CN111250225B - Centrifugal grinding system - Google Patents

Abstract

The invention is suitable for the technical field of ball milling and crushing. The invention discloses a centrifugal grinding system, which comprises a grinding cylinder, a centrifugal separator and a driving mechanism for driving the centrifugal separator to work, wherein the centrifugal separator comprises a separation outer sleeve and a separation inner cylinder arranged in the separation outer sleeve, and the separation inner cylinder is provided with an inner cylinder separation hole; the separation sleeve is provided with a sleeve composite hole which enables grinding media to move outwards during rotation and grades materials, and an axially closed separation cavity is arranged between the separation inner cylinder and the separation sleeve and is respectively communicated with the sleeve composite hole and the inner cylinder separation hole. When the separator is used, the separator rotates under the drive of the separation driving shaft, the outer sleeve composite hole can enable grinding media and larger-diameter materials to be far away from the separation outer sleeve to provide power, and can provide a passage for smaller-diameter materials to enter the separation cavity in a grading manner, so that the materials can enter the separation cavity in a grading manner easily, the materials are discharged through the separation hole of the inner cylinder, and the separation efficiency is improved.

Description

Centrifugal grinding system

Technical Field

The invention relates to the technical field of ball milling and crushing, in particular to a centrifugal grinding system.

Background

The existing wet ball milling and crushing equipment comprises a grinding cylinder body, a stirrer or a disperser which is arranged on the grinding cylinder body and connected with a rotating shaft, and a separator which is arranged on a material discharging hole in the grinding cylinder body. When the separator adopting the centrifugal principle works, the disperser and the separator connected with the main shaft rotate at high speed, the grinding balls are distributed near the inner wall of the grinding cylinder, less grinding balls are distributed around the separator in the middle of the grinding cylinder, and only the ground materials can enter the discharge hole from the separation hole on the separator under the action of centrifugal force during separation. When the grinding device is in a static state, such as stop operation or initial operation, as the disperser and the separator are not rotated, the grinding balls are deposited at the lower part of the grinding cylinder under the action of gravity, the separator is immersed by the grinding balls, part of the grinding balls can enter the separation holes of the separator, and part of the grinding balls are discharged from the discharge holes when the grinding device is reused, so that the quantity of the grinding balls in the grinding cylinder is reduced, and the grinding efficiency is further influenced.

In order to prevent the grinding balls from entering the separation holes on the separator when the separator is at rest, the length of the separation holes is increased, as in the invention patent of a stirring ball mill with the Chinese patent document number of CN101385989A, the separation holes are arranged into a spiral structure, and the length of the separation holes is increased, so that even if the separator is immersed with the grinding balls when the separator is at rest, the grinding balls are not easy to enter the separation holes due to the bending structure of the separation holes and are discharged through the discharge holes when the separator is in operation. Although the above-described structure partially solves the problem that the grinding balls are discharged through the separation holes, the processing is difficult due to the complicated structure of the separator. Meanwhile, the dynamic balance of the separator during high-speed rotation is not easy to control, and the service life is influenced; meanwhile, the separation path of the separation holes with the spiral structure is long, so that the separation holes are easy to be blocked, and the separation efficiency is influenced.

Disclosure of Invention

The invention mainly solves the technical problem of providing a centrifugal grinding system, which avoids that part of grinding balls enter a discharge channel when stopping or starting, thereby influencing grinding quality and efficiency.

In order to solve the problems, the invention provides a centrifugal grinding system, which comprises a grinding cylinder, a centrifugal separator and a driving mechanism for driving the centrifugal separator to work, wherein the centrifugal grinding system comprises a separation outer sleeve and a separation inner cylinder arranged in the separation outer sleeve, and the separation inner cylinder is provided with an inner cylinder separation hole; the separation sleeve is provided with a sleeve compound hole which enables the grinding medium to move outwards and grade the materials during rotation, and a separation cavity which is axially closed is arranged between the separation inner cylinder and the separation sleeve and is respectively communicated with the sleeve compound hole and the inner cylinder separation hole.

Further, the separation inner barrel comprises a cylindrical inner barrel body, an inner barrel accommodating cavity is axially formed in the center of the inner barrel body, and the inner barrel accommodating cavity is used for accommodating the separation driving shaft and is communicated with the inner barrel separation hole.

