RU2657900C1 - Centrifugal device for mixing and grinding with elastic shell - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to devices for mixing and grinding powdered, cereal or lump materials and can be used for the preparation of powders and loose mixtures in construction, chemical, food and other industries, as well as in agriculture. Centrifugal device for mixing and grinding with an elastic shell consists of a body, a loading and unloading device, a drive of rotation of the working container, mounted on the housing with a rotatable and having a bottom, a cover and an elastic casing, rollers mounted on the rotation mechanisms of the roller rotation axis, the rollers being mounted outside the elastic casing such that the outer surface of the rollers contacts the outer surface of the elastic casing and deforms it in the direction of the rotation axis of the working container, flexible shell of the working capacity is attached to the lid, which is rotatably mounted in the housing, and radial projections are provided on the outer surface of the rollers in contact with the elastic shell of the working container.

EFFECT: reduction of wear of grinding bodies and working element of a centrifugal device for mixing and grinding with an elastic shell.

13 cl, 12 dwg

Description

The invention relates to a device for mixing and grinding powdered, grain or lump materials and can be used for the preparation of powders and bulk mixtures in the construction, chemical, food and other industries, as well as in agriculture.

A centrifugal mixer-dispersant is known, comprising a vertical cylindrical body, an elliptical cover and a bottom, a vertical shaft with a rotor in the form of a disk, on which a hollow thin-walled truncated truncated cone with bypass windows is concentrically mounted, guide vanes are installed spiral-shaped on the inner surface of the cone, having a circular arc profile, characterized in that bypass holes are made in the lower part along the entire length of the guide vanes, and cutouts having a rectangular shape are made in the upper part Ormu (RU No. 2311951, IPC B01F 7/26, B28C 5/16, d.p. 10.12.2007).

The disadvantage of the mixer is the relatively low quality of mixing and grinding by the homogeneity of the final product, the high duration of grinding and the presence of regrinding. In addition, the presence inside the working capacity of the working bodies in the form of a truncated cone and guide vanes leads to the appearance of grinding during grinding and mixing, as well as the need for a systematic replacement of worn working bodies.

The prototype of the claimed device is a mixer containing a housing, loading and unloading device, a rotational drive of an elastic container with a pressure roller and mixing rods, while it is equipped with a mechanism for changing the angle of the roller position, a disk placed kinematically connected to the rotation drive at the end of which is mounted rods and additional rollers, with one end of the axis of each of the rollers pivotally mounted in the housing, and the other connected with a mechanism for changing the angle of the position of the roller, complete in the form of a plate fixed to the body, in the radial grooves of which the ends of the axes of the rollers are placed, articulated by means of rods with a cross-piece that can be rotated, and a device for turning the plate (AC No. 1560427, B28C 5/00, V02C 17/02, publ. 30.04 .1990 g.).

The disadvantages include the presence within the elastic working capacity of quickly wearing working bodies - fingers requiring regular replacement, in addition, the absence of a speed difference between the fingers and the components being processed significantly increases the time for preparing the mixture. Low efficiency of grinding materials in the mixer when used as a mill, especially when grinding solid materials. The complexity of the design and implementation of the process of unloading the processed material from an elastic working tank.

A common disadvantage of the known mixers is the inefficiency of the use of these devices for grinding.

The technical result of the claimed invention is to reduce grinding, wear of grinding bodies and shells, increasing grinding fineness, and uniformity of the final processing product.

