JP2001009376A - Classifying apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a classifying apparatus capable of holding stable classifying accuracy regardless of the quality (moist degree) in spite of a low cost. SOLUTION: The raw material supplied to a second raw material supply pipe 201 is separated into a coarse powder 51a and a fine powder 51b before dispersed by a dispersing plate 203 and, therefore, the classifying accuracy of a classifying apparatus can be enhanced. Since the raw material 51 supplied through the second raw material supply pipe 201 is dried, the coarse and fine powders 51a, 51b bonded to each other can be made easy to separate and it can be prevented that the once separated coarse and fine powders 51a, 51b again adhere to each other. That is, stable classifying accuracy can be held regardless of the quality (moist degree) of the raw material 51.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a classification device,
The present invention relates to a classifier capable of maintaining stable classification accuracy irrespective of the quality (degree of wetness) of a raw material despite being inexpensive.

[0002]

2. Description of the Related Art A classifier classifies raw materials into coarse powder and fine powder. The classifier generally includes a classifying chamber for classifying raw materials into coarse powder and fine powder, A dispersion plate rotatably arranged in the classification chamber and a raw material supply pipe for supplying a raw material to the dispersion plate are provided. According to this classification device, when the raw material is supplied to the dispersion plate via the raw material supply pipe,
The raw material is dispersed in the classification chamber by the dispersion plate, and the raw material is classified into coarse powder and fine powder in the classification chamber.

[0003] Some classifiers have been devised in various ways in order to increase the classification accuracy. Specifically, a classifier in which the shape of the dispersion plate is changed, a classifier in which an annular ring member is provided in a classifying chamber, and the like have been invented.

[0004]

However, a classifier in which the shape of the dispersion plate is changed or a classifier in which an annular ring member is provided in the classifying chamber does not consider the degree of wetness of the raw material. Was. That is, there is a problem that the classification accuracy is lowered when the raw material is humid.

Further, when the shape of the dispersion plate is changed or an annular ring member is provided in the classifying chamber, the structure of the classifying device becomes complicated and the manufacturing cost of the classifying device increases.

Accordingly, the present invention was devised,
It is an object of the present invention to provide a classifier capable of maintaining stable classification accuracy irrespective of the quality (degree of wetness) of a raw material, despite being inexpensive.

[0007]

In order to achieve this object, a classifying apparatus according to the first aspect of the present invention includes a classifying chamber for classifying raw materials into coarse powder and fine powder, and a rotatably disposed classifying chamber. Provided with a dispersing plate provided, and a raw material supply pipe for supplying a raw material to the dispersing plate, and further provided with a compressed air injection port for injecting compressed air to the raw material supplied via the raw material supply pipe. Is what it is.

According to the first aspect of the present invention, the raw material classified into the coarse powder and the fine powder in the classification chamber is supplied to the dispersion plate by the raw material supply pipe, and is supplied to the classification room by the dispersion plate. Distributed. Raw materials dispersed in this classification chamber,
That is, even when the coarse powder and the fine powder constituting the raw material supplied through the raw material supply pipe adhere to each other (even when they are stuck together), the compressed air injected through the compressed air injection port Before the raw material is dispersed in the classification chamber by the dispersing plate, the coarse powder and the fine powder adhering to each other are separated by the wind pressure. The temperature of the compressed air is higher than that of the uncompressed air. For this reason, even when the raw material supplied through the raw material supply pipe is wet, the raw material is dehumidified.

According to a second aspect of the present invention, there is provided the classifying apparatus according to the first aspect, further comprising a dehumidifying device for dehumidifying the compressed air injected through the compressed air injection port.

According to a third aspect of the present invention, in the classifying apparatus according to the first or second aspect, the fine powder classified in the classification chamber is sucked together with the gas through the suction port and the suction port. A plurality of filter members for separating fine powder from gas, an injection device for injecting gas into the filter member in a direction opposite to a suction direction of fine powder separated by the filter member, and a gas And a switching device for switching the filter member from which is sprayed from one filter member to another filter member at predetermined time intervals.

According to the classification device of the third aspect, the operation is the same as that of the classification device of the first or second aspect.
The fine powder classified in the classification chamber is sucked together with the gas through the suction port, and the fine powder is separated from the sucked gas by the plurality of filter members. The separated fine powder adheres to each of the plurality of filter members. However, if the fine powder continues to adhere to the filter members, the power of sucking the fine powder classified in the classification chamber decreases. However, the fine powder attached to the filter member is removed by the injection of the gas by the injection device, and the filter device from which the gas is injected by the injection device is separated from the one filter member every predetermined time by the switching device. Switch to filter member.

According to a fourth aspect of the present invention, there is provided a classification device comprising a classification chamber for classifying raw materials into coarse powder and fine powder, and a suction port for sucking the fine powder classified in the classification chamber together with gas. And a plurality of filter members for separating fine powder from gas sucked through the suction port, and a direction opposite to a suction direction of fine powder separated by the filter member with respect to the filter members. And a switching device for switching a filter member from which gas is injected by the injector from one filter member to another filter member at predetermined time intervals.

According to the classification device of the fourth aspect, the fine powder classified in the classification chamber is sucked together with the gas through the suction port, and the fine powder is separated from the sucked gas by the plurality of filter members. Separated. The separated fine powder adheres to each of the plurality of filter members. However, if the fine powder continues to adhere to the filter members, the power of sucking the fine powder classified in the classification chamber decreases. However, the fine powder attached to the filter member is removed by the injection of the gas by the injection device, and the filter device from which the gas is injected by the injection device is separated from the one filter member every predetermined time by the switching device. Switch to filter member.

According to a fifth aspect of the present invention, there is provided a classifying apparatus according to any one of the first to fourth aspects, wherein the fine powder removed from the filter member by gas injection by the injection device is collected. And an attachment opening for attaching a bag-shaped bag member for putting the fine powder collected in the fine powder collecting groove,
A screw-shaped screw member rotatably disposed in the fine-powder collecting groove for pushing fine powder into the bag-shaped bag member attached to the attachment opening. .

According to the classification device of the fifth aspect, the operation is the same as that of the classification device of any one of the first to fourth aspects, and the fine powder removed from the filter member is collected in the fine powder collecting groove. Then, the fine powder collected in the fine powder collecting groove is pushed into the bag member attached to the attachment opening by the screw member. When the structure is such that the bag member is attached to the attachment port, the cost can be reduced. On the other hand, due to the negative pressure applied in the vicinity of the attachment port, the fine powder collected in the fine powder collecting groove hardly enters the bag member. , Accumulate in the fine powder collecting groove. However, as described above, the fine powder collected in the fine powder collecting groove is pushed into the bag member by the screw member, so that the fine powder accumulates in the fine powder collecting groove despite the low cost. Is prevented.

According to a sixth aspect of the present invention, there is provided a classification apparatus comprising a classification chamber for classifying raw materials into coarse powder and fine powder, and a collecting groove for collecting the fine powder classified in the classification chamber. An attachment opening for attaching a bag-shaped bag member for putting the fine powder collected in the collection groove, and the above-mentioned in order to push the fine powder into the bag-shaped bag member attached to the attachment opening. And a screw-shaped screw member rotatably disposed in the collection groove.

According to the classification device of the present invention, the fine powder classified in the classification chamber is collected in the collecting groove, and the fine powder collected in the collecting groove is attached to the mounting opening by the screw member. Is pushed into the bag member. When the structure is such that the bag member is attached to the attachment port, the cost can be reduced. On the other hand, due to the negative pressure applied in the vicinity of the attachment port, the fine powder collected in the fine powder collecting groove hardly enters the bag member. , Accumulate in the fine powder collecting groove. However, as described above, the fine powder collected in the fine powder collecting groove is pushed into the bag member by the screw member, so that the fine powder accumulates in the fine powder collecting groove despite the low cost. Is prevented.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 1 is an elevation view (side view) of a classification device 1 according to one embodiment of the present invention.

As shown in FIG. 1, the classification device 1 includes a classification unit 2 and a dust collection unit 3. Classification part 2
This is a part for classifying the raw material 51 (see FIG. 5) into a coarse powder 51a (see FIG. 5) and a fine powder 51b (see FIG. 5), and a raw material hopper 21, a raw material delivery device 22, a raw material supply pipe 23,
A classification chamber 24, an intake port 25, an intake pipe 26, a first motor 27, a coarse powder discharge port 28, a compressed air supply pipe 29,
It has a compressor and a dehumidifier. The raw material hopper 21 is for storing the raw material 51 supplied into the classification chamber 24, is made of an iron material, and has a bottom 21a inclined downward. The raw material delivery device 22 includes the raw material hopper 2
The raw material 51 in 1 is sent to the raw material supply pipe 23, and the raw material supply pipe 23 is a pipe for supplying the raw material 51 sent out by the raw material sending device 22 into the classification chamber 24.

