RU2353438C2 - Drum-type vibrating screen - Google Patents

Abstract

FIELD: nanotechnology.

SUBSTANCE: invention relates to technology of screening granular materials and can be used during the manufacture of catalysts for obtaining nanostructure materials. Drum-type screen includes a frame with a vibration generator at the base through a shock-absorber, mounted on it with the capability of rotation of the drum with a screening surface, loading and unloading device. Screening is additionally provided with a reversible drive rotation. Arms in the form of plates are installed inside the drum, distance R₁ between the near edges of the plates and the axis of rotation of the drum is (0.65-0.7)R, and the distance R₂ between the distant edges of the plates and the axis of rotation - (0.8-0.95)R, where R - internal radius of the drum. Arms are connected to the drum with the help of hinges and provided with restrictors, which allows the plates to turn relative to the radial position at an angle if 15-25 degrees. Plates are connected with the rod through a link with an adjustable length; the rod is placed coaxially with the drum and is provided with a reversible drive, which turns this rod in a direction opposite to the turning of the drum.

EFFECT: increase in the efficiency of the screening process of a poly-disperse material.

3 cl, 8 dwg

Description

The proposed solution relates to the screening technique of granular materials and can be used in the manufacture of catalysts to obtain nanostructured materials.

A device is known comprising a drum with a screening surface, a rotation drive, loading and unloading units (AS USSR 1745367, B07B 1/22, publ. 07.07.92).

The disadvantage of this screen is low efficiency when screening particles with a diameter of less than 1-2 mm

This drawback is due to structural features of the known technical solutions.

For the prototype, a screen was adopted, including a frame with a vibration exciter located on the base by means of shock absorbers, a drum with a screening surface mounted on it with the possibility of rotation, loading and unloading devices (AS USSR No. 1747194, B07V 1/40, publ. 15.07.92) .

The disadvantage of this device is the low classification efficiency in the case when the source material contains a small amount (less than 30%) of small particles and at the final stage of the process the formation of a segregation core in the vicinity of the circulation center is inevitable, i.e. away from the screening surface.

The technical task of the proposed solutions is to increase the efficiency of the screening process.

The solution of the technical problem is achieved as follows.

The screen is additionally equipped with a reversible rotation drive, and blades in the form of plates are installed inside the drum, and the distance R ₁ between the proximal edges of the plates and the axis of rotation of the drum is (0.65-07) R, and the distance

R ₂ between the far edges of the plates with the axis of rotation of the drum is (0.8-0.95) R, where R is the inner radius of the drum.

The blades are connected to the drum by means of hinges and are equipped with stops that allow the blades to rotate relative to the radial position by an angle equal to 15-25 degrees.

In the device according to claim 1, in contrast to the known solutions, the blades are connected to the shaft by means of rods with adjustable length, and the shaft is located coaxially with the drum and is equipped with a reversible drive that rotates this shaft in the opposite direction to the rotation of the drum.

Figure 1 shows a drum screen, a General view; figure 2 is an option for fixing the blades pivotally with the installation of limiters; figure 3 shows a drum screen with blades connected to the shaft; figure 4 shows an option for mounting the blades with rods of adjustable length; figure 5 is a section aa in figure 1.

The drum screen contains a base 1 (Fig. 1), located on the base by means of shock absorbers 2, a frame 3 with a vibration exciter 4, a drum 5 with a screening surface 6 mounted on the frame with the possibility of rotation, where the diameter of the holes d is 1.05-1.1 of the diameter fine particles, loading 7 and unloading 8 devices, sampler 9, reversible rotation drive 10, blades 11, made in the form of plates and installed inside the drum 5. Figure 2 shows the mounting of the blades 11 to the drum 5 using hinges 12. For ogran For the rotation of the blades, limiters 13 and 14 are installed. Figure 3 shows a drum screen, in which the blades 11 are rigidly connected to the drum shaft.

