KR101602890B1 - Classifier that is configured filtration fan - Google Patents

Abstract

A classifier (100) having filtration fans according to the present invention comprises: an external chamber (110) formed to make powdered material flow in and connected to a discharge pipe (160); an internal chamber (120) housed within the external chamber (110) and connected to the discharge pipe (160); an inflow pipe (130) formed to be connected to the side of the internal chamber (120); and the filtration fans (140) installed at ends (137) of the inflow pipe (130) separated from each other while facing each other and filtering powdered particles. Thus, the present invention filters thick particles via an air membrane formed via the filtration fans (140) and fine particles pass through the air membrane while rotating with blades (143) of the filtration fans (140). In addition, the classifier of the present invention basically prevents the phenomenon that powder flows into a gap between the blade (143) and the inflow pipe (130), thereby being capable of efficiently selecting the fine powder with a size of 0.7-10 μm from the powdered material.

Description

The classifier is configured with a filtration fan.

The present invention relates to a classifier having an air filtration fan, and more particularly, to a classifier having an air filtration fan configured to easily select desired fine particles from a powdery material by using an air filtration unit.

1 is a cross-sectional view illustrating a classifier according to the background art.

In general, it is necessary to sort powder materials such as calcium chloride, potassium chloride, and sodium hydroxide into fine particles desired by a user, for example, a specified size (0.7 to 10 mu m).

In order to achieve this object, the classifier 1 shown in Fig. 1 is used.

The classifier 1 is constituted by an outer chamber 10 formed with a discharge port 13 downwardly and is supported in the outer chamber 10 so as to be accommodated in the outer chamber 10 and spaced apart from the outer chamber 10 And an inner chamber 20 which is open upward and has a discharge port 23 formed downward. A rotor 30 on the disc plate is accommodated in the outer chamber 10 so as to be disposed on the upper portion of the inner chamber 20. The rotor 30 is fixed to the rotor 30 and passes through the outer chamber 10 The rotating shaft 40 is constituted. A motor 50 for transmitting power to the rotary shaft 40 is fixed to the upper portion of the outer chamber 10. Since the powder flows through the upper portion of the outer chamber 10 and is directed to the upper portion of the rotor 30, a charging tube 60 for guiding the powdered material is formed. A conduit 70, which is connected to the discharge port 23 of the inner chamber 20 through the lower portion of the outer chamber 10 and which is closed at one side, is constructed. A suction fan (not shown) is connected to the conduit 70 and a conveyor 80 is formed below the discharge port 13 of the outer chamber 10.

Hereinafter, an operation example of the classifier 1 will be described.

First, power is applied to the motor (50) to rotate the rotor (30). The suction fan (not shown) is driven to suck air through the inner chamber 20 and the conduit 70. In this state, the powdery material is supplied through the conduit (70). Then, the rotor 30 is bumped by the centrifugal force toward the inner side surface of the outer chamber 10 while the material hits the rotor 30.

At this time, the large particles collide with the inner surface of the outer chamber 10 and are discharged to the conveyor 80 through the discharge port 13 of the outer chamber 10, and the fine particles smaller than the particles discharged to the conveyor 80 And is sucked into the chamber 20 through the conduit 70 after being sucked into the space between the rotor 30 and the inner chamber 20 by the suction force of the suction fan (not shown).

By this operation, the outer chamber 10 and the inner chamber 20 are sorted into powder materials of different sizes.

However, according to the background art, coarse particles of powder are reflected between the rotor 30 and the inner chamber 20 while being collided with the inner surface of the outer chamber 10, and the suction force of the suction fan And flows into the space between the rotor 30 and the inner chamber 20. Accordingly, since the particles selected through the suction fan (not shown) are mixed in various sizes, there is a problem that the sorting performance is difficult to actually apply.

Therefore, it is troublesome to obtain a powder having a desired particle size because the material selected through the suction fan (not shown) is supplied to the powder feeder 1 and sorted repeatedly.

Korean Patent Publication No. 10-1993-0002069 (March 26, 1993)

The classifier comprising the air filtering fan according to the present invention can efficiently solve the problem of repeatedly filtering the fine particles by appropriately selecting the powder of the fine particles from the powdery materials having various sizes, And it is an object of the present invention to provide a classifier having an air filtration fan which is superior in speed and selectivity to background arts, because it solves the problem of energy waste and delay in production time.

A classifier constructed by a filtration fan according to the present invention comprises an outer chamber formed to introduce a powdered material into which a discharge tube is connected, an inner chamber accommodated in the outer chamber and connected to the discharge tube, And a filtration fan which is opposed to the end portion of the inflow pipe and faces the powder particles.

