RU2656462C1 - Method for mixing and grinding - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to grinding and mixing methods, using centrifugal methods and is intended for grinding lumpy, cereal and powder materials, as well as for the preparation of mixtures used in various industries. Use of the method for mixing and grinding is made of the fact that the material to be processed is loaded into the elastic shell of the working container, the working container is rotated at a speed, which provides clamping of the material to be cut to the inner surface of the elastic shell under the action of centrifugal forces, and the elastic shell is deformed from the outer surface of the elastic shell inwardly in the direction of the axis of rotation of the working container, at least, with one roller, mounted on the body with the possibility of rotation, while the deformation of the elastic shell is regulated in magnitude and direction, by changing the position of the rollers on the body, while the elastic shell is deformed using the rollers so that the movement of the inner surface of the elastic shell in the deformation zone under the action of the rollers occurs with jumps of acceleration.

EFFECT: reduction of wear of the elastic shell, improvement of the homogeneity of the finished product, shortening the processing cycle and increasing the level of fineness (fineness of grinding) of the material to be crushed.

5 cl, 6 dwg

Description

The present invention relates to methods of grinding and mixing using centrifugal methods and is intended for grinding lump, grain and powder materials, as well as for the preparation of mixtures used in various industries.

A known mixing method, in which the mixture is fed into a loading funnel, under the action of centrifugal force, the particles of the material accelerate from the center to the periphery are distributed evenly on the inner surface of the cone, while the thickness of the layer on the periphery decreases due to an increase in the particle distribution surface. The path of the material flow relative to the cone is twisted in the direction opposite to the direction of rotation of the rotor. On the cone, the material of the bedding is divided into three parts: the first passes through the bypass windows, while dispersing; the second moves along the generatrix of the cone and is discharged through its upper base to the surface of the elliptical bottom, where the main and leading flows overlap; the third part of the flow, reflected from the inner surface of the guide vanes, returns to the base of the cone. After completion of the process, the mixture is discharged from the apparatus by the discharge blade through a pipe. (RU No. 2311951, IPC B01F 7/26, B28C 5/16 on December 10, 2007)

The disadvantage of this method is the relatively low quality of mixing and grinding by the uniformity 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.

Of the known methods, the closest to the claimed method is a method of mixing and grinding, in which the material to be processed is loaded into the elastic shell of the working tank, the working tank is rotated at a speed that provides clamping of the crushed material to the inner surface of the elastic shell under the action of centrifugal forces, and the elastic shell deform from the side of the outer surface of the elastic shell inward in the direction of the axis of rotation of the working container with at least one roller, the mouth updated on the housing with rotation. (A.S. No. 1560427, В28С 5/00 В02С 17/02, published on April 30, 1990).

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.

The technical result of the invention is to reduce the wear of the elastic shell, improve the uniformity of the finished product, reduce the duration of the processing cycle and increase the level of dispersion (fineness of grinding) of the crushed material.

The technical result is achieved by the fact that in the method of mixing and grinding, in which the material to be processed is loaded into the elastic shell of the working container, the working container is rotated at a speed that provides clamping of the crushed material to the inner surface of the elastic shell under the action of centrifugal forces, and the elastic shell is deformed from the side the outer surface of the elastic shell inward in the direction of the axis of rotation of the working capacity, at least one roller mounted on the housing with possibility of rotation, with elastic deformation of the sleeve is adjusted in magnitude and direction by changing the position of the rollers on the housing wherein the flexible sleeve is deformed by the rollers so that movement of the inner surface of the sleeve in the elastic deformation zone occur under the action of the rollers with an irregular acceleration; the elastic shell is deformed by rollers, the outer surface of which is provided with radial protrusions; the elastic shell is deformed by rollers that are smooth or provided with radial protrusions, which are imparted by vibrational movement in the direction of the axis of rotation of the working container; that the elastic shell is deformed during acceleration of the working capacity or after reaching an angular velocity of rotation of the working capacity, which provides a clamp under the action of centrifugal forces of the processed material to the inner surface of the elastic shell; the processed material is loaded into the elastic shell along with grinding media.

The essence of the proposed method is illustrated by drawings.

FIG. 1. A longitudinal section of a device for mixing and grinding with an elastic shell and a vertical axis of rotation with a movement pattern of the processed material and grinding media.

