KR102258402B1 - Powder classification apparatus - Google Patents

Abstract

The present invention relates to a powder distribution apparatus. According to an embodiment of the present invention, a powder distribution apparatus comprises: a powder supply unit for supplying powder; a main distribution unit for receiving the powder from the powder supply unit and separating a part of the powder; an auxiliary distribution unit for receiving the remaining powder, excluding the powder separated by the main distribution unit, from the main distribution unit, and separating another part of the powder; a recovery unit for receiving the remaining powder, excluding the powder separated by the auxiliary distribution unit, from the auxiliary distribution unit, and recovering the remainder of the powder; a gas supply unit for supplying an inert gas to the main distribution unit in order to supply powder from the main distribution unit to the auxiliary distribution unit and from the auxiliary distribution unit to the recovery unit; and a supply pipe through which the powder, supplied from the main distribution unit to the auxiliary distribution unit or from the auxiliary distribution unit to the recovery unit, flows together with the inert gas. By the main distribution unit, powder having a size greater than or equal to a predetermined first reference size is separated. By the auxiliary distribution unit, powder having a second reference size or more preset to have a value less than the first reference size, and having less than the first reference size is recovered. By the recovery unit, powder having a size less than the second reference size is recovered. Therefore, fine powder having a size of 20 μm or less can be easily separated.

Description

Powder classifier {POWDER CLASSIFICATION APPARATUS}

The present invention relates to a classification device.

The classification device is a device for dividing powder according to size, and recently, various techniques for dividing nano-sized powder, that is, for classifying, have been proposed. Meanwhile, a powder having a size of 20 to 80 μm is generally used for 3D printing. However, in the case of light metals such as magnesium or aluminum, it is not easy to separate fine powders having a size of 20 μm or less, and this causes a problem in that the quality of 3D printing is ultimately degraded. In addition, conventionally, since only the powder having a required size is separated from the powder, it is impossible to separate the powder into various sizes.

Republic of Korea Patent Registration No. 0586184 (Name: electrostatic dispersion and classification device of nanoparticle production system) Republic of Korea Patent Registration No. 1097397 (Name: Metal nano-powder classification apparatus and method using a pulsed magnetic field) Republic of Korea Patent Publication No. 2017-0102496 (name: powder classifier)

The present invention is to solve the problems caused by the prior art as described above, and an object of the present invention is to provide a classification apparatus configured to facilitate separation of fine powders having a size of 20 μm or less.

Another object of the present invention is to provide a classification apparatus configured to separate powder into various sizes.

One aspect of the classification apparatus according to an embodiment of the present invention for achieving the above object, a powder supply unit for supplying the powder; A main classifying unit receiving powder from the powder supply unit and separating a part of the powder; An auxiliary classifying unit for receiving the remaining powder other than the powder separated by the main classifying unit from the main classifying unit, and separating another part of the powder; A recovery unit receiving the remaining powder other than the powder separated by the auxiliary classifying unit from the auxiliary classifying unit, and recovering the remainder of the powder; A gas supply unit for supplying an inert gas to the main classification unit in order to supply powder from the main classification unit and the auxiliary classification unit to the auxiliary classification unit and the recovery unit; And a supply pipe through which powder supplied from the main classification unit to the auxiliary classification unit or the auxiliary classification unit to the recovery unit flows together with an inert gas. Including, in the main classification unit, a powder having a predetermined first reference size or more is separated, and in the auxiliary classification unit, a second reference size or more and the first predetermined size is less than the first reference size. Powder less than a reference size is recovered, and in the recovery unit, powder less than the second reference size is recovered.

In one aspect of an embodiment of the present invention, the main classification unit includes: a classification chamber receiving powder from the powder supply unit and receiving an inert gas from the gas supply unit; And a main collection tank in which the powder of the first standard size or more among the powder supplied to the classification chamber is dropped by its own weight and collected. Including, among the powder supplied to the classification chamber, the powder less than the first standard size is supplied to the auxiliary classification unit together with the inert gas supplied from the gas supply unit.

In one aspect of the embodiment of the present invention, the main classification unit further includes an ionizer that provides an electric charge for removing static electricity from the powder supplied to the classification chamber.

In one aspect of the embodiment of the present invention, the auxiliary classifying unit receives the powder together with an inert gas from the classifying chamber, and at least one powder in which the second standard size or more and less than the first standard size is centrifuged. Centrifugal dust collector; And at least one auxiliary collection tank in which the powder centrifuged by the centrifugal dust collector is dropped and collected by its own weight. Includes.

