KR20210023554A - Air current forming net and separating apparatus containing the same - Google Patents

Abstract

The present invention includes: a first perforation forming part in which a plurality of recessed areas and a plurality of protruding areas are alternately formed; and a second perforation forming part having the same shape as the first perforation forming part, wherein the first perforation forming part and the second perforation forming part are coupled such that each of the recessed areas and the protruding areas cross each other, and provided continuously to form a surface, thereby passing through a plurality of perforations repeatedly formed between the intersected recessed area and the protruding area so that the blowing direction is dispersed and discharged in a right angle direction.

Description

Air current forming net and specific gravity screening apparatus including the same

The present invention relates to an airflow-forming network and a specific gravity screening apparatus including the same, and more particularly, an airflow-forming network that sorts a mixture of two or more particles having different specific gravity by specific gravity using blowing and vibration, and the same. It relates to a specific gravity sorting device to include.

As the price of crude oil has recently increased explosively, efforts to secure an energy source that can replace crude oil are increasing.

Accordingly, research on new energy sources that can replace existing fossil fuels such as solar energy and bio energy is actively being conducted, but there are still many limitations in industrial use, and thus, the demand for coal is increasing again in recent years.

In general, run of mine coal, which is the coal as it is excavated from the coal bed, contains a large amount of coal powder, and the pure coal with low ash content and gangue, which is the destruction stone of rock, are mixed.

At this time, if the gangue is contained in the pure coal, the amount of heat decreases during the combustion process of the pure coal, and harmful gas (SO _x ) is generated.In particular, the alkali components (K ₂ O, Na ₂ O) contained in mica, chlorite, and clay among gangues In the combustion process, the melting point of ash is lowered, causing slagging or fouling inside the boiler of a thermal power plant, which is the cause of the life of the boiler.

Therefore, in order to improve the combustion efficiency and extend the life of the boiler, technology development for removing gangue mixed with raw coal by a physical method has been attempted.

In the prior art Korean Patent Registration No. 1010940, a grinder body having an accommodating portion formed to accommodate both low-grade coal and water having an ash content of a certain level or higher, and a receiving portion of the grinder body are accommodated to collide and friction with the coal. A wear pulverizer having a plurality of friction balls for pulverizing the coal and a stirrer that is rotatably installed on the pulverizer body and stirs the coal and the friction ball to collide and rub with each other, and an upper side of the receiving part of the wear pulverizer A screen that is installed in and has a plurality of permeable holes through which only particles of a certain size or less can pass, and a catcher that hydrophobicizes the pulverized coal particles so that the coal particles pulverized in the abrasion pulverizer can float to the upper side of the receiving part. An apparatus for upgrading low-grade coal, characterized in that it comprises a water catcher supply device for supplying the agent to the receiving part, is provided.

In summary, in the prior art, the raw coal is floated and classified into fine coal particles and gangue particles, but the prior art requires a post-treatment process of dehydrating and drying the fine coal particles, which requires a lot of cost.

Accordingly, there is a need to develop various coal sorting devices to solve the above-described problems.

It is an object of the present invention to sort out a mixture supplied by mixing two or more particles having different specific gravity by the difference in specific gravity, so that a plurality of perforations formed along a direction perpendicular to the supply direction of the air supplied from the air blowing fan It is possible to control the amount of air blown to the deck to be uniform by allowing it to pass through and to be divided and the mixture to be supplied to the deck, and since the plurality of perforated areas have a curved structure, the flow rate of each selected particle can be indirectly controlled. It is to provide an airflow forming network and a specific gravity screening device including the same.

The airflow forming network according to the present invention includes a first perforation forming portion in which a plurality of depressions and a plurality of protruding regions are alternately formed, and a second perforation forming portion having the same shape as the first perforation forming portion, and the first perforation The formation portion and the second perforation forming portion are coupled to each other so as to intersect each other, and are continuously provided to form a surface, so that a plurality of repetitively formed between the intersected recessed area and the protruding area It is characterized in that the direction in which the air is blown through the perforation is distributed and discharged in a right angle direction.

On the other hand, the specific gravity sorting device according to the present invention has a plurality of upper surfaces formed with an inclined surface inclined to one side in the front-rear direction and one side in the left and right direction, the main body having the inclined surface open, and seated on the inner side of the inclined surface, and forming an airflow-forming net. A first deck having a first perforation formed thereon, a guide coupled to the upper surface of the first deck in plurality, a mixture supply unit supplying a mixture to the upper surface of the first deck, and installed inside the body, and the An air blowing fan that blows air into the first perforation, and a vibration unit that applies horizontal vibration to the first deck to discharge particles constituting the mixture through different paths, wherein the first perforation includes the air blowing fan. It is formed in a direction perpendicular to the direction of blowing air through and guides the direction in which air is supplied.

