RU46686U1 - Vibrating Screen - Google Patents

Abstract

The invention relates primarily to the mining industry and can be used for processing suspensions with a sticky solid phase. The technical result is an increase in the performance of the screen. The screen consists of a vibration frame, sieving elements, vibration isolators, two unbalanced self-synchronizing vibration exciters whose rotation axes are parallel to each other, located perpendicular to the longitudinal plane of symmetry of the vibration frame and installed at a distance from the center of gravity of the vibration frame, whose ratio is inversely proportional to the ratio of the masses and the eccentricities of the corresponding unbalances, and the bisector of the angle between the lines connecting the center of gravity with the axes of rotation imbalances, tilted to the horizon in the direction of movement of the crashing material. This design of the vibrating screen provides an increase in the performance of the screen when processing a drilling fluid with a sticky solid phase due to giving the vibration frame an elliptical plane-parallel oscillation path with a given angle and lengths of the axes of the ellipse.

Description

The invention relates mainly to the mining industry and can be used for processing suspensions with a sticky solid phase, for example, clay mud.

Known vibrating screen (US Patent No. US 5,265,730 dated 10/30/1993 Vibration screen separator), used for processing suspensions. It contains a vibration frame, sieving elements, vibration isolators, two unbalanced self-synchronizing vibration exciters mounted on a vibration frame with unbalanced rotation axes located at an angle between themselves and relative to the longitudinal plane of symmetry of the vibration frame. At this screen, suspensions with a sticky solid phase, for example, clay drilling mud, are effectively processed by providing plane-parallel elliptical trajectories of the vibration frame with a given shape and angle of inclination of the axes of the ellipse. However, the inclined axis of rotation of the unbalanced exciters create an additional load on the bearings of the unbalanced exciters,

reducing the reliability of the unbalanced vibration exciter.

Also known is a vibration screen (A.S. No. 1643116 A.N.Kosolapov, I.I. Blekhman, G.V. Dakalov, V.A. Oleneva, V.I. Gladkikh), adopted as a prototype. It contains a vibration frame , screening elements, vibration isolators, two unbalanced self-synchronizing vibration exciters. Unbalanced vibration exciters are mounted on the vibration frame so that the axis of rotation of the unbalances are parallel to each other. In addition, the axis of rotation of the unbalances is perpendicular to the longitudinal plane of symmetry of the vibration frame. Unbalanced vibration exciters do not create additional load on the bearings due to the installation of the axis of unbalance perpendicular to the longitudinal plane of symmetry of the vibration frame. This arrangement of the axis of rotation of the unbalances creates plane-parallel linear trajectories of the vibration frame. However, when processing slurries with a sticky solid phase, such as clay mud, a decrease in screening performance is observed. This is due to the fact that linear vibrations cause the sticky solid phase to move along closed paths, which, in turn, leads to a partial or complete termination of the transportation of the screening material over the surface

sifting elements.

The technical result of using the proposed screen is to increase the performance of the screen.

The proposed screen consists of a vibration frame, screening elements, vibration isolators. Two unbalanced self-synchronizing vibration exciters are fixed on the vibration frame. In this case, the axis of rotation of the unbalances are parallel to each other. In addition, the axis of rotation of the unbalances is perpendicular to the longitudinal plane of symmetry of the vibration frame. This goal is achieved by the fact that, in contrast to the prototype, the unbalance rotation axes are set with the distance from the center of gravity of the vibration frame to a distance whose ratio is inversely proportional to the mass product of the corresponding unbalances and their eccentricities, and the location of the center of gravity of the vibration frame is selected so that the bisector the angle between the lines connecting the center of gravity with the axes of rotation of the unbalance is inclined to the horizon in the direction of movement of the crashing material. Such a set of features of the proposed vibrating screen provides an increase in the performance of the screen when processing a drilling fluid with a sticky, for example, clay, solid phase

due to the efficient transportation of the sticky solid phase through the screening elements. Efficient transportation is provided by a plane-parallel elliptical trajectory of the vibration frame, and the ellipses of this trajectory have a given angle of inclination and a given size of the major and minor axes.

The invention is illustrated in the drawing.

The proposed screen consists of a vibration frame 1 with sieving elements 2 mounted on vibration isolators 3. Two unbalanced self-synchronizing vibration exciters 4 and 5 are fixed on the vibration frame. The axis of rotation of the unbalances is parallel to each other and perpendicular to the longitudinal plane of symmetry of the vibration frame. Denote the mass of unbalances m ₁ , m ₂ , eccentricities ε ₁ , ε _{2 the} distance from the center of gravity of the vibration frame C to the axis of rotation of the unbalances r ₁ , r ₂ . The location of the axis of rotation of the unbalances on the vibration frame is made in compliance with the ratio:

In this case, the bisector of the angle between r ₁ and r _{2 is} inclined to the horizon at an angle a in the direction of motion of the screened material.

The screen works as follows. When switched on, unbalanced vibration exciters are driven in rotation in opposite

directions. Due to the self-synchronization effect, vibration exciters rotate synchronously. The indicated ratio between the values of m ₁ , m ₂ , ε ₁ , ε ₂ , r ₁ , r ₂ provides such a vibration path of the vibration frame, in which suspensions with a sticky solid phase, such as clay, are effectively transported through the screening elements by giving the vibration frame an elliptical plane-parallel oscillation path with a given angle of inclination a ₁ and lengths a and in the axes of the ellipse.

An example of the application of the proposed screen. On a vibrating sieve with linear vibrations CB1Λ (TU 39-0147001-145-96), instead of one double vibrator housing, two single vibrator housings are mounted at distances determined by formula (1). In this case, the motion paths have the form shown in the drawing, with a ₁ = 45 °, a = 2 mm, and = 4 mm. Experimental studies have shown greater efficiency in transporting clay lumps along the screening elements of the proposed screen, compared with the CB1Λ vibrating screen and higher drilling fluid productivity.

From the example it can be seen that the proposed screen does not require special materials and devices, can be manufactured using known technical means and provides technical

result. Therefore, it has industrial applicability.

Claims (1)

A vibration screen containing a vibration frame, sieving elements, vibration isolators, two unbalanced self-synchronizing vibration exciters mounted on a vibration frame to ensure that the axes of rotation of the unbalances are parallel to each other and the axes are perpendicular to the longitudinal plane of symmetry of the vibration frame, characterized in that the axis of rotation of the debans are installed the center of gravity of the vibrational frame over distances, the ratio of which is inversely proportional to the ratio of the mass products of unbalance to their eccentricities, and the location of the center of gravity of the vibration frame is chosen so that the bisector of the angle between the lines connecting the center of gravity with the axes of rotation of the unbalances is inclined to the horizon in the direction of movement of the screened material.