Drum screen works as follows. The source material through the loading device 7 is fed into the drum 5, which vibrates due to the vibration exciter 4 and rotates (for example, clockwise) by a reversible drive 10. Under the action of vibration and rotation, the source material moves along the axis of the drum from the loading device 7 to the unloading device 8. When small particles pass through holes in the screening surface 6 and are removed from the drum by means of a unit 9. In the cross section of the rotating drum, the material moves in a closed circuit circulation circuit. When the polydisperse material moves in the cross section of the drum, particle size segregation occurs. Smaller particles are concentrated in the vicinity of the circulation center (v. C in FIG. 5). Thus, small particles are removed from the screening surface, resulting in reduced screening intensity, i.e. screen productivity decreases. In addition, small particles, even as a result of a long stay in the screen, do not pass through holes in the screening surface and screening efficiency is reduced. The blades 11 are installed in such a way that the segregation core is periodically destroyed and small particles move from the center of circulation to the screening surface. The destruction of the segregation core increases the intensity and efficiency of screening. It is from these considerations that the values of the radii R ₁ and R _{2 are} determined. Since the degree of filling the cross section of the drum in industrial screens varies from 0.1 to 0.4, R ₁ = (0.65-0.7) R, and R ₂ = (0.8-0.95) R. Smaller values of radius R are impractical to use, since in this case the blade will capture part of the material located in the rolling layer, and the concentration of small particles transported to the screening surface will decrease. For large values of the radius R2, the blade will capture part of the material of the rising layer in which the concentration of small particles is small, thereby decreasing the concentration of small particles moving to the screening surface 6. The value of the radius R ₁ > 0.7R is impractical to use, since in this case a large degree of filling the drum with material, part of the small particles located in the segregation core will not be captured by the blade, which will reduce the intensity of screening. For the same reasons, it is not practical to use R ₂ <0.8R.

The hinged mounting of the blades and their rotation relative to the radial position by an angle equal to 15-25 degrees, allows to increase the screening intensity by 10-15%. The choice of the angle of rotation is justified by the values of the angle of friction of the rest of granular material along the blade. For almost all granular materials, the angle of friction on the metal does not exceed 25 degrees.

The destruction of the core of the segregation is also promoted by the reverse rotation of the drum, since it also violates the cyclic process. When rotating in the opposite direction, small and large particles are mixed and the concentration of small particles near the screening surface increases, which contributes to an increase in screening intensity.

Comparison of the proposed device with analog and prototype was carried out on a laboratory setup with a drum diameter of 250 mm

During the experiments, a pre-prepared two-component mixture with a fixed concentration of the fine fraction was loaded into the drum. They included either a rotation drive or vibration. At regular intervals, small particles were weighed, which fell into the sampler through the holes in the shell of the drum. During the experiments, the drum rotation speed varied from 3 to 20 rpm. The concentration of the fine fraction varied from 10 to 90%. The degree of filling of the drum with polydisperse material varied from 0.1 to 0.4. The ratio of the diameters of large and small particles is from 1.2 to 3.

Figure 6 shows the characteristic dependence of the change in productivity on time during rotation of the drum, and figure 7 - with vibration. In Fig. 8, a characteristic dependence of the change in productivity on time is given under the combined action of the reverse rotation of the drum and vibration, and in this latter case, blades in the form of plates are installed inside the drum.

From the graphs it is seen that when using the proposed device, the intensity and efficiency of screening of the fine fraction is greater than when using vibration and rotation separately. In particular, the area under the curve in Fig. 8 when using the blades and reverse rotation is greater than the total area under the curves in Figs. 6 and 7.

Thus, the amount of the fine fraction screened for 100 s when using the present invention is greater, therefore, the efficiency is higher.

As the experimental results showed, the reverse rotation of the drum increases the screening efficiency compared to one-way rotation by 10-15%, and this maximum positive result is achieved if you change the direction of rotation of the drum after 10-20 full revolutions.

Thus, the results of experimental studies have shown that the best screening in intensity and efficiency is obtained when using the screen in accordance with the proposed technical solution.

Claims (3)

1. A drum screen, including a frame with vibration exciter located on the base by means of shock absorbers, a drum with a screening surface mounted on it with the possibility of rotation, loading and unloading devices, characterized in that the screen is additionally equipped with a reversible rotation drive, and blades in the form of plates are installed inside the drum and the distance R ₁ between the proximal edges of the plates and the axis of rotation of the drum is (0.65-0.7) R, and the distance R ₂ between the proximal edges of the plates and the axis of rotation of the drum is (0.8-0.95) R, where R is the inner radius of the drum. 2. The screen according to claim 1, characterized in that the blades are connected to the drum by means of hinges and are equipped with limiters, which allow the blades to rotate relative to the radial position by an angle equal to 15-25 °. 3. The screen according to claim 1, characterized in that the blades are connected to the shaft by means of rods with an adjustable length, the shaft being aligned with the drum and equipped with a reversible drive that rotates this shaft in the opposite direction to the rotation of the drum.

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