And a rotation shaft connected to the filtration fan and passing through the outer chamber and rotatably supported by the outer chamber, wherein the filtration fan includes a rotation plate fixed to the rotation axis, And a plurality of blades attached along the periphery and spaced apart and opposed to the inlet tube.

The inlet pipe includes an inner pipe and an outer pipe for receiving the inner pipe. The inner pipe and the outer pipe are closed at both ends thereof. The inner pipe is connected to the outer pipe, Said blades being disposed along an end portion of said inlet tube and having an air hole penetrating between said outer tube and said inner tube at an end of said inlet tube toward said blade, do.

The inner tube is fixed through the inner chamber. The outer tube is fixed to the inner chamber by receiving the inner tube. The outer tube is attached to the opposite end of the blade at the inner tube and the inner tube, And a ring-shaped cover plate for finishing between the inner tube and the inner tube, wherein the air hole penetrates the cover plate.

The inner chamber includes a cyclone pipe fixed to an inner upper surface of the outer chamber and connected to the outer chamber in such a manner that the inner chamber is disposed below the inner chamber and is wound around an outer periphery of the outer chamber, The supply port is opened at an end of the outer chamber, and is opened so that it is connected to the outer chamber, and the width is narrower as it enters the outer chamber.

The hermetic protrusions are formed on the blade so as to extend along a circumference at one side of the opposite surface facing the blade. The hermetic protrusions are spaced apart from the hermetic protrusions of the cover plate by a predetermined distance so as not to interfere with rotation of the blades, And an airtight groove portion formed to correspond to the airtight projection portion so as to be accommodated.

Wherein the airtight protrusion has a plurality of protruding grooves spaced along the circumference of the outer circumferential surface and the inner circumferential surface of the airtight protruding portion, a first airtight member made of a resin material is laminated on the plurality of protruding grooves, A plurality of spaced apart blade grooves are formed on the upper side or the lower side thereof, and a second airtight member is laminated on the blade grooves.

The classifier having the filtration fan according to the present invention firstly separates coarse particles of powder through a cyclone pipe, and then coarse particles are filtered once again through an air film formed through the filtration fan, So that it can be easily selected because it is discharged through a discharge pipe through an air membrane.

In addition, since the phenomenon that the powder flows into the gap between the blade and the cover plate can be originally blocked, there is an effect of preventing the coarse particle powder from being mixed.

1 is a sectional view showing a classifier according to the background art;
2 is a perspective view illustrating a classifier having an air filtering fan according to an embodiment of the present invention.
3 is a cross-sectional view taken along the line F-F 'in Fig.
Fig. 4 is an enlarged view showing part A of Fig. 3; Fig.
5 is a cross-sectional view taken along the line J-J 'in Fig. 2;
FIG. 6 is a perspective view illustrating a filtration fan constructed in a classifier having an air filtration fan according to an embodiment of the present invention. FIG.
7 is an enlarged view of part A showing a classifier having an air filtration fan according to another embodiment of the present invention.
8 is an enlarged view of part A showing a classifier constructed with an air filtering fan according to another embodiment of the present invention.
Fig. 9 is a view showing an apparatus for forming the blade groove of the blade according to Fig. 7;
Fig. 10 is a view showing an apparatus for forming a projection groove groove of the cover plate according to Fig. 8;

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.

3 is a cross-sectional view taken along line F-F 'of Fig. 2, Fig. 4 is an enlarged view showing part A of Fig. 3, and Fig. 5 is an enlarged view of the air distributor of Fig. FIG. 6 is a perspective view showing a filtration fan constructed in the classifier constructed by the air filtering fan according to the present invention. FIG.

7 is an enlarged view of a portion A of a classifier constructed by an air filtration fan according to another embodiment of the present invention. FIG. 8 is a cross-sectional view of an air filtering fan according to another embodiment of the present invention, Fig. 9 is a view showing an apparatus for forming the blade groove of the blade according to Fig. 7, and Fig. 10 is a view showing an apparatus for forming the groove groove of the cover plate according to Fig.

