KR100203945B1 - A inflow protecting structure device - Google Patents

Abstract

The present invention relates to a centrifugal rotor coarse inflow prevention structure of the classifier which prevents coarse powder from being mixed into the separated fraction and improves the classification efficiency, and is in communication with the classifying chamber (10a) formed inside the main body (10). The centrifugal rotor 30 is rotatably installed directly under the discharge pipe 20, and is formed on the centrifugal rotor 30 in the shielding wall 21 formed on the outer circumferential surface of the lower end of the government discharge pipe 20 at a predetermined position. In the partition wall 31 is configured to form an air sealing hole (A), the partition wall of the centrifugal rotor 30 so as to be positioned in connection with the lower portion of the shielding wall 21 formed at the lower end of the fractional discharge pipe (20). A plurality of wing plates 32 are vertically attached at equal intervals around the outer circumferential surface of the air 31, and the air between the lower end of the fractional discharge pipe 20 and the partition wall 31 at the top of the centrifugal rotor 30 is provided. The coarse powder approaching toward the sealing hole (A) side Stage to the centrifugal rotor is a bun one trillion minutes inflow preventing structure of the supply air to be distributed.

Description

Coarse inflow prevention structure of centrifugal rotor of classifier

The present invention is intended to separate the crude powder obtained from the crushing process into coarse powder and fine powder. In particular, it prevents coarse powder from being mixed into the separated fraction and improves the classification efficiency. It's about structure.

In general, in the powder grinding process of cement, ceramic raw material, powder type chemicals or foods, sludge, etc., raw materials crushed to a certain granularity are selected, and powders having a certain particle size are selected. A classifier has been installed and used as a means for separating and giving a cycle for recirculation.

Such classifiers have been developed in various structures and forms according to their use and purpose, and the conventional classifiers, which may be typical, are in the tangential direction of the classifying chamber together with the powder inlet for supplying powder raw materials into the cylindrical classifying chamber. A main body provided with an air inlet for supplying air, a centrifugal rotor rotatably installed in the classifying chamber of the main body and sorting fine powder as air fed in a tangential direction while dispersing the supplied powder, and an upper portion of the centrifugal rotor And a coarse discharge pipe which is connected to the coarse discharge chamber and extends to the outside to discharge the selected fine powder, and a coarse discharge pipe which is formed integrally with the lower part of the classification chamber of the main body to discharge the coarse powder separated and dropped from the classification chamber. It consists of.

Therefore, the classifier is divided by the air introduced in the tangential direction through the air inlet while the powder introduced into the classification chamber by the rotation of the centrifugal rotor, the fraction is introduced into the inside of the centrifugal rotor through the upper part of the discharge pipe It is discharged to the outside to be collected in a separate dust collector, and the coarse grain having a larger particle size than the refined powder is dropped by its own weight so as to be discharged to the grinder through the coarse discharge pipe and regrind.

As described above, in the classifier of the structure in which the separated powder is discharged upward, a specific method for preventing coarse flow into the centrifugal rotor is provided through a gap formed between the fixed discharge pipe and the centrifugal rotor.

That is, as shown in Figure 1, the centrifugal rotor (4) is rotatably installed directly below the fractional discharge pipe (2) in communication with the classification chamber (2) formed inside the main body (1), the fine discharge pipe The fractional discharge pipe 2 and the centrifugal rotor are positioned so that the partition wall 3a formed on the top of the centrifugal rotor 3 is positioned with a fine gap in the shielding wall 2a formed on the outer circumferential surface at a predetermined position of the lower end of the bottom portion (2). An air sealing hole A was formed between the partition walls 3a of (3).

Therefore, when the centrifugal rotor 3 rotates at an appropriate rotational speed, an air layer is formed in the air sealing hole A between the partition wall 3a and the fractional discharge pipe 2 which are integrally rotated with the centrifugal rotor 3. Due to this, it is true that it has an advantage of preventing the coarse powder from flowing from the outside of the centrifugal rotor (3).

