RU2594882C1 - Mill - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: invention relates to grinding of hard materials and can be used in construction, chemical and metallurgical industry, as well as in agriculture. Mill comprises a base, elastically mounted on the basis of the hollow housing with vibrator, loading and unloading devices. Housing is spiral from hollow tunnel with multistart screw surface. Along the perimeter housing is folded along a spiral axis 0₁-0₁ around the central rectilinear axis 0₂-0₂ of spiral housing. Housing is equipped with screw grooves in the form of pockets with three and more lateral sides. Housing consists of sections in the form of rings of identical shape and size, coiled from identical rhomb-shaped strips to trapezoids arranged on them. Trapezoids of lateral sides are located on lateral sides of rhomb-shaped strips. Top and bottom bases of trapezoids are arranged at an acute angle to axis of symmetry of the strip 0₃-0_3, wherein sections are interconnected with lateral sides of trapezium.

EFFECT: mill enhances the milling performance.

1 cl, 7 dwg

Description

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

Known vibration mill containing an elastically mounted housing with a vibrator ("Equipment of the factories of the paint and varnish industry", Publishing house "Chemistry", Leningrad branch, 1986, p. 371).

A disadvantage of the known device is the low intensity of grinding and limited technological capabilities in view of the low intensity of mixing.

Closest to the proposed invention is a vibration mill (RF patent No. 2350391, MKI, V02C 17/02, publ. 03/27/2009, bull. No. 9), containing an elastically mounted base with a vibrator mounted vertically.

The disadvantages of the known device are limited technological capabilities due to the circular shape of the trajectory of the vibrations of the body and the small grinding performance.

The technical solution is the expansion of technological capabilities, increasing the productivity of the mill.

The technical solution is achieved by the fact that in a mill containing a hollow body with a vibrator resiliently mounted on the base, loading and unloading devices, the housing is made spiral from a hollow tunnel with a multi-helical surface, rolled around a spiral axis 0 ₁ -0 ₁ around a central straight axis 0 ₂ -0 ₂ volute casing provided with helical grooves inside and outside the spiral at an angle to the axis 0 _{1 1} -0 hollow tunnel in the form of pockets with three or more sides, and is assembled from a ktsy as identical in shape and size of rings rolled from strips of the same diamond shape, which has a trapezoid, the sides of which are located on the sides of the rhomboid strip, and the upper and lower bases of the trapezoids are arranged at an acute angle to the axis of symmetry of the strip ₃ -0 0 ₃ and are fold lines located at distances from each other, equal to the length of the sides of the pockets, while the sections are connected to each other by the lateral sides of the trapezoid.

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 mill.

The novelty is seen in the fact that the case is made spiral with a multi-helical screw surface around the perimeter, which increases the grinding performance and expands the technological capabilities.

The novelty is due to the fact that due to the installation of a vibrator horizontally below the platform with the body, the shape of the body oscillation path is changed from circular to vertical ellipse, which provides an increase in the specific gravity of the total kinetic energy (E _p ) by 1.3-1.5 times and increases productivity.

The novelty is that the spiral case with a multi-start screw surface around the perimeter is equipped with screw grooves inside and outside at an angle to the axis of the spiral of the center of symmetry axis 0 ₁ -0 _{1 of the} spiral tunnel with the central rectilinear axis 0 ₂ -0 ₂ , which increases productivity.

The novelty is that the helical grooves of the spiral case are made in the form of pockets with three or more sides, which also increases productivity.

The novelty is seen in the fact that the spiral case is mounted from sections in the form of identical rings, rolled up from the same diamond-shaped strips, the sides of which are located on the sides of the diamond-shaped stripe, and the upper and lower bases of the trapezoid are at an acute angle to the axis of symmetry of the diamond-shaped stripe 0 ₃ -0 ₃ and are fold lines located at distances from each other, equal to the length of the sides of the pockets, while the sections are connected to each other by the lateral sides of the trapezoid, which increases productivity .

