RU2603040C1 - Small-size machine for loose materials mixing - Google Patents

Abstract

FIELD: technological processes; machine building.

SUBSTANCE: invention relates to feedstuffs and other loose materials mixing devices. Machine comprises screw drum, loading device, unloading device and loading and unloading-separating devices mounted into machine. Screw drum is divided in two and more helical drums mounted in tiers, one above other and connected into single process chain in container, equipped with vibration exciter, resilient elements, loading and unloading devices. Screw drums are made of two parts rigidly connected to each other, and are made of sections throughout entire length. Every next section is turned relative to previous one by 120° to form conical shaped multiple-start helical surface. Along screw drum entire length three broken screw lines are formed. Direction of three broken helical lines below each of tiered screw drums is opposite to direction of three broken helical lines mounted above screw drum.

EFFECT: invention will allow to improve bulk materials mixing quality.

1 cl, 12 dwg

Description

The invention relates to devices for mixing, in particular to continuous mixers for mixing feed components and other bulk materials.

Known drum feed mixer and.with. No. 1666173, cl. A23N 17/00, 1987, comprising a drum with helical surfaces, consisting of sections, each of which is made of identical plates, having the shape of equilateral triangles, interconnected by two sides on the surface of the drum and placed at an angle to each other and to its axis, while the sections are interconnected by the free sides of the plates and form multidirectional screw surfaces of equal pitch, and the number of plates in the section is even and at least six.

A disadvantage of the known device is the insufficient productivity of the preparation of feeds due to some stationarity of the movement of feed flows in a multi-helical drum with equal-pitch helical surfaces directed towards each other and with the same number of strokes, assembled from elements of equal size, size and configuration in the form of equilateral triangles, forming in the cross section coaxial with the axis of rotation of the drum flat figures polyhedrons, as well as large dimensions in length.

Closest to the proposed invention is a machine for preparing feed and separating them into fractions (patent No. 2540583, class A23N 17/00, publ. 02/10/2015, bull. No. 4), containing mounted on a bed with a rotary drive of the screw drum , means for loading feed components and means for receiving finished feeds and mounted loading and unloading-separating devices.

A disadvantage of the known device is the large dimensions in length, limited technological capabilities due to the fact that the preparation of mixing bulk materials is carried out with an almost constant longitudinal and cross section of the screw drum from loading to unloading and insufficient productivity due to the insufficient intensity of interaction of particles of bulk materials with each other .

The technical solution to the problem is to reduce dimensions along the length, increase productivity and expand technological capabilities by imparting to the particles of bulk materials a complex pulsating-wave spatial motion and simultaneous exposure to vibrations in three mutually perpendicular directions.

The technical solution is achieved by the fact that in a small-sized machine for mixing bulk materials containing a screw drum, a means for loading, a means for unloading and loading and unloading-separating devices mounted in the machine, the screw drum is divided along the length into two or more screw drums mounted in tiers under each other and connected in a single technological chain in a container equipped with vibration exciters, elastic elements, means for loading and unloading, while screw ba rabans are made of two parts rigidly connected to each other and made of sections along the entire length, and the first part is first collected from loading bulk materials from sections in the form of identical hollow tetrahedrons mounted from equilateral triangles with side W and the formation of a multi-helical helical surface of cylindrical shape, and the second part is assembled before unloading bulk materials from successively installed sections, each of which is mounted from two pairs of triangles connected by the sides mi, while the first pair is made of identical isosceles triangles with a base equal to the side W of the triangle of the tetrahedron of the first part, and the second pair is made of an isosceles triangle equal to the isosceles triangle of the first pair and an equilateral triangle, the sides of which are equal to the side of the isosceles triangle, and each subsequent the section is rotated, relative to the previous one, by 120 °, with the formation of a multi-start helical surface of a conical shape, and along the entire length of the screw drum broken lines would be formed three helices, with the direction of the polygonal three helices each of tiered screw installed below the drum opposite the direction of three lines of the helical screw polygonal drum mounted above.