The technical result is achieved by the fact that in a centrifugal device for mixing and grinding with an elastic shell consisting of a housing, a loading and unloading device, a rotational drive of the working container mounted on the housing with the possibility of rotation and having a bottom, a cover and an elastic shell, rollers mounted on the rotation mechanisms axis of rotation of the rollers, while the rollers are installed outside the elastic shell so that the outer surface of the rollers is in contact with the outer surface of the elastic shell and deformations it is aligned in the direction of the axis of rotation of the working container, while the elastic shell of the working tank is attached to the cover mounted for rotation, and on the outer surface of the rollers in contact with the elastic shell of the working tank, radial protrusions, radial protrusions of at least one the roller is made on surfaces providing the law of motion of the deformable elastic shell of the working container in the direction of the axis of its rotation, with at least one final jump in acceleration; it is additionally equipped with mechanisms for translational movement of the rollers, and the mechanisms of rotation and translational movement are installed sequentially one after another; a movable platform is additionally mounted on the housing, on which at least one roller is rotatably mounted; the movable platform contains at least one mechanism for translational movement of at least one roller, at least one of the three possible coordinates and / or at least one rotation mechanism of the axis of rotation of at least one roller at least with respect to one of the three possible coordinates; at least one translational movement mechanism and / or at least one rotation mechanism of the axis of rotation of the rollers are provided with drives; the rollers are evenly distributed around the circumference of the elastic shell of the working tank with the outer radius R of the _tank , and their maximum number K and radius R of the _roller are determined from the condition of the neighborhood

one roller is equipped with a drive; the bottom of the working tank has a concave shape; the surface of the rollers is made of friction material; one roller is mounted on elastic supports; at least one roller mounted on elastic supports and / or at least one translational movement mechanism and / or at least one mechanism for turning the axis of rotation of the roller is equipped with a vibro drive; the elastic shell is provided with at least one rim.

The device is illustrated by drawings.

FIG. 1. A longitudinal section of a centrifugal device for mixing and grinding with an elastic shell;

FIG. 2. Schedule of movement S of the deformable element of the elastic and / or flexible shell of the working container in the direction perpendicular to the axis of rotation of the roller depending on the angle ϕ of rotation of the roller;

FIG. 3. The velocity graph V of the deformable element of the elastic and / or flexible shell of the working container in the direction perpendicular to the axis of rotation of the roller depending on the angle ϕ of rotation of the roller;

FIG. 4. Acceleration schedule A of the deformable elastic and / or flexible shell of the working container in the direction perpendicular to the axis of the roller with three final acceleration jumps depending on the angle ϕ of rotation of the roller;

FIG. 5. The layout of the roller when its axis of rotation is located in a plane parallel to the axis of rotation of the working tank;

FIG. 6. The layout of the roller when its axis of rotation is located in the plane of the axis of rotation of the working vessel at an angle to it;

FIG. 7. The layout of the roller when the axis of rotation of the working tank and the roller are crossed, with each other, without intersecting;

FIG. 8. A longitudinal section of a centrifugal device for mixing and grinding with an elastic shell, where the axis of rotation of the working container and the roller are crossed, with each other, without intersecting;

FIG. 9. Scheme of a mobile platform with mechanisms for translational movement of the roller along the coordinates;

FIG. 10. Scheme of a movable platform with mechanisms for rotating the axis of rotation of the roller relative to the coordinate axes;

FIG. 11. Scheme for determining the number and diameter of rollers from the conditions of the neighborhood;

FIG. 12. A longitudinal section of a centrifugal device for mixing and grinding with an elastic shell with elastic roller bearings and a vibratory drive.

The centrifugal device for mixing and grinding with an elastic shell (Fig. 1) contains a working tank 1, consisting of a cover 2 and a bottom 3 between which an elastic and / or flexible shell 4 is installed. The elastic and / or flexible shell 4 has a cylindrical or convex shape and provided with at least one rim 5, with which, an elastic and / or flexible shell 4 is attached to the bottom 3 and / or cover 2. Thus, the cover 2 is rigidly connected to the elastic and / or flexible shell 4. Working capacity 1 equipped with a loading device 6 processing aemogo material 7 and the grinding bodies 8 and unloading apparatus 9 of the finished product 10. The through channel of the device for discharging 9 for discharging the crushed final product 10 as a dust-air mixture by a fan (Fig. not shown). In the bottom 3, a cavity can be made. The working capacity is mounted on the housing 11 by means of bearing assemblies 12, a shaft 13 fixedly connected to the bottom 3, and / or shaft 14 fixedly connected to the cover 2. Thus, the cover 2 provided with a shaft 14 is installed in the housing 11 by means of bearing assemblies 12 rotatably. The surface of the bottom 3, facing the inside of the working container 1 has a flat or concave shape, for example, in the form of a spherical, parabolic, hyperbolic surface of revolution or the shape of a truncated cone. In addition, a central protrusion 15 can be made on the bottom 3. Through-holes 16 are made in the bottom 3 and / or the central protrusion 15, connecting the internal volume of the working container 1 with the cavity of the bottom 3. The cavity of the bottom 3 with a fixed sleeve 17 mounted inside the hollow the shaft 13 is connected to a compressed gas supply device (not shown in FIG.). The fixed sleeve 17 is provided with seals 18. The shaft 13 of the working container 1 is connected to the drive 19 by a belt drive 20. A roller 21 mounted on an axis 22 is mounted on the housing 11 outside the working container 1, so that the outer surface of the roller 21 is in contact with the outer surface elastic and / or flexible shell 4, and deforms it in the direction of the axis of rotation of the working tank 1.