The classifying chamber 24 is for classifying the raw material 51 supplied through the raw material supply pipe 23 into coarse powder 51a and fine powder 51b, and the intake port 25 is classified in the classification chamber 24. The fine powder 51b is sucked together with air.
The intake pipe 26 is a pipe for transporting air (including fine powder 51b) sucked through the intake port 25 to the dust collection unit 3, and the first motor 27 is connected to a dispersion plate 203 (see FIG. See) to rotate. The coarse powder outlet 28 is
The compressor (not shown) is a device for compressing air, and the dehumidifier (not shown) is a device for discharging compressed powder generated by the compressor. Is a device for drying and removing moisture from the compressed air. Compressed air supply pipe 29
Is a pipe for supplying the compressed air dehumidified by the dehumidifier into the classification chamber 24.

The dust collecting section 3 is composed of the fine powder 5 classified by the classifying section 2.
1b, a portion for collecting dust, a dust collecting chamber 31, a second motor 32, an exhaust pipe 33, an inclined surface 34, and a fine powder collecting groove 3.
5, an attachment port 36, an air tank 38, a second compressed air supply pipe 39, and an air tank attachment stay 40. The dust collection chamber 31 is a container (housing) for taking out the fine powder 51b from the air sucked through the intake pipe 26.
The second motor 32 generates a force (hereinafter, simply referred to as “suction force”) for sucking the fine powder 51b together with air (hereinafter, referred to as “suction force”). See). The exhaust pipe 33 is a pipe for exhausting air sucked together with the fine powder 51b through the intake pipe 26, and exhausts only air without discharging the fine powder 51b classified in the classification chamber 24. I do.

The runner 305 does not need to rotate at a constant speed, and the rotation speed may be changeable. With this configuration, the classifying point of the raw material can be set to an appropriate value by changing the suction force.

The inclined surface portion 34 is for guiding the fine powder 51b separated in the dust collecting chamber 31 to the fine powder collecting port 35.
It is inclined downward toward the fine powder collecting groove 35. The fine powder collecting groove 35 is for collecting the fine powder 51b separated in the dust collecting chamber 31, and the attachment port 36 is provided with the fine powder collecting groove 35.
For attaching a bag-like bag member 50 for storing the fine powder 51b collected in the bag. The fine powder 51b collected in the fine powder collecting groove 35 is attached to the bag member 50 attached to the opening 36.
Collected within. The air tank 38 is for removing the fine powder 51b from a filter 302 described later, and the second compressed air supply pipe 39 is a pipe for supplying compressed air to the air tank 38. The second compressor (not shown) is a device for compressing air, and the second dehumidifier (not shown) dries the compressed air generated by the second compressor to remove moisture from the compressed air. Device. The compressed air supplied through the second compressed air supply pipe 39 is air dehumidified by the second dehumidifier.

FIG. 2 is a sectional view of the classifying section 2. As shown in FIG. 2, the classification unit 2 further includes a second raw material supply pipe 201.
, A transmission shaft 202, a distribution plate 203, and a compressed air injection port 204. The second raw material supply pipe 201 transfers the raw material 51 supplied through the raw material supply pipe 23 to the dispersion plate 203.
And is formed in a substantially cylindrical shape. The transmission shaft 202 transmits the rotation of the first motor 27 to the dispersion plate 2.
03, and is formed in a substantially rod shape.
The dispersion plate 203 is for dispersing the raw material 51 supplied through the raw material supply pipe 23 and the second raw material supply pipe 204 into the classification chamber 24, and is formed in a substantially disk shape.

The compressed air injection port 204 is for injecting compressed air to the raw material 51 supplied through the second raw material supply pipe 201, and is provided at a substantially central portion of the second raw material supply pipe 201. I have. The raw material 51 supplied through the second raw material supply pipe 201 is composed of a coarse powder 51a and a fine powder 51b, and usually contains moisture, so that the coarse powder 51a and the fine powder 51b Adhered to (attached to) each other. For this reason, when the degree of wetness of the raw material 51 is high, the coarse powder 51a and the fine powder 51b can be simply obtained by colliding the raw material 51 with the dispersion plate 203 and dispersing the raw material 51 into the classification chamber 24 by rotating the dispersion plate 203. Were dropped in the classifying chamber 24 without being separated and attached to each other, and were discharged from the coarse powder discharge port 28. That is, there is a problem that the classification accuracy varies depending on the degree of wetness of the raw material 51.

However, as described above, in the present classifier 1, compressed air injection is performed on the raw material 51 supplied through the second raw material supply pipe 201, that is, the raw material 51 before being dispersed by the dispersion plate 203. Compressed air is injected through port 204. Therefore, by the wind pressure of the compressed air,
The coarse powder 51a and the fine powder 51b adhered to each other can be separated. Also, since the temperature of the compressed air is higher than the temperature of the uncompressed air, the raw material supply pipe 2
The raw material 51 supplied through the third and second raw material supply pipes 201 is dried, so that the coarse powder 51a and the fine powder 51b can be easily separated, and the coarse powder 51a once separated
And the fine powder 51b can be prevented from adhering (adhering) again. Furthermore, as described above, since the compressed air is simply injected into the raw material 51,
In order to be able to maintain stable classification accuracy regardless of the quality of the raw material 51, the present classification device 1
It is possible to suppress an increase in the manufacturing cost of the device.

Since the compressed air supplied through the compressed air injection port 204 has been dehumidified by the dehumidifier,
Due to the moisture contained in the compressed air, coarse powder 51a and fine powder 5
It is possible to prevent the separation from 1b from being hindered.

It should be noted that the compressed air injection port 204 is not necessarily provided at a substantially central portion of the second raw material supply pipe 201, and the compressed air injection port 204 and the second raw material supply pipe
What is necessary is just to be provided in any place in the raw material supply pipe 201. Further, the compressed air injection port 204 may be provided between the raw material supply pipe 201 and the dispersion plate 203. Further, the compressed air injection port 204 need not be provided at one place, but may be provided at a plurality of places.

Next, the configuration of the dust collecting section 3 will be described in detail with reference to FIG. FIG. 3 is a cross-sectional view of the dust collection unit 3. As shown in FIG. 3, the dust collecting unit 3 further includes a filter 302, a filter stay 303, and an air passage 3
04, the runner 305, the second transmission shaft 306, and the second
An air passage 307, a cyclone 308, a screw 309, and an internal pipe 311 are provided.

The filter 302 separates the fine powder 51b from the air sucked through the intake pipe 26, is disposed in the dust collection chamber 31, is made of paper, and has a substantially star-shaped cross section. Are formed in a columnar shape. Since the cross section of the filter 302 is formed in a substantially star shape, the surface area can be increased, and even if some fine powder 51b adheres to the surface of the filter 302, the suction force is prevented from being reduced. You can do it.

The filter stay 303 includes a filter 3
02, and is for partitioning the inside of the dust collection chamber 31 into an upper space 301a and a lower space 301b, and is formed in a substantially plate shape. The air passage port 304 is a hole formed in the filter stay 303,
For discharging the air sucked through the upper space 301a.

The runner 305 rotates,
This is for generating a suction force. This runner 30
The fine powder 51b classified in the classification chamber 24 is sucked together with the air by the suction force accompanying the rotation of No. 5. The second transmission shaft 306 controls the rotation of the second motor 32 to the runner 305.
, And is formed in a rod shape having a substantially circular cross section.

The second air passage 307 is connected to the runner 305
The air sucked through the filter 302 by the suction force accompanying the rotation of
To discharge to

The cyclone 308 is for separating the fine powder 51b from the air sucked through the intake pipe 26, and is formed in a substantially cylindrical shape whose upper part is closed and whose lower part is opened. , In the lower space 301b of the dust collection chamber 31. Since the air sucked through the suction pipe 26 turns in the cyclone 308, the fine powder 51b contained in the air sucked through the suction pipe 26 falls due to gravity, and the fine powder collection port 35 Will be collected. Therefore, the amount of the fine powder 51b adhering to the filter 302 is reduced, and it is possible to prevent the suction force from dropping. Further, since the cyclone 308 is provided in the dust collection chamber 31, the classifier 1 can be space-saving.