The novelty of the proposal also lies in the fact that along the entire perimeter of the spiral casing, the passage section varies not only in shape but also in area, which provides alternate compression and expansion of the crushed materials in each section of the spiral casing, which means increased productivity and expanded technological capabilities.

The novelty of the invention lies in the fact that the trapezoid of the diamond-shaped strips from which the sections are mounted are not only inclined to each other, but also to the axis of symmetry of the spiral casing, therefore, the degree of compression of particles of crushed materials increases, the process of grinding materials is intensified.

The novelty also lies in the fact that the spiral casing is made of sections, the walls of which are not only inclined to each other, but also to the direction of the rotational movement of particles of crushed materials moving under the influence of vibration in planes perpendicular to the passage section of the spiral casing, which complicates the trajectories of their movement , increases the intensity of grinding materials and expands technological capabilities.

The novelty is due to the fact that the sections from which the spiral case is assembled are mounted around the perimeter from rhomboid strips with trapeziums of different sizes and sizes marked on them, so the intensity and efficiency of grinding materials increases, and technological capabilities expand.

The invention is illustrated by drawings, where: in FIG. 1 shows a mill, a general view; in FIG. 2 is a section AA in FIG. one; in FIG. 3 - a visual image of a spiral casing; in FIG. 4 - a visual representation of the relative position of the spiral 0 ₁ -0 ₁ , along which a hollow tunnel with a multiple helical surface is rolled around a central straight axis 0 ₂ -0 ₂ ; in FIG. 5 - one of the diamond-shaped strips on which trapezoids are placed, the upper and lower bases of which are located at an acute angle to the axis of symmetry of the strip 0 ₃ -0 ₃ in the form of fold lines; in FIG. 6 - a strip of rhomboid shape, bent along the fold lines - the upper and lower bases of the trapezoid; in FIG. 7 is a pictorial representation of a diamond-shaped strip rolled up into a ring when the upper base nn ′ of the trapezium mnn′m is connected to the lower base of the trapezoid NMM′N ′.

The mill (Fig. 1, Fig. 2) contains a hollow spiral casing 1, rigidly fixed to the platform 2 elastically using four rubber-cord cylinders 3 mounted on the base 4. On the platform 2, the loading device 5 is rigidly fixed, and attached to the platform 2 below rigidly vibrator 6 with a horizontal axis of rotation. The mill is equipped with a discharge device 7.

The housing 1 (Fig. 1, Fig. 2, Fig. 3) is made spiral. In FIG. 4 shows a graphical representation of the relative position of the axis of the spiral - the center of the axis of symmetry 0 ₁ -0 _{1 of the} hollow tunnel of the spiral casing 1 (in Fig. 4 the spiral casing is shown conditionally with a cross section 8 of the hollow tunnel with a multiple helical surface) and the central straight axis 0 ₂ -0 ₂ spiral housing 1.

Thus, around the perimeter, the spiral casing 1 is made in the form of a spiral-shaped tunnel with a multi-screw helical surface around the perimeter and is provided with screw grooves inside and outside, arranged at an angle α to the axis of symmetry of the spiral 0 ₁ -0 _{1 of the} center of the axis of symmetry (Fig. 3) of the tunnel spiral, coiled 0 ₁ -0 ₁ around the central axis 0 ₂ -0 _{2 of the} spiral housing 1.

The helical grooves of the spiral casing 1 are made in the form of pockets 9, 10, 11, 12, 13, 14 along the inner surface and pockets along the outer surface 15, 16, 17, 18, 19, 20 of the spiral-shaped tunnel (Fig. 3 and Fig. 4) with three or more sides mounted from sections in the form of identical rings 21 (Fig. 7), connected to each other by the sides 22 and 23.

The result is a hollow tunnel of the spiral casing 1 (Fig. 1, Fig. 2, Fig. 3) with the axis of the spiral - the center of the axis of symmetry 0 ₁ -0 _{1 of the} spiral casing 1, twisted around the central straight axis 0 ₂ -0 _{2 of the} spiral casing 1 in diameter D _cp with the formation of a spiral casing 1 with an outer diameter of D _max and with an inner diameter of D _min (Fig. 4).