The centrifugal device for mixing and grinding with an elastic shell may be provided with several rollers 21, while their location relative to each other and the location of the roller 21 relative to the elastic and / or flexible shell 4 can be adjusted. All the rollers 21 installed on the housing 11 outside the working container 1 are in contact with the outer surface of the elastic and / or flexible shell 4, and deform it with its outer surface in the direction of the axis of rotation of the working container 1. The outer surface of the roller 21 in contact with the elastic and / or flexible the shell 4 is made in the form of a surface of revolution, for example, cylindrical, toroidal or conical. At least one radial protrusion 23. At least one radial protrusion 23 can be made on the outer surface of the roller 21 in contact with the elastic and / or flexible shell 4 of the working container 1. The radial protrusions 23 of the roller 21 are made on surfaces that provide the law of motion of the deformable section of the elastic and / or flexible shell 4 of the working tank 1 in the direction of the axis of rotation, with at least one final jump in acceleration (Fig. 2, Fig. 3, Fig. 4). For example, given that in FIG. 2 of the movement diagram S of the deformable section of the elastic and / or flexible shell 4 of the working vessel 1 in contact with the radial protrusion 23 of the roller 21 in the direction perpendicular to the axis of rotation of the roller 21 depending on the rotation angle ϕ of the roller 21, the speed V (Fig. 3) of the deformable element is elastic and / or flexible shell 4 of the working tank 1 varies linearly. In this case, the deformable section of the elastic and / or flexible shell 4 during the deformation by the radial protrusion 23 of the roller 21 will experience three soft impacts (final acceleration jumps A) at points ABC of the acceleration graph A in the direction perpendicular to the axis of rotation of the roller 21 depending on the rotation angle ϕ roller 21 (Fig. 4). That is, the deformable section of the elastic and / or flexible shell 4 will move with three final acceleration jumps when interacting with the radial protrusion 23 of the roller 21.

At least one roller 21 may be provided with a drive 24 (Fig. 1) connected to the axis 22. The axis 22 of the roller 21 may occupy different positions relative to the axis of rotation of the working container 1, for example, the axis of rotation of at least one roller 21 can be located in the plane of the axis of rotation of the working tank 1 parallel to it (Fig. 5, Fig. 1) or at an angle to it (Fig. 6). In addition, the axis of rotation of at least one roller 21 and the axis of rotation of the working container 1 can be located so that they cross with each other at an angle without intersecting (Fig. 7). The roller 21 can be mounted rotatably on the housing 11 or on a movable platform 25 mounted on the housing 11. The movable platform 25 is equipped with at least one translational movement 26 (Fig. 9) and / or at least one mechanism rotation 27 (Fig. 10) of the axis 22 of the roller 21. The mechanisms of translational movement 26 and the rotation mechanisms 27 of the axis 22 of the roller 21 can be installed sequentially on the platform one after another, while at least one roller 21 is installed on the extreme relative to the housing 11 and / or platforms s 25 gear. The mechanisms of translational movement 26 provide movement of the roller 21 in three coordinates X, Y and Z (Fig. 9), and the rotation mechanisms 27 of the axis of rotation of the roller 21 can rotate the axis 22 of the roller 21 relative to the axes X, Y and Z (Fig. 10). As a translational movement mechanism 26, screw pairs with a manual or mechanical drive (electric, pneumatic, hydraulic) can be used. As the rotation mechanism 27 (Fig. 8, Fig. 10), the axis of rotation of the roller 21 can be used, for example, worm gears or rocker mechanisms equipped with a manual or mechanical drive (electric, pneumatic, hydraulic). The mechanisms of translational movement 26 and the rotation mechanisms 27 of the axis of rotation of the roller 21 can adjust the position of the roller 21 separately or together, providing its required position relative to the flexible and / or elastic shell 4 of the working tank 1.