However, when the number of revolutions of the centrifugal rotor 3 is increased in order to obtain the fine powder in the powder classification process, the air between the partition wall 3a and the fraction discharge pipe 2, which are rotated integrally with the centrifugal rotor 3, is increased. As the air layer becomes thinner in the sealing hole (A), a suction force for sucking the outside air is generated, so that coarse powder flows into the centrifugal rotor (3) together with the air sucked through the air sealing hole (A). This resulted in incorporation with the already separated fraction.

As a result of the above, when the rotating speed of the centrifugal rotor is increased, the classifier is randomly introduced into the inside of the centrifugal rotor through the air sealing hole. First, the particle size distribution of the obtained fraction is obtained by mixing the crude powder into the selected fraction. The classification efficiency was lowered due to unevenness. Second, the classification range was limited by the rotational speed of the centrifugal rotor, which caused problems such as the inability to select fractions of various particle sizes.

The purpose of the present invention is to configure the separation of crude powder and crude oil strictly without regard to the rotational speed of the centrifugal rotor, firstly, to maximize the range of classification by allowing the selection of various particle sizes. The present invention provides a structure for preventing coarse inflow of centrifugal rotors of a classifier, which enables to classify fractions of equal particle size, thereby greatly improving the classification efficiency of powder.

1 is an overall cross-sectional view of a classifier illustrating a state where a conventional centrifugal rotor is installed.

2 is an overall cross-sectional view of a classifier illustrating a state in which the centrifugal rotor of the present invention is installed.

3 is a perspective view of the lumbar excerpt of the present invention.

4 is a plan view of FIG.

5 is a partial cross-sectional view illustrating another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

10: main body 10a: classification room

20: fraction discharge pipe 21: shielding wall

30: centrifugal rotor 31: partition wall

32: wing plate A: air sealing hole

The present invention is installed rotatably a centrifugal rotor 30 directly below the fractional discharge pipe 20 in communication with the classification chamber (10a) formed in the main body 10, the predetermined position of the lower end of the fractional discharge pipe (20) The partition wall 31 formed on the top of the centrifugal rotor 30 in the shielding wall 21 formed on the outer circumferential surface of the centrifugal rotor 30 has a fine gap therebetween so that the partition wall of the fractional discharge pipe 20 and the centrifugal rotor 30 31) in terms of the air sealing hole (A) is formed between the same as the conventional technical concept.

However, the centrifugal rotor installation structure of the classifier of the present invention, as shown in Figures 2 and 4, the centrifugal rotor 30 so as to be located in connection with the shielding wall 21 formed at the lower end of the fractional discharge pipe (20). A plurality of wing plates 32 are vertically attached at regular intervals around the outer circumferential surface of the partition wall 31 of the partition wall 31, and the partition wall 31 at the lower end of the fractional discharge pipe 20 and the upper portion of the centrifugal rotor 30. It is characterized in that the technical configuration to be dispersed by blocking the coarse powder approaching toward the air sealing hole (A) side between.

Reference numeral 11 is a powder inlet.

This invention according to the present invention, unlike the prior art that the coarse powder is sucked through the air sealing hole (A) and introduced into the centrifugal rotor 30 when the rotational speed of the centrifugal rotor 30 is increased, together with the centrifugal rotor 30 The blades 32 to be rotated are dispersed while blocking the crude powder flowing into the air sealing hole (A) side, thereby preventing the crude powder from being introduced into the centrifugal rotor 30 to prevent mixing with the already refined ingredients. Will be given.

Hereinafter, the technical configuration of the present invention in more detail as follows.

The main body 10 allows the powder raw material to be supplied from the upper portion through the powder inlet 11 communicated with the internal classification chamber 10a, and the air inlet 12 formed in the tangential direction of the classification chamber 10a. Allow air to flow through

As shown in FIG. 2, the fractional discharge pipe 20 is installed so as to penetrate the upper center of the classification chamber 10a in the main body 10 to extend to the outside.

The fractional discharge pipe 20 may be provided with a shielding wall 21 protruding horizontally on the outer peripheral surface of the lower portion at a predetermined position.

As shown in FIG. 3, the centrifugal rotor 30 is disposed in the classifying chamber 10a in the main body 10 so as to be connected to the lower portion of the fractional discharge pipe 20 and connected to the fractional discharge pipe 20. It is installed vertically through the rotation to rotate as a rotating shaft 40 connected to the drive motor (not shown).

