RU2188720C2 - Drum-type screen - Google Patents

Abstract

FIELD: construction industry, metallurgy and other branches of industry using bulk material classifying equipment. SUBSTANCE: drum-type screen has screening surface arranged between end cheeks and made in the form of broken line spiral tunnel having rectangular section. Tunnel is assembled from sections, each subsequent section being turned relative to previous section through 90 deg. Screen is further provided with charging and discharge devices, and drive. Each section is composed of large and small rectangles and two similar trapeziums, whose lower bases are equal to side of small rectangle. Sides of trapezium are equal to two other sides of large and small rectangles so as to define squares at ends of sections, these squares being equally inclined in different directions toward section axis. EFFECT: increased efficiency and improved quality of screening bulk materials. 8 dwg

Description

 The invention relates to techniques for the classification of bulk materials and can be used in the construction, mining, metallurgical and other industries.

 Known drum screen (AS USSR 613830, class B 07 B 1/00, 1976), containing a screening surface located between the end cheeks, loading, unloading devices and drive.

 A disadvantage of the known drum screen is the insufficient mixing intensity, while rotating the drum there is a simple sliding of the screening mass on the inner surface of the drum.

A drum screen is known, including a screening surface located between the end cheeks, made in the form of a broken spiral shape of a tunnel assembled from sections, each subsequent of which is rotated 90 ^° relative to the previous one, loading and unloading devices, drive (see 1808417 A1, 15.04 .1993, 07 B 1/22), adopted as a prototype.

 A disadvantage of the known drum screen is the insufficient intensity of mixing the screening mass due to some stationary motion of the streams of the screening mass in a multi-start helical drum in the form of a helical tetrahedral column with equal-pitch helical lines directed to each other and with the same number of strokes, as well as insufficient mixing intensity in the drum assembled from elements of the same size, size and configuration in the form of equilateral triangles forming transversely m section coaxial with the axis of rotation of the drum-flat shape polyhedrons.

 The technical solution to the problem is to increase the productivity and efficiency of screening.

The task is achieved in that in a drum screen, including a screening surface located between the end cheeks, made in the form of a broken spiral shape of a tunnel assembled from sections, each of which is rotated relative to the previous one by an angle of 90 ^o , loading and unloading devices, drive, according to According to the invention, the tunnel is made with a rectangular cross-section, and each of the sections is mounted from large and small rectangles and two identical trapeziums, the lower bases of which are equal to the lateral side of the small rectangle, while the sides of the trapezoid are equal to the other two sides of the large and small rectangles with the formation of squares at the ends of the sections, equally inclined in different directions to the axis of the section.

 The novelty of the invention lies in the fact that such a structural design of the screening surface allows, due to the presence on the surface of the drum intermittent broken helical lines, to increase the efficiency of screening due to increased miscibility.

In addition, the novelty is due to the fact that the cross-sectional passage of the drum is rotated relative to the previous along the length of the drum and for each revolution of the screening surface, the passage-through section makes a rotation of 360 ^o , which increases the miscibility and intensity of screening.

 The novelty is that the axis of each section is inclined to the axis of the screening surface at an acute angle, and the axis of each section and the axis of the screening surface are crossed and do not intersect.

 The novelty lies in the fact that a tunnel with a rectangular flow cross section formed along the length of the screening surface provides not only the axial movement of the classified material from loading to unloading, but also increases productivity and screening efficiency.

 In FIG. 1 shows a drum screen; in FIG. 2 - section aa; in FIG. 3 - screening surface; in FIG. 4 - screening surface, top view; in FIG. 5 - one of the sections of the screening surface; in FIG. 6 and 7 - arrangement of axes of sections of the screening surface, two projections; in FIG. 8 - view B.