According to the patent literature not found a technical solution similar to the claimed, which allows to judge the inventive step of the proposed small-sized machine for mixing bulk materials.

The novelty of the invention lies in the fact that the screw drum is divided along the length into two or more screw drums mounted tiered one under the other and connected in a single technological chain in a container equipped with a vibration exciter, elastic elements, means for loading and unloading, which reduces the working area and reduces the dimensions of the machine in length.

The novelty is due to the fact that screw drums are made of sections along the entire length, and first from loading bulk materials from sections in the form of identical hollow tetrahedrons made of equilateral triangles with the formation of a multi-helical helical surface of a cylindrical shape, and then to unloading bulk materials from successively installed sections , each of which is mounted from two pairs of triangles connected by the sides, while the first pair is made of identical isosceles triangles ikov, and the second pair is made of an isosceles triangle equal to an isosceles triangle of the first pair and an equilateral triangle, the sides of which are equal to the lateral side of the isosceles triangle, and each subsequent section is rotated 120 ° relative to the previous one, with the formation of a multi-helical conical shape, which is not only increases the frequency of interaction of particles of bulk materials with each other and with the walls of the screw drum, but also increases the energy intensity of collisions, manufacturer spine and extends the technological capabilities.

The novelty of the invention lies in the fact that during the operation of the vibration exciter, particles of bulk materials circulating inside the screw drums rigidly fixed in the vibrating housing in planes perpendicular to their horizontal axes receive additional movement from the internal surfaces of a triangular shape, which increases the mixing performance, extends the technological opportunities.

The novelty also lies in the fact that under the influence of the perturbing forces of the vibrator through the container walls, the particles of bulk materials rotate in planes perpendicular to the axis of symmetry of the screw drums, while the helical surfaces of the triangular shape of the screw drums change and give additional movement to the particles of bulk materials, provide increased productivity and also move them from loading to the outlet openings of the screw drums.

The novelty is that this design of the screw drum allows for axial pulsed-wave movement of particles of bulk materials from loading to unloading with a horizontal axis of the screw drums, which simplifies operation due to the lack of slope of the screw drums.

The novelty lies in the fact that thanks to the broken triangular-shaped internal screw pockets, the vectors of the speed of movement of particles of bulk materials during their transportation from loading to unloading change, which helps to increase productivity and extends technological capabilities.

The novelty of the proposal also lies in the fact that inside the drum helical surfaces are formed in the form of pockets of a triangular shape, which increases productivity and expands technological capabilities.

The novelty also lies in the fact that with the same diameters of the drums in the proposed design, the length of the path of the passage of particles of bulk materials compared with the known designs of the drums is much larger, which makes it possible to reduce the dimensions of the screw drum both in length and in diameter, as well as Enhances productivity and technology.

The novelty of the proposal lies in the fact that by increasing the bore of each screw drum from loading to unloading, i.e. first, a conditionally cylindrical, and then a conditional conical shape of each screw drum, the stationary movement of particles of bulk materials is violated, productivity is increased and technological capabilities are expanded.

The novelty is also due to the fact that the area and cross-sectional shape of each screw drum changes from loading to unloading, which changes the speeds and trajectories of the movement of particles of bulk materials as they move from loading to unloading, expanding technological capabilities.

The novelty is also due to the multiple changes in the longitudinal and cross sections, the speed of movement of particles of bulk materials in each of the three screw drums, namely: first, one speed of particles of bulk materials in the first part of the upper screw drum, then a different speed of particles of bulk materials in the second part a conical shape of a helical drum, then one speed of particles of bulk materials in the first part of the middle screw drum, then another changing speed of particles of bulk material fishing in the second part of the conical shape of the screw drum, then one speed of particles of bulk materials in the first part of the screw drum, then another changing speed of particles of bulk materials in the second part of the conical shape of the screw drum. Such a pulsating-wave change in the velocity of particles of bulk materials increases the intensity of miscibility, expands technological capabilities.