Further, when the number of the composite holes of the outer sleeve is two or more, the composite holes of the outer sleeve are uniformly distributed on the same circle with the axle center of the separated outer sleeve as the circle center.

Further, the outer sleeve composite hole and the inner barrel separation hole are respectively in a strip shape.

Further, the outer sleeve composite hole and the inner barrel separation hole are obliquely arranged.

Further, the included angle between the radius of the outer sleeve composite hole and the radius of the inner cylinder separating hole and the radius of the hole center are 30-45 degrees.

Further, the inner barrel separation hole and the outer sleeve composite hole are positioned on different radiuses.

Further, the separation inner cylinder comprises a free end and a limiting end, and the limiting end is provided with a first step for limiting the separation sleeve.

Further, the side wall of the inner barrel accommodating cavity at the free end is provided with a second step matched with the separation driving shaft.

Further, a fixing hole for fixing the separation driving shaft and the separation inner barrel is formed in the bottom of the inner barrel accommodating cavity.

Further, the inner sides of the two axial ends of the separation sleeve are provided with a sleeve fixing groove matched with the inner cylinder fixing groove on the separation inner cylinder and a fixing pin matched with the inner cylinder fixing groove and the sleeve fixing groove after assembly.

Further, the inner cylinder separation hole and the outer sleeve composite hole are respectively in a strip shape, and the lengths of the outer sleeve composite hole and the inner cylinder separation hole are the same.

The invention discloses a centrifugal grinding system, which comprises a grinding cylinder, a centrifugal separator and a driving mechanism for driving the centrifugal separator to work, wherein the centrifugal grinding system comprises a separation outer sleeve and a separation inner cylinder arranged in the separation outer sleeve, and the separation inner cylinder is provided with an inner cylinder separation hole; the separation sleeve is provided with a sleeve composite hole which enables grinding media to move away from the separation outer cylinder and feed materials in a grading way during rotation, and an axially closed separation cavity is arranged between the separation inner cylinder and the separation sleeve and is respectively communicated with the sleeve composite hole and the inner cylinder separation hole. When the separator is used, the separator rotates under the drive of the separation driving shaft, the outer sleeve composite hole can accelerate the grinding medium and the larger-diameter material close to the separation outer sleeve to provide power, so that the grinding medium and the larger-diameter material move away from the direction of the separation outer sleeve, and can provide a passage for the smaller-diameter material to enter the separation cavity in a grading manner, so that the material can enter the separation cavity in a grading manner easily, the material is discharged through the inner cylinder separation hole, and the separation efficiency is improved. Meanwhile, the inner barrel separation hole is only one, and the inner barrel separation hole and the nearest outer sleeve composite hole are located in different radiuses, namely are arranged in a staggered mode, under the action of tension among slurry and the like, materials are not easy to enter the inner barrel separation hole when the slurry is stopped or started, grinding media are prevented from being generated in discharged materials, the number of the grinding media is reduced, and the grinding efficiency and the grinding quality are influenced.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions of the prior art, the following brief description will be given of the drawings required for the description of the embodiments or the prior art, it being apparent that the drawings in the description only illustrate certain embodiments of the invention and should not be construed as limiting the scope, and that other relevant drawings can be obtained from these drawings without inventive effort to a person skilled in the art.

FIG. 1 is a schematic cross-sectional structural view of an embodiment of a centrifugal grinding system along its axial centerline.

Fig. 2 is a cross-sectional view of the centrifugal grinding system with the drive shaft secured along its axial centerline.

Figure 3 is a schematic structural view of an embodiment of the jacket.

Fig. 4 is a schematic view of a radial cross-sectional structure along with the outer jacket.

Fig. 5 is a schematic view of the cross-sectional structure of fig. 4 taken along the A-A direction.

Fig. 6 is a schematic cross-sectional view of the structure of fig. 4 taken along the direction B-B.

Fig. 7 is a schematic view of the sectional structure of fig. 2 taken along the direction E-E.

FIG. 8 is a schematic diagram of the distribution of the material grinding media during operation.

Fig. 9 is a schematic diagram of another embodiment of a centrifugal grinding system.

The achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

The claims hereof are to be understood as being further detailed below, with reference to specific embodiments and figures, it being understood that the described embodiments are only a partial embodiment of the invention. Based on the embodiments of the present invention, one of ordinary skill in the art would be able to devise all other embodiments that are obtained without inventive effort and that fall within the scope of the present invention.