 The drum screen consists (Fig. 1 and 2) of a frame 1 on which the drive 2 is mounted, an unloading device 3, end cheeks 4 and 5, between which a screening surface 6 is fixed, a loading device 7, which is made in the form of a rigidly fixed in the shell 8 equipped with a cone 9, screw winding 10. The screening surface 6 is fixed rigidly between the cheeks 4 and 5 and is equipped with a support ring 11, which is supported by two support rollers 12 and 13. The cheek 4 is rigidly connected by rods 14 to the disk 15 of the drive shaft 2. Support rollers 12 and 13 mounted on frame 1. On frame 1, under the unloading device 3, a receiving tray 16 for large fractions is mounted. Under the screening surface 6, a receiving tray 17 is mounted for receiving fine fractions.

 The screening surface 6 (Fig. 3 and 4) is made in the form of a broken spiral shape of a tunnel with a rectangular passage section and is mounted from sections 18.

 Each of the sections 18 is assembled (Fig. 3) from two rectangles: large 19, small 20, and two trapezoids 21 and 22, the lower bases of which are equal to the side of the small rectangle 20. Moreover, the remaining two free sides of the rectangles 19 and 20 are equal to the sides trapezoid 21 and 22 with the formation at the ends of the sections of squares, equally inclined in different directions to the axis of the section.

When mounting the screening surface 6, each section 18 relative to the previous one is rotated through an angle of 90 ^o .

 As a result of joining the sections, a screening surface is formed in the form of a broken spiral tunnel shape with a rectangular passage section and with intermittent broken helical lines around the perimeter 23-24-25; 26-27-28, 29-30-31 (Figs. 3 and 4).

 When mounting the screening surface and rotating sections 18 clockwise, a drum is formed with a spiral tunnel shape, with the right direction of intermittent broken helical lines and the right direction of movement of the classified material. In FIG. 6-8, arrows show the direction of movement of the classified material.

The axes of the sections, including the axis i ₁ -i _{1 of the} first section (Fig. 6 - 8), to which the second section is connected with the axis i ₂ -i ₂ , then the third section is connected with the axis i ₃ -i ₃ , and also attached the fourth section with the axis i ₄ -i ₄ , then the fifth section is connected with the axis i ₅ -i ₅ and so on, relative to the axis of rotation of the drum screen O ₁ -O ₂ are intersecting straight lines and they do not intersect with each other.

The drum screen works as follows:
The classified material enters the loading device 7, from which it is fed to the inlet of the screening surface 6 by winding 10. When the screening surface 6 rotates, the classified material makes a complex spatial movement, which is aggravated by the asymmetry of movement of the classified material, and moves from loading to unloading.

As a result, not only the stationary motion of the loading masses is violated by the geometry of the passage section, but also the miscibility increases due to the removal of the axes of the tunnel sections i ₁ -i ₁ ; i ₂ -i ₂ ; i ₃ -i ₃ ; i ₄ -i ₄ ; i ₅ -i ₅ etc. from the axis of rotation of the screening surface O ₁ -O ₂ , as well as their location as intersecting straight lines relative to each other. Intermittent broken lines 23-24-25, 26-27-28, 29-30-31 also contribute to this.

 When moving the classified material inside the screening surface from loading to unloading, small fractions are discharged into the receiving tray 17, and large fractions are discharged through the unloading device 3 into the receiving tray 16.

Since the cross section varies along the length of the screening surface relative to each other and the distance from the axis of rotation of the drum is O ₁ -O ₂ , as well as the shape of the sections (from rectangle to polygon) at the junction of sections, there is an increase in productivity and screening efficiency .

Claims (1)

A drum screen, including a screening surface located between the end cheeks, made in the form of a broken spiral shape of a tunnel assembled from sections, each of which is rotated 90 ^° relative to the previous one, loading and unloading devices, the drive, characterized in that the tunnel is made with a rectangular passage section, and each of the sections is mounted from a large and a small rectangle and two identical trapezoids, the lower bases of which are equal to the side of the small rectangle while the sides of the trapezoid are equal to the other two sides of the large and small rectangles with the formation at the ends of the sections of squares, equally inclined in different directions to the axis of the section.

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