The novelty was created by imposing on a complex rotational movement from vibration in planes perpendicular to the horizontal axis of the screw drums, additional movement of particles of bulk materials imparted by the walls of the triangular shape of the screw drums, which expands technological capabilities, and also by increasing the speed in the second part of the conical screw drums forms. In the process of moving particles of bulk materials from loading to unloading, they make a complex spatial movement, since the direction of their movement under the influence of vibration changes under the influence of the triangular walls of the screw drums, which are different in size in each screw drum, which increases productivity.

The novelty is also ensured by reducing the working area of the occupied small-sized machine for mixing bulk materials by dividing along the length of the screw drum into two or more screw drums mounted tiered one under the other in a single technological chain.

In FIG. 1 shows a general view of a small-sized machine for mixing bulk materials; in FIG. 2 is a section AA in FIG. one; in FIG. 3 is a view A in FIG. one; in FIG. 4 is a view B in FIG. one; in FIG. 5 - one of three screw drums, front view; in FIG. 6 is a view B in FIG. 5; in FIG. 7 - the first part of the screw drum in the form of a multiple helical surface of a cylindrical shape; in FIG. 8 is a view D in FIG. 7; in FIG. 9 - the second part of the helical drum in the form of a multiple-helical surface of a conical shape; in FIG. 10 is a view D in FIG. 9; in FIG. 11 - section of the second part of the screw drum, a visual image; in FIG. 12 is an assembly diagram of a second part of a screw drum.

Small-sized machine for mixing bulk materials (Fig. 1, 2, 3, 4) consists of means for loading 1, means for unloading 2, container 3, mounted with elastic elements 4 on the base 5. At the bottom of the container 3, vibration exciters 6 are mounted . In the container 3, made closed on all sides, screw drums 7, 8, 9 are mounted under each other and connected into a single technological chain.

The helical drums 7, 8, 9 are hollow, one of which, for example 7, is shown in FIG. 5 and 6.

The direction of the helical lines of each of the belts below the screw drums is opposite to the direction of the helical lines of the screw drum mounted above, for example, the direction of the helical lines of the screw drum 8 is opposite to the direction of the helical lines of the screw drum 7, and the direction of the helical lines of the screw drum 9 is opposite to the direction of the helical lines of the screw drum 8 ( Fig. 1). Therefore, the operation of a small-sized machine for mixing bulk materials ensures continuous movement of particles of bulk materials from loading to unloading.

The nozzle of the loading device 1 is mounted in the inlet of the screw drum 7. The outlet 10 of the screw drum 7 is closed by a lid 11, which simultaneously covers the inlet 12 of the screw drum 8, which ensures the movement of particles of bulk materials from the upper (first) screw drum 7 to the underlying (second) screw drum 8, namely from the outlet 10 of the screw drum 7 to the inlet 12 of the screw drum 8. The outlet 13 of the second screw drum 8 is closed by a cover 14, which simultaneously closes the inlet 15 of the underlying third screw drum 9, allowing the transfer of particle flows of bulk materials from the second middle screw drum 8 to the lower third screw drum 9. For receiving flows of finished materials mounted under the outlet 16 of the third screw drum 9 means for unloading 2 .

Screw drums 7, 8, 9, for example 7 (Fig. 5, 6), are made of two parts, rigidly connected to each other, and made along the entire length of the sections, the first part 17 first from loading bulk materials from the sections in the form identical hollow tetrahedrons made of equilateral triangles with side W (Fig. 7, 8) and the formation of a multi-helical helical surface of a cylindrical shape, and the second part 18 (Fig. 9, 10) before unloading bulk materials is made of sequentially installed sections, each of which mounted of two pairs of triangles connected by the lateral sides, the first pair being made of identical isosceles triangles with a base equal to the side W (Fig. 9) of the tetrahedron triangle of the first part of the screw drum, and the second pair is made of an isosceles triangle equal to an isosceles triangle of the first pair, and an equilateral triangle, the sides of which are equal to the side of the isosceles triangle, with each subsequent section being rotated relative to the previous one by 120 °, made of conical shape from after well-established sections, for example 19, 20, 21 (Fig. 12), each of which is made in the form of mounted two pairs of triangles A and B (Fig. 11) connected by the sides. The first pair of triangles A is made of two identical isosceles triangles 22 and 23. The second pair of triangles B is mounted from an isosceles triangle 24, equal to triangles 22 and 23 of the first pair A and an equilateral triangle 25, whose sides are equal to the lateral sides of triangles 22, 23, 24.