It should be understood that in the description of the present invention, all directional terms, such as "upper", "lower", etc., are used for convenience in describing the present invention and simplifying the description only, and do not indicate or imply that the apparatus or elements being referred to must have a specific orientation, be constructed and operate in a specific orientation, based on the orientation or positional relationship shown in the drawings or the orientation or positional relationship in which the inventive product is conventionally put. Merely to explain the relative positional relationship, movement, etc. of the components shown in the drawings, the directional indication may be changed when the specific posture is changed.

Furthermore, descriptions in this disclosure as pertaining to "first," "second," etc. are used solely for the purpose of distinguishing between them and should not be construed as indicating or implying a relative importance or an implicit indication of the number of features being indicated. The features "first", "second" and the like may thus be limited to either explicit or implicit and at least one of these features. In the description of the present invention, the meaning of "plurality" means at least two, i.e., two or more, unless otherwise specifically defined; the meaning of "at least one" is one or more.

As shown in fig. 1-7, the present invention provides an embodiment of a centrifugal grinding system.

In the invention, the slurry refers to a mixture of grinding media, grinding materials and liquid during wet grinding. The grinding medium refers to grinding balls. The ball mill centrifugal separator is used for separating materials ground into smaller diameters from a separation grinding medium from grinding slurry. That is, the desired material is separated from the separation grinding media and larger diameter material particles.

The centrifugal grinding system is used for separating grinding media from grinding slurry and comprises a grinding cylinder, a centrifugal separator and a driving mechanism for driving the centrifugal separator to work, wherein the centrifugal grinding system comprises a separation outer sleeve 1 and a separation inner cylinder 2 arranged in the separation outer sleeve 1, and the separation inner cylinder 2 is provided with an inner cylinder separation hole 21; the separation sleeve 1 is provided with a sleeve compound hole 11 which enables grinding media to move outwards and grade materials during rotation, a separation cavity 3 which is sealed in the axial direction is arranged between the separation inner cylinder 2 and the separation sleeve 1, and the separation cavity 3 is respectively communicated with the sleeve compound hole 11 and the inner cylinder separation hole 21.

Specifically, the separation inner cylinder 2 includes a cylindrical inner cylinder body having an inner cylinder receiving chamber 23 provided in the center axial direction thereof for receiving the separation drive shaft 5 and communicating with the inner cylinder separation hole 21. The separation drive shaft 5 is provided with a discharge channel 51, which discharge channel 51 communicates with the separation chamber 3 via an inner cylinder separation bore 21.

When the number of the outer sleeve composite holes 11 is two or more, the outer sleeve composite holes 11 are uniformly distributed on the same circle with the separated outer sleeve axle center as the center of a circle.

The outer sleeve composite hole 11 and the inner cylinder separating hole 21 are respectively in a strip shape, and the lengths of the outer sleeve composite hole 11 and the inner cylinder separating hole 21 are the same in general cases, so that balance is easier to keep and manufacturing is easier.

The outer sleeve composite hole 11 and the inner cylinder separation hole 21 are obliquely arranged, and the included angle a between the radius of the outer sleeve composite hole and the radius of the inner cylinder separation hole and the radius of the hole center are 30-45 degrees.

The separating inner barrel comprises a free end and a limiting end, and the limiting end is provided with a first step 22 for limiting the separating sleeve 1. The side wall of the inner cylinder accommodating cavity 23 of the free end is provided with a second step 24 matched with the separation driving shaft 5. The bottom of the inner cylinder accommodating cavity 23 is provided with a fixing hole 25 for fixing the separation driving shaft 5 and the separation inner cylinder 2 through a fixing bolt.

The inner sides of the two axial ends of the separation sleeve 1 are provided with a sleeve fixing groove matched with the inner cylinder fixing groove on the separation inner cylinder and a fixing pin 4 matched with the inner cylinder fixing groove and the sleeve fixing groove after assembly.

During installation, the inner sides of the two axial ends of the separation sleeve 1 are provided with a sleeve fixing groove 12 matched with the inner cylinder fixing groove on the separation inner cylinder 2 and a fixing pin 4 matched with the inner cylinder fixing groove and the sleeve fixing groove 12 after assembly. The fixing bolt is fixed with the separation driving shaft 5 through a fixing hole 25 at the bottom of the inner cylinder accommodating cavity 23.

