KR200310843Y1 - Dispersion rotor of classifier for powder - Google Patents

Abstract

The present invention relates to a dispersion rotor of a powder classifier, and more particularly, the tip of the dispersing blade of the dispersion rotor is radially curved in the opposite direction of rotation to maximize the degree of dispersion of the powder raw material, thereby improving the classification efficiency of the powder raw material. Not only to increase, but also to a dispersing device that can increase the marketability of the product thereby.

According to the present invention, the dispersing rotor of the powder classifier is provided, characterized in that the end is formed in the opposite direction of rotation of the classification rotor 100 at the front end of the dispersing wing (40).

Description

Dispersion rotor of classifier for powder

The present invention relates to a dispersion rotor of a powder classifier, and more particularly, the tip of the dispersing blade of the dispersion rotor is radially curved in the opposite direction of rotation to maximize the degree of dispersion of the powder raw material, thereby improving the classification efficiency of the powder raw material. Not only to increase, but also to a dispersing device that can increase the marketability of the product thereby.

In general, classification means the separation of solids according to chemical composition, particle diameter, shape, color, density, radioactive, magnetic and electrostatic properties. According to this, the operation is divided into two or more particle groups.

In the general classifier (A) used for the classification, the classification rotor 100 divided into the upper plate 10 and the lower plate 10 'is mounted, and the classification rotor 100 is shown in FIG. Rotating shaft 20 insertion hole 30 is formed at the center of the upper surface, and radial dispersion blades 40 having a spaced space at predetermined intervals are formed at the outer circumference of the insertion hole 30. The classification rotor 100 has a classification blade 50 having a separation space at a predetermined interval on the outer circumference thereof, and an upper differential inlet 60 through which fine powder flows into the separation space between the classification blades 50 is formed. The fine inlet 60 and the fine outlet 60 'below the classification rotor 100 are connected to each other to form a differential passage 70.

When the powder raw material is put into the raw material inlet of the classifier equipped with the classification rotor as described above, the powder is subjected to the first dispersion process due to the rotation of the scattering cone. As it moves to the end, it is rubbed with the dispersing blade, which causes a secondary dispersion process in which the powder material is dispersed. In addition, the powder raw material that has undergone the first and second dispersion processes is classified into coarse powder and fine powder by the classification blade of the classification rotor.

However, in the secondary dispersion process, the dispersing blade of the classification rotor is formed in a straight radial shape so that no friction occurs in the powder raw material and the dispersing blade. Thus, the dispersion degree of the powder raw material is lowered, and the classification precision of the coarse powder and fine powder is also reduced. In addition, the situation is occurring such as degradation of the product quality.

The purpose of the present invention is to solve such a conventional problem, by forming a plurality of radial dispersion blades formed on the upper surface of the classification rotor to be curved in the opposite direction of rotation, thereby increasing the friction of the powder raw material and the dispersion blades The purpose of the present invention is not only to increase the dispersion of powder raw materials, but also to increase the precision of classification, thereby providing a dispersion rotor of a powder classifier capable of producing a high quality product.

1 is a cross-sectional view showing a conventional classification rotor

Figure 2 is a cross-sectional view showing the classification rotor of the present invention

Figure 3a or 3b is a perspective view and a plan view showing the upper surface of the classification rotor in the present invention

Figure 4 is a state diagram showing the operating state of the classification rotor of the present invention

5 is a cross-sectional view showing a mounting state of the present invention

<Description of Symbols for Major Parts of Drawings>

10: upper plate 10 ': lower plate 20: axis of rotation

30: insertion hole 40: dispersion wing 50: classification wing

60: differential inlet 60 ': differential outlet 70: differential passage

100: classifier rotor: classifier

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

The rotary shaft 20 insertion hole 30 is formed at the center of the upper surface of the classification rotor 100 divided into the upper plate 10 and the lower plate 10 ', and has a spaced space at a predetermined interval on the outer periphery of the insertion hole 30. Radial dispersion wing 40 is formed, the classification rotor 100 is formed on the outer circumferential edge of the classification blade having a spaced space at a predetermined interval, but the differential flows into the spaced space between the classification wing 50 The fine powder inlet 60 of the upper side is formed, and the fine powder inlet 60 and the fine powder outlet 60 ′ of the lower side of the classification rotor 100 are connected to each other so that the fine powder passage 70 is formed. In the distributed rotor of the air supply, the present invention is characterized in that the end is formed in the distal end of the dispersing blade 40 in the opposite direction of rotation of the classification rotor 100 as shown in Figures 2 to 3b. .