In this case, the hollow spiral casing 1 with a multiple helical surface is provided with helical grooves in the form of pockets 9-14 on the inner surface and pockets 15-20 on the outer surface of the spiral casing 1 (Fig. 4).

Thus, a hollow tunnel with its own spiral axis of symmetry 0 ₁ -0 _{1 is} folded along this spiral 0 ₁ -0 ₁ around the central rectilinear axis 0 ₂ -0 ₂ and forms a spiral case 1 (Fig. 4).

Section 21 is made in the form of a ring (Fig. 7), mounted from a diamond-shaped strip 24 (Fig. 5), on which trapeziums are placed, the sides of which are located on the sides of the diamond-shaped strip 24, and the upper and lower bases of these trapezoids (Fig. 5 ) are located at an acute angle β to the axis of symmetry of the diamond-shaped strip 0 ₃ -0 ₃ and are fold lines (Fig. 5 and Fig. 6) located at distances from each other equal to the length of the sides of the pockets of the spiral casing 1, made in the form of a spiral hollow tunnel .

In FIG. 5 shows the trapezoid:

NMM′N ′ - the first trapezoid,

MFF′M ′ - second trapezoid,

FEE′F ′ - the third trapezoid,

ETT′E ′ - the fourth trapezoid,

TNN′T ′ - fifth trapezoid,

HRR′H ′ - sixth trapezoid,

RSS′R ′ is the seventh trapezoid,

SLL′S ′ - the eighth trapezoid,

LGG′L ′ - ninth trapeze,

GJJ′G ′ - the tenth trapezoid,

JZZ′J ′ - the eleventh trapezoid,

ZWW′Z ′ is the twelfth trapezoid.

In this case, NN ′ is the smallest of all the upper bases of the trapezoid located on the diamond-shaped strip 24, below the bend line WW ′ ′, and WW ′ is the largest of all the lower bases of the trapezoid located on the diamond-shaped strip 24, below the bend line WW ′ and the above twelve trapezoid.

In FIG. 5 also shows the trapezoid:

WPP′W ′ - the thirteenth trapezoid,

Pjj′P ′ - the fourteenth trapezoid,

jgg′j ′ - the fifteenth trapezoid,

gkk′g ′ is the sixteenth trapezoid,

kss′k ′ - seventeenth trapezoid,

srr′s ′ - the eighteenth trapezoid,

rhh′r ′ - nineteenth trapezoid,

htt′h ′ is the twentieth trapezoid,

tee′t ′ - twenty-first trapeze,

eff′е ′ - twenty-second trapezoid,

fmm′f ′ - twenty-third trapezoid,

mnn′m ′ is the twenty-fourth trapezoid.

Moreover, nn ′ is the smallest base of all the upper bases of the trapezoid located on the diamond-shaped strip 24, above the fold line WW ′, which for all trapezoids, in turn, is the largest of all the lower bases from the thirteenth to twenty-fourth trapezoid.

Thus, the fold line WW ′ is not only the lower base of the trapezoid ZWW′Z ′, but also the upper base of the trapezoid PWW′P ′ and the longest fold line of the ring 21 and the diamond-shaped strip 24.

Moreover, the fold lines NN ′ and nn ′ are the shortest of all the fold lines of the diamond-shaped strip 24 and ring 21.

The ratio of the length of the bending line WW ′ and NN ′ (nn ′) determines the value of step S, spiral 0 ₁ -0 ₁ , and hence the pitch of winding the hollow tunnel around the straight axis 0 ₂ -0 _{2 of} spiral housing 1.

The diamond-shaped strip 24 is bent along the straight fold lines, which are the bases of twenty-four trapezoids, as shown in FIG. 6, parallel to each other, and then rolled into a ring 21 (vig. 7) with a multifaceted surface.

