KR20150110038A - Grain Size Classification Apparatus - Google Patents

Abstract

According to the present invention, provided is a particle size sorting apparatus comprising: one or more sieves for straining powder having a mesh unit where the meshes of a net are formed and a hollow shaft arranged on the center; a case which has the sieves for straining powder inside; and an insertion rotary shaft which is attached to the case and the hollow shaft of the sieves for straining powder, maintains the case and the one or more sieves for straining powder to be rotated and has a bent unit for providing vibration.

Description

{Grain Size Classification Apparatus}

The present invention relates to a particle size classifying apparatus, and more particularly, to a particle size classifying apparatus having at least one powder separating body and classifying the particle size of the powder particles by vibration together with a centrifugal force by an insertion rotating shaft having a bent portion .

Generally, a particle size separating apparatus equipped with a sieve is used to classify the powder according to the grain size. In most particle size classifiers, the particle size is separated using the weight and vibration of the powder itself. For example, powder of carbon nanotubes can be classified according to the mesh size of the sieve by receiving vibrations in the sieve classifier.

The particle size classifying apparatus according to the prior art takes a long time to complete classification and there is a problem that the powder particles are caught in the mesh of the sieve. The phenomenon that the powder particles adhere to the meshes acts as a direct cause of suppressing particle size classification of the particles, so that the classification time is further delayed. It is considered that the problem of the conventional technique is that the force applied to the powder particles mainly depends on the vibration and the gravity of the powder itself.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a particle size classifier capable of classifying powder particles using centrifugal force and vibration.

Another object of the present invention is to provide a particle size classifying apparatus in which powder particles can be prevented from being caught in a mesh of a mesh portion.

Another object of the present invention is to provide a particle size classifying apparatus which can be performed within a short period of time and can be subdivided according to the particle size.

In order to achieve the above object, according to the present invention,

At least one powder separating body having mesh-shaped mesh portions and a hollow shaft disposed at the center;

A case for containing the at least one powder separating body therein; And

And an insertion rotary shaft coupled to the case and the hollow shaft of the at least one powder separating body to rotatably hold the case and the at least one powder separating body and having a bending portion for imparting vibration, A classification apparatus is provided.

According to one aspect of the present invention, the at least one powder separating body includes first to third powder separating bodies having diameters different from each other, and the first to the third powder separating bodies, And a space is formed between the first to third separators when the first to third separators are accommodated in the casing.

According to another aspect of the present invention, a second powder separating body is disposed so as to surround the first powder separating body, a third powder separating body is disposed to surround the second separating body, The hollow shaft of the second powder separating body is inserted into the hollow shaft of the separating body, the hollow shaft of the third separating body is inserted into the hollow shaft of the second separating body, And the insertion rotation shaft is inserted into the hollow shaft of the third powder separation body.

According to another aspect of the present invention, there is further provided a cover for covering the case, wherein a nut formed at an upper end of the insertion rotation shaft is engaged with a bolt inserted through a hole formed at the center of the cover.

According to another aspect of the present invention, the mesh size of the mesh portion of the first powder separation body is larger than the mesh size of the mesh portion of the second powder separation body, and the mesh size of the mesh portion of the second powder separation body is larger than the mesh size of the mesh portion of the second powder separation body. Is larger than the mesh size of the mesh portion of the third powder separating body.

According to another aspect of the present invention, the bent portion is formed by bending the insert rotation shaft twice at an angle of 90 degrees.

According to another aspect of the present invention, the third powder separating body is supported on the upper surface of the insert portion formed at the center of the inner surface of the case, and the upper surface of the step portion formed at the lower end of the hollow shaft of the third powder separating body And the first powder separating body is supported on the upper surface of the stepped portion formed at the lower end of the hollow shaft of the second powder separating body.

According to another aspect of the present invention, there is further provided a linear insertion rotary shaft which is interchangeable with the insertion rotary shaft, and the linear insertion rotary shaft lacks the bending portion for imparting the vibration.

According to another aspect of the present invention, there is provided a method of manufacturing a honeycomb structure, comprising the steps of: during a rotation of the first to third powder separation bodies, a space between the first powder separation body and the second powder separation body, The powder particles in the space between the third powder separator and the space between the third powder separator and the case are classified according to their sizes.

In the particle size classification apparatus according to the present invention, vibrations can be applied simultaneously with strong centrifugal force at the time of particle size classification of powder particles. Therefore, in the particle size classification apparatus of the present invention, particle size classification can be performed quickly in a short period of time, and the phenomenon that the powder particles adhere to the mesh of the mesh portion can be prevented. Further, the particle size classifying apparatus of the present invention is provided with one or more powder separating bodies, so that subdivisions according to the particle size of the powder particles can be made.

