RU2362628C1 - Device for grinding of loose materials - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention is related to procedure of hard materials grinding. Device for grinding of loose materials comprises multi-section drum, every section of which is assembled out of quadrangles with end creation of sections of square turned relative to square of previous section by 90°, made of large and small rectangles and two identical trapezoids, lower bases of which are equal to lateral side of large rectangle, and upper bases are equal to lateral side of small rectangle. Lateral sides of trapezoids are equal to remaining two sides of large and small rectangles with end creation of sections inclined to different sides and to axis of square sections, at that creating broken helical shape of tunnel with rectangular flow section, loading, unloading accessories and drive mounted in frame suspended by means of rubber-cord pneumatic balloons to bed plate. Sections are arranged as different in shape and size increasing from loading to unloading, are joined serially and alternately. The first section is made of two sub-sections, one of which is mounted out of two large scalene triangles joined by their bases to lateral sides of large equilateral trapezoid, and the second sub-section is mounted from small equilateral trapezoid, to lateral sides of which two small scalene triangles are joined by their small lateral sides, bases of which are equal to large lateral sides of triangles of the first sub-section, with which sub-sections are joined to each other. Upper bases of trapezoids of two sub-sections are equal to each other and are equal to small lateral sides of triangles of the first sub-section with creation of small inlet opening of section, and lower bases of trapezoids are equal to each other and are equal to large lateral sides of the second sub-section triangles with creation of large outlet opening of section, to which the second section is connected, arranged in the form of straight triangular prism created by cube section along diagonal.

EFFECT: expansion of technological resources.

10 dwg

Description

The invention relates to techniques for grinding solid materials and can find application in the construction, chemical, metallurgical industries, as well as in agricultural production.

Known tube mill (A.S. No. 1733086, class B02C 17/02, publ. BI No. 18, 05/15/1992) containing a drum, loading, unloading device and drive mounted on a frame suspended by rubber cord pneumocylinders to the frame, the lateral surface of each drum section is made by alternately connected rectangles and parallelograms with the formation of square sections at the ends, while the square of each subsequent section is rotated relative to the previous square by an angle of 90 ° with the formation of continuous zigzas on the surface of the drum Ago-shaped lines with a step that is constant along the length of the drum and with a constant passage diameter of the drum.

A disadvantage of the known device is the insufficient intensity of grinding and limited technological capabilities due to the fact that grinding is carried out with a practically constant longitudinal and cross section of the drum from loading to unloading and insufficient mixing intensity and insufficient intensity of interaction of material particles with each other, as well as the need to create a tilt of the drum for transporting material from loading to unloading.

Closest to the proposed device is a drum mill (patent No. 2209669, class B02C 17/04, publ. BI No. 22, 08/10/2003), containing a drum, loading, unloading devices and a drive mounted on a frame suspended by rubber-cord pneumocylinders to bed, each section of the drum is assembled from quadrangles made of large and small rectangles and two identical trapezoids, the lower bases of which are equal to the side of the large rectangle, and the upper bases are equal to the side of the small rectangle alpine, the sides of the trapezoid are equal to the other two sides of the large and small rectangles with the formation of squares on the ends of the sections, which are differently inclined in different directions and to the axis of the sections, while forming a broken spiral-shaped tunnel with a rectangular passage section and with interrupted zigzag-shaped broken helical lines.

A disadvantage of the known device is the limited technological capabilities due to the fact that the grinding is carried out with a practically constant longitudinal and cross section of the drum from loading to unloading and insufficient mixing intensity and insufficient interaction of material particles with each other, insufficient grinding intensity, and the need to create a tilt of the drum to move material from loading to unloading.

The technical solution of the problem is the expansion of technological capabilities due to the formation of a multi-start conditionally conical helical surface along the drum perimeter and four broken conical helical lines of the main direction and two broken helical lines of the opposite direction with increasing not only the pitch of the helical lines, but also the cross-sectional area directed towards each other drum from loading to unloading.

The technical solution is achieved by the fact that in a device for grinding bulk materials containing a multi-section drum, each section of which is assembled from quadrangles with the formation at the ends of the sections of the square, rotated 90 ° relative to the square of the previous section, made of large and small rectangles and two identical trapeziums, whose lower bases are equal to the lateral side of the large rectangle, and the upper bases are equal to the lateral side of the small rectangle, with the sides of the trapezoid equal to the rest the two sides of the large and small rectangles with the formation on the ends of the sections of squares differently inclined in different directions and to the axis of the sections, thus forming a spiral-shaped tunnel with a rectangular passage section, loading, unloading devices and a drive mounted on a frame suspended by rubber-cord pneumocylinders to according to the invention, the sections are made different in shape and size, increasing from loading to unloading, connected in series and alternately, with the first The section is made up of two subsections, one of which is mounted from two large miscellaneous triangles connected by its bases to the sides of the large equilateral trapezoid, and the second subsection is mounted from the small equilateral trapezoid, to the lateral sides of which are two small miscellaneous triangles, bases which are equal to the large lateral sides of the triangles of the first subsection, by which the subsections are connected to each other, and the upper bases of the trapezoid are two x subsections are equal to each other and equal to the small lateral sides of the triangles of the first subsection with the formation of a small inlet of the section, and the lower bases of the trapezoid are equal to each other and equal to the large lateral sides of the triangles of the second subsection with the formation of a large outlet of the section to which the second section is connected, made in in the form of a straight triangular prism formed by a diagonal cube section.