In one aspect of the embodiment of the present invention, the auxiliary classifying unit includes two or more connected in series in the flow direction of the powder.

In one aspect of the embodiment of the present invention, the auxiliary classifying unit receives powder together with an inert gas from the classifying chamber, and a relatively large powder among powders of the second standard size or more and less than the first standard size is centrifuged. A separated first centrifugal dust collector; A first auxiliary collection tank in which the powder centrifuged by the first centrifugal dust collector is dropped and collected by its own weight; The powder is supplied with an inert gas from the first centrifugal dust collector, and among the powders of the second standard size or more and less than the first standard size, a relatively small powder compared to the powder centrifuged in the first centrifugal dust collector is centrifuged. A second centrifugal dust collector; And a second auxiliary collecting tank in which the powder centrifuged by the second centrifugal dust collector is dropped and collected by its own weight. Includes.

In one aspect of the present invention, the supply pipe includes a first supply pipe connecting the classification chamber and the first centrifugal dust collector, and a part of the first supply pipe extends into the classification chamber. , Is bent in a direction inclined at a predetermined angle with respect to a direction in which the powder is supplied from the powder supply unit to the classification chamber inside the classification chamber, and the ionizer is the first supply extending into the classification chamber. It is arranged adjacent to the end of the pipe.

In one aspect of the embodiment of the present invention, the set values of the first and second reference sizes are varied according to the supply amount of the inert gas from the gas supply unit to the main classification unit.

In one aspect of the embodiment of the present invention, the first reference size is proportional to the supply amount of inert gas from the gas supply unit to the main classification unit, and the second reference size is, inertness from the gas supply unit to the main classification unit. It is inversely proportional to the amount of gas supplied.

According to the classification apparatus according to the embodiment of the present invention, the following effects can be expected.

First, in the present invention, a relatively large powder among powders supplied from the powder supply unit to the main classification unit is separated, and then a relatively small powder is supplied to the auxiliary classification unit together with an inert gas for separation. Therefore, according to the embodiment of the present invention, in particular, it is possible to more efficiently classify fine powder having a size of 20 μm or less.

Further, in the embodiment of the present invention, the powder supplied from the powder supply unit is separated into different sizes in the main classification unit, the auxiliary classification unit, and the recovery unit. Therefore, according to the embodiment of the present invention, it is possible to classify the powder into various sizes. In particular, in the embodiment of the present invention, powders of more various sizes are obtained by adjusting the size of the powder separated from each of the powders according to the amount of inert gas supplied to supply the powder from the main classifying part to the auxiliary classifying part and the recovery part. Classification becomes possible.

1 is a front view showing a classification device according to an embodiment of the present invention.
Figure 2 is a side view showing an embodiment of the present invention.

Hereinafter, a classification apparatus according to an embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a front view showing a classifying apparatus according to an embodiment of the present invention, and FIG. 2 is a side view showing an embodiment of the present invention.

1 and 2, the classification apparatus according to the present embodiment includes a powder supply unit 100, a main classification unit 200, an auxiliary classification unit 300, a recovery unit 400, a gas supply unit 500, and Includes a supply pipe (600). In particular, in this embodiment, powders of different sizes are separated and collected or collected in the main classification unit 200, the auxiliary classification unit 300, and the recovery unit 400, respectively.

More specifically, the powder supply unit 100 supplies powder. The powder supply unit 100 may be installed above the frame F, for example. In this embodiment, the powder supply unit 100 includes a supply tank 110 and a cover 120. The supply tank 110 may be formed in a hollow hopper shape, for example, and powder is stored therein. Substantially, the powder stored in the supply tank 110 moves downward by its own weight and is supplied to the main classification unit 200. In addition, the cover 120 selectively opens and closes the upper surface of the supply tank 110. A supply pipe 600 for receiving the powder stored in the supply tank 110 from the outside may be connected to the cover 120.

In addition, the powder supply unit 100 may further include a supply impeller 130. The supply impeller 130 is rotatably installed inside the main classification unit 200, substantially, inside the classification chamber 210, which will be described later, and is classified in the supply tank 110 according to the rotational speed. The amount of powder supplied to the chamber 210 is adjusted.

Next, the main classification unit 200 receives powder from the powder supply unit 100. In the main classification unit 200, a relatively large powder, that is, a powder having a predetermined first reference size or more among the powder supplied from the powder supply unit 100 is separated. Here, the'first reference size' is a value set according to the use purpose of the powder, and may be set to a value between 20 and 80 μm, for example, in the case of a powder for 3D printing. In this embodiment, the main classification unit 200 includes a classification chamber 210, a main collection tank 220, and an ionizer 230.