(Фиг. 11). Условие соседства предполагает, что ролики 21, расположенные по окружности эластичной и/или гибкой обечайки 4 рабочей емкости 1 в одной плоскости не должны соприкасаться между собой. Тогда условие соседства получится из рассмотрения треугольника ABC (Фиг. 11).The rollers 21 can be evenly distributed in one or several parallel planes around the circumference of the elastic and / or flexible shell 4 of the working tank 1. If the rollers 21 are located in the same plane and evenly distributed around the elastic and / or flexible shell 4 of the working tank 1 with an outer radius R _capacity , and their maximum number is equal to K, the radius R _roll is determined from the condition of the neighborhood

(Fig. 11). The condition of the neighborhood implies that the rollers 21 located on the circumference of the elastic and / or flexible shell 4 of the working tank 1 in the same plane should not be in contact with each other. Then the neighborhood condition is obtained from the consideration of the triangle ABC (Fig. 11).

The surface of the rollers 21 may be made of friction material, and the elastic and / or flexible shell 4 of rubber or polymer. At least one roller 21 can rotate due to friction between the elastic and / or flexible rim 4 and the outer surface of the roller 21. In addition, at least one roller 21 can rotate using the actuator 24, in which case equality must be ensured linear speeds V of the elastic and / or flexible shell 4 and the roller 21 at the point of contact. The working tank 1 may not have its own drive and be driven into rotation by at least one roller 21 equipped with a drive 24. The axis 22 with the roller 21 can be mounted using the bearing assembly 28 on the housing 11 or on the movable platform 25 or on the translational movement 26 or a rotation mechanism 27 of the axis of rotation of the roller 21, including using elastic supports 29 (Fig. 12). When the axis 22 with the roller 21 is mounted on the elastic supports 29, it can be equipped with a vibratory drive 30 (Fig. 12). In addition, the vibrating actuator 30 can be equipped with a movable platform 25 mechanisms of translational movement 26, rotation mechanisms 27 of the axis of rotation of the roller 21 (not shown in Fig.).

The discharge device 9 can be made in the form of a pipe with an open conical part. The bottom 3, the cover 2 and the rim 5 are made of wear-resistant material or lined with wear-resistant plates.

A centrifugal device for mixing and grinding with an elastic shell (Fig. 1) works as follows.

Depending on the properties of the material being processed 7 and the processing technology, the following options are possible for starting a centrifugal device for mixing and grinding with an elastic shell.

In the first case, the elastic and / or flexible shell 4 is not deformed by the rollers 21, and the processed material 7 and / or grinding bodies 8 are loaded into a working container 1 that is stationary or rotates from the drive 19.

In the second case, the elastic and / or flexible shell 4 is pre-deformed in the direction of the axis of rotation of the working container 1, and then the processed material 7 and / or grinding media 8 are loaded into a fixed or rotating working container 1.

The amount of deformation and the direction of deformation of the elastic and / or flexible shell 4 depends on the technological properties of the processed material 7 and the requirements for the finished product. The deformation of the elastic and / or flexible shell 4 by at least one roller 21 is carried out using the movable platform 25 or the mechanisms of translational movement 26 of the roller 21 and / or the rotation mechanisms 27 of the axis of rotation of the roller 21 mounted on it. The magnitude and direction of deformation of the elastic and / or flexible shell 4 are determined (depend) on the position of the roller 21 relative to the outer surface of the elastic and / or flexible shell 4 and can be installed (set) before turning on the drive 19 or installed and adjusted when the working capacity 1 using the mechanisms of translational movement 26 and rotation mechanisms 27 of the axis of rotation of the roller 21.