According to the patent literature not found a technical solution similar to the claimed, which allows us to judge the inventive step of the proposed device for grinding bulk materials.

The novelty of the invention lies in the fact that by increasing the bore of the drum from loading to unloading, i.e. conditionally conical shape of the drum, the stationary motion of the crushed material and grinding bodies is violated, the productivity and grinding efficiency are increased and their movement from loading to unloading is ensured, technological capabilities expand.

The novelty is that the elements from which the sections and subsections are assembled are different in shape and size, so the mixing intensity increases, since these elements, working like shelves, capture different portions of the material being ground and grinding bodies and directing them towards to each other and to the walls of the drum, violate the stationarity of their movement, increase productivity and grinding efficiency, expand technological capabilities.

The novelty is also due to the fact that since the number of visits of helical broken lines of the main direction is twice as large as the number of helical broken lines of the opposite direction and the pitch of these helical lines increases from loading to unloading, not only is the intensification of mixing, energy intensity and particle interaction frequency material, but also their transportation from loading to unloading, expanding technological capabilities.

The novelty also lies in the fact that the centers of symmetry of each cross section of the drum along its length are displaced not only relative to each other, but also relative to the axis of rotation of the drum, which provides a significant increase in energy consumption, intensity and frequency of interaction of material particles and expands technological capabilities.

The novelty is also due to the fact that the elements from which the sections of the drum are assembled, different in area, size and configuration, interact with the material moving inside the drum, are directed to each other at certain angles and therefore direct this material at different angles, which increases the miscibility of the material, energy intensity and frequency of interaction of material particles and expands technological capabilities.

The novelty also lies in the fact that since the length of the drum changes not only the dimensions of the drum cross section, but also the shape of the drum cross section, which increase from loading to unloading, the mixing process is intensified, the amplitude of oscillations of the portions of the crushed materials and grinding media increases, t .e. the length of the path of their movement increases until they meet with other portions of the crushed materials and grinding bodies and with opposite walls of the rotating drum.

The invention is illustrated by drawings, where: in Fig.1 shows a device for grinding bulk materials, General view; figure 2 is a section aa in figure 1; figure 3 - mill drum, General view, front view; figure 4 - mill drum, top view of figure 3; 5 is a mill drum, view A, figure 3; 6 is a first section Assembly, a perspective view; Fig.7 is a first subsection of the first section in the Assembly, axonometric projection; Fig. 8 is a second sub-section of the first section, a perspective view; Fig.9 - the second section, axonometric projection; 10 is a diagram of an assembly of sections of a mill drum.

A device for grinding bulk materials consists (figure 1, figure 2) of the drum 1, loading 2 and unloading 3 devices and a drive (not shown). The drum 1 is provided with sleeves 4 and 5 with the possibility of rotation in the bearing bearings 6 and 7. The toe 8 of the loading device 2 enters the hole of the sleeve 4 of the drum 1. Loading device 2, the bearing supports 6 and 7 with the drum 1 mounted in them are fixed on the frame 9. The frame is suspended on four pneumatic tanks 10, which are mounted on the frame 11.

