SU740302A1 - Method of screening loose materials on mutually moving grates - Google Patents

Description

one

The invention relates to mining equipment, in particular to methods for separating bulk materials on vibrating screens with reciprocating grate.

Methods are known for separating bulk materials on vibrating surfaces and, in particular, in screens, the grate bars of which perform counter-Q phase directional linear oscillations 1.

However, methods for separating materials onto mutually moving grates do not allow for regular reorientation of pieces of a difficult class in the process of moving along the grate, which reduces screening efficiency.

A known method of screening loose materials 20 on mutually moving grates, which means that additional grades of directional straight-line oscillations, which are equal to sharp angles with the screening surface, are reported in the plane, perpendicular to the vertical screen of the screen. With this method, the grate communicates longitudinal vibrations, providing 30

vibrotransporting of the tombstone product, and additional vibrations that help the passage of particles down between the grate bars and loosening the semi-loaded pieces.

However, transportation of semi-loaded pieces with a center of gravity above the surface of the lattice, as well as having one or two sizes smaller than the width of the slit, is carried out without reorientation in the process of moving along the screening surface. In this case, rotational oscillations of such pieces are possible only in the transverse plane of the rumble that do not ensure their reorientation. Therefore, the likelihood of these pieces getting into the tombstone product is high, which reduces the screening efficiency.

The purpose of the invention is to increase the efficiency of screening due to the reorientation of pieces of the hard class to the screening surface of the screen.

The goal is achieved by the fact that adjacent grate bars are additionally reported with out-of-phase rotary vibrations relative to their longitudinal axes.

The combination of directional straight-line oscillations of each grate with rotary grabs provides a complex spatial spiral oscillatory motion of the grates, which leads to translational-rotational vibratory displacement of pieces of a hard-toed class. This increases the likelihood of such pieces passing into inter-grid targets and helps to eliminate seizures and, consequently, increases the efficiency of screening.

Figure 1 shows the roar, side view; Fig. 2 is the same, view from above and diagram of the action of forces for small particles (II) and jammed particles (III); FIG. 3 is a diagram of the forces acting on the pieces of the screened material in the transverse screen of the screen (1 for pieces of a difficult class, the center of gravity of which is above the surface of the lattice; III - for jammed pieces, the center of the body of gravity is below the surface of the lattice; IV - for pieces with sizes close to smaller or equal to the size of the gap).

The screen consists of fixed grates 1, rigidly mounted on the foundation, and movable grates 2, mounted on fixed ones by means of bar-shaped guide elastic links 3, which allow vibrating grate to oscillate along and around their longitudinal axis. The gaps between the grate expands in the direction of material movement. A four-unbalance inertial vibrator 4 is attached to each movable grate. The vibrator shafts of the adjacent grate are connected to each other and the motors 5 by means of elastic couplings 6. The unbalance weights of the adjacent vibrators 4 are turned relative to each other, and the vibrator loads 4 located at opposite ends of the shafts, they are turned relative to each other at a certain angle определ determined by the value of the amplitude of the rotary oscillations.

When the shafts of the vibrators 4 are rotated, the moving grate 2 oscillates along and around their longitudinal axes, resulting from these vibrations will be antiphase directional helical vibrations of the adjacent moving grates 2, which provide for the treadmill vibro-movement of the proposed method.

The bottoms of pieces whose center of gravity lies above the surface of the grid (1), resting, for example, on the grate, at points A and B at the moments of separation of each of the points from the corresponding

The vibrating surface of the grate is acted upon by the force and G, which coincide along the direction and act tangentially to the surface of the piece, i.e. they tend to rotate it relative to the center of gravity. The rotation of the pieces is also due to the fact that at the moments of separation of each of the points of the piece from the corresponding grate of his friend, the point is in the phase of flight, and nothing prevents its rotation at these moments, i.e. reorientation on the screening surface. The small particles (P) that fall on the surface of the grate are acted upon by the forces Rd and moving them at an angle to the longitudinal axis of the grate, i.e. to a crack, which eliminates the possibility of transporting such particles into the sub-groove product. For jammed pieces with a center of gravity below the surface of the grates (III) in the transverse plane of the lattice, the forces Gd and Fg are applied, which loosen and periodically push them out from the intergrate slots. In addition, in the case of application of gratings with widening gaps due to the difference in the moments of forces F. and F,

due to

Noah different size shoulders OD and OS; There is a moment MQ, turning a piece in the plane of the lattice. For pieces with sizes close to but smaller or equal to the size of the slit (IV), forces F) and F) periodically act to accelerate the collapse and movement of such pieces between the grate bars. The use of the proposed method of screening bulk materials at mutually moving contactors provides, in comparison with existing methods, an intensification of the process, an increase in the efficiency of screening, as well as the elimination of seizures between the grate bars.

Claims (2)

1. USSR Author's Certificate No. 418225, cl. B 07 B 1/40, 1972. 2. USSR author's certificate No. 410825, class B 07 B 1/12, 1976 : gk gh I- / I g S w W