Problem statement. Designing and manufacturing of efficient resonant vibratory lapping machines with linear oscillations of laps demand an accurate and detailed calculation of parameters of their elastic systems and electromagnetic drives. Purpose. The main objective of this research consists in derivation of analytical dependencies for calculating the stiffness and excitation parameters of mechanical oscillatory system of vibratory finishing machine in order to ensure its resonance operation mode.
The purpose of research. Substantiation of inertial, stiffness and excitation parameters of mechanical oscillatory system of mobile vibratory robot in order to maximize its motion speed. Methodology. The technique of the research is based on fundamental concepts of engineering mechanics and theory of mechanical vibrations. In order to deduce the differential equations of motion of the mechanical system of mobile vibratory robot the Lagrange second order equations were used.
When designing pumping equipment the question arises not only of the improvement of the existing types but also the search for a new principle of uniting the supporting elements with the elements of the formation of the working cameras of the pump. The purpose of the work is to provide a substantiation of the possibilities and expediency of designing a de-axial pump based on the Rolomite mechanism. Conditions ensuring the efficiency of the mechanism are considered on the basis of a specific hydraulic pump; the principle of inlet and outlet windows placement is justified.
Vibratory conveying devices with electromagnetic drive are widely used in the different branches of industry. As a rule, they deal with relatively small piece goods and are not suitable for conveying of the large massive goods with high productivity. The conveying of massive piece goods needs the using of non-hopping modes of moving in which the high velocity can be reached only in the case of non-linear vibration trajectories of the conveying track, for example elliptical trajectories.
An industrial necessity of creation of 100-Hz vibratory tables is grounded. The prospect of researches of just resonance electromagnetic vibratory tables is conditioned. The existing vibrating tables on the basis of electromagnetic drive are considered. It is noted that the stages and problems which arise during the creating of high-frequency two-mass vibration table of middle sizes constructed according to classic chart are oulined in the article. The principle scheme of an electromagnetic vibratory table which is to be developed is described.
The influence of the reaction of concrete mixture during its vibratory compaction on the dynamics of vibration unit with an electromagnetic drive, which is operated in the near-resonant mode, is researched. The dynamic model, which allows calculating the transients in multi-mass vibration devices with a controlled electromagnetic drive and which allows to choose the structure and the parameters of automatic control system regulators, is developed.
The article considers two options for accomplishment of vibro-brunt resonant systems with an impulse electromagnetic drive based on asymmetric piecewise elastic characteristics. Basic kinematic, power and energy characteristics of comparative system are presented. Relative and generalized criteria for complex (of multi-criteria) valuation of vibro-brunt system with an impulsive drive are determined.
The paper describes an approach to create two-mass vibratory table with an electromagnetic drive. The design of vibratory machines is shown and described in details. The calculation of its parameters that provide the necessary modes is done. Based on these calculations, a model of a vibratory table is designed. An experiment that confirms the serviceability of the design is conducted.