RU2132753C1 - Hydraulic screen - Google Patents

Abstract

FIELD: concentration equipment used in mining, construction, metallurgical and other branches of industry for separating and sorting of solid materials. SUBSTANCE: hydraulic screen has box mounted on flexible members and submerged into hopper filled with water. Box has receiving and discharge systems. Hydraulic screen is further provided with sludge receiver, discharge chute, and drive for transmitting vibrations to box. Drive has differential dual-crank mechanism made in the form of driven crank whose center of rotation is positioned with vertical and horizontal eccentricity relative to center of rotation of driving crank. EFFECT: increased efficiency in screening and reduced power consumption. 2 cl, 5 dwg

Description

 The invention relates to the field of mineral processing equipment and can be used for separation and sorting of solid materials in the mining, metallurgical, construction and other industries.

 A known hydraulic screen, including a support frame, relative spring and partially immersed in the tub box with a screening surface, a vibrator shaft associated with the box, and pipes for feeding and removing screening products. The hydraulic screen is equipped with support rollers. The box is formed by disk-shaped sides mounted at the ends of the vibrator shaft coaxially with it, and the screening surface is made in the form of an endless tape covering the support rollers adjacent to its sides, immersed in the bathtub, and mounted with the possibility of joint rotation with it, one of the supporting rollers mounted above the nozzle to remove the oversize product. The hydraulic screen is equipped with a drive for uniform movement of the screening surface (1).

 This hydraulic screen is complex, bulky and energy-intensive, requiring additional costs for maintenance and repair.

 The closest technical solution, selected as a prototype, is a hydraulic screen, including a frame, a box with receiving and unloading sieves, immersed in a water bath with drain thresholds, an eccentric drive that informs the box of straight vibrations, loading and unloading funnels, electromagnetic vibrators with a frequency the oscillations are greater than the oscillation frequency of the eccentric drive and the oscillation direction, perpendicular to the oscillation direction of the latter (2).

A disadvantage of the known hydraulic screen is the difficulty in obtaining a steady ore movement up the discharge sieve. The screening surface of a known hydraulic screen is in the form of a tray, where the discharge screen is located at an angle of about 6 ^o to the horizon. The applied superposition of vertical vibrations from electric vibrators to uniform symmetrical horizontal vibrations from an eccentric drive does not ensure the stability of the directed ore supply upward at an angle of 6 ^o to the horizontal, and therefore it is difficult to provide the required performance and efficiency. In addition, high energy consumption.

 The purpose of the invention is to increase the intensity and efficiency of screening, reducing energy costs.

 This goal is achieved by the fact that in a hydraulic screen, including a box with receiving and unloading sieves, mounted on elastic elements and immersed in a hopper with water, a slurry receiver, an unloading chute, the drive is equipped with a differential two-crank mechanism made in the form of a driven crank, the center of rotation of which is located with vertical and horizontal eccentricities relative to the center of rotation of the driving crank.

 The hydraulic screen box is equipped with vertical guides for screens.

In the known hydraulic screen does not create a stable directional supply of rock mass up the discharge sieve at an angle of 6 ^o to the horizon. The present invention, equipped with a differential two-crank mechanism, provides a stable directional flow of rock mass up the discharge sieve at an angle of more than 5 ^o to the horizon.

 The invention is illustrated by drawings. In FIG. 1 shows a General view of the hydraulic screen; in FIG. 2 is a kinematic diagram of a differential two-crank mechanism of a hydraulic screen; in FIG. 3 is a diagram of the movement of the links of the differential two-crank mechanism by one revolution; in FIG. 4 - arrangement of vertical guides for screens; in FIG. 5 is a view A in FIG. 4.

The hydraulic screen contains a box 1 with a receiving sieve 2 and an unloading sieve 3, a slurry receiver 4, an unloading chute 5. On the frame 6 there is a hopper 7 with water on the screw jacks 8. The box 1 is mounted on the frame using elastic elements 9. A drive 10 is mounted on the frame 6 reporting box 1 oscillations. The drive 10 is equipped with a differential two-crank mechanism 11. The differential two-crank mechanism 11 (articulated four-link) has a driving crank 12, a fork 13, a driven crank 14, the center of rotation of which O ₁ is located with horizontal eccentricity "a" and vertical eccentricity "in" relative to the center of rotation O leading crank 12, connecting rod 15.

 On the machines of the box 1 installed vertical guides 16 for the receiving sieve 2 and unloading sieve 3.

 Short vertical guides 16 sieve (receiving 2 or unloading 3) is easily and quickly installed in the box 1 or replaced, reducing downtime of the hydraulic screen.