The classification chamber 210 may be formed in a hollow polyhedral shape, for example, a hexahedral shape. The classification chamber 210 may be installed at the center of the frame F to communicate with the powder supply unit 100. Accordingly, the classification chamber 210 receives powder from the powder supply unit 100. In addition, the classification chamber 210 receives an inert gas from the gas supply unit 500.

In addition, in the main collection tank 220, the powder having the first standard size or more among the powder supplied to the classification chamber 210 is dropped by its own weight and collected. To this end, the main collection tank 220 may be installed under the frame F corresponding to the lower side of the classification chamber 210 so as to communicate with the classification chamber 210.

In addition, the ionizer 230 provides electric charges for removing static electricity from the powder supplied to the classification chamber 210. Accordingly, by removing static electricity from the powder by the ionizer 230, a phenomenon in which powders less than the first reference size are mutually condensed by static electricity and separated from the main classifier 200 may be reduced.

Meanwhile, the auxiliary classifying unit 300 receives the remaining powders other than the powder separated by the main classifying unit 200, that is, the powder less than the first reference size, from the main classifying unit 200. Further, in the auxiliary classifying unit 300, a powder that is relatively smaller than the powder separated by the main classifying unit 200, that is, a powder having a predetermined second reference size or more and less than the first reference size is separated. Here, the'second reference size' is a value less than the first reference size and may be set according to the use of the powder. Substantially, the main classification unit 200, that is, the powder less than the first reference size among the powder supplied to the classification chamber 210, together with the inert gas supplied from the gas supply unit 500, the auxiliary classification unit Supplied in 300. Further, in the auxiliary classifier 300, a relatively large powder, that is, a powder having a size greater than or equal to the second reference size and less than the size of the first reference size among powders supplied together with the inert gas is separated.

In this embodiment, the auxiliary classification unit 300 includes a first centrifugal dust collector 311, a first auxiliary collection tank 313, a second centrifugal dust collector 321, and a second auxiliary collection tank 323. . In FIG. 1, the first centrifugal dust collector 311, the first auxiliary collection tank 313, the second centrifugal dust collector 321, and the second auxiliary collection tank 323 are disposed outside the frame F. Although shown, the size of the frame (F) is increased, the first centrifugal dust collector 311, the first auxiliary collecting tank 313, the second centrifugal dust collector 321 and the second auxiliary collecting tank 323 May be installed adjacent to the powder supply unit 100 and the main classification unit 200.

In more detail, the first centrifugal dust collector 311 receives powder together with an inert gas from the classification chamber 210. Further, in the first centrifugal dust collector 311, the powder of the second reference size or more and less than the first reference size is centrifuged. Substantially, the powder supplied with the inert gas into the first centrifugal dust collector 311, that is, the powder of the second standard size or more and less than the first standard size is dropped and separated by centrifugal force and its own weight. In addition, among the powders supplied from the first centrifugal dust collector 311, the remaining powders that cannot be centrifuged are supplied to the second centrifugal dust collector 321 together with an ascending inert gas.

The first auxiliary collecting tank 313 is a place where the powder centrifuged by the first centrifugal dust collector 311 is dropped by its own weight and collected. To this end, the first auxiliary collecting tank 313 is installed below the first centrifugal dust collector 311.

In addition, the second centrifugal dust collector 321 receives powder together with an inert gas from the first centrifugal dust collector 311. As described above, the powder that was not separated by the first centrifugal dust collector 311 among the powders centrifuged by the first centrifugal dust collector 311 will be supplied to the second centrifugal dust collector 321 together with an inert gas. . As described above, in the second centrifugal dust collector 321, substantially, the powder that is not centrifuged by the first centrifugal dust collector 311 or more and less than the first reference size will be centrifuged.

In addition, the second auxiliary collecting tank 323 is a place where the powder centrifuged by the second centrifugal dust collector 321 is dropped by its own weight and collected. The second auxiliary collecting tank 323 is installed below the second centrifugal dust collector 321, similar to the first auxiliary collecting tank 313.

Meanwhile, the recovery unit 400 receives and recovers the remaining powder other than the powder separated by the auxiliary classification unit 300. In this embodiment, the recovery unit 400 includes a recovery tank 410, an exhaust port 420 and a filter 430. In the recovery tank 410, powder other than the powder centrifuged by the second centrifugal dust collector 321, that is, powder less than the second reference size is supplied together with an inert gas to be recovered. In addition, the exhaust port 420 is a place for discharging the inert gas supplied together with the powder to the outside of the recovery tank 410. In addition, the filter 430 serves to remove powder in the inert gas discharged through the exhaust port 420. Of course, the inert gas discharged to the outside of the recovery tank 410 through the exhaust port 420 after the powder is removed by the filter 430 may be recovered to the gas supply unit 500.