The first deck is formed in the same shape as the plurality of first perforation forming portions and the first perforation forming portions formed by repeatedly forming a curved area in which a protruding area and a depressed area are repeated along the length direction on the inside of the inclined surface. And a plurality of second perforation forming portions having the same directionality and arranged to cross each of the protruding regions and the depressed regions between the plurality of first perforated forming portions disposed adjacent to each other.

Here, the first perforation is a plurality of recessed regions of the first hole forming part, a plurality of protruding regions of the second hole forming part, a plurality of protruding regions of the first hole forming part, and a plurality of recessed regions of the second hole forming part It is formed as a space that is repeatedly generated between.

On the other hand, the specific gravity screening device according to the present invention is provided between the first deck and the air blowing fan, the second having a plurality of second perforations that divide the air blown from the air blowing fan into a uniform size. A deck and a frame in which the first and second decks are fitted to the upper and lower surfaces, respectively, so as to be inclinedly seated on the inside of the inclined surface in the inclined direction of the inclined surface.

In the second deck, the second perforation is wider than the first perforation.

In addition, the specific gravity screening device according to the present invention defines the first corner, the second corner, the third corner, and the fourth corner in the order in which the corners of the first deck are located higher, respectively, the upper end of the second corner and the A first ripple arranged between the upper end of the fourth corner, a second ripple arranged between the upper end of the first corner and the upper end of the third corner, and between the upper end of the first corner and the upper end of the second corner It further includes an enclosing barrier wall.

In addition, in the specific gravity screening device according to the present invention, in the first corner, the second corner, the third corner, and the fourth corner in the order in which the corners of the first deck are respectively positioned higher, the upper end of the fourth corner and the fourth corner The upper end of the third corner is divided into a first discharge space adjacent to the fourth corner and a second discharge space adjacent to the third corner by a first partition wall and a second partition wall, and the first Among the mixture supplied to the deck, particles having a relatively high flow force are discharged to the first discharge space, and particles having a relatively low flow force are discharged to the second discharge space.

In addition, the specific gravity screening device according to the present invention further includes a suction unit installed on the upper side of the main body to suck dust.

In the present invention, in order to sort the supplied mixture by mixing two or more particles having different specific gravity by the difference in specific gravity, the air supplied from the air blowing fan passes through a plurality of perforations formed along a direction perpendicular to the supply direction, and It is possible to adjust the amount of air blown toward the deck to be uniform by allowing the divided and mixed mixture to be fed to the deck, and since the plurality of perforated areas have a curved structure, it is possible to indirectly control the flow rate of the selected particles. Has an effect.

Further, in the present invention, since the flow direction of the particles is formed in a direction perpendicular to the supply direction of air, the problem of clogging of the perforation by the particles that are sorted and flowed can be prevented in advance.

1 is a perspective view of a specific gravity sorting device according to an embodiment of the present invention.
2 is an exploded perspective view of a specific gravity sorting device according to an embodiment of the present invention.
3A to 3B are enlarged views of the airflow forming network for the specific gravity sorting apparatus according to an embodiment of the present invention.
3C to 3D are views showing the flow of air blown through the airflow forming network for the specific gravity sorting device according to an embodiment of the present invention.
4 is an enlarged perspective view of a vibration unit for a specific gravity sorting device according to an embodiment of the present invention.
5 is an exploded perspective view of a first deck, a second deck, and a frame for a specific gravity sorting device according to an embodiment of the present invention.
6 is an operation diagram of a specific gravity sorting device according to an embodiment of the present invention.
7 is a plan view of an embodiment of a specific gravity sorting device according to an embodiment of the present invention.
8 is an operation diagram of an embodiment of a specific gravity sorting device according to an embodiment of the present invention.

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

Advantages and features of the present invention, and a method of achieving the same will become apparent with reference to the embodiments described later in detail together with the accompanying drawings.

However, the present invention is not limited by the embodiments disclosed below, but will be implemented in a variety of different forms, only the present embodiments make the disclosure of the present invention complete, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the scope of the invention to those who have, and the invention is only defined by the scope of the claims.

In addition, in describing the present invention, when it is determined that related known technologies or the like may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

1 is a perspective view of a specific gravity sorting device according to an embodiment of the present invention, Figure 2 is an exploded perspective view of the specific gravity sorting device according to an embodiment of the present invention.

In addition, Figures 3a to 3b are enlarged views of the airflow forming network for the specific gravity sorting device according to an embodiment of the present invention, and Figures 3c to 3d are blown through the airflow forming network for the specific gravity sorting device according to an embodiment of the present invention. It is a view showing the flow of the air, Figure 4 is an enlarged perspective