2 and 3, the centrifugal rotor 30, the upper plate (30a) is formed with a discharge passage in the center so as to be connected to the fractional discharge pipe 20, and the lower plate is fixed to the rotating shaft 40 And a plurality of blades 30c in the outer circumferential direction between the upper plate 30a and the lower plate 30b.

In the embodiment of the present invention, as shown in Figure 3, the centrifugal rotor 30 has a partition wall 31 protruding annularly around the outer periphery of the parting pipe formed in the center of the upper plate (30a) It is exemplified as formed integrally with the wing plate 32 which is vertically attached at equal intervals along the outer circumferential surface of the partition wall 31.

On the other hand, Figure 5 shows another embodiment of the present invention, to form a bent jaw 22 bent downward at the outer end of the shielding wall 21 of the fractional discharge pipe 20, the bent jaw 22 In consideration of the height to form the wing plates 32 of the centrifugal rotor 30 to be located below the shield wall (21).

The reason why the bent jaw 22 is formed is to form a protrusion downward from the outer end of the shield wall 21 of the fractional discharge pipe 20 so as to classify the powder in the classification chamber so that an outer gap is formed by the projected vertical length. This is to prevent the coarse particles falling in the narrower than the inner gap from being introduced.

The centrifugal rotor structure of the classifier of the present invention is the centrifugal rotor (30) when the powder raw material is supplied to the classification chamber (10a) in the main body 10 from the powder inlet (11) to rotate the centrifugal rotor (30). As the powder introduced into the classification chamber 10a by the rotation of 30 is dispersed, the air introduced in the tangential direction through the air inlet 12 passes through the spaces between the blades 30c and the inside of the centrifugal rotor 30. The fractions are separated and introduced into the furnace.

At this time, air between the partition wall 31 formed on the upper surface of the centrifugal rotor 30 and the shielding wall 21 formed at the lower end of the fractional discharge pipe 20 is dispersed and supplied into the classification chamber 10a. Approaching to the sealing hole (A) side, the wing plate 32 that rotates with the centrifugal rotor (30) is to cause the wind to disperse at the same time while blocking the coarse powder to be introduced into the air sealing hole (A).

In summary, the effects of the present invention are constructed and implemented as follows.

That is, the present invention, firstly, by separating the coarse flow into the centrifugal rotor at the source, it is possible to separate and select only fractions of equal particle size, and second, at the desired classification point without regard to the rotational speed of the centrifugal rotor It will have the advantage of separating the fine powder.

Thirdly, indirectly supporting the dispersion of the initially supplied powder has an effect of increasing the secondary classification efficiency.

Claims (2)

The centrifugal rotor 30 is rotatably installed directly under the fraction discharge pipe 20 communicating with the classification chamber 10a formed in the main body 10, and is formed on the outer circumferential surface of the lower end of the fraction discharge pipe 20 at a predetermined position. The partition wall 31 formed on the top of the centrifugal rotor 30 in the shielding wall 21 is positioned with a fine gap, so that the partition wall 31 and the partition wall 31 of the centrifugal rotor 30 are located. The outer peripheral surface of the partition wall 31 of the centrifugal rotor 30 so as to be positioned in connection with the lower portion of the shielding wall 21 formed in the lower end of the fractional discharge pipe 20 in the air sealing hole (A). The air sealing hole (A) side between the partition wall 31 of the upper part of the centrifugal rotor 30 at the lower end of the fractional discharge pipe 20 is provided with a plurality of wing plates 32 vertically attached at regular intervals. Centrifugal rotor of the classifier, characterized in that to be dispersed by blocking the coarse approached toward Powder inflow prevention structure. The method of claim 1, wherein the bent projection 22 is formed at the outer end of the shield wall 21 of the portion discharge pipe 20 is formed to be bent downward and the height of the shielding wall 21 in consideration of the bent projection (22) The coarse flow prevention structure of the centrifugal rotor of the classifier, characterized in that by forming the wing plate 32 of the centrifugal rotor (30) to be located at the bottom.

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