Drum 1 (Fig. 3, Fig. 4, Fig. 5) is mounted from two different sections alternately connected - the first section - A (Fig. 6) and the second section - B (Fig. 9) and is equipped with multidirectional broken conical helical lines with variable along the length of the drum 1 step S ₁ and S ₂ . The step of four broken conical helical lines S ₁ , one of which is shown in FIG. 3, FIG. 4 with a thickened line 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, twice the step of two broken conical helical lines of the opposite direction S ₂ , one of which is shown in Fig. 3, Fig. 4 by a double line 22-13-14-23-24-24-25-26-16-17-27-28-29-30-19-20- 31-32-33. Sections A and B differ from each other not only in shape, but also in size. The first section A (Fig.6) is mounted from two subsections 34 (Fig.7) and 35 (Fig.8) connected to each other by sides 36 and 37 (Fig.6). Subsection 34 (Fig. 7) is mounted from a large equilateral trapezoid 38 and two different-sided triangles 39 and 40, the bases of which are equal to the lateral sides of the trapezoid 38, along which they are connected at an angle of 90 °. The lateral sides 41 and 42 of the triangles 39 and 40 are equal to the upper base 43 of the trapezoid 38 with the lower base 44. The second subsection 35 (Fig. 6) is mounted (Fig. 8) from a small equilateral trapezoid 45, which is connected with its lateral sides 46 and 47 at an angle 90 ° with the small lateral sides of the triangles 48 and 49. The large lateral sides 50 and 51 of the triangles 48 and 49 are equal to the lower base 52 of the small trapezoid 45 and the lower base 44 (Fig.7) of the large trapezoid 38 with the formation of a large outlet of the first section. The upper base 53 of the small trapezoid 45 of the second subsection (Fig. 8) is equal to the upper base 43 of the trapezoid 38 and the sides 41 and 42 of the triangles 39 and 40 of the first subsection (Fig. 7) to form a small inlet of the first section. Therefore, when connecting subsections 34 and 35 (Fig. 6), since the sides 41, 42, 43, 53 forming the inlet of the first section are equal to each other and are located at an angle of 90 °, an inlet of a square shape is formed, and the sides 50 , 51, 52, 44, forming the outlet of the first section, are also equal to each other and are also located at an angle of 90 °, then the outlet is also square in shape, along which the second section B is connected to the first section A.

The second section B (Fig. 9) is made in the form of a straight triangular prism formed by the cross section of the cube diagonally, with the formation of the sides 54, 55, 56, along which the second section B is attached to the outlet of the first section A after rotation through 90 ° (Fig. 10).

The installation of the drum 1 (Fig. 10) is carried out in the following sequence: to the first section A with an inlet of a square shape equal to, for example, a = 500 mm, and an outlet of a square shape, for example, b = 600 mm, attached after 90 ° the second section B with side dimensions B = 600 mm, which, in turn, after turning 90 °, joins the next first section A with the dimensions of the square inlet already equal to = 600 mm, and the output square hole d = 700 mm. The next second section B is connected to the outlet of this section already with side dimensions w = 700 mm, etc. Installation of the drum sections 1 is subsequently carried out by sections A and B with the dimensions of the inlet and outlet square holes increasing from loading to unloading, sequentially and alternately. This structural design of the drum 1 provides a change in the length of the drum not only the size of the passage section of the drum (Fig.1-5), but also the shape of the passage section of the drum. Moreover, the centers of symmetry of the inner surface of the drum 1 in each of its cross-sectional elements along its length are displaced relative to the axis of rotation of the drum 1, which violates the stationary motion of the particles of the material.

A device for grinding bulk materials is as follows. The drum 1 is filled with balls or other crushing medium and crushed material or one crushed material. When the drum rotates a mixture of grinding media and material or a mixture of particles of different particle sizes, complex spatial motion along helical lines is reported with the material moving along helical lines from loading to unloading. The presence on the perimeter of four helical broken lines of the main direction and two broken helical lines of the opposite direction with different pitch helical lines complicates the trajectory of movement of the crushed materials, expands the technological capabilities of the device.

Technical and economic advantages arise due to increased mixing intensity, increased energy intensity and frequency of interaction between grinding media and material, which increases productivity and expands technological capabilities.

Claims (1)

A device for grinding bulk materials containing a multi-section drum, each section of which is assembled from quadrangles with the formation at the ends of the sections of the square, turned 90 ° relative to the square of the previous section, made of large and small rectangles and two identical trapezoid, the lower bases of which are equal to the side of the large rectangle, and the upper bases 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 straight polygons with the formation at the ends of the sections of differently inclined squares in different directions and to the axis of the sections of the squares, forming a spiral-shaped tunnel with a rectangular passage section, loading and unloading devices and a drive mounted on a frame suspended by rubber cord pneumocylinders to the bed, characterized in that sections are made different in shape and size, increasing from loading to unloading, connected in series and alternately, while the first section is made of two subsections, one of which which is mounted from two large miscellaneous triangles connected by their bases to the sides of a large equilateral trapezoid, and the second subsection is mounted from a small equilateral trapezoid, to the sides of which are attached two smaller miscellaneous triangles whose bases are equal to the large lateral sides of the triangles of the first subsection by which the subsections are connected to each other, and the upper bases of the trapezoid of the two subsections are equal to each other and equal to small the lateral sides of the triangles of the first subsection with the formation of a small inlet section, and the lower bases of the trapezoid are equal to each other and equal to the large lateral sides of the triangles of the second subsection with the formation of a large outlet section, to which the second section is connected, made in the form of a straight triangular prism formed by a cube section diagonally.

Images