The screw 309 is rotatably disposed in the fine powder collecting groove 35, and the fine powder 51 b collected in the fine powder collecting groove 35 has the bag member 5 attached to the opening 36.
It is for pushing into 0. The inside of the dust collection chamber 31
A negative pressure is generated by the suction force accompanying the rotation of the runner 305. Therefore, if the bag member 50 is simply attached to the attachment port 36, the fine powder 51 collected in the fine
b hardly enters the bag member 50 and accumulates in the fine powder collecting groove 35. However, the fine powder 51b collected in the fine powder collecting groove 35 by the screw 309 is
Since it is pushed into 0, it is possible to prevent the fine powder 51b from accumulating in the fine powder collecting groove 35 despite the low cost.

The second compressed air injection port 310 is for injecting compressed air to the filter 302, and the internal arrangement pipe 311 is configured to supply the compressed air stored in the air tank 38 to the second compressed air injection port 310. This is a pipe for supplying to The plurality of (in this embodiment, four) second compressed air injection ports 310 are provided in the internal arrangement pipe 311.

The solenoid valve 312 is opened and closed to
This is for switching whether or not the compressed air stored in the air tank 38 is supplied via the internal pipe 311. Specifically, by opening the solenoid valve 312,
The supply of the compressed air stored in the air tank 38 is stopped by closing the solenoid valve 312 while supplying the compressed air stored in the air tank 38 through the internal pipe 311. is there.

FIG. 4 is a sectional view taken along line IV-IV in FIG. As shown in FIG. 4, the air tank 38 includes:
A plurality (four in the present embodiment) of internal installation pipes 31
1 is attached, and the solenoid valve 312 is connected to each of the internal pipes 3.
11 are provided. This solenoid valve 312
The solenoid valve 312 is opened for a predetermined time (for example, 0.1 to 0.2 s (seconds)), and the solenoid valves 312 are opened in order from the solenoid valve 312 disposed at the top of FIG. The time from when the opening of one solenoid valve 312 ends to when the next solenoid valve opens is set to a predetermined time (for example, 20 to 30 s). Then, when the opening of the lowermost electromagnetic valve 312 is completed, the uppermost electromagnetic valve 312 is opened again. That is, the filter 302 from which the compressed air is injected from the second compressed air injection port 310 is switched from one filter 302 to another filter 302 every predetermined time. Therefore, even when the filter 302 is used to increase the efficiency of separating the fine powder 51b classified in the classification chamber 24 from the air, the fine powder 51b classified in the classification chamber 24 is also used.
The suction force (suction force) can be kept constant. That is, the classification accuracy of the classification device 1 can be kept constant. Note that the order in which the solenoid valves 312 are opened is not necessarily the order in which the top solenoid valve 31 in FIG.
It is not necessary to open sequentially from 2, and it is only necessary that the electromagnetic valves 312 disposed at four locations be opened evenly.

Next, the operation of the classifier 1 configured as described above will be described with reference to FIGS. FIG. 5 is a diagram illustrating a state in which compressed air is injected into the raw material 51 charged into the classification device 1, and FIG. 6 illustrates a state in which the fine powder 51 b is sucked into the dust collection chamber 31. FIG.

When the raw material 51 is put into the raw material hopper 21, the raw material 51 put into the raw material hopper 21 is sent out to the raw material supply pipe 23 by the raw material delivery device 22 at predetermined intervals. Raw material 51 sent out to raw material supply pipe 23
Is further connected to the second raw material supply pipe 2 through the raw material supply pipe 23.
01. The raw material 51 supplied to the second raw material supply pipe 201 falls in the second raw material supply pipe 201, but the raw material 51 is supplied to the second raw material supply pipe 201 by the wind pressure of the compressed air injected through the compressed air injection port 204. The raw material 51 is separated into the coarse powder 51a and the fine powder 51b by colliding with the side wall 201a or colliding with the plurality of raw materials 51. Also, the temperature of the compressed air is higher than that of the uncompressed (uncompressed) air. For this reason, even when the raw material 51 supplied through the second raw material supply pipe 201 is wet,
The raw material 51 is dried.

As described above, the raw material 51 supplied to the second raw material supply pipe 201 is separated into coarse powder 51a and fine powder 51b before being dispersed by the dispersion plate 203. Therefore,
The classification accuracy of the classification device 1 can be improved. Also, since the raw material 51 supplied through the second raw material supply pipe 201 is dried, the coarse powder 51 adhered to each other is dried.
a and the fine powder 51b can be easily separated, and the once separated coarse powder 51 and the fine powder 51b can be prevented from adhering (adhering) again. That is, regardless of the quality (degree of wetness) of the raw material 51, stable classification accuracy can be maintained.

The raw material 51 separated into the coarse powder 51a and the fine powder 51b by the compressed air injected from the compressed air injection port 204 falls down the second raw material supply pipe 201 by gravity and collides with the dispersion plate 203. You. The dispersing plate 203 includes a first
The dispersion plate 203 is rotated by the motor 27.
The raw material 51 that has collided with the
Distributed within. In the classifying chamber 24, an updraft is generated by rotation of a runner 305 provided in the dust collecting section 3. For this reason, among the raw materials 51 dispersed in the classification chamber 24 by the dispersion plate 203, the fine powder 51b having a small mass is conveyed upward in the classification chamber 24 by an ascending airflow, and the coarse powder 51a having a large mass is removed. It is dropped down in the classification chamber 24 by gravity.

Fine powder 51 conveyed upward in the classification chamber 24
a is sucked together with air through the air inlet 25.
The fine powder 51a sucked through the air inlet 25 is
6 and is conveyed into the dust collection chamber 31. On the other hand, classification room 2
The coarse powder 51 a that has been dropped downward in the inside 4 is discharged out of the classification chamber 24 through the coarse powder outlet 28.

The fine powder 51 b transported together with the air into the dust collecting chamber 31 is swirled in the cyclone 308. At this time, the speed of the air conveyed into the dust collection chamber 31 decreases, and a part of the fine powder 51b contained in the air is dropped by gravity and collected in the fine powder collecting port 35.
Accordingly, the amount of the fine powder 51b attached to the filter 302 is reduced, and the suction force (the fine powder 51 classified in the classification chamber 24) is reduced.
(a force for sucking b together with air) can be prevented from dropping.

The air that has passed through the cyclone 308 is sucked above the dust collecting chamber 31 and further sucked through the filter 302. Fine powder 51b contained in the air is attached to the surface of the filter 302. Since the cross section of the filter 302 is formed in a substantially star shape,
Since the surface area is increased, even if some fine powder 51b adheres to the surface of the filter 302, it is possible to prevent the suction force from dropping.

FIG. 7 is a sectional view taken along line VII-VII of FIG. First, the leftmost solenoid valve 312 in FIG.
Is released for a predetermined time. When the leftmost electromagnetic valve 312 is opened for a predetermined time, the compressed air stored in the air tank 38 is injected into the leftmost filter 302 via the internal pipe 311. Filter 302 in the leftmost column
When the compressed air is injected into the filter 302, the fine powder 51b attached to the
Is removed.

When the leftmost solenoid valve 312 is opened for a predetermined time, next, the solenoid valve 312 on the right (that is, the second from the left) is opened for a predetermined time. At this time, as soon as the leftmost solenoid valve 312 is closed, the rightmost solenoid valve 312 is opened. When the second electromagnetic valve 312 from the left is opened, the fine powder 51b attached to the filter 302 in the second column from the left is removed, as in the case where the leftmost electromagnetic valve 312 is opened. Hereinafter, similarly, the third electromagnetic valve from the left and the fourth electromagnetic valve 312 from the left are sequentially opened. When the fourth solenoid valve 312 from the left is closed, the leftmost solenoid valve 312 is opened again.

As described above, by injecting compressed air into the filter 302, the fine powder 5 adhering to the filter
1b is removed, but the filter 302 from which the compressed air is injected is switched at predetermined intervals. Therefore, in order to increase the efficiency of separating the fine powder 51b classified in the classification chamber 24 from air, the filter 302 is used.
Is used, the fine powder 51 classified in the classification chamber 24 is also used.
The force for sucking b (suction force) can be kept constant. That is, the classification accuracy of the classification device 1 can be kept constant.