The working tank 1 can be driven into rotation either by means of a belt drive 18 with a drive 19, or due to frictional forces from a rotating roller 21 equipped with a drive 24.

A loaded or empty working vessel 1 with an undeformed or previously deformed elastic and / or flexible shell 4 with the help of a drive 19 and / or a drive 24 is accelerated to a predetermined angular velocity of rotation of the working vessel 1. When the working vessel 1 is rotated, it is preloaded or loaded into it during processing, the processed material 7 and grinding bodies 8 under the action of centrifugal forces move along the bottom 3 of the working tank 1 and due to friction forces are accelerated to the angular speed of rotation of the working tank 1. Getting on e the flexible and / or flexible shell 4, the material to be processed 7 and the grinding bodies 8 move along it and partially deform it outward due to the acting centrifugal forces. The pressure value of the processed material 7 and grinding bodies 8 on the elastic and / or flexible shell 4 and its deformation outside depends on the radius of the working vessel 1, the angular velocity of rotation and the thickness of the layer of processed material 7 and grinding bodies 8. During the movement of the processed material 7 and grinding bodies 8 along the bottom 3 and elastic and / or flexible shell 4 the processed material 7 is mixed and crushed due to shear deformations arising in the flow of the mixture of the processed material 7 and grinding bodies 8. During the deformation of the elastic and / or flexible shell 4 by roller 21, the flow of the mixture of the processed material 7 and / or grinding bodies 8 located on the deformable section is detached from the inner surface of the elastic and / or flexible shell 4 and moves in the direction of the axis of rotation of the working vessel 1. The direction and flow rate of the mixture to be processed material 7 and / or grinding bodies 8 when leaving the deformed section of the elastic and / or flexible shell 4 of the working tank 1 depend on the size, method and form of deformation of this section. Thus, after the passage of the deformed section of the elastic and / or flexible shell 4, the flow of the mixture of the processed material 7 and grinding media 8 is torn off from the inner surface of the elastic and / or flexible shell 4 and falls to the bottom of the working vessel 1. When the mixture flow of the processed material 7 and / or grinding bodies 8 at the bottom of the working tank 1 there is additional mixing and grinding of the processed material 7. In addition, while moving along the deformed section of the elastic and / or flexible shell 4 in the mixture flow about ops material 7 and 8 of grinding bodies occurs intensive shear deformation. Repeated cycles of movement of the processed material 7 and grinding media 8 in the working tank 1 leads to uniform mixing of the ingredients in the case of preparation of mixtures or intensive grinding of the processed material 7 due to multiple shear deformations (abrasion) occurring in the flow of the mixture of processed material 7 and grinding bodies 8 , and shock effects of grinding media 8.

In order to increase the intensity of shear deformations, increase the intensity of the impacts of grinding media 8, as well as to more completely separate the processed material 7 from the elastic and / or flexible shell 4, the deformation of the elastic and / or flexible shell 4 should be carried out according to special laws that ensure the creation of shock (spasmodic ) accelerations in the flow of the mixture of the processed material 7 and grinding media 8. The impact on the processed material 7 and grinding media 8 can be implemented by creating additional shock-deforming effects on the elastic and / or flexible shell 4 of the working tank 1 in the zone of its deformation. In a centrifugal device for mixing and grinding with an elastic shell, the impact-deformation effect is realized in two ways.

In the first case, the shock-deforming effect occurs as a result of the interaction of the elastic and / or flexible shell 4 of the working vessel 1 with radial protrusions 23 made on the outer contact surface of the roller 21. Radial protrusions 23 are made along a profile that provides impact on an elastic and / or flexible shell 4. For example, the radial protrusion 23 can deform the elastic and / or flexible shell 4 according to the law (Fig. 4), which provides three finite jumps of acceleration A.