The gas supply unit 500 is to the main classification unit 200 to supply powder from the main classification unit 200 and the auxiliary classification unit 300 to the auxiliary classification unit 300 and the recovery unit 400. Supply inert gas. The gas supply unit 500 may supply argon or the like into the main classification unit 200, that is, the classification chamber 210. At this time, the gas supply unit 500 is in a direction in which the powder is supplied from the powder supply unit 100 to the classification chamber 210, that is, in a direction inclined at a predetermined angle with respect to a vertical direction, for example, in a horizontal direction. Inert gas may be supplied to the classification chamber 210.

Finally, in the supply pipe 600, the powder supplied from the main classification unit 200 to the auxiliary classification unit 300 or the auxiliary classification unit 300 to the recovery unit 400 together with an inert gas. This is where it flows. In this embodiment, the supply pipe 600 includes first to third supply pipes 610, 620, and 630. The first supply pipe 610 connects the classification chamber 210 and the first centrifugal dust collector 311, and the second supply pipe 620 includes the first and second centrifugal dust collectors 311 ( 321 is connected, and the third supply pipe 630 connects the second centrifugal dust collector 321 and the recovery unit 400.

In particular, in the present embodiment, a part of the first supply pipe 610 extends into the classification chamber 210 and is bent downward from the inside of the classification chamber 210. In addition, an end of the first supply pipe 610 extending substantially into the classification chamber 210 is disposed adjacent to the ionizer 230. Accordingly, the phenomenon that the powder supplied from the powder supply unit 100 to the classification chamber 210 is not only prevented from being supplied to the first centrifugal dust collector 311 through the first supply pipe 610 is prevented. Powder, which is sufficiently prevented from condensation by the electric charge provided from the niger 230, may be supplied to the first centrifugal dust collector 311 through the first supply pipe 610.

In addition, in this embodiment, the set values of the first and second reference sizes are varied according to the supply amount of the inert gas from the gas supply unit 500 to the main classification unit 200. In other words, according to the amount of inert gas supplied from the gas supply unit 500 to the classification chamber 210, the main collection tank 120, the first and second auxiliary collection tanks 313, 323 and recovery The size of the powder collected or recovered in the unit 400 is adjusted.

More specifically, the first reference size is proportional to the amount of inert gas supplied from the gas supply unit 500 to the main classification unit 200. That is, when the amount of the inert gas supplied from the gas supply unit 500 to the classification chamber 210 is increased, a relatively large powder among the powders supplied from the powder supply unit 100 to the classification chamber 210 also has its own weight. It cannot fall due to, and is supplied from the classification chamber 110 to the first centrifugal dust collector 311 together with an inert gas. Therefore, when the amount of the inert gas supplied from the gas supply unit 500 to the main classification unit 200 increases, the size of the powder separated from the main classification unit 200, that is, the first reference size, is also increased. . Conversely, when the amount of the inert gas supplied from the gas supply unit 500 to the classification chamber 210 is reduced, a relatively small amount of the powder supplied from the powder supply unit 100 to the classification chamber 210 is also It falls by its own weight without being interfered with the flow of inert gas. Therefore, when the amount of the inert gas supplied from the gas supply unit 500 to the main classifying unit 200 is reduced, the size of the powder separated by the main classifying unit 200, that is, the first reference size, is also reduced. .

On the other hand, the second reference size is in inverse proportion to the supply amount of the inert gas from the gas supply unit 500 to the main classification unit 200. That is, when the amount of the inert gas supplied from the gas supply unit 500 to the classification chamber 210 is increased, substantially, the first and second centrifugal dust collectors 311 and 321 from the classification chamber 210 The amount of inert gas supplied to the furnace is also increased. However, when the supply amount of the inert gas increases, the speed of the powder in the first and second centrifugal dust collectors 311 and 321 increases, and consequently, the centrifugal force of the relatively small powder, that is, the powder having a small mass is also increased. , Even relatively small powder is separated by centrifugal dust collection in the first and second centrifugal dust collectors 311 and 321. Therefore, when the amount of the inert gas supplied from the gas supply unit 500 to the main classification unit 200 increases, the size of the powder separated by the auxiliary classification unit 300, that is, the second reference size, decreases. . Conversely, when the amount of the inert gas supplied from the gas supply unit 500 to the classification chamber 210 is decreased, the speed of the powder in the first and second centrifugal dust collectors 311 and 321 is reduced, Only relatively large powders can be centrifugally collected by securing centrifugal force. Therefore, when the amount of the inert gas supplied from the gas supply unit 500 to the main classification unit 200 is reduced, the size of the powder separated by the auxiliary classification unit 300, that is, the second reference size, is increased. .