FIG. 2 Scheme of movement of the processed material and grinding bodies in a device for mixing and grinding with an elastic shell and a horizontal axis of rotation;

FIG. 3 Scheme of movement of the processed material and grinding media inside the elastic shell in cross section AA in FIG. 2;

FIG. 4. Schedule of movement S of the deformable section of the elastic 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 with radial protrusions;

FIG. 5. The graph of the speed V of the deformable section of the elastic shell of the working capacity in the direction perpendicular to the axis of rotation of the roller depending on the angle ϕ of rotation of the roller with radial protrusions;

FIG. 6. Acceleration graph A of the deformable section of the elastic 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 with radial protrusions;

The method is as follows.

In the rotating working container 1, with an elastic shell 2, mounted on the housing 3 with the possibility of rotation, which may have a vertical (Fig. 1), or horizontal (Fig. 2) axis of rotation, the crushed material 4 and grinding bodies 5 are loaded into the elastic shell 2.

Depending on the type of material being processed and the technological processing modes to be set, the working capacity 1 is rotated by the drive 6 and accelerated to an angular velocity, which provides clamping of the processed material 4 and grinding media 5 to the inner surface of the elastic shell 2. The grinding media 5 and the processed material 4 are loaded inside working capacity 1 through the loading device 7 (Fig. 1). In the motion diagram of the processed material and grinding media in a device for mixing and grinding with an elastic shell with a horizontal axis of rotation of the working capacity (Fig. 2), the drive of the working capacity, as well as the loading and unloading device, are not conventionally shown. Before the acceleration of the working capacity 1 or in the process of its acceleration or after reaching the working capacity 1 of the angular velocity of rotation, which provides the clamping of the processed material 4 and grinding media 5 to the inner surface of the elastic shell 2 using the mechanism 8 for adjusting the position of the roller 9, the elastic shell 2 is deformed from the outside the surface of the elastic shell 2 inward in the direction of the axis of rotation of the working tank 1, at least one roller 9 mounted on the housing 3 with the possibility of rotation. The magnitude and direction of deformation of the elastic shell 2 by the rollers 9 is set and adjusted during processing depending on the technical properties of the processed material 4, the angular velocity of rotation of the working vessel 1 and the required final dispersion of the processed material 4. Regulation of the position of the rollers 9 using the mechanism 8, providing a change in position the axis of rotation of the roller 9 relative to the axis of rotation of the working tank 1, allows you to create the desired size and direction of deformation of the elastic shell 2. In this case, the axis in ascheniya roller 9 may be installed parallel to the axis of rotation of the working container 1 at an angle to the axis of rotation of the working tank 1, its axis of rotation intersecting or crossing over the working rotation axis of the container 1 without crossing it.

When the working container 1 rotates, the processed material 4 and grinding media 5 loaded into it are pressed against the inner surface of the elastic shell 2 of the working container 1 by the action of centrifugal forces and, due to the friction forces, are accelerated to the angular velocity of rotation of the working container 1. The pressure of the processed material 4 and grinding bodies 5 on the elastic shell 2 depends on the radius of the working capacity 1, the angular velocity of rotation and the thickness of the layer of the processed material 4 and grinding bodies 5 and can be adjusted by changing the speed of rotation and the amount of loaded processed material 4 and grinding bodies 5. During the joint movement of the processed material 4 and grinding bodies 5 with an elastic shell 2, the processed material 4 is compacted by centrifugal forces and crushed due to shear deformations arising in the flow of the mixture of processed material 4 and grinding 5 bodies in the process of compaction.

During the deformation of the elastic shell 2 by the rollers 9, the flow of the mixture of the processed material 4 and grinding bodies 5 located on the deformable section is torn off from the inner surface of the elastic shell 2. The direction of the flow of the mixture of the processed material 4 and grinding bodies 5 depends on the direction of the deforming effect of the rollers 9. If the axis of rotation of the roller is parallel to the axis of rotation of the working vessel 1, then the processed material 4 and grinding media 5 are moved in the direction of the axis of rotation of the working vessel 1 (Fig. 1). If the axes of the rollers 9 are installed at an angle to the axis of rotation of the working tank 1 (Fig. 2), then the processed material 4 and grinding media 5 can be additionally moved along the axis of rotation of the working tank 1, for example, in the direction of the discharge zone. The direction and flow rate of the mixture of the processed material 4 and grinding media 5 when leaving the deformed section of the elastic shell 2 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 shell 2, the flow of the mixture of the processed material 4 and grinding bodies 5 is torn off from the inner surface of the elastic shell 2 and falls on the bottom of the working tank 1 (Fig. 1) or on the inner surface of the elastic shell 2 (Fig. 2) which can be coated with hard wear plates. The trajectory of the processed material 4 and grinding media 5 inside the working vessel 1 with a horizontal axis of rotation in cross section is shown in FIG. 3. When the flow of the mixture of the processed material 4 and grinding media 5 falls onto the inner surface of the elastic shell 2 (Fig. 2) or to the bottom of the working tank 1 (Fig. 1), additional mixing and grinding of the processed material 4 occurs upon impact with the grinding bodies 5, the bottom of the working tank 1 or wear-resistant plates covering the inner surface of the elastic shell 2. In addition, while moving along the deformed section of the elastic shell 2 in the flow of the mixture of the processed material 4 and grinding bodies 5 intensive shear deformations, providing additional mixing and grinding of the processed material 4, which is under volumetric compression under the action of centrifugal forces and forces acting on the inner surface of the elastic shell 2. Repeated cycles of movement of the processed material 4 and grinding media 5 in the working tank 1 lead uniform mixing of the ingredients in the case of preparation of mixtures or intensive grinding of the processed material 4 due to multiple shifts deformation (abrasion) occurring in the flow of the mixture of the processed material 4 and the grinding media 5, and the impact of grinding media 5.