2 and 3, an outer chamber 110 is formed in which a powdery material is introduced and a discharge tube 160 is connected. The outer chamber 110 is accommodated in the outer chamber 110 and is connected to the discharge tube 160 An associated inner chamber 120 is constructed. An inlet pipe 130 connected to a side of the inner chamber 120 and guiding the material to be fed into the inner chamber 120 is formed. The inlet pipe 130 is spaced apart from the end 137 of the inlet pipe 130, Thereby constituting a filtration fan 140 for filtering the powdery particles. The inner chamber 120 is fixed to an inner upper surface of the outer chamber 110 and is disposed below the inner chamber 120. The inner chamber 120 is wound around the outer circumference of the outer chamber 110, A cyclone pipe 170 connected to the crankshaft 170 is constructed. Further, a frame 180, which functions to support the outer chamber 110 on the ground, is attached to the outer surface of the outer chamber 110.

The above configuration will be described in more detail with reference to FIG. 2 to FIG.

The outer chamber 110 is formed in a cylindrical shape elongated in the upper and lower chambers and has an opening / closing opening 113 for opening / closing the lower end thereof. The suction / discharge pump 190 is connected to the outer chamber 110. Further, a discharge tube 160 is connected to the upper surface to communicate with the inside.

The inner chamber 120 is fixed to the inner upper surface of the outer chamber 110 and is connected to the discharge pipe 160. In addition, the remaining portion except for the inflow pipe 130 is configured to be sealable.

3 and 4, the inflow pipe 130 includes an inner pipe 131 and an outer pipe 132 for receiving the inner pipe 131. The inner pipe 131 and the outer pipe And an air pipe 133 connected to the outer pipe 132 and connected between the inner pipe 131 and the outer pipe 132 and passing through the outer chamber 110, ). The blade 143 is disposed around the end portion 137 of the inflow pipe 130 and the outer pipe 132 is connected to the end portion 137 of the inflow pipe 130 facing the blade 143. [ And an air hole (134) passing through the inner tube (131).

The inner tube 131 is fixed through the inner chamber 120 so that the connection between the inner tube 131 and the inner chamber 120 can be hermetically sealed .

The outer tube 132 receives the inner tube 131 and is fixed to the outer surface of the inner chamber 120 so that the connection between the outer tube 132 and the inner chamber 120 can be hermetically sealed .

An example of closing the outer tube 132 and the end of the inner tube 131 is an outer tube 132 attached to an end of the inner tube 131 and the outer tube 132 facing the blade 143, Shaped cover plate 135 for closing between the inner tube 131 and the inner tube 131 is formed.

Accordingly, the air holes 134 are formed through the cover plate 135, and the cover plate 135 faces the filtration fan 140. A hermetic protrusion 135a is formed on the surface of the cover plate 135 facing the blade 143 along a circular trace and the hermetic protrusion 135a of the cover plate 135 is interfered with the blade 143 The airtight groove portion 143a is formed so as to be spaced apart from each other by a predetermined distance.

3 and 4, the filtration fan 140 is rotatably supported by the outer chamber 110. The filtration fan 140 is connected to the filtration fan 140 and penetrates the outer chamber 110, 110 are rotatably supported by a rotating shaft 151. [ That is, the housing 153, which receives the rotation shaft 151, is fixed through the outer chamber 110 and transmits a rotational force to the rotation shaft 151 protruding outside the outer end of the housing 153 150 are mounted on the outer chamber 110.

2 and 3, the driving unit 150 includes a driven pulley 158 fixed to an end of a rotating shaft 151 protruding outward from an outer end of the housing 153 and a driven pulley 158 corresponding to the driven pulley 158 And a motor 155 to which the driving pulley 157 is attached is fixed to the outer chamber 110. The rotational force of the motor 155 can be transmitted to the rotary shaft 151 by the belt 159 connecting the drive pulley 157 and the driven pulley 158.

It is needless to say that the transmission from the motor 155 to the rotary shaft 151 in the driving unit 150 may be a gear transmission system and a transmission system using a sprocket and a chain. Alternatively, the motor 155 may be directly connected to the rotating shaft 151.

4 and 6, the filtration fan 140 includes a rotation plate 141 fixed to the rotation axis 151, and is installed along the circumference of the rotation plate 141 toward the inflow pipe 130 And a plurality of opposed blades 143 are formed spaced apart from the inflow pipe 130.

The blade 143 is, for example, a plate-like rectangular shape and is formed in a circular shape along the front surface of the rotary plate 141 so that both side surfaces thereof face each other.

The airtight groove 143a is formed at the opposite end of the blade 143 coupled to the rotation plate 141. The airtight groove 143a is formed in the airtight protrusion 135a of the cover plate 135, And is configured to receive the hermetic protrusion 135a at a predetermined interval.