The scope of the present invention is not limited to the embodiments described above, but is defined by what is described in the claims, and various modifications and adaptations within the scope of the claims by those of ordinary skill in the technical field of the present invention It is self-evident that you can do it.

100: powder supply unit 110: supply tank
120: cover 130: supply impeller
200: main classification unit 210: classification chamber
220: main collection tank 230: ionizer
300: auxiliary classification unit 311: first centrifugal dust collector
313: first auxiliary collection tank 321: second centrifugal dust collector
323: second auxiliary collection tank 400: recovery unit
410: recovery tank 420: exhaust port
430: filter 500: gas supply
600: supply pipe 610: first supply pipe
620: second supply pipe 630: third supply pipe

Claims (9)

A powder supply unit 100 for supplying powder;
A main classification unit 200 receiving powder from the powder supply unit 100 and separating a part of the powder;
An auxiliary classifying unit 300 for receiving the remaining powder other than the powder separated by the main classifying unit 200 from the main classifying unit 200, and separating another part of the powder;
A recovery unit 400 for receiving the remaining powder other than the powder separated by the auxiliary classifying unit 300 from the auxiliary classifying unit 300, and recovering the rest of the powder;
A gas supply unit for supplying an inert gas to the main classification unit 200 in order to supply powder from the main classification unit 200 and the auxiliary classification unit 300 to the auxiliary classification unit 300 and the recovery unit 400 ( 500); And
A supply pipe 600 through which powder supplied from the main classification unit 200 to the auxiliary classification unit 300 or the recovery unit 400 from the auxiliary classification unit 300 flows together with an inert gas; Including,
In the main classification unit 200, powder having a predetermined first reference size or more is separated,
In the auxiliary classifier 300, a powder having a second reference size or more and less than the first reference size, which is preset to a value less than the first reference size, is recovered,
In the recovery unit 400, powder less than the second reference size is recovered,
The main classification unit 200,
A classification chamber 210 receiving powder from the powder supply unit 100 and receiving an inert gas from the gas supply unit 500; And
A main collection tank 220 in which the powder having the first reference size or more among the powder supplied to the classification chamber 210 is dropped by its own weight and collected; Including,
The auxiliary classification unit 300,
A first centrifugal dust collector 311 for receiving powder together with an inert gas from the classification chamber 210, and for centrifuging a relatively large powder among powders of the second standard size or more and less than the first standard size;
A first auxiliary collecting tank 313 in which the powder centrifuged by the first centrifugal dust collector 311 is dropped and collected by its own weight;
The powder is supplied together with an inert gas from the first centrifugal dust collector 311, and among the powders of the second reference size or more and less than the first reference size, relative to the powder centrifuged in the first centrifugal dust collector 311 A second centrifugal dust collector 321 in which the small powder is centrifuged; And
A second auxiliary collecting tank 323 in which the powder centrifuged by the second centrifugal dust collector 321 is dropped and collected by its own weight; Classification device comprising a.
delete The method of claim 1,
The main classification unit 200 further comprises an ionizer 230 for providing an electric charge for removing static electricity from the powder supplied to the classification chamber 210.
delete delete delete The method of claim 3,
The supply pipe 600 includes a first supply pipe 610 connecting the classification chamber 210 and the first centrifugal dust collector 311,
A part of the first supply pipe 610 extends into the classification chamber 210, and powder is supplied from the powder supply unit 100 to the classification chamber 210 within the classification chamber 210. It is bent in a direction that is inclined at a preset angle with respect to the
The ionizer 230 is a classification device disposed adjacent to an end of the first supply pipe 610 extending into the classification chamber 210.
The method of claim 1,
Classification apparatus in which the set values of the first and second reference sizes are varied according to the supply amount of the inert gas from the gas supply unit 500 to the main classification unit 200.
The method of claim 1,
The first reference size is proportional to the supply amount of the inert gas from the gas supply unit 500 to the main classification unit 200,
The second reference size is inversely proportional to the supply amount of the inert gas from the gas supply unit 500 to the main classification unit 200.

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