As shown in fig. 8, in use, the separating device rotates under the drive of the separating driving shaft 5, and rotates along the direction E, the separating driving shaft 5 is axially provided with a discharge channel 51, and the discharge channel 51 is communicated with the inner cylinder separating hole 21 and the outer sleeve composite hole 11, and when the grinding medium a and the material are distributed on the surface of the separating device during high-speed rotation, the outer sleeve composite hole 11 simultaneously enables part of the grinding medium a and the material to move away from the separating sleeve 1 in a directional manner along the direction F, and forms a layer around the surface of the separating sleeve 1, i.e. the material with a smaller diameter is distributed nearer to the separating sleeve 1, and the material with a larger diameter and the grinding medium a are distributed farther from the separating sleeve 1. And during high-speed rotation, the outer sleeve composite hole 11, the inner cylinder separation hole 21 and the discharge channel 51 form negative pressure, so that materials with smaller diameters can be sucked into the outer sleeve composite hole 11 and discharged through the discharge channel 51, and materials with larger diameters and the grinding medium A are left outside the separation sleeve 1, thereby realizing separation, avoiding blockage caused by the grinding medium distributed near the separation device during separation, and being shorter in separation channel path and higher in separation efficiency. But also can provide grinding energy for materials with larger diameters and grinding media A, thereby improving the grinding efficiency.

Meanwhile, the inner barrel separation hole 21 is only one, and the separation cavity 3 is arranged between the inner barrel separation hole 21 and the nearest outer sleeve composite hole 11, and the inner barrel separation hole 21, so that materials are not easy to enter the inner barrel separation hole when the machine is stopped or started under the action of tension among slurries and the like, the occurrence of grinding media in discharged materials is avoided, the quantity of the grinding media is reduced, the grinding efficiency is influenced, and the grinding quality is also influenced.

According to the need, in order to further avoid that the material enters the inner barrel separation hole 21 to be discharged when the machine is stopped or started, the outer sleeve composite hole 11 and the inner barrel separation hole 21 are arranged in a staggered mode, as shown in fig. 9, that is, the inner barrel separation hole 21 and the nearest outer sleeve composite hole 11 are positioned on different radiuses, and the material and the grinding balls can be better prevented from entering the inner barrel separation hole when the machine is stopped or started.

The above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical schemes described in the foregoing embodiments may be modified or some technical features may be replaced with other technical schemes, and the modifications or the substitutions may also make the essence of the corresponding technical schemes deviate from the spirit and scope of the technical schemes of the embodiments of the present invention.

Claims (7)

1. The centrifugal grinding system comprises a grinding cylinder, a centrifugal separator and a driving mechanism for driving the centrifugal separator to work, and is characterized in that the centrifugal separator comprises a separation outer sleeve and a separation inner cylinder arranged in the separation outer sleeve, and the separation inner cylinder is provided with an inner cylinder separation hole; the separation sleeve is provided with a sleeve compound hole which enables the grinding medium to move outwards and grade the materials during rotation, and a separation cavity which is axially closed is arranged between the separation inner cylinder and the separation sleeve and is respectively communicated with the sleeve compound hole and the inner cylinder separation hole.

2. The centrifugal grinding system of claim 1, wherein: the separation inner barrel comprises a cylindrical inner barrel body, an inner barrel accommodating cavity is axially formed in the center of the inner barrel body, and the inner barrel accommodating cavity is used for accommodating the separation driving shaft and is communicated with the inner barrel separation hole.

3. The centrifugal grinding system of claim 1, wherein: when the number of the composite holes of the outer sleeve is two or more, the composite holes of the outer sleeve are uniformly distributed on the same circle taking the axis of the separated outer sleeve as the center of a circle.

4. A centrifugal grinding system according to claim 3, wherein: the outer sleeve composite hole and the inner barrel separation hole are respectively in a strip shape.

5. The centrifugal grinding system of claim 1, wherein: the outer sleeve composite hole and the inner barrel separation hole are obliquely arranged.

6. The centrifugal grinding system of claim 5, wherein: the included angle between the radius of the outer sleeve composite hole and the radius of the inner cylinder separating hole and the radius of the hole center are 30-45 degrees.

7. The centrifugal grinding system of claim 1, wherein: the inner barrel separation hole and the outer sleeve composite hole are positioned on different radiuses.