The rotating roller 21 with radial protrusions 23 periodically deforms the surface of the elastic and / or flexible shell 4, creating a shock deformation of the elastic and / or flexible shell 4. The energy of the impact deformation of the elastic and / or flexible shell 4 is transferred to the processed material 7 and grinding bodies 8 located in the zone shock deformation. Due to the impact of the inner surface of the elastic and / or flexible shell 4, the processed material 7 and grinding bodies 8 are torn off from it, move inside the working tank 1 and fall on the bottom 3, where they continue to move along the bottom 3 due to the friction forces and the action of centrifugal forces the inner surface of the elastic and / or flexible shell 4. After which the process is repeated.

In the second case, the shock-deforming effect on the elastic and / or flexible shell 4 of the working tank 1 can be realized due to the vibration effect of the roller 21 on the elastic and / or flexible shell 4. The vibration of a smooth or radially protruded 23 roller 21 fixed in elastic supports 29 is carried out by a vibrodrive 30. All of the rollers 21 mounted on elastic supports 29 can be provided with a vibrodrive 30. In addition, structurally, the vibrodrive 30 can be connected to a movable platform 25 and / or a post mechanism stupid movement 26 and / or the rotation mechanism 27 of the axis of rotation of the roller 21.

When shock-deforming effects on the elastic and / or flexible shell 4, the processed material 7 is subjected to additional impact-abrasion. In this case, the mixing of the ingredients of the processed material is more intensive due to the difference in the perception of the impact by particles of different sizes and masses and more intensive grinding due to the impact on the processed material 7, grinding media 8 and large particles of the processed material 7. In the absence of shock-deformation impact, grinding the processed material 7 occurs mainly due to the crushing and abrasion of the grinding media 8 on the processed material 7 when it the movement along the concave surface of the elastic and / or flexible shell 4 and the bottom 3, as well as when moving along the deformed surface of the elastic and / or flexible shell 4, and during the impact of the grinding media 8 on the material being processed 7 when the grinding media 8 collide and the material 7 with the surface of the bottom 3. And, in the case of shock-deformation effects on the elastic and / or flexible shell 4, additional grinding of the processed material 7 occurs in the impact zone, and also by increasing the speed with impact of the processed material 7 and grinding bodies 8 with the bottom 3.

Downloading the processed material 7 and grinding media 8 into the working tank 1 is carried out through the channel of the loading device 6, and the finished product 10 is unloaded through the through channel of the discharge device 9 in the form of a dust and gas mixture. During periodic operation of the centrifugal device for mixing and grinding with an elastic shell, as well as in the preparation of cohesive mixtures, the processed material is unloaded after stopping the rotation of the working container 1 through the hole in the cover 2.

To avoid over-grinding of the processed material 7 or the implementation of a continuous grinding process, a compressed gas is fed into the working container 1 through a stationary sleeve 17 installed inside the shaft 13 into the cavity of the bottom 3, which passes through the openings 16 of the central protrusion 15 into the working container 1. Compressed gas or air, emerging from the hole 16, passes through a moving layer of grinding media 8 and the processed material 7 and removes particles of a given dispersion from it.

The maximum size of the removed particles of the processed material 7 is regulated by the flow rate and pressure of gas or air entering the working tank 1 through the through holes 16 of the bottom 3. In addition, the particle size of the removed particles of the processed material 7 can be further controlled by the capacity of the suction fan and the level of vacuum generated in the working tank 1. When operating a centrifugal device for mixing and grinding with an elastic shell, dust emission to the environment practically does not occur since the working tank 1 is sealed, and all the dusty products are discharged from the working tank 1 through a sealed discharge channel 9. The dust-gas mixture of the finished product 10 from the working tank 1 is removed by a fan (not shown in Fig.), and then the crushed material is deposited using cyclones or air filters (not shown). If necessary, the finished product 10 is classified into fractions, and the under-ground processed material 7 enters again into a centrifugal device for mixing and grinding with an elastic shell.

