova-Hristova P, Petrov T, Kirilov L, Lukarski Y.J. Mathematical Modeling and Optimization of Parameters of the Mode for Tungsten-Inert Gas Remelting with Nanomodification of the Surface Layer. Journal of Materials Science and Technology, 2016, vol. 24, no. 4, pp. 230–243.

5. Peng J, Yang L. Mathematical model on characteristics of V groove molten pool during MIG welding. CIESC J., 2016, no. 67 (S1), pp. 117‒126. DOI: 10.11949/j.issn.0438-1157.20160625