FIG. 8 is an enlarged view of the vicinity of the screw 309. The fine powder 51b dropped from the air passing through the cyclone 308 and the fine powder 51b removed from the filter 302 fall along the inclined surface portion 34 or directly without passing through the inclined surface portion 34, It is collected in the fine powder collecting groove 35. The fine powder 51b collected in the fine powder collecting port 35 is rotated by the rotation of the screw 309.
It is collected at the attachment port 36 and further pushed into the bag member 50 attached to the attachment port 36. When the fine powder 51b is pushed into the bag member 50, the classification of the raw material 51 ends.

As described above, by rotating the screw 309, the fine powder 51b collected in the fine powder collecting groove 35 is removed.
Is pushed into the bag member 50, so that the fine powder 51b can be pushed into the bag member 50 at low cost even if the inside of the dust collection chamber 31 is at a negative pressure.
5 can be prevented from accumulating the fine powder 51b.

As described above, the present invention has been described based on the embodiments. However, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the gist of the present invention. Can be easily inferred.

For example, in the present embodiment, the classification device 1
A classification unit (a part (device) for classifying the raw material 51) 2 and a dust collecting unit (a part (device) for collecting the classified fine powder 51b) 3 are configured separately. However, the classification unit 2 and the dust collection unit 3 do not necessarily need to be configured separately,
You may make it comprise integrally.

[0053]

According to the classification device of the first aspect, before the raw material is dispersed into the classification chamber by the dispersing plate by the compressed air injected through the compressed air injection port, the raw material constituting the raw material is formed. The flour and fines are separated. Therefore, there is an effect that the classification accuracy of the present classification device can be improved. Further, even when the raw material supplied through the raw material supply pipe is wet, the raw material is dried by simply injecting compressed air into the raw material, and the coarse powder and the fine powder adhering to each other are removed. Are easily separated. That is, there is an effect that stable classification accuracy can be maintained irrespective of the quality (degree of wetness) of the raw material. Further, as described above, the present classification apparatus merely injects compressed air to the raw material, so that the classification apparatus can maintain stable classification accuracy regardless of the quality of the raw material. There is an effect that an increase in the manufacturing cost of the classification device can be suppressed to a low level.

According to the classifier of the second aspect, in addition to the effect of the classifier of the first aspect, the dehumidifier dehumidifies the compressed air injected through the compressed air injection port. Therefore, due to the moisture contained in the compressed air,
There is an effect that it is possible to prevent the separation of the coarse powder and the fine powder from being hindered.

According to the classification device of the third aspect, in addition to the effects of the classification device of the first or second aspect, further, fine powder adhered to the plurality of filter members by gas injection by the injection device. Is removed, and the switching device switches the filter member from which gas is injected by the injection device from one filter member to another at predetermined time intervals, so that the fine powder classified in the classification chamber is separated from air. Also in the case where a filter member is used to increase the efficiency of the operation, there is an effect that the force for sucking the fine powder classified in the classification chamber can be kept constant. That is, there is an effect that the classification accuracy of the classification device can be kept constant.

According to the classification device of the fourth aspect, the fine powder attached to each of the plurality of filter members is removed by the injection of the gas by the injection device, and the filter is used by the switching device to inject the gas by the injection device. Since the member can be switched from one filter member to another at predetermined time intervals, even when the filter member is used to increase the efficiency of separating the fine powder classified in the classification chamber from air, the classification is performed in the classification chamber. There is an effect that the force for sucking the fine powder can be kept constant. That is, there is an effect that the classification accuracy of the classification device can be kept constant.

According to the classification device of the fifth aspect, in addition to the effect of the classification device of any one of the first to fourth aspects, the fine powder collected in the fine powder collecting groove by the screw member is further reduced. Since it is pushed into the bag member attached to the attachment opening, it is possible to prevent the accumulation of the fine powder in the fine powder collecting groove despite the low cost.

According to the classification device of the sixth aspect, the fine powder collected in the collecting groove is pushed into the bag member attached to the attachment opening by the screw member, so that the cost is low. In addition, there is an effect that accumulation of fine powder in the collecting groove can be prevented.

[Brief description of the drawings]

FIG. 1 is a side view of a classification device according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of a classifying unit constituting the classifying apparatus.

FIG. 3 is a cross-sectional view of a dust collecting unit constituting the classification device.

FIG. 4 is a sectional view taken along line IV-IV in FIG.

FIG. 5 is a diagram showing a state where compressed air is injected into a raw material charged into a classification device.

FIG. 6 is a diagram showing a state in which fine powder is sucked into the dust collection chamber.

FIG. 7 is a sectional view taken along line VII-VII in FIG.

FIG. 8 is an enlarged view near the screw.

[Explanation of symbols]

 1 Classifier 24 Classifier 25 Inlet (suction port) 35 Fine powder collecting groove 36 Attachment port 38 Air tank (part of injection device) 39 Second compressed air supply pipe (part of injection device) 201 Second raw material Supply pipe (raw material supply pipe) 203 Dispersion plate 204 Compressed air injection port 302 Filter (filter member) 309 Screw (screw member) 310 Second compressed air injection port (part of injection apparatus) 311 Internally installed pipe (of injection apparatus) 312) Solenoid valve (switching device)

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[Procedure amendment]

[Date of submission] October 16, 2000 (2000.10.
16)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of the Invention] Classifier

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

TECHNICAL FIELD The present invention relates to a classification device,
The present invention relates to a classifier capable of maintaining stable classification accuracy irrespective of the quality (degree of wetness) of a raw material despite being inexpensive.

[0002]

2. Description of the Related Art A classifier classifies raw materials into coarse powder and fine powder. The classifier generally includes a classifying chamber for classifying raw materials into coarse powder and fine powder, and a classifying chamber for classifying the raw material into coarse powder and fine powder. A dispersion plate rotatably arranged in the classification chamber and a raw material supply pipe for supplying a raw material to the dispersion plate are provided. According to this classification device, when the raw material is supplied to the dispersion plate via the raw material supply pipe,
The raw material is dispersed in the classification chamber by the dispersion plate, and the raw material is classified into coarse powder and fine powder in the classification chamber.

[0003] Some classifiers have been devised in various ways in order to increase the classification accuracy. Specifically, a classifier in which the shape of the dispersion plate is changed, a classifier in which an annular ring member is provided in a classifying chamber, and the like have been invented.

[0004]

However, a classifier in which the shape of the dispersion plate is changed or a classifier in which an annular ring member is provided in the classifying chamber does not consider the degree of wetness of the raw material. Was. That is, there is a problem that the classification accuracy is lowered when the raw material is humid.

Further, when the shape of the dispersion plate is changed or an annular ring member is provided in the classifying chamber, the structure of the classifying device becomes complicated and the manufacturing cost of the classifying device increases.

Accordingly, the present invention was devised,
It is an object of the present invention to provide a classifier capable of maintaining stable classification accuracy irrespective of the quality (degree of wetness) of a raw material, despite being inexpensive.

[0007]

In order to achieve this object, a classifying apparatus according to the first aspect of the present invention includes a classifying chamber for classifying raw materials into coarse powder and fine powder, and a rotatably disposed classifying chamber. a set variance plate, and a raw material supply pipe for supplying the raw material to the distribution plate, further, the raw material supplying tube, or the original
A compressed air injection port provided between the material supply pipe and the dispersion plate and configured to inject compressed air to the raw material supplied through the raw material supply pipe.

According to the first aspect of the present invention, the raw material classified into the coarse powder and the fine powder in the classification chamber is supplied to the dispersion plate by the raw material supply pipe, and is supplied to the classification room by the dispersion plate. Distributed. Raw materials dispersed in this classification chamber,
That is, even when the coarse powder and the fine powder constituting the raw material supplied through the raw material supply pipe adhere to each other (even when they are stuck together), the compressed air injected through the compressed air injection port Before the raw material is dispersed in the classification chamber by the dispersing plate, the coarse powder and the fine powder adhering to each other are separated by the wind pressure. The temperature of the compressed air is higher than that of the uncompressed air. For this reason, even when the raw material supplied through the raw material supply pipe is wet, the raw material is dehumidified.

According to a second aspect of the present invention, there is provided the classifying apparatus according to the first aspect, further comprising a dehumidifying device for dehumidifying the compressed air injected through the compressed air injection port.