Depending on the technological properties of the processed material, the intensity of the impact-abrasion during the grinding process must be regulated. The magnitude of the impact-abrasion effect is controlled by changing the magnitude and direction of deformation of the elastic and / or flexible shell 4 by the roller 21, as well as changing the angular velocity of rotation of the working vessel 1. For weakly connected materials, the direction of deformation of the elastic and / or flexible shell 4 does not significantly the intensity of grinding or mixing of the processed material. For cohesive materials, for example, clay mixtures, the deformation of the elastic and / or flexible shell is directed towards the bottom 3 of the working tank 1 in order to prevent sticking of the processed material 7 to the elastic and / or flexible shell 4. The direction of deformation of the elastic and / or flexible 4 towards the bottom 3 is also used for grinding hard and brittle materials, since in this case the collision speed of the processed material 7 and grinding media 8 with the bottom 3 increases.

The use of a centrifugal device for mixing and grinding with an elastic shell for preparing mixtures is carried out without the use of grinding media 8. In this case, the main factor ensuring intense and uniform mixing is the multiple spatial displacement of the particles of the processed material 7 relative to each other. In addition, the grinding of certain types of materials can also be carried out without the use of grinding media 8.

After processing the processed material 7 when operating in batch mode or upon completion of processing in a continuous mode, when the crushed processed material 7 is continuously sucked by the fan through the discharge channel 9, the working tank 1 is stopped and the processed material 7 and grinding bodies 8 are unloaded from the working tank 1 through the hole in the cover 2.

Thus, the proposed centrifugal device for mixing and grinding with an elastic shell allows you to reduce the wear of grinding media and elastic shell. The high intensity of the shock-abrasive effect of grinding media on the processed material allows to obtain fine and ultrafine powders. Repeated cycles of material processing in the working tank allows you to prepare the product (mixtures and powders) with a high level of uniformity.

The use of a centrifugal device for mixing and grinding eliminates dust emissions into the environment.

Claims (14)

1. A centrifugal device for mixing and grinding with an elastic shell, consisting of a housing, a loading and unloading device, a rotational drive of a working container mounted on the housing with the possibility of rotation and having a bottom, a cover and an elastic shell, rollers mounted on the rotation mechanisms of the axis of rotation of the rollers while the rollers are installed outside the elastic shell so that the outer surface of the rollers is in contact with the outer surface of the elastic shell and deforms it in the direction of the axis of rotation of the slave eyes of the tank, characterized in that the elastic shell of the working tank is attached to the lid mounted in the housing with the possibility of rotation, and on the outer surface of the rollers in contact with the elastic shell of the working tank, made radial protrusions. 2. The device according to p. 1, characterized in that the radial protrusions of at least one roller are made on surfaces that provide the law of motion of the deformable elastic shell of the working container in the direction of its rotation axis with at least one finite acceleration jump. 3. The device according to p. 1, characterized in that it is additionally equipped with mechanisms for translational movement of the rollers, and the mechanisms of rotation and translation are installed sequentially one after another. 4. The device according to p. 1, characterized in that the housing is additionally equipped with a movable platform on which at least one rotary roller is mounted. 5. The device according to p. 4, characterized in that the movable platform contains at least one mechanism for translational movement of at least one roller, at least one of the three possible coordinates and / or at least one mechanism of rotation of the axis of rotation of at least one roller, at least with respect to one of the three possible coordinates. 6. The device according to p. 3 or 5, characterized in that at least one translational movement mechanism and / or at least one rotation mechanism of the axis of rotation of the rollers are equipped with drives. 7. The device according to claim 1, characterized in that the rollers are evenly distributed around the circumference of the elastic shell of the working vessel with an outer radius R of the _vessel and their maximum number K and radius R of the _{roller are} determined from the condition of the neighborhood

8. The device according to p. 1, characterized in that at least one roller is equipped with a drive. 9. The device according to p. 1, characterized in that the bottom of the working tank has a concave shape. 10. The device according to p. 1, characterized in that the surface of the rollers is made of friction material. 11. The device according to p. 1, characterized in that at least one roller is mounted on elastic supports. 12. The device according to p. 11, characterized in that at least one roller mounted on elastic supports and / or at least one translational movement mechanism and / or at least one rotation mechanism of the axis of rotation of the roller equipped with a vibrodrive. 13. The device according to p. 1, characterized in that the elastic shell is provided with at least one rim.

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