 At t ≥ 1.5 b (where t is the thickness of the sieve 2, 3, d is the diameter of the vertical guide 16) and a small gap “S”, the displacement of any end of the sieve during screening causes it to “bite” on all vertical guides 16 and hold it firmly on place without additional fastening.

 The hydraulic screen works as follows. On the vertical guides 16, a receiving sieve 2 and an unloading sieve 3 are installed. The rock mass is fed through the pulp receiver 4 to the box 1 to the receiving sieve 2. The drive 10 with a differential two-crank mechanism 11 creates uneven vibrations that are communicated to the box 1 through the connecting rod 15. The driving crank 12 rotates evenly and through the fork 13 reports an uneven rotation to the driven crank 14, which through the connecting rod 15 reports uneven vibrations to the duct 1 with the intake screen 2 and the discharge screen 3.

Uneven rotation of the driven crank 14 is due to the presence of horizontal eccentricity "a" and vertical eccentricity "b". During the first half of the stroke (in the direction of the arrow), the leading crank 12 describes the arc AA ₁ , equal to 180 ^° , the driven crank 14, during the same time, rotating rapidly, describes (in the direction of the arrow) the arc BB ₁ - much more than 180 ^° . During the second half of the stroke, the leading crank 12, rotating uniformly, still describes an arc of 180 ^o , the driven crank 14, respectively, moving slowly, describes an arc much less than 180 ^o . So, during one revolution, the driven crank 12 moves then acceleratedly, which is slowed down, informing the box 1 of uneven fluctuations.

The differential two-crank mechanism is mounted so that the maximum acceleration coincides with the direction of supply of the rock mass. When the box 1 moves in the direction of the rock mass supply, the acceleration increases to the maximum value, then takes a negative value at the end of the stroke, and the box 1 starts to slow down. At this moment of burning, the mass, overcoming the frictional resistance, begins to slide by inertia towards the feed, ahead of box 1. In this state, box 1 reaches left dead center (Fig. 2) and starts a backward move to the right with increasing acceleration. The rock mass, along with the box 1, moves to the right, but slower than the last, lagging behind him and thereby continuing to feed. As a result, the supply of rock mass consists of the fact that first the rock mass goes to the left faster than box 1, then to the right slower than box 1, which allows you to get the effect of dropping the rock mass by unloading sieve 3 into unloading tray 5 and confidently supplying the rock mass upward in unloading sieve 3 under some angle to the horizon, greater than 6 ^o . Oversize product does not linger on discharge sieve 3, intensifying screening. The optimal conditions for the interaction of a water stream with a crashing rock mass are created. With the accelerated movement of the box 1 towards the supply of rock mass, the discharge sieve 3 moves to the left - upward due to the rise of the box 1 on the elastic elements 9. At this time, the water flow exits through the slots of the discharge sieve 3, carrying the under-sieve product into the hopper 7, creating optimal conditions for sliding the oversize product to the unloading chute 5. During the return stroke, the unloading sieve 3 moves to the right - down in the water, creating conditions for the oncoming water flow, which bursting from below through the slots of the unloading sieve 3 pieces in the cracks, loosens the next portion of the rock mass.

 The box 1, swinging on the elastic elements 9, discharges the oversize product moving along the unloading sieve 3 into the unloading tray 5. The undersize screening product falls through the slots of the intake sieve 2 and the unloading sieve 3 into the hopper 2, mounted using screw jacks 8 on the frame 6 .

 The use of a differential two-crank mechanism (articulated four-link) allows to increase the intensity and efficiency of screening and significantly reduce energy consumption, eliminating the electric vibrators.

 Simplified assembly and disassembly of screens reduces the downtime of the hydraulic screen during installation and disassembly.

Sources of information
1. USSR author's certificate N 1554989, MKI B 07 B 1/00, 1/40, publ. 04/07/90. Bull. N 13. Hydro screen. V.F.Slesarenko.

 2. USSR author's certificate N 485783, MKI B 07 B 1/00, publ. 09/30/75. Bull. N 36.

Claims (2)

 1. A hydraulic screen, including a box with receiving and unloading sieves, mounted on elastic elements and immersed in a hopper with water, a slurry receiver, unloading tray, a drive that informs the vibration box, characterized in that the drive is equipped with a differential two-crank mechanism made in the form of a driven crank, the center of rotation of which is located with vertical and horizontal eccentricities relative to the center of rotation of the driving crank.  2. The hydraulic screen according to claim 1, characterized in that the hydraulic screen box is equipped with vertical guides for screens.

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