In the present invention as described in Figure 3a or 3b, as shown in Figure 3a or 3b to form a plurality of dispersing wings (40) radiating about the insertion hole 30 of the upper surface center of the classification rotor (100), the dispersing wing (40) The end of the classification rotor 100 is completed by the classification rotor 100 implemented by the present invention by forming a curved in the direction of the rotational direction of the classification rotor 100.

Referring to the action generated by mounting the classification rotor 100 as described above in the ordinary classifier (a),

First, as shown in FIG. 5, a classification rotor 100 is mounted in a housing in which a raw material inlet 1 is formed at an upper center and a coarse flow passage 2 is formed at one side, and the classification rotor 100 is installed. The lower end of the insertion hole 30 is mounted to the rotary shaft 20, the upper center of the classification rotor 100 equipped with the rotary shaft 20 is equipped with a scattering cone (3). Further, a differential movement case 5 having a differential outlet 4 is formed at one side of the differential outlet 60 ′ below the classification rotor 100.

When the powder raw material is introduced into the raw material inlet 1 in the state where the classification rotor 100 is installed in the classifier (A) as described above, the powder raw material collides with the scattering cone 3 which is rotating at high speed through the rotating shaft 20. Undergoes the first dispersion process. And the dispersed powder raw material is separated into a space between the plurality of dispersing blades 40 formed on the upper surface of the classification rotor 100 is subjected to the secondary dispersion process, as shown in Figure 4 dispersing blades (40) ) Is radially curved in the opposite direction of rotation to form a wide area where the incoming powder raw material strikes the curved surface of the dispersal wing 40. As a result, the friction between the dispersion blade 40 and the powder raw material is increased to increase the dispersion efficiency.

And the powder raw materials that have undergone the first and second dispersion processes are divided into coarse powder and fine powder by the rotary centrifugal force of the classification rotor 100, and the coarse powder is divided into the coarse flow passage 2 formed on one side of the classifier. Withdrawal to the outside through the differential is connected to the cyclone to collect the differential through the differential movement case (5) connected to the lower end of the classification rotor (100).

In the above coarse powder and fine powder is increased the precision of the classification, it is possible to produce a high quality product through the above process.

As such, the present invention forms a radial dispersion blade 40 formed on the upper surface of the classification rotor 100 so as to be curved in the opposite direction of rotation, thereby increasing the friction area between the powder raw material and the dispersion blade 40 so that the dispersion of the powder raw material is increased. Not only is this increased, thereby also increasing the precision of classification, thereby maximizing the merchandise of the product.

Claims (1)

The rotary shaft 20 insertion hole 30 is formed at the center of the upper surface of the classification rotor 100 divided into the upper plate 10 and the lower plate 10 ', and has a spaced space at a predetermined interval on the outer periphery of the insertion hole 30. Radial dispersion wing 40 is formed, the classification rotor 100 is formed on the outer circumferential edge of the classification blade having a spaced space at a predetermined interval, but the differential flows into the spaced space between the classification wing 50 The fine powder inlet 60 of the upper side is formed, and the fine powder inlet 60 and the fine powder outlet 60 ′ of the lower side of the classification rotor 100 are connected to each other so that the fine powder passage 70 is formed. In the distribution rotor of the air supply, the dispersing rotor of the powder classifier, characterized in that the end of the dispersing blade 40 is formed in the end curved in the opposite direction of rotation of the classification rotor (100).