The edges nn ′ and NN ′ are joined by known methods, for example, welding, soldering, etc. with the formation of the section in the form of rings 21 (Fig. 7).

Sections in the form of identical rings 21 are connected to each other sequentially by the lateral sides 22 and 23 so that all the fold lines are a continuation of the fold lines of the same name of the previous ring.

As a result of such assembly, helical lines are formed along the perimeter of the hollow spiral tunnel, as shown in FIG. 3, for example, with a thickened line 25-26-27-28-29-30-31-32-33-34-35.

Thus, the spiral case 1 (Fig. 1, Fig. 2, Fig. 3) is made around the perimeter in the form of a multiple helical spiral surface with helical lines around the perimeter of the spiral case 1 (one of the helical lines is shown in Fig. 3 with a thickened line 25- 26-27-28-29-30-31-32-33-34-35, and with helical grooves inside and outside the spiral case 1 in the form of pockets of a polygonal shape 9, 10, 11, 12, 13, 14 on the inner surface and 15 , 16, 17, 18, 19, 20 on the outer surface in the form of pockets of a polygonal shape at an angle α to the spiral axis of the hollow tunnel of the spiral shape of the spir 1 housing.

The spiral housing 1 (Fig. 1, Fig. 2, Fig. 3) in the form of a spiral hollow tunnel with a helical surface along its inner and outer perimeters with the formation of pockets of a polygonal shape can be made in another way.

The mill operates as follows.

The disturbing force of the vibrator through the walls of the spiral casing 1 is transmitted to the particles of crushed materials inside the spiral casing 1 and entering the spiral casing 1 in a continuous stream through the loading device 5. The particles of crushed materials rotate along vertical elliptical trajectories, during which the process of grinding materials occurs. In this case, the particles of the crushed materials not only intensively interact with each other, but also under the influence of vibration rotate in a plane perpendicular to the through section of the spiral casing 1. Since the spiral casing 1 has cross-sectional dimensions, shape and location, the disturbance of particle movement is aggravated crushed materials, which in this case interact with pockets of the polygonal shape of the inner walls of the spiral casing 1, i.e. there is an increase in the intensity of the crushed materials. The presence of helical surfaces and helical lines around the perimeter of the spiral casing 1 contributes not only to the complication of the trajectories of particles of the crushed materials, but also to their movement along the bore of the spiral casing 1 towards the discharge and discharge device 7.

When particles of the crushed materials move along the bore of the spiral casing 1 due to changes in the bore in shape and size, compression and rarefaction zones are formed in each section of the spiral casing 1 throughout its volume, which also intensifies the process of grinding materials and expands technological capabilities.

Technical and economic advantages arise due to the fact that the spiral case is made spiral from a hollow tunnel with a multi-start screw surface along the perimeter, coiled in a spiral, which provides increased productivity and expansion of technological capabilities, as well as due to the installation of a vibrator horizontally below the platform with a spiral case 1 that provides an increase in the specific gravity of kinetic energy by 1.3-1.5 times and increases productivity.

Claims (1)

A mill containing a hollow body with a vibrator resiliently mounted on the base, loading and unloading devices, characterized in that the body is made of a spiral from a hollow tunnel with a multi-helical surface, rolled around a spiral axis 0 ₁ -0 ₁ around a central straight axis 0 ₂ - 0 ₂ volute casing provided with helical grooves inside and outside the spiral at an angle to the axis 0 _{1 1} -0 hollow tunnel in the form of pockets with three or more sides, and is assembled from sections of the same x shapes and sizes of rings rolled from strips of the same diamond shape, which has a trapezoid, the sides of which are located on the sides of the rhomboid strip, and the upper and lower bases of the trapezoids are arranged at an acute angle to the axis of symmetry of the strip ₃ -0 0 ₃ and are fold lines located at distances from each other equal to the length of the sides of the pockets, while the sections are connected to each other by the lateral sides of the trapezoid.

Images