In devices for mixing and grinding with an elastic shell and a vertical axis of rotation, the removal of crushed material can be carried out by suction of the resulting dusty air mixture through special holes or the finished material is removed after stopping the working tank 1.

In devices for mixing and grinding with an elastic shell and with a horizontal axis of rotation, the removal of crushed or mixed material can be carried out by moving the processed material 4 along the axis of rotation of the working vessel 1. Moving the processed material 4 and grinding bodies 5 in the direction of the discharge zone that at least one roller 9 deforms the elastic shell 2 at an angle to the axis of rotation of the working tank 1 in the direction of the discharge zone (Fig. 2). The speed of movement of the grinding media 5 and the processed material 4 inside the working tank 1 in the direction of the discharge zone is controlled using the mechanism 8 for regulating the position of the roller 9 by changing the inclination of its rotation axis to the position of the axis of rotation of the working tank 1 and changing the direction of deformation of the elastic shell 2. Working capacity 1 with a horizontal axis of rotation can be performed from several sections equipped with an elastic shell 2. The process of mixing and grinding is similar in each section of the working tank 1 (Fig. 2.), since ops material 4 and the grinding bodies 5 can move along the axis of rotation of the working container 1 from one section to another.

In order to increase the intensity of shear deformations, increase the intensity of the shock effects of grinding media 5, as well as to more completely separate the material 4 from the elastic shell 2 and to avoid overgrowing, the elastic shell 2 is deformed according to special laws that ensure the creation of shock (spasmodic) accelerations on the inner surface elastic shell 2 and in the flow of the mixture of the processed material 4 and grinding bodies 5, for example, providing movement of the deformable stretch of elastic both Aiki 2 according to the laws of FIG. 4, FIG. 5, FIG. 6. For example, for a given (Fig. 4) schedule of displacement S of the deformable section of the elastic shell 2 of the working container 1 in contact with the radial protrusion 10 of the roller 9 in the direction perpendicular to the axis of rotation of the roller 9 depending on the rotation angle ϕ of the roller 9, the speed V (Fig. 5) the deformable element of the elastic shell 2 of the working tank 1 varies according to a linear law. In this case, the deformable section of the elastic shell 2 during the deformation by the radial protrusion 10 of the roller 9 will experience three soft impacts (final acceleration jumps A) at the points ABC of the acceleration graph A in the direction perpendicular to the axis of rotation of the roller 8 depending on the angle ϕ of rotation of the roller 9 (Fig. . 6). That is, the deformable section of the elastic shell 2 will move with three final acceleration jumps when interacting with the radial protrusion 10 of the roller 9.

The impact on the processed material 4 and grinding media 5 is realized by creating additional shock-deforming effects on the elastic shell 2 of the working tank 1 in the zone of its deformation. Shock-deforming effect is realized in two ways.

In the first case, the shock-deforming effect on the deformable section of the elastic shell is created by deforming the elastic shell 2 of the working tank 1 with rollers 9 provided with radial protrusions 10 (Fig. 1, Fig. 2), made on the outer contact surface of the rollers 9. Radial protrusions 10 perform along the profile providing impact on the elastic shell 2. For example, the radial protrusions 10 deform the elastic shell 2 according to the law, which provides three final jumps of acceleration A (Fig. 6).