1 is a schematic exploded perspective view of a particle size classification apparatus according to the present invention.
FIG. 2 is a schematic perspective view of one of the powder separation bodies included in the particle size classification apparatus according to the present invention shown in FIG. 1;
3 is a schematic cross-sectional view showing the granularity separating apparatus shown in FIG. 1 in an assembled state.

1 is a schematic exploded perspective view of a particle size classification apparatus according to the present invention.

The particle size classification apparatus according to the present invention comprises at least one powder separation body (21, 22, 23) having mesh portions (27, Fig. 2) having mesh portions of different sizes, A case 11 accommodated in the case 1, a case 11 coupled to the at least one powder separating body 21, 22, 23 and the case 11 to rotatably hold the powder separating body and the case, And an insertion rotation shaft 13 formed with a rotation shaft 13b. In the example shown in the figure, each of the one or more powder separation bodies 21, 22, and 23 is formed in a generally cylindrical shape and has different diameters and heights. 3, the first powder separation body 21, the second powder separation body 22, and the third powder separation body 23 are formed in the same manner as the case 11 And an annular space is formed between one powder separating body and another powder separating body. The case 11 is also formed into a cylindrical shape as a whole. An annular space is also formed between the third powder separating body (23) disposed at the outermost position and the inner surface of the case (11) when one or more powder separating bodies are accommodated in the case (11).

The case 11 is covered with a lid 12. A hole 12a through which the coupling bolt 15 can be inserted is formed in the center of the lid 12. [ The coupling bolt 15 is coupled to the coupling nut 13a formed on the upper portion of the insertion rotary shaft 13 as will be described in more detail later so that the one or more powder separation bodies 21, And the lid 12 are fixed to each other. Therefore, when the insertion rotating shaft 13 rotates, the one or more powder separating bodies 21, 22, and 23, the case 11, and the lid 12 can rotate together with being coupled to each other.

FIG. 2 is a schematic perspective view of one of the powder separation bodies included in the particle size classification apparatus according to the present invention shown in FIG. 1;

3, the third powder separation body 23 includes a bottom plate 23a, a support portion 26 extending from the bottom plate 23a, a mesh portion 27 supported by the support portion 26, ). The bottom plate 23a may be made of metal, plastic or other suitable material and has a circular shape in the embodiment shown in the figures. The support portion 26 supports the mesh portion 27 and has a lower extension portion 26a fixed to the rim of the bottom plate 23a in the embodiment shown in the figure and a lower extension portion 26b upwardly extending from the lower extension portion 26a Four elongated vertical extending portions 26b and an upper extended portion 26c connected to the upper end of the vertical extending portion 26b.

The mesh portion 27 is supported by the support portion 26. The mesh portion 27 is formed of, for example, a metal material or other suitable material, and has a mesh of a predetermined size. The size of the powder particles that can pass through the mesh portion 27 of the third powder separator 23 is determined according to the mesh size. The mesh size of the mesh portion 27 of the third powder separation body 23 is different from the mesh size of the mesh portion of the second and first powder separation bodies 22 and 21. For example, the mesh size of the mesh portion of the first powder separation body 21 is the largest, the mesh size of the mesh portion of the third powder separation body 23 is the smallest, and the mesh size of the second powder separation body 22 The mesh size of the mesh portion has a medium size.

A shaft 25 is provided at the center of the bottom plate 23a. The shaft 25 extends upward in the center of the bottom plate 23a as shown in the figure. The shaft 25 is formed with a hollow portion 25a so that the insertion rotation shaft 13 described with reference to Fig. 1 can be inserted into the hollow portion 25a of the shaft 25. At the lower end of the shaft 25, a step 25b is formed.

Although not shown in detail in the drawing, the second powder separator 22 and the first powder separator 21 also have a configuration similar to that of the first powder separator 21 described above. That is, each of the powder separation bodies is provided with a bottom plate, a supporting portion and a mesh portion. A hollow shaft is provided at the center of the bottom plate.

3 is a schematic cross-sectional view showing the granularity separating apparatus shown in FIG. 1 in an assembled state.

Referring to the drawings, a first powder separation body 21, a second powder separation body 22, and a third powder separation body 23 are stacked and accommodated in a casing 11. The insertion rotary shaft 13 is introduced into the case 11 through the insertion portion 11a formed on the bottom surface of the case 11. The hollow rotary shaft 13 is inserted into each of the hollow bodies 21, And reaches the hole 12a of the lid 12 through the shaft. The coupling bolt 15 is coupled to the coupling nut 13a provided at the upper end of the insertion rotation shaft 13 through the hole 12a formed in the lid 12 so that the coupling bolt 15 is inserted into the space formed by the case 11 and the lid 12 The received first to third powder separation bodies 21, 22, and 23 are mutually coupled.