According to a third aspect of the present invention, in the classifying apparatus according to the first or second aspect, the fine powder classified in the classification chamber is sucked together with the gas through the suction port and the suction port. A plurality of filter members for separating fine powder from gas, an injection device for injecting gas into the filter member in a direction opposite to a suction direction of fine powder separated by the filter member, and a gas And a switching device for switching the filter member from which the liquid is injected from one filter member to another filter member at predetermined time intervals.

According to the classification device of the third aspect, the operation is the same as that of the classification device of the first or second aspect.
The fine powder classified in the classification chamber is sucked together with the gas through the suction port, and the fine powder is separated from the sucked gas by the plurality of filter members. The separated fine powder adheres to each of the plurality of filter members. However, if the fine powder continues to adhere to the filter members, the power of sucking the fine powder classified in the classification chamber decreases. However, the fine powder attached to the filter member is removed by the injection of the gas by the injection device, and the filter device from which the gas is injected by the injection device is separated from one filter member by the switching device every other predetermined time. Switch to filter member.

According to a fourth aspect of the present invention, there is provided a classification device.
In the classifier of
The fines removed from the filter
Put the collected powder in the powder collecting groove and the fine powder collecting groove
An attachment opening for attaching a bag-shaped bag member, and an attachment
The fine powder to push the fine powder into the bag-shaped bag member.
A screw-like screw rotatably arranged in the collection groove
Queue member.

[0013] According to the classification device of the fourth aspect , the contractor
The same function as the classification device according to claim 3, and a filter
The fine powder removed from the components is collected in the fine
The fines collected in the fine powder collecting groove by the screw member
The powder is pushed into the bag member attached to the attachment opening. Attachment
Low cost if the bag is attached to the mouth
On the other hand, the negative pressure applied near the
The fine powder collected in the collecting groove is difficult to enter into the bag member.
It accumulates in the collecting channel. However, as mentioned above
The fine powder collected in the fine powder collecting groove
The bag is pushed into the bag member at low cost.
Fine powder accumulates in the fine powder collecting groove
Is prevented.

According to a fifth aspect of the present invention, there is provided a classification device, wherein a raw material is converted into a coarse powder.
Classification room for classifying into fine powder and classification in the classification room
And a suction port for sucking the fine powder together with the gas.
In the gas sucked through the suction port.
And a dust collection chamber for removing fine powder from
Cyclone installed and closed at the top and open at the bottom
A member and the cyclone sucked through the suction port and
Multiple filters to separate fine powder from gas passing through
Filter member and its filter member
-Is the direction opposite to the suction direction of the fine powder separated by the member?
Device that injects gas from the
The filter member from which the
Switching equipment that switches from one filter unit to another at predetermined time intervals
And a device.

According to the classification device of the fifth aspect, the suction device
Fine powder classified in the classification chamber through the inlet with gas
Is aspirated, and the aspirated
Fines are separated from the trapped gas. The separated fine powder
It adheres to each of multiple filter members,
If fine powder continues to adhere to the filter member,
The power for sucking the fine powder is reduced. However
Injection of gas by the injection device
-Fine powder adhering to the member is removed and
And a filter section from which gas is injected by the injection device.
Material is removed from one filter element every other
Switch to the monitor member.

On the other hand, separation by such a filter member
Gas is sucked through the suction port and cyclone
This is the gas that has passed through the member. This cyclone member is above
Is closed and the lower part is open, so through the suction port
Fine powder contained in the sucked gas falls due to gravity
You. Therefore, the amount of fine powder adhering to the filter member is low.
Thus, the suction force is prevented from being reduced. Further
Because the cyclone is located in the dust collection chamber,
Class device is space saving.

According to a sixth aspect of the present invention, there is provided a classification device comprising a classification chamber for classifying raw materials into coarse powder and fine powder, and a collecting groove for collecting fine powder classified in the classification chamber. An attachment opening for attaching a bag-shaped bag member for putting the fine powder collected in the collection groove, and the above-mentioned in order to push the fine powder into the bag-shaped bag member attached to the attachment opening. And a screw-shaped screw member rotatably disposed in the collection groove.

According to the classification device of the sixth aspect, the classification
After the fine powder classified in the classroom is collected in the collection channel,
As the crown member rotates, it is collected at the collection port.
Fine powder is collected at the opening, and further attached to this opening.
Into the bag member.

According to a seventh aspect of the present invention, the classification device comprises the steps of:
Classification room for classifying into fine powder and classification in the classification room
And a suction port for sucking the fine powder together with the gas.
From the gas sucked through the suction port.
Multiple filter members to be separated and the filter members
Against the fine powder separated by the filter member.
An injection device that injects gas from the direction opposite to the pulling direction,
The filter member from which gas is injected by the injection device of
Predetermined time from one filter element to another
A switching device that switches every time,
Fine powder removed from the filter member by injection
Collected in the fine powder collecting groove and the fine powder collecting groove
Opening for attaching a bag-like bag member for putting fine powder
The fine powder was pushed into the bag-like bag member attached to the attachment opening.
For this purpose, a screw rotatably arranged in the fine powder collecting groove is used.
And a screw-shaped screw member.

According to the classification device of the present invention, the suction device
Fine powder classified in the classification chamber through the inlet with gas
Is aspirated, and the aspirated
Fines are separated from the trapped gas. The separated fine powder
It adheres to each of multiple filter members,
If fine powder continues to adhere to the filter member,
The power for sucking the fine powder is reduced. However
Injection of gas by the injection device
-Fine powder adhering to the member is removed and
And a filter section from which gas is injected by the injection device.
Material is removed from one filter element every other
Switch to the monitor member.

On the other hand, the fines removed from the filter member
The powder is collected in the fine powder collecting groove, and by the screw member,
Fine powder collected in the fine powder collecting groove was attached to the attachment port
It is pushed into the bag member. Attach a bag to the opening
The cost can be reduced by making
Fine powder collected in the fine powder collecting channel by negative pressure applied nearby
Is difficult to enter into the bag member and accumulates in the fine powder collecting groove.
U. However, as described above,
The fine powder is pushed into the bag by screw
Fine powder despite being low cost
Accumulation of fine powder in the collecting groove is prevented.

In the classification device according to the eighth aspect, the inside of the classification device has a negative pressure.
Dust collection chamber, and the dust collection chamber
And a collecting groove for collecting the fine powder classified indoors.
Bag-shaped bag member for putting the fine powder collected in the collection groove
And a bag-shaped bag attached to the opening
In order to push the fine powder into the member,
And a screw-shaped screw member disposed
Is what it is.

[0023] According to the classification device of the present invention, the classification is performed.
The fine powder classified in the classroom is collected in a collection port. here
The collection port is located in a dust collection chamber where the inside is under negative pressure.
Have been. For this reason, the bag member was simply attached to the attachment opening.
Alone, the fine powder collected in the collection port enters the bag member
Difficult and accumulates in the collection port. However, collecting
Fine powder collected in the mouth, the screw member rotates
Is collected at the opening, and further
It is pushed into the worn bag member. Therefore, the dust collection room
Fine powder accumulates in the collection port even if
Is prevented at low cost.

[0024]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 1 is an elevation view (side view) of a classification device 1 according to one embodiment of the present invention.

As shown in FIG. 1, the classifying device 1 includes a classifying section 2 and a dust collecting section 3. Classification part 2
This is a part for classifying the raw material 51 (see FIG. 5) into a coarse powder 51a (see FIG. 5) and a fine powder 51b (see FIG. 5), and a raw material hopper 21, a raw material delivery device 22, a raw material supply pipe 23,
A classification chamber 24, an intake port 25, an intake pipe 26, a first motor 27, a coarse powder discharge port 28, a compressed air supply pipe 29,
It has a compressor and a dehumidifier. The raw material hopper 21 is for storing the raw material 51 supplied into the classification chamber 24, is made of an iron material, and has a bottom 21a inclined downward. The raw material delivery device 22 includes the raw material hopper 2
The raw material 51 in 1 is sent to the raw material supply pipe 23, and the raw material supply pipe 23 is a pipe for supplying the raw material 51 sent out by the raw material sending device 22 into the classification chamber 24.

