RU91540U1 - VIBROSTEND - Google Patents

Abstract

1. Vibration stand containing a base intended for installation on it of technological capacities, unbalances, vibration mounts, characterized in that the vibration mounts are made in the form of elastic rods, they are equipped with a vibration stand base on which unbalances having an independent rotation frequency are fixed. ! 2. The vibration bench according to claim 1, characterized in that it has at least three vibration mounts. ! 3. The vibration bench according to claim 1, characterized in that the vibration mounts are rigidly fixed to the housing with a lower end, and the upper end is connected to the base using a ball joint. ! 4. Vibration stand according to any one of claims 1 to 3, characterized in that the unbalance is fixed in a plane located at an angle to the base.

Description

The vibration stand can be used in chemical, mining, food and agricultural engineering technologies to create various mixing (shakers) or screening (screening) devices.

A vibrostand is a mechanical device that allows you to obtain circular axisymmetric vibrations of more than one harmonic, where the vertical axis of symmetry is perpendicular to the base, from unbalances rotating at different frequencies, where the base on which the technological capacities are installed is a summing element. The use of two or more harmonic frequencies will speed up the process of mixing substances of different physical properties or sizes when mixing or eliminate the sticking of viscous or wet substances during sifting (screening).

The closest to the claimed structural features is a biharmonic vibrostand (RF patent for utility model No. 17145 from 08.16.00), which works as follows (see Figure 1). Shafts O1 and O2, rotate with frequencies that differ by a factor of two. Cranks 1 and 2 located on the shafts transmit the motion of the connecting rods 3 and 4 pivotally connected to them. They, in turn, perform the summing arm pivotally connected to their free ends. 6, placed in the support of the housing, which converts it into translational biharmonic oscillations - the result of the summation of two harmonics sieve mill 7.

The disadvantages of the prototype are the design complexity associated with the use of two pairs of connecting rods, a summing lever and traction, fixed in the support of the housing, as well as a limited scope only for mixing.

The technical result of the utility model is to simplify the design by halving the total number of constituent elements and expanding the functionality of the mechanism by using a vibrating stand not only for mixing but also for screening.

The technical result is achieved through the implementation of a vibrating stand with a base designed for installation of technological capacities on it, has unbalances, vibration mounts that are made elastic, they have a vibrating stand base on which unbalances having a different rotation frequency are fixed.

The vibration bench has at least three vibration mounts.

Vibration mounts are rigidly fixed to the body with the lower end, and the upper end, connected to the base using a ball joint. Imbalances are fixed in a plane located at an angle to the base.

The utility model is illustrated by drawings.

Figure 2 presents the vibration stand

Figure 3 shows the shape of the vibrations.

The vibration stand (figure 2) contains two unconnected unbalances 6 and 7, rotating on the axes O ₁ and O ₂ , mounted on a common base 4. The unbalances are the causative agents of oscillations of independent frequencies, and the base 4 is a summing element connected to the housing 1 by means of vibration mount 2 Vibration support 2 is an elastic rod of length L with one end (lower) rigidly fixed in the housing 1, and the other (upper) pivotally 3 connected to the base 4.

The vibration stand works as follows: unbalances 6 and 7 rotating on the axes O ₁ and 0 ₂ , parallel to the plane of the base 4, lead the latter to axisymmetric oscillatory circular motion in one plane.

The axisymmetric movement is relative to the vertical axis of symmetry of the vibrating stand passing through the center of mass. Vibration mounts 2 serve as an elastic oscillating element, allowing to produce oscillatory movements. The swivel joint of the vibration support with the base allows free circular oscillatory movements, which makes it possible to increase the amplitude of vibrations, and accordingly increase the net power, as a result of which the process is accelerated.

Adjustment of the oscillation frequency of the stand is carried out by changing the rotation frequency of each of the unbalances 6 and 7.

By changing the length L of the vibration support 2, it is possible to limit the total frequency of oscillations, the smaller the length L, the higher the frequency, which is determined by the stiffness of the support material.

The number of vibration mounts must be at least three to obtain a circular motion of the base 4 strictly in the same plane.

When the plane of rotation of the unbalances is positioned at an angle to the base, a vertical vector of variable force is obtained corresponding to the “shaking” of the technological capacities.

As a result, when using two unbalances, we obtain biharmonic oscillations - the result of the summation of the two harmonics of the base 4 (Figure 3) for mixing the masses in technological tanks. When using three or more unbalances, more complex vibrations will be obtained - polyharmonic for sifting (screening) of various bulk solids from technological tanks.

Claims (4)

1. Vibration stand containing a base intended for installation on it of technological capacities, unbalances, vibration mounts, characterized in that the vibration mounts are made in the form of elastic rods, they are equipped with a vibration stand base on which unbalances having an independent rotation frequency are fixed. 2. The vibration bench according to claim 1, characterized in that it has at least three vibration mounts. 3. The vibration bench according to claim 1, characterized in that the vibration mounts are rigidly fixed to the housing with a lower end, and the upper end is connected to the base using a ball joint. 4. Vibration stand according to any one of claims 1 to 3, characterized in that the unbalance is fixed in a plane located at an angle to the base.