As can be seen from Fig. 3, the diameter of the hollow portion of the shaft formed in the first to third powder separation bodies 21, 22 and 23 and the shaft length are formed differently from each other. The shaft provided in the second powder separating body 22 can be inserted through the hollow portion formed in the shaft 30 of the first powder separating body 21 and the shaft provided in the second powder separating body 22 can be inserted into the shaft The shaft 25 provided in the third powder separating body 23 can be inserted through the formed hollow portion. The insertion rotary shaft 13 is inserted through the shaft 25 of the third powder separator 23 so that it passes through the shafts of the first and second powder separation bodies 21 and 22 as a result.

On the other hand, the bottom plate 23a of the third powder separating body 23 is supported on the upper surface of the insertion portion 11a formed at the center of the bottom surface of the case 11, and thus the third powder separating body 23 A space is formed between the bottom plate 23a of the case 11 and the bottom surface of the case 11. [ The bottom plate 22a of the second powder separating body 22 is supported on the upper surface of the step 25b of the third powder separating body 23 so that the bottom surface 22a of the third powder separating body 23 A space is formed between the plate 23a and the bottom plate 22a of the second powder separation body 22. [ Similarly, the bottom plate 21a of the first powder separating body 21 is supported on the upper surface of the step portion 31 of the second powder separating body 22, A space is formed between the bottom plate (22a) and the bottom plate (21a) of the first powder separation body (21).

On the other hand, as described above, since the first to third powder separation bodies 21, 22, and 23 are formed in cylindrical shapes having different diameters from each other, the mesh portion of the first powder separation 21 and the second powder separation The mesh portion of the second powder separating body 22 and the mesh portion of the third powder separating body 23 and the mesh portion of the third powder separating body 23, And the inner surface of the case 11, respectively.

The bending portion 13b provided at the lower portion of the insertion rotary shaft 13 is for imparting vibration to the particle size classifier at the time of rotation of the insertion rotary shaft 13. [ The bending portion 13b is formed by bending a part of the insertion rotation shaft 13 extending straight by two times at an angle of 90 degrees from the outside of the case 11 as shown in the drawing. The insertion shaft 13 is formed with a bent portion 13b so that the case 11 coupled to the insertion rotary shaft 13 and the first to third separators 21 and 22 , 23 can be oscillated in the lateral direction.

Although it is not shown in the drawing, it is preferable to further include an insertion rotation axis in which the bent portion 13b is not formed. The insertion rotary shaft without the bending portion 13b is engaged with the case 11 and the first to third powder separation bodies 21, 22 and 23 instead of the insertion rotary shaft 13 to rotate at a high speed, It can be used to separate the powder that is sandwiched in the mesh.

Hereinafter, the operation of the particle size classifying apparatus according to the present invention will be schematically described.

As one example, the particle size classifying apparatus according to the present invention may be used to classify powder such as carbon nanotubes according to particle size. As described above, the first powder separation body 21, the second powder separation body 22 and the third powder separation body 23 are accommodated in the casing 11. [ At this time, the shaft provided in each powder separating body is inserted into the hollow portion of the shaft provided in the other powder separating body, whereby mutual coupling of the powder separating bodies is achieved, and further, An annular space is formed between the solvent (23) and the case (11). The insertion rotating shaft 13 is inserted through the insertion portion 11a of the case 11 and is inserted through hollow portions formed in the shafts of the first to third powder separation bodies 21, .

Before rotating the particle size distribution device, the powder is contained in the first powder separation body (21). Next, the lid 12 is closed, and the operation bolt 15 is inserted into the hole 12a and engaged with the coupling nut 13a of the insertion rotary shaft 13 to complete the operation.

Next, when the insertion rotating shaft 13 is rotated, the powder contained in the first powder separating body 21 is subjected to centrifugal force, and accordingly, it passes through the mesh portion provided in each powder separating body according to the particle size of the powder. On the other hand, the particle size classification device experiences vibration due to the centrifugal force due to the rotational motion and the bending portion 13b formed on the insertion rotary shaft 13. [

3, since the mesh size of the mesh portion provided in the first powder separation body 21 is largest, relatively large powder particles pass through the mesh portion of the first powder separation body 21, The powder particles reaching the space between the separating body 21 and the second powder separating body 22 while the powder particles not passing through the mesh of the mesh portion of the first separating body 21 (21).