Each subsequent section (Fig. 12) when assembling a screw drum is rotated relative to the previous one by 120 °. For example, in FIG. 12 section 20 is rotated clockwise relative to the previous section 19, the next section 21 is also rotated 120 ° relative to the previous section 20, etc., the rotation of sections 19, 20, 21 in FIG. 12 is fixed by the vertices D ₁ for clarity , D ₂ and D ₃ ,

The first part of the screw drums 7, 8, 9, for example in FIG. 7 and 8 show the first part 17 of the screw drum 7, first from loading bulk materials made of sections in the form of identical hollow tetrahedrons made of equilateral triangles with side W with the formation of a multi-helical helical surface of a cylindrical shape. The tops of the tetrahedra 26-27-28-29-30; 31-32-33-34-35; 36-37-38-39-40 form clearly defined three broken helical lines (Fig. 7) around the perimeter of the hollow first part 17 of the screw drum, for example 7, inside which particles of bulk materials move. The cross-sectional shape of the first part 17 of the screw drum, for example 7 (Fig. 8), is an irregular quadrangle, while along the length of the first part 17 of the screw drum 7 not only the shape and dimensions of the sides of the quadrangle change, but also their location relative to the axis of symmetry of the first part of the screw drum.

The second part 18 of the screw drums 7, 8, 9, for example in FIG. 9 and 10 show the second part 18 of the screw drum 7, made conical with broken helical lines around the perimeter, which are shown in FIG. 9 and 10 with thickened lines 41-42-43-44; 45-46-47-48; 49-50-51-52. Thus, the second part 18 (Fig. 9, 10) before unloading bulk materials is assembled from successively installed sections, each of which is mounted from two pairs of triangles connected by the sides, while the first pair is made of identical isosceles triangles with a base equal to the side W (Fig. 9) of the triangle of the tetrahedron of the first part, and the second pair is made of an isosceles triangle, equal to an isosceles triangle of the first pair, and an equilateral triangle, whose sides are equal to the side obedrennogo triangle, and each subsequent section is rotated relative to the previous one by 120 °. Those. the second part of the helical drum is made of conical shape from sequentially installed sections, for example 19, 20, 21 (Fig. 12), each of which is made in the form of mounted two pairs of triangles A and B (Fig. 11) connected by the side sides. The first pair of triangles A is made of two identical isosceles triangles 22 and 23. The second pair of triangles B is mounted from an isosceles triangle 24, equal to triangles 22 and 23 of the first pair A, and an equilateral triangle 25 whose sides are equal to the lateral sides of triangles 22, 23, 24.

Each subsequent section (Fig. 12) when assembling the second part of the screw drum is rotated relative to the previous one by 120 °. For example, in FIG. 12 section 20 is rotated clockwise relative to the previous section 19, the next section 21 is also rotated 120 relative to the previous section 20, etc., rotation of the sections 19, 20, 21 in FIG. 12 for clarity, is fixed by the vertices D ₁ , D ₂ and D ₃ .

After assembling the first part 17 and the second part 18, they are rigidly joined, for example by welding, to each other, for example, with their end hole 30-35-40 of the first part 17 of the screw drum with the end hole 45-49-41 of the second part of the screw drum with the formation along the perimeter a helical drum, for example 7 three helical lines 36-37-38-39-40 (41) -42-43-44; 26-27-28-29-30 (45-35 (49) -50-51-52; 31-32-33-34-30 (45) -46-47-48 (Fig. 5).

Small-sized machine for mixing bulk materials is as follows.