The classifying chamber 24 is for classifying the raw material 51 supplied through the raw material supply pipe 23 into coarse powder 51a and fine powder 51b, and the intake port 25 is classified in the classification chamber 24. The fine powder 51b is sucked together with air.
The intake pipe 26 is a pipe for transporting air (including fine powder 51b) sucked through the intake port 25 to the dust collection unit 3, and the first motor 27 is connected to a dispersion plate 203 (see FIG. See) to rotate. The coarse powder outlet 28 is
The compressor (not shown) is a device for compressing air, and the dehumidifier (not shown) is a device for discharging compressed powder generated by the compressor. Is a device for drying and removing moisture from the compressed air. Compressed air supply pipe 29
Is a pipe for supplying the compressed air dehumidified by the dehumidifier into the classification chamber 24.

The dust collecting section 3 is composed of the fine powder 5 classified by the classifying section 2.
1b, a portion for collecting dust, a dust collecting chamber 31, a second motor 32, an exhaust pipe 33, an inclined surface 34, and a fine powder collecting groove 3.
5, an attachment port 36, an air tank 38, a second compressed air supply pipe 39, and an air tank attachment stay 40. The dust collection chamber 31 is a container (housing) for taking out the fine powder 51b from the air sucked through the intake pipe 26.
The second motor 32 generates a force (hereinafter, simply referred to as “suction force”) for sucking the fine powder 51b together with the air, so as to generate a runner (also referred to as “propeller”) 306 (to be described later) (FIG. 3). See). The exhaust pipe 33 is a pipe for exhausting air sucked together with the fine powder 51b through the intake pipe 26, and exhausts only air without discharging the fine powder 51b classified in the classification chamber 24. I do.

The runner 306 does not need to rotate at a constant speed, and the rotation speed may be changeable. With this configuration, the classifying point of the raw material can be set to an appropriate value by changing the suction force.

The inclined surface portion 34 is for guiding the fine powder 51b separated in the dust collecting chamber 31 to the fine powder collecting port 35,
It is inclined downward toward the fine powder collecting groove 35. The fine powder collecting groove 35 is for collecting the fine powder 51b separated in the dust collecting chamber 31, and the attachment port 36 is provided with the fine powder collecting groove 35.
For attaching a bag-like bag member 50 for storing the fine powder 51b collected in the bag. The fine powder 51b collected in the fine powder collecting groove 35 is attached to the bag member 50 attached to the opening 36.
Collected within. The air tank 38 is for removing the fine powder 51b from a filter 302 described later, and the second compressed air supply pipe 39 is a pipe for supplying compressed air to the air tank 38. The second compressor (not shown) is a device for compressing air, and the second dehumidifier (not shown) dries the compressed air generated by the second compressor to remove moisture from the compressed air. Device. The compressed air supplied through the second compressed air supply pipe 39 is air dehumidified by the second dehumidifier.

FIG. 2 is a sectional view of the classifying section 2. As shown in FIG. 2, the classification unit 2 further includes a second raw material supply pipe 201.
, A transmission shaft 202, a distribution plate 203, and a compressed air injection port 204. The second raw material supply pipe 201 transfers the raw material 51 supplied through the raw material supply pipe 23 to the dispersion plate 203.
And is formed in a substantially cylindrical shape. The transmission shaft 202 transmits the rotation of the first motor 27 to the dispersion plate 2.
03, and is formed in a substantially rod shape.
The dispersion plate 203 is for dispersing the raw material 51 supplied through the raw material supply pipe 23 and the second raw material supply pipe 204 into the classification chamber 24, and is formed in a substantially disk shape.

The compressed air injection port 204 is for injecting compressed air to the raw material 51 supplied through the second raw material supply pipe 201, and is provided at a substantially central portion of the second raw material supply pipe 201. I have. The raw material 51 supplied through the second raw material supply pipe 201 is composed of a coarse powder 51a and a fine powder 51b, and usually contains moisture, so that the coarse powder 51a and the fine powder 51b Adhered to (attached to) each other. For this reason, when the degree of wetness of the raw material 51 is high, the coarse powder 51a and the fine powder 51b can be simply obtained by colliding the raw material 51 with the dispersion plate 203 and dispersing the raw material 51 into the classification chamber 24 by rotating the dispersion plate 203. Were dropped in the classifying chamber 24 without being separated and attached to each other, and were discharged from the coarse powder discharge port 28. That is, there is a problem that the classification accuracy varies depending on the degree of wetness of the raw material 51.

However, as described above, in the present classifying apparatus 1, the compressed air injection is performed on the raw material 51 supplied through the second raw material supply pipe 201, that is, the raw material 51 before being dispersed by the dispersion plate 203. Compressed air is injected through port 204. Therefore, by the wind pressure of the compressed air,
The coarse powder 51a and the fine powder 51b adhered to each other can be separated. Also, since the temperature of the compressed air is higher than the temperature of the uncompressed air, the raw material supply pipe 2
The raw material 51 supplied through the third and second raw material supply pipes 201 is dried, so that the coarse powder 51a and the fine powder 51b can be easily separated, and the coarse powder 51a once separated
And the fine powder 51b can be prevented from adhering (adhering) again. Furthermore, as described above, since the compressed air is simply injected into the raw material 51,
In order to be able to maintain stable classification accuracy regardless of the quality of the raw material 51, the present classification device 1
It is possible to suppress an increase in the manufacturing cost of the device.

Since the compressed air supplied through the compressed air injection port 204 is dehumidified by the dehumidifier,
Due to the moisture contained in the compressed air, coarse powder 51a and fine powder 5
It is possible to prevent the separation from 1b from being hindered.

It should be noted that the compressed air injection port 204 does not necessarily have to be provided substantially at the center of the second raw material supply pipe 201, and the raw material supply pipe 201 and the second
What is necessary is just to be provided in any place in the raw material supply pipe 201. Further, the compressed air injection port 204 may be provided between the raw material supply pipe 201 and the dispersion plate 203. Further, the compressed air injection port 204 need not be provided at one place, but may be provided at a plurality of places.

Next, the configuration of the dust collecting section 3 will be described in detail with reference to FIG. FIG. 3 is a cross-sectional view of the dust collection unit 3. As shown in FIG. 3, the dust collecting unit 3 further includes a filter 302, a filter stay 303, and an air passage 3
04, a propeller 305, a second transmission shaft 306, and a second
An air passage 307, a cyclone 308, a screw 309, and an internal pipe 311 are provided.

The filter 302 separates the fine powder 51b from the air sucked through the intake pipe 26, is disposed in the dust collection chamber 31, is made of paper, and has a substantially star-shaped cross section. Are formed in a columnar shape. Since the cross section of the filter 302 is formed in a substantially star shape, the surface area can be increased, and even if some fine powder 51b adheres to the surface of the filter 302, the suction force is prevented from being reduced. You can do it.

The filter stay 303 includes a filter 3
02, and is for partitioning the inside of the dust collection chamber 31 into an upper space 301a and a lower space 301b, and is formed in a substantially plate shape. The air passage port 304 is a hole formed in the filter stay 303,
For discharging the air sucked through the upper space 301a.

By rotating the propeller 305,
This is for generating a suction force. This propeller 30
The fine powder 51b classified in the classification chamber 24 is sucked together with the air by the suction force accompanying the rotation of No. 5. The second transmission shaft 306 transmits the rotation of the second motor 32 to the propeller 305.
, And is formed in a rod shape having a substantially circular cross section.

The second air passage 307 is provided with the propeller 305
The air sucked through the filter 302 by the suction force accompanying the rotation of
To discharge to

The cyclone 308 is for separating the fine powder 51b from the air sucked through the intake pipe 26, and is formed in a substantially cylindrical shape whose upper part is closed and whose lower part is opened. , In the lower space 301b of the dust collection chamber 31. Since the air sucked through the suction pipe 26 turns in the cyclone 308, the fine powder 51b contained in the air sucked through the suction pipe 26 falls due to gravity, and the fine powder collection port 35 Will be collected. Therefore, the amount of the fine powder 51b adhering to the filter 302 is reduced, and it is possible to prevent the suction force from dropping. Further, since the cyclone 308 is provided in the dust collection chamber 31, the classifier 1 can be space-saving.

The screw 309 is rotatably disposed in the fine powder collecting groove 35, and the fine powder 51 b collected in the fine powder collecting groove 35 has the bag member 5 attached to the attachment opening 36.
It is for pushing into 0. The inside of the dust collection chamber 31
A negative pressure is generated by the suction force accompanying the rotation of the propeller 305. Therefore, if the bag member 50 is simply attached to the attachment port 36, the fine powder 51 collected in the fine
b hardly enters the bag member 50 and accumulates in the fine powder collecting groove 35. However, the fine powder 51b collected in the fine powder collecting groove 35 by the screw 309 is
Since it is pushed into 0, it is possible to prevent the fine powder 51b from accumulating in the fine powder collecting groove 35 despite the low cost.