Next, the powder passes through the mesh portion of the second powder separating body 22 by centrifugal force and reaches the space between the second powder separating body 22 and the third powder separating body 23, The mesh size of the mesh portion of the separating body (22) is smaller than the mesh size of the mesh portion of the first powder separating body (21). Powder particles smaller than the powder particles left in the first powder separation body 21 are left in the space between the first powder separation body 21 and the second powder separation body 22.

Similarly, the powder particles pass through the mesh portion of the third powder separator 23 to reach the space between the third powder separator 23 and the case 11, depending on the size. The powder particles which have not passed through the mesh portion of the third powder separation body 23 are left in the space between the second powder separation body 22 and the third powder separation body 23, Is smaller than the powder particles left in the space between the first powder separator (21) and the second powder separator (22). The size of the powder particles reaching the space between the case 11 and the third powder separating body 23 passing through the mesh portion of the third powder separating body 23 is the smallest.

As described above, the powder particles pass through the mesh portions of the respective powder separating bodies 21, 22 and 23 or remain in spaces between the powder separating bodies depending on their sizes. The relatively largest powder particles are left in the first powder separator 21 and the relatively small powder particles reach the space between the third powder separator 23 and the case 11. [ As a result, when three powder separation bodies 21, 22, and 23 are provided, the powder particles can be classified into four classes.

After the above operation is completed, it may be necessary to rotate the particle size classifier at a high speed in order to take out the powder particles sandwiched between the respective mesh portions. To this end, the insertion rotation axis 13 is replaced by another linear insertion type rotation axis (not shown) having no bent portion. When the particle size classifier is rotated at a high speed using a linear insertion axis, the powder particles sandwiched by the mesh portion are separated from the mesh portion by centrifugal force.

The particle separation apparatus 10 according to the present invention described above has been described with respect to three powder separation bodies 21, 22 and 23, for example, in which the powder particles can be classified into four particle sizes. However, those skilled in the art will appreciate that more or less than three powder separators may be provided in the particle separator 10. For example, if four powder separators are provided, the powder particles can be further subdivided into five particle sizes.

10. Particle size classifier 11. Case
12. Lid 13. Insertion rotary shaft
15. Connecting bolts 21.22.23. Powder separator

Claims (9)

At least one powder separating body having mesh-shaped mesh portions and a hollow shaft disposed at the center;
A case for containing the at least one powder separating body therein; And
And an insertion rotary shaft coupled to the case and the hollow shaft of the at least one powder separating body to rotatably hold the case and the at least one powder separating body and having a bending portion for imparting vibration, Classification apparatus. The method according to claim 1,
Wherein the at least one powder separating body includes first to third powder separating bodies having different diameters, the mesh sizes formed in the mesh portions of the first to third powder separating bodies are different, And a space is formed between the first to third powder separation bodies when the third powder separation bodies are housed in the case. 3. The method of claim 2,
A second powder separation body is disposed so as to surround the first powder separation body, a third powder separation body is disposed to surround the second powder separation body,
Wherein a hollow shaft of the second powder separation body is inserted into a hollow shaft of the first powder separation body and a hollow shaft of the third powder separation body is inserted into a hollow shaft of the second powder separation body, And the insertion shaft is inserted into the hollow shaft of the third powder separation body. The method of claim 3,
Further comprising a cover for covering the case, and the nut formed at the upper end of the insertion rotation shaft is engaged with a bolt inserted through a hole formed at the center of the cover. 3. The method of claim 2,
Wherein the mesh size of the mesh portion of the first powder separating body is larger than the mesh size of the mesh portion of the second powder separating body and the mesh size of the mesh portion of the second powder separating body is larger than the mesh size of the mesh portion of the third powder separating body Wherein the particle size distribution is larger than the net mesh size. 3. The method according to claim 1 or 2,
And the bent portion is formed by bending the insert rotary shaft twice at an angle of 90 degrees. 3. The method of claim 2,
The third powder separating body is supported on the upper surface of the insertion portion formed at the center of the inner surface of the case,
The second powder separating body is supported on the upper surface of the stepped portion formed at the lower end of the hollow shaft of the third powder separating body,
Characterized in that the first powder separating body is supported on the upper surface of the stepped portion formed at the lower end of the hollow shaft of the second powder separating body. 3. The method according to claim 1 or 2,
Further comprising a linear insertion rotation axis which is interchangeable with the insertion rotation axis, wherein the linear insertion rotation axis is devoid of a bending section for imparting the vibration. 3. The method of claim 2,
Wherein a space between the first powder separator and the second powder separator, a space between the second powder separator and the third separator while the first to third separators are rotating, And the powder particles are classified according to their sizes in a space between the third powder separator and the case.

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