By means of a loading device 1, particles of bulk materials are continuously loaded into the upper screw drum 7. Under the influence of the disturbing forces of the rotating vibrators 6, disturbing forces are transmitted to the particles of bulk materials through the walls of the container 3 and rigidly connected screw drums 7, 8, 9. Particles of bulk materials under the influence of these disturbing forces under the influence of vibration rotate in planes perpendicular to the axis of symmetry of the screw drums 7, 8, 9. Moreover, the triangular walls of the screw drums 7, 8, 9 change and give additional movements to the particles of bulk materials and provide increase mixing performance, and also move them from the load to the outlet, for example to the outlet 10 of the screw drum 7.

Under the influence of vibration and helical lines around the perimeter of the screw drum 7, as well as using the cover 11, particles of bulk materials are loaded through the hole 12 into the underlying screw drum 8, along the perimeter of which there are helical lines whose direction is opposite to the direction of the helical lines of the upper helical drum 7. Under the action of vibration and helix lines around the perimeter of the screw drum 8 particles of bulk materials in the screw drum 8 are moved to the outlet 13 and through the cover 14 are moved h Through the inlet 15 into the inner cavity of the screw drum 9. Under the influence of vibration and helical lines around the perimeter of the screw drum 9, the particles of bulk materials move along the horizontal axis and through the hole 16, as well as with the help of a discharge device 2 are moved outside the small-sized machine for mixing bulk materials .

Technical and economic advantages arise due to multiple changes in the longitudinal and cross sections, as well as the speed of movement of particles of bulk materials in each of the three screw drums, namely, at first one speed is communicated to the particles of bulk materials in the first part of the upper screw drum 7, then a different speed is communicated particles of bulk materials in the second part of the conical shape of the screw drum 7, then one speed is communicated to the particles of bulk materials in the first part of the middle screw about the drum 8, then another varying speed is communicated to the particles of bulk materials in the second part of the conical shape of the screw drum 8, then one speed is communicated to the particles of bulk materials in the first part of the screw drum 9, then another varying speed is communicated to the particles of bulk materials in the second part of the conical shape of the screw drum 9. Such a pulsating-wave change in the velocity of particles of bulk materials increases the intensity of miscibility, increases productivity, extends technology RP G capability.

Technical appraisal and economic advantages of the invention arise due to an increase in productivity, imposition of complex rotational motion from vibration in planes perpendicular to the horizontal axis of the screw drums, additional movement of particles of bulk materials imparted with different sizes and relative positioning by the walls of the triangular shape of the screw drums, which expands the technological capabilities, and also by increasing the speed in the second part of the helical drums of a conical shape. In the process of moving particles of bulk materials from loading to unloading, they make a complex spatial movement, since the direction of their movement under the influence of vibration changes under the influence of the triangular walls of the screw drums, which are different in size in each screw drum, which increases productivity. Technical and economic advantages are also ensured by reducing the working area of the occupied small-sized machine for mixing bulk materials.

Claims (1)

A small-sized machine for mixing bulk materials containing a screw drum, a means for loading, means for unloading and loading and unloading-separating devices mounted in the machine, characterized in that the screw drum is divided along the length of two or more screw drums mounted half-under one another and connected in a single technological chain in a container equipped with vibration exciters, elastic elements and means for loading and unloading, while the screw drums are made of two parts rigidly connected to each other and made of sections along the entire length, the first part being assembled first from loading bulk materials from sections in the form of identical hollow tetrahedrons mounted from equilateral triangles with side W to form a multi-helical helical surface of a cylindrical shape, and the second the part is assembled before unloading bulk materials from sequentially installed sections, each of which is mounted from two pairs of triangles connected by the sides, while the first the pair is made of identical isosceles triangles with a base equal to the side W of the triangle of the tetrahedron of the first part, and the second pair is made of an isosceles triangle, equal to the isosceles triangle of the first pair, and an equilateral triangle, whose sides are equal to the side of the isosceles triangle, with each subsequent section turned relative to the previous 120 ° with the formation of a multi-helical conical surface of the helix, moreover, three broken lines are formed along the entire length of the screw drum helical lines, while the direction of the three broken helical lines of each of the half-below the installed helical drums is opposite to the direction of the three broken helical lines of the helical drum mounted above.

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