The second compressed air injection port 310 is for injecting compressed air to the filter 302, and the internal arrangement pipe 311 is configured to use the compressed air stored in the air tank 38 for the second compressed air injection port 310. This is a pipe for supplying to The plurality of (in this embodiment, four) second compressed air injection ports 310 are provided in the internal arrangement pipe 311.

The solenoid valve 312 is opened and closed to
This is for switching whether or not the compressed air stored in the air tank 38 is supplied via the internal pipe 311. Specifically, by opening the solenoid valve 312,
The supply of the compressed air stored in the air tank 38 is stopped by closing the solenoid valve 312 while supplying the compressed air stored in the air tank 38 through the internal pipe 311. is there.

FIG. 4 is a sectional view taken along the line IV-IV in FIG. As shown in FIG. 4, the air tank 38 includes:
A plurality (four in the present embodiment) of internal installation pipes 31
1 is attached, and the solenoid valve 312 is connected to each of the internal pipes 3.
11 are provided. This solenoid valve 312
It is opened for a predetermined time (for example, 5 s (seconds)), and when the opening of one solenoid valve 312 is completed, the next solenoid valve is opened. The solenoid valve 312 is opened by opening the solenoid valve 312 disposed at the top of FIG.
, In order from a predetermined time (for example, every 5 seconds). Then, when the opening of the lowermost electromagnetic valve 312 is completed, the uppermost electromagnetic valve 312 is opened again. That is, the second
The filter 302 from which the compressed air is injected from the compressed air injection port 310 is switched from one filter 302 to another filter 302 every predetermined time.
Therefore, even when the filter 302 is used to increase the efficiency of separating the fine powder 51b classified in the classification chamber 24 from the air, the force for sucking the fine powder 51b classified in the classification chamber 24 (suction force) ) Can be kept constant. That is, the classification accuracy of the classification device 1 can be kept constant. The order in which the solenoid valves 312 are opened does not necessarily have to be opened in order from the uppermost solenoid valve 312 in FIG. 4, and the solenoid valves 312 disposed at four locations are evenly opened. You can do it.

Next, the operation of the classification device 1 configured as described above will be described with reference to FIGS. FIG. 5 is a diagram illustrating a state in which compressed air is injected into the raw material 51 charged into the classification device 1, and FIG. 6 illustrates a state in which the fine powder 51 b is sucked into the dust collection chamber 31. FIG.

When the raw material 51 is put into the raw material hopper 21, the raw material 51 put into the raw material hopper 21 is sent out to the raw material supply pipe 23 by the raw material delivery device 22 at predetermined intervals. Raw material 51 sent out to raw material supply pipe 23
Is further connected to the second raw material supply pipe 2 through the raw material supply pipe 23.
01. The raw material 51 supplied to the second raw material supply pipe 201 falls in the second raw material supply pipe 201, but the raw material 51 is supplied to the second raw material supply pipe 201 by wind pressure of compressed air injected through the compressed air injection port 204. The raw material 51 is separated into the coarse powder 51a and the fine powder 51b by colliding with the side wall 201a or colliding with the plurality of raw materials 51. Also, the temperature of the compressed air is higher than that of the uncompressed (uncompressed) air. For this reason, even when the raw material 51 supplied through the second raw material supply pipe 201 is wet,
The raw material 51 is dried.

As described above, the raw material 51 supplied to the second raw material supply pipe 201 is separated into coarse powder 51a and fine powder 51b before being dispersed by the dispersion plate 203. Therefore,
The classification accuracy of the classification device 1 can be improved. Also, since the raw material 51 supplied through the second raw material supply pipe 201 is dried, the coarse powder 51 adhered to each other is dried.
a and the fine powder 51b can be easily separated, and the once separated coarse powder 51 and the fine powder 51b can be prevented from adhering (adhering) again. That is, regardless of the quality (degree of wetness) of the raw material 51, stable classification accuracy can be maintained.

The raw material 51 separated into the coarse powder 51a and the fine powder 51b by the compressed air injected from the compressed air injection port 204 falls down the second raw material supply pipe 201 by gravity and collides with the dispersion plate 203. You. The dispersing plate 203 includes a first
The dispersion plate 203 is rotated by the motor 27.
The raw material 51 that has collided with the
Distributed within. In the classification chamber 24, an upward airflow is generated by rotation of a propeller 305 provided in the dust collecting section 3. For this reason, among the raw materials 51 dispersed in the classification chamber 24 by the dispersion plate 203, the fine powder 51b having a small mass is conveyed upward in the classification chamber 24 by an ascending airflow, and the coarse powder 51a having a large mass is removed. It is dropped down in the classification chamber 24 by gravity.

The fine powder 51 conveyed upward in the classification chamber 24
a is sucked together with air through the air inlet 25.
The fine powder 51a sucked through the air inlet 25 is
6 and is conveyed into the dust collection chamber 31. On the other hand, classification room 2
The coarse powder 51 a that has been dropped downward in the inside 4 is discharged out of the classification chamber 24 through the coarse powder outlet 28.

The fine powder 51 b transported together with the air into the dust collecting chamber 31 is swirled in the cyclone 308. At this time, the speed of the air conveyed into the dust collection chamber 31 decreases, and a part of the fine powder 51b contained in the air is dropped by gravity and collected in the fine powder collecting port 35.
Accordingly, the amount of the fine powder 51b attached to the filter 302 is reduced, and the suction force (the fine powder 51 classified in the classification chamber 24) is reduced.
(a force for sucking b together with air) can be prevented from dropping.

The air that has passed through the cyclone 308 is sucked above the dust collection chamber 31 and further sucked through the filter 302. Fine powder 51b contained in the air is attached to the surface of the filter 302. Since the cross section of the filter 302 is formed in a substantially star shape,
Since the surface area is increased, even if some fine powder 51b adheres to the surface of the filter 302, it is possible to prevent the suction force from dropping.

FIG. 7 is a sectional view taken along the line VII-VII of FIG. First, the leftmost solenoid valve 312 in FIG.
Is released for a predetermined time. When the leftmost electromagnetic valve 312 is opened for a predetermined time, the compressed air stored in the air tank 38 is injected into the leftmost filter 302 via the internal pipe 311. Filter 302 in the leftmost column
When the compressed air is injected into the filter 302, the fine powder 51b attached to the
Is removed.

When the leftmost solenoid valve 312 is opened for a predetermined time, next, the rightmost (ie, the second from the left) solenoid valve 312 is opened for a predetermined time. At this time, as soon as the leftmost solenoid valve 312 is closed, the rightmost solenoid valve 312 is opened. When the second electromagnetic valve 312 from the left is opened, the fine powder 51b attached to the filter 302 in the second column from the left is removed, as in the case where the leftmost electromagnetic valve 312 is opened. Hereinafter, similarly, the third electromagnetic valve from the left and the fourth electromagnetic valve 312 from the left are sequentially opened. When the fourth solenoid valve 312 from the left is closed, the leftmost solenoid valve 312 is opened again.

As described above, by injecting the compressed air into the filter 302, the fine powder 5
1b is removed, but the filter 302 from which the compressed air is injected is switched at predetermined intervals. Therefore, in order to increase the efficiency of separating the fine powder 51b classified in the classification chamber 24 from air, the filter 302 is used.
Is used, the fine powder 51 classified in the classification chamber 24 is also used.
The force for sucking b (suction force) can be kept constant. That is, the classification accuracy of the classification device 1 can be kept constant.

FIG. 8 is an enlarged view of the vicinity of the screw 309. The fine powder 51b dropped from the air passing through the cyclone 308 and the fine powder 51b removed from the filter 302 fall along the inclined surface portion 34 or directly without passing through the inclined surface portion 34, It is collected in the fine powder collecting groove 35. The fine powder 51b collected in the fine powder collecting port 35 is rotated by the rotation of the screw 309.
It is collected at the attachment port 36 and further pushed into the bag member 50 attached to the attachment port 36. When the fine powder 51b is pushed into the bag member 50, the classification of the raw material 51 ends.

