
Substantiation of amplitude-frequency characteristics and design parameters of the vibration exciter of the separator of volume vibrations
Author(s) -
Igor Palamarchuk,
Volodymyr Vasyliv,
Mikhailo Mushtruk,
Mikhailо Mushtruk,
Марія Михайлівна Жеплінська,
Zinaida Burova,
Maxim Gudzenko,
S. Filin,
Oleg Omelyanov
Publication year - 2021
Publication title -
tvarinnictvo ta tehnologìï harčovih produktìv
Language(s) - English
Resource type - Journals
eISSN - 2706-834X
pISSN - 2706-8331
DOI - 10.31548/animal2021.02.006
Subject(s) - vibration , conical surface , mechanics , separator (oil production) , amplitude , acoustics , equations of motion , control theory (sociology) , physics , mechanical engineering , engineering , classical mechanics , computer science , optics , control (management) , artificial intelligence , thermodynamics
The main effects of the developed design for vibratory separator: the increased driving force in the process of bulk material separation in this work, achieved by providing the working cylindrical-conical container with vibrational motion; improving the conditions for the passage of product particles through openings, achieved by providing the sieve surface with volume oscillations; reduction of energy consumption and improvement of operating conditions for support nodes during the operation of the designed vibrating screen, achieved due to the installation of additional elastic elements between the separator body and bearing assemblies of the vertical drive shaft in vibration exciter. Providing the working bodies of the designed vibrating screen with volume oscillating motion allows increasing the performance and quality of the separation process of solid bulk materials. To determine the rational parameters for vibration screening process, the equations of motion of working bodies as a conical sieve surface were obtained using the method of the Lagrange equations of the second order. When applying solutions of the Cauchy problem for linear nonhomogeneous differential equations, the solution of the latter was obtained. The obtained dependences of oscillation amplitudes, vibration velocity and vibration acceleration, and the intensity of oscillating motion allowed us to perform a mathematical analysis for power and energy parameters of vibration drive in the developed separator. The inclined placement of the conical sieve surface allows for spatial gyration or circular translational motion, which makes it possible to realize the advantages of volumetric separation of bulk materials. The results of the conducted analytical study made it possible to substantiate the optimal inclination angle for working sieve surface. Based on our analysis, the design parameters of vibration exciter were substantiated and clarified, and the design of this technical system was demonstrated.