The radial protrusions 10 of the rotating roller 9 periodically deform the surface of the elastic shell 2, creating a movement of the inner surface of the elastic shell 2 with jumps in accelerations (impacts). The energy of shock deformation of the elastic shell 2 is transferred to the flow of the processed material 4 and grinding media 5, located in the zone of shock deformation. Due to the impact of the inner surface of the elastic shell 2, the flow of the processed material 4 and grinding bodies 5 is torn off from it and moves inside the working tank 1 until it interacts with the bottom (Fig. 1) or the elastic shell 2 of the working tank 1. After that, the process of acceleration and separation the flow of the processed material 4 and grinding bodies 5 from the inner surface of the elastic shell 2 is repeated.

In the second case, the shock-deforming effect on the elastic shell 2 of the working tank 1 is realized due to the vibrational effect of the roller 9 on the elastic shell 2. Vibro-movement of the roller 9, smooth or equipped with radial protrusions 10, mounted in elastic supports (not shown conditionally) is carried out by a vibrodrive 11 (Fig. . 1, Fig. 2) mounted on the mechanism 8 for regulating the position of the roller 9. The vibrodisplacement of the roller 9 in the direction of the axis of rotation of the working tank 1, and, consequently, the deformation of the elastic shell 2 also Gut laws implemented by providing acceleration jumps, for example, according to the laws of FIG. 4, FIG. 5, FIG. 6.

Both methods of impact-deforming action can be structurally implemented both on one roller 9 and on all other rollers mounted on the housing and deforming the elastic shell 2.

When shock-deforming effects on the elastic shell 2, the processed material 4 is subjected to additional impact-abrasion. In this case, the mixing of the ingredients of the processed material 4 occurs more intensively due to the difference in the perception of the impact by particles of different sizes and masses and the grinding process is more intensive due to the impact on the processed material 4, grinding media 5 and large particles of the processed material 4. In the absence of shock deformation impact grinding of the processed material 4 occurs mainly due to the crushing and abrasion effect of grinding bodies 5 on the processing material 4 when moving along the surface of elastic shell 2, as well as when moving along a deformed portion of the surface of elastic shell 2. And in the case of shock-deforming effects on elastic shell 2, not only additional grinding of the processed material 4 occurs in the impact zone, but also by increasing the collision speed of the processed material 4 and grinding bodies 5 with the inner surface of the elastic shell 2, covered with wear-resistant plates or the bottom of the working tank 1.

The crushed processed material 4, in the case of a working tank 1 with a vertical axis of rotation in the form, for example, of a dust-air mixture 12, is discharged through a discharge device 13 (Fig. 1).

The ground processed material 4, in the case of a working vessel 1 with a horizontal axis of rotation, and grinding media 5 are gradually moved along the axis of rotation of the working vessel 1 in the direction of the discharge zone.

Thus, the proposed method for mixing and grinding can dramatically reduce the wear of the elastic shell, since the level of wear of the processed material on the inner surface of the elastic shell is significantly reduced due to a decrease in the amount of slippage of the processed material relative to the inner surface of the elastic shell. Improving the uniformity of the finished product (mixture or powder) is associated with repeated repetition of material processing cycles in a working tank. The presence of a high-impact impact of grinding media on the processed material, as well as repeated repetition of abrasive shear deformations in the flow of the processed material and grinding media, can significantly reduce the processing cycle time and increase the level of dispersion (grinding fineness) of the processed material.

Claims (5)

1. The method of mixing and grinding, in which the processed material is loaded inside the elastic shell of the working tank, the working tank is rotated at a speed that provides clamping of the crushed material to the inner surface of the elastic shell under the action of centrifugal forces, and the elastic shell is deformed from the outside of the elastic shell inside in the direction of the axis of rotation of the working container, at least one roller mounted on the housing with the possibility of rotation, while the deformation of the electric cal mantle controlled in magnitude and direction by changing the position of the rollers on the housing, characterized in that the elastic sleeve is deformed by the rollers so that movement of the inner surface of the sleeve in the elastic deformation zone occur under the action of the rollers with an irregular acceleration. 2. The method according to p. 1, characterized in that the elastic shell is deformed by rollers, the outer surface of which is provided with radial protrusions. 3. The method according to p. 1, characterized in that the elastic shell is deformed by rollers that are smooth or provided with radial protrusions, which are given vibrational movement in the direction of the axis of rotation of the working container. 4. The method according to p. 1, characterized in that the elastic shell is deformed during acceleration of the working capacity or after reaching an angular velocity of rotation of the working capacity, which provides pressure under the action of centrifugal forces of the processed material to the inner surface of the elastic shell. 5. The method according to p. 1, characterized in that the processed material is loaded into the elastic shell along with grinding media.

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