As described above, the rotation of the screw 309 causes the fine powder 51b collected in the fine powder collecting groove 35 to be removed.
Is pushed into the bag member 50, so that the fine powder 51b can be pushed into the bag member 50 at low cost even if the inside of the dust collection chamber 31 is at a negative pressure.
5 can be prevented from accumulating the fine powder 51b.

As described above, the present invention has been described based on the embodiments. However, the present invention is not limited to the above embodiments, and various improvements and modifications can be made without departing from the gist of the present invention. Can be easily inferred.

For example, in the present embodiment, the classification device 1
A classification unit (a part (device) for classifying the raw material 51) 2 and a dust collecting unit (a part (device) for collecting the classified fine powder 51b) 3 are configured separately. However, the classification unit 2 and the dust collection unit 3 do not necessarily need to be configured separately,
You may make it comprise integrally.

[0059]

According to the classification device of the first aspect, before the raw material is dispersed into the classification chamber by the dispersing plate by the compressed air injected through the compressed air injection port, the raw material constituting the raw material is formed. The flour and fines are separated. Therefore, there is an effect that the classification accuracy of the present classification device can be improved. Further, even when the raw material supplied through the raw material supply pipe is wet, the raw material is dried by simply injecting compressed air into the raw material, and the coarse powder and the fine powder adhering to each other are removed. Are easily separated. That is, there is an effect that stable classification accuracy can be maintained irrespective of the quality (degree of wetness) of the raw material. Further, as described above, the present classification apparatus merely injects compressed air to the raw material, so that the classification apparatus can maintain stable classification accuracy regardless of the quality of the raw material. There is an effect that an increase in the manufacturing cost of the classification device can be suppressed to a low level.

According to the classification device of the second aspect, in addition to the effect of the classification device of the first aspect, the compressed air injected through the compressed air injection port is dehumidified by the dehumidifying device. Therefore, due to the moisture contained in the compressed air,
There is an effect that it is possible to prevent the separation of the coarse powder and the fine powder from being hindered.

According to the classification device of the third aspect, in addition to the effects of the classification device of the first or second aspect, further, the fine powder adhered to the plurality of filter members by gas injection by the injection device. Is removed and the switching device switches the filter member from which gas is injected by the injection device from one filter member to another at predetermined time intervals, so that the fine powder classified in the classification chamber is separated from air. Also in the case where a filter member is used to increase the efficiency of the operation, there is an effect that the force for sucking the fine powder classified in the classification chamber can be kept constant. That is, there is an effect that the classification accuracy of the classification device can be kept constant.

According to the classification device of the fourth aspect,
In addition to the effects of the classifier described in 3, the screw
-The fine powder collected in the fine powder collecting groove by the member
Can be pushed into the bag member attached to the
Despite the presence, fine powder accumulates in the fine powder collection groove.
There is an effect that it can be prevented.

According to the classification device of the fifth aspect, the injection device
To multiple filter members by gas injection
The fine powder adhering to each is removed and the switching device
And a filter section from which gas is injected by the injection device.
The material is removed from one filter member to another
-Can be switched to other components,
Filter section to increase the efficiency of separating powder from air
Even when using materials, the fine powder classified in the classification room is sucked.
Has the effect of maintaining a constant
You. That is, the classification accuracy of the classification device must be kept constant.
There is an effect that can be.

On the other hand, separation by such a filter member
Gas is sucked through the suction port and cyclone
This is the gas that has passed through the member. This cyclone member is above
Is closed and the lower part is open, so through the suction port
Fine powder contained in the sucked gas falls due to gravity
You. Therefore, the amount of fine powder adhering to the filter member is reduced.
Can reduce the suction power
There is an effect that can be prevented. In addition,
Since the Cyclone is located in the dust collection chamber,
Can be saved in space.

According to the classification device of the sixth aspect, the classification room
When the fine powder classified in the
-Fine powder collected in the collection port by rotating the member
Is collected at the opening, and further attached to this opening.
Into the bag member. Therefore, the cost is low
Nevertheless, it prevents fine powder from accumulating in the collecting groove
There is an effect that can be.

According to the classification device of the seventh aspect, the injection device
To multiple filter members by gas injection
The fine powder adhering to each is removed and the switching device
And a filter section from which gas is injected by the injection device.
The material is removed from one filter member to another
-It is possible to switch to the
Filter section to increase the efficiency of separating powder from air
Even when using materials, the fine powder classified in the classification room is sucked.
Has the effect of maintaining a constant
You. That is, the classification accuracy of the classification device must be kept constant.
There is an effect that can be.

On the other hand, the fine powder is collected by the screw member.
The fine powder collected in the groove is pushed into the bag member attached to the attachment port.
Fine powder despite being low cost
This prevents fine powder from accumulating in the collection channel.
There is an effect that can be cut.

According to the classification device of the eighth aspect, the classification room
The fine powder classified in the inside is collected in a collection port. Where
The collection port is located in a dust collection chamber with a negative pressure inside.
I have. Therefore, simply attaching the bag member to the attachment port
Means that fine powder collected in the collection port is difficult to enter into the bag
Accumulated at the mouth. However, collected at the collection port
The fine powder is removed by rotating the screw member.
Collected at the opening, and further attached to this opening
Into the bag member. Therefore, the negative pressure is
Fine powder accumulates in the collection port even if
Can be prevented at low cost.
You.

[Brief description of the drawings]

FIG. 1 is a side view of a classification device according to an embodiment of the present invention.

FIG. 2 is a cross-sectional view of a classifying unit constituting the classifying apparatus.

FIG. 3 is a cross-sectional view of a dust collecting unit constituting the classification device.

FIG. 4 is a sectional view taken along line IV-IV in FIG.

FIG. 5 is a diagram showing a state where compressed air is injected into a raw material charged into a classification device.

FIG. 6 is a diagram showing a state in which fine powder is sucked into the dust collection chamber.

FIG. 7 is a sectional view taken along line VII-VII in FIG.

FIG. 8 is an enlarged view near the screw.

[Description of Signs] 1 Classifier 24 Classifier 25 Inlet (suction port) 35 Fine powder collecting groove 36 Attachment port 38 Air tank (part of injector) 39 Second compressed air supply pipe (part of injector) 201 second raw material supply pipe (raw material supply pipe) 203 dispersion plate 204 compressed air injection port 302 filter (filter member) 309 screw (screw member) 310 second compressed air injection port (part of injection apparatus) 311 Internal arrangement Pipe (part of injection device) 312 Solenoid valve (switching device)

Claims (6)

[Claims] 1. A classifying chamber for classifying raw materials into coarse powder and fine powder, a dispersion plate rotatably disposed in the classification room, and a raw material supply pipe for supplying raw materials to the dispersion plate. A classifying apparatus, comprising: a compressed air injection port for injecting compressed air to a raw material supplied through the raw material supply pipe. 2. The classifier according to claim 1, further comprising a dehumidifier for dehumidifying compressed air injected through the compressed air injection port. 3. A suction port for sucking fine powder classified in a classifying chamber together with gas, a plurality of filter members for separating fine powder from gas sucked through the suction port, An injection device for injecting gas from a direction opposite to a suction direction of the fine powder separated by the filter member, and a filter member from which the gas is injected by the injection device is predetermined from one filter member to another filter member The classification device according to claim 1, further comprising: a switching device that switches every time. 4. A classifying apparatus comprising: a classifying chamber for classifying raw materials into coarse powder and fine powder; and a suction port for sucking fine powder classified in the classifying chamber together with gas. A plurality of filter members for separating fine powder from gas sucked through a mouth, and an injection device for injecting gas from the direction opposite to the suction direction of the fine powder separated by the filter member to the filter member And a switching device for switching a filter member from which gas is injected by the injection device from one filter member to another filter member at predetermined time intervals. 5. A fine powder collecting groove for collecting fine powder removed from a filter member by gas injection by an injection device, and a bag-like bag member for storing fine powder collected in the fine powder collecting groove. An attachment port to be attached, and a screw-shaped screw member rotatably disposed in the fine powder collection groove, for pushing fine powder into a bag-shaped bag member attached to the attachment port. The classification device according to any one of claims 1 to 4, further comprising: 6. A classification apparatus comprising: a classification chamber for classifying raw materials into coarse powder and fine powder; and a collection groove for collecting fine powder classified in the classification chamber, wherein: An opening for attaching a bag-shaped bag member for storing the fine powder, and a rotatable inside the collecting groove for pushing the fine powder into the bag-shaped bag member attached to the opening. A classifier, comprising: a screw-shaped screw member provided.