The airtight protrusion 135a of the cover plate 135 is formed with a plurality of protrusion groove grooves 135b spaced along the circumference on the outer circumferential surface and the inner circumferential surface thereof, A plurality of spaced apart blade grooves 143b are formed on the upper side or the lower side of the airtight groove portion 143a and a plurality of spaced apart blade grooves 143b are formed in the blade groove 143b And the second hermetic member 143c is laminated.

7 shows an embodiment in which a plurality of blade grooves 143b extending on the airtight groove 143a of the blade 143 are formed and then a second airtight member 143c is laminated. The second airtight member 143c of the blade 143 is formed and a plurality of protruding grooves 135b are formed on the airtight protrusion 135a of the cover plate 135. Thereafter, Are laminated.

If only the airtight protrusion 135a of the cover plate 135 and the airtight groove 143 of the blade 143 are formed as described above, it is possible to prevent powder particles flowing into the space between the airtight protrusion 135a and the blade 143, The space between the airtight protrusion 135a and the airtight groove 143a is further minimized by additionally providing the first airtight member 135c and the second airtightness member 143c so that the powder particles can be prevented from being introduced into the space between them do.

9 shows an example of the cutting device 200 for forming the blade groove 143b in the airtight groove portion 143a. The cutter 200 includes an extension protrusion (not shown) extending in one direction along a circular trace on a donut- A cutter 211 is formed on the outer circumferential surface and the inner circumferential surface of the extended protrusion 210 so that the cutter 211 of the cutting device 200 is separated from the blade 143, And then the blade groove 143b is formed.

At this time, the blade groove 143b is formed by rotating the blade 143 or rotating the apparatus after the extension protrusion 210 and the cutter 211 of the cutting device 200 are introduced onto the airtight groove 143a The upper blade groove 143b or the lower blade groove 143b of the airtight groove portion 143a is formed by raising or lowering the apparatus by the depth of the blade groove 143b when rotating one side.

10 is an example of a cutting apparatus 200 that forms a protrusion groove 135b on the outer circumferential surface and the inner circumferential surface of the airtight protrusion 135a of the cover plate 135. The protrusion 135b is formed in the shape of a donut A first extension portion 220 and a second extension portion 230 are formed on the body along the circular path so as to extend upward and downward, respectively, and a plurality of spaced apart cutters 220 are formed on the inner peripheral surface of the first extension portion 220, A plurality of cutters 231 are installed on the outer circumferential surface of the second extension protrusion 230 so that the cutters 221 and 231 of the cutting device 200 are mounted on the cover plate 221, (135b) is formed on the outer circumferential surface and the inner circumferential surface of the airtight protrusion (135a) of the piston (135).

2 and 5, the cyclone pipe 170 is opened by a supply port 173 through which the material is supplied to the outer end portion 171. The cyclone pipe 170 is opened in contact with the outer chamber 110, (B) is formed to be narrower along the periphery of the outer chamber 110, so that the introduced material is swirled and flows.

Hereinafter, an operation example of the classifier 100 constituted by the filtration fan according to the above configuration will be described.

First, the discharge pipe 160 is connected to a suction fan (not shown), and the motor 155 is driven to rotate the filtration fan 140. In this state, a powdery material composed of particles of various sizes is supplied to the cyclone pipe 170 by a blowing fan (not shown).

Then, the material is circled along the cyclone pipe 170 and gradually narrows in the direction in which the width b of the cyclone pipe 170 is introduced, so that the material flows inwardly and gradually as shown by arrows in Fig. Thus, the material is supplied into the outer chamber 110 while swirling. Further, a suction force is generated by the suction fan (not shown) through the discharge pipe 160 and the filtering plate 140, and an airflow is formed upward, so that the material for swirling is raised. At this time, the material of coarse particles which can not rise together with the eddy current falls downward.

Further, an air film is formed around the blade 143 due to the rotation of the filtration fan 140, and a suction force is generated through the air membrane through the discharge pipe 160. Therefore, the fine particles rotate together with the blade 143 and then pass through the air membrane by the suction force of the discharge pipe 160, pass through the inner chamber 120 through the inlet pipe 130, and then escape to the discharge pipe 160.

The coarse protrusion 135a of the cover plate 135 and the airtight groove 143a of the blade 143 may be configured to be coarse grains flowing into the gap between the cover plate 135 and the blade 143. [ And the air supplied through the air pipe 133 is discharged through the air hole 134, so that a gap is formed between the cover plate 135 and the blade 143 Air curtains are formed to block the passage of coarse particles.

