SU962133A1 - Vibratory feeder - Google Patents

Description

(54). VIBRATION FEEDER

The invention relates to lifting, transport engineering, namely, to vibratory feeders for the discharge of bulk material from storage tanks.

A vibrating transporting machine is known with excitation masses fixed with the help of springs and rubber elements on the load-carrying body, which ensure the direction of oscillation of the load-carrying body at a certain angle of vibration and reduce the weight of the load-carrying body, and by reducing the weight increase the amplitude of oscillation of the load-carrying body and, therefore, , notify transport speed and machine performance

However, rubber elements operating in a resonant .ESHKIM do not provide stable oscillations of the load-carrying body, which leads to a decrease in the speed of transportation. In addition, in the resonant mode of vibrations, the rubber elements operate with large shear stresses, which sharply reduces their durability.

 The closest to the proposed technical solution is a vibrating feeder containing a non-responsive body mounted on depreciation hangers with excitant masses fixed on its sides using springs and a self-balance vibrator t2j.

However, the known vibrating feeder has a low transport speed around the vibrator, since the mass of the vibrator reduces the vibration angle of the load-carrying body. The excitation masses in the operating mode have ciM oscillation amplitudes exceeding several times the working amplitudes of the colds, exceeding several times the amplitudes of the vibrations of the carrying body, which leads to unstable oscillations of the carrying body and, consequently, to a decrease in transport speed and increase

20 dynamic loads on springs and shock absorbers, reducing the reliability of the feeder.

The purpose of the invention is to increase the speed of transportation, reliability and

25 and the durability of the feeder by selecting the rational ratio of its dynamic parameters.

Claims (4)

This goal is achieved by the fact that the vibrating feeder, which contains an organ mounted on a shock absorbing boat of a nonconditioning body with the excitant masses fixed on its borg with the help of springs and a self-balance vibrator, is provided with an additional spring; a vibrator mounted on the body, and an additional excitation mass placed on it, while the ratio of the total excitation mass to the mass of the body with the vibrator and the ratio of the natural frequency of the stimulating masses to the frequency of forced oscillations range from 1: 3.3 to 1: 2. The drawing shows a vibrating feeder, a general view. The vibrating feeder contains a self-balancing vibrator 1, a load-carrying body 2 with excitation masses 4 mounted on its sides using springs 3, mounted on shock absorbers 5. An additional spring 3 is fixed to the body of the vibrator 1 on its free the end. an additional excitation mass 8 is installed, so that the reactive vector P, the force arising from the oscillations and bending of the spring, passes through the center of the vibrator (point a). At the same time, the excitation masses 4, mounted on the sides of the load-carrying organ for 2, and the excitation masses 8 are fixed at the free ends 7 of the springs 3 with the possibility of their movement and fixation, for example, using bolts along the springs so that the straight lines CC and DD passing through the centers of the exciting masses (points a and b), are joined by the bending (oscillation) nodes of the resistor 3, which ensures minimal oscillations of the exciting masses 4 and 8 and the bending of the springs 3, thereby increasing the stability of oscillations of the load-carrying organ and the durability of the springs . . The ratio of the total excitation masses 4 and 8 to the mass of the bodies of the existing organ 2 with the vibrator 1 is in the range from 1: 3.3 to 1: 2,. which ensures the stability of oscillations of the load-carrying body, and, consequently, the speed of transportation with a minimum value of exciting masses 4 and B. In addition, the ratio of the natural frequency of the exciting masses to the desired frequency of oscillations I also accept r from J: 3.3 to 1: 2. The vibratory feeder operates as follows. The load-carrying body 2, freely mounted on the damping suspensions 5, the longitudinal oscillations communicate with a self-balancing vibrator 1, while the springs 3 bend relative to the exciting masses 4 and 8, and the reactive forces (P |) arising in the springs 3 when they oscillate and bend transferred to the load-carrying body 2 along the normal to the plane of the springs 3. The resulting oscillations of the load-carrying body 2 are folded from the vibrating 1 from the vibrator 1 (vector P) and the angular jet (the vector R) from the springs 3. Om B to its longitudinal axis causes the tossing of the material and its movement along the load-carrying body 2, with the vector P- | reactive force arising from oscillations and bending of springs 3 passes through the center of mass of the vibrator 1 (point a), and the exciting masses 4 and (8 in operation have minimal vibration amplitudes. The invention improves the transport speed, reliability and durability of elastic elements 2-3 times in comparison with the known vibratory feeders. Formula of the invention Vibration feeder containing a load-carrying body mounted on depreciation hangers with exciters mounted on its sides the self-balancing vibrator itself, characterized by 4TOf to increase the speed of transportation, reliability and ds of operation, it is provided with an additional spring, installed) on the body of the vibrator, and placed on it the additional exciting mass to the mass of the load-carrying body with a vibrator and the ratio of the natural frequency of the exciting mass to the frequency of forced oscillations take in the range from 1: 3.3 to 1: 2 Sources of information taken into account during the examination 1. Spivakovsky A.O., GoncharEVICH I.F. Vibrating conveyors, feeders and auxiliary devices. M., Mechanical Engineering, 1972, p. 213, fig. 86 2. Mine and quarry transport, vol. 3M. ,. V week, 1977, p. 181182, fig. five. 4. (PROTOTYPE). R L / UP 7777} S 7