Therefore, the fine powder having a size of 0.7 to 10 mu m can be easily selected through the discharge pipe 160. [ In addition, after stopping the present invention, powder of coarse particles of 10 mu m or more can be discharged through the suction pump 190. [

According to the present invention, the coarse particles are first filtered through the cyclone pipe 170, the coarse particles are filtered through the air film formed through the filtration fan 140, Rotates together with the blade 143 of the filtration fan 140, and then passes through the air membrane. In addition, since the phenomenon that the powder flows into the gap between the blade 143 and the cover plate 135 is originally blocked, fine powder having a size of 0.7 to 10 μm can be efficiently selected from the powdered material.

The embodiments and the accompanying drawings described in the present specification are merely illustrative of some of the technical ideas included in the present invention. Therefore, it is to be understood that the embodiments disclosed herein are not for purposes of limiting the technical idea of the present invention, but are intended to be illustrative, and therefore, the scope of the technical idea of the present invention is not limited by these embodiments. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100: Classifier provided with a filtration fan 110: External chamber
120: inner chamber 130: inlet pipe
131: inner tube 132: outer tube
133: air pipe 134: air hole
135: cover plate 140: filtration fan
141: spindle 143: blade
150: driving part 151:
153: housing 155: motor
157: Driving pulley 158:
159: Belt 160: Discharge tube
170: Cyclone pipe 171: Outer end
173: feed port 180: frame
190: Suction pump 200: Cutting device

Claims (6)

An outer chamber 110 formed to introduce powdered material and connected to a discharge tube 160,
An inner chamber 120 accommodated in the outer chamber 110 and connected to the discharge pipe 160,
An inlet pipe 130 connected to the inner side of the inner chamber 120,
And a filtration fan (140) facing the end portion (137) of the inflow pipe (130) and filtering powder particles,
And a rotation shaft (151) connected to the filtration fan (140) and supported to rotate in the outer chamber (110)
The filtration fan 140 includes a rotation plate 141 fixed to the rotation axis 151,
And a plurality of blades 143 attached to the circumference of the rotating plate 141 facing the inflow pipe 130 and spaced apart from the inflow pipe 130,
The inlet pipe 130 includes an inner pipe 131 and an outer pipe 132 for receiving the inner pipe 131,
The inner tube 131 and the outer tube 132 are closed at both ends,
And an air pipe 133 connected to the outer pipe 132 and connected between the inner pipe 131 and the outer pipe 132 and passing through the outer chamber 110,
The blades 143 are disposed around the end 137 of the inlet tube 130,
And an air hole (134) formed in the end portion (137) and passing through between the outer tube (132) and the inner tube (131).
The method according to claim 1,
The inner tube 131 is fixed through the inner chamber 120,
The outer tube 132 receives the inner tube 131 and is fixed to the inner chamber 120,
And a ring-shaped cover plate 135 attached to an end of the outer tube 132 and the inner tube 131 opposite to the blade 143 to close the outer tube 132 and the inner tube 131 and,
Wherein the air hole (134) is formed through the cover plate (135).
The method according to claim 1,
The inner chamber 120 is fixed to the inner upper surface of the outer chamber 110,
And a cyclone pipe (170) disposed below the inner chamber (120) and connected to the outer chamber (110) so as to wind around the outer periphery of the outer chamber (110)
The cyclone pipe 170 has a supply port 173 opened at an outer end 171 of the cyclone pipe 170. The inner end of the cyclone pipe 170 contacting the outer chamber 110 is opened to be connected to the outer chamber 110, And is formed so as to become narrower along the periphery of the outer chamber (110).
3. The method of claim 2,
The cover plate 135 includes a hermetic protrusion 135a protruding and extending along a circumference on one side of the opposite side facing the blade 143 and a hermetic protrusion 135a formed on the blade 143, And a hermetic groove portion 143a spaced apart from the hermetic seal portion 135a by a predetermined distance so as not to interfere with the rotation of the blade 143 and configured to correspond to the hermetic protrusion 135a so as to receive the hermetic protrusion 135a. A classifier consisting of a filtration fan.
5. The method of claim 4,
The airtight protrusion 135a is formed with a plurality of protrusion grooves 135b spaced along the circumference on the outer circumferential surface and the inner circumferential surface of the airtight protrusion 135a and a first airtight member 135c are laminated,
The airtight groove 143a is formed by extending a plurality of spaced apart blade grooves 143b on the upper or lower side thereof and a second airtight member 143c is laminated on the blade groove 143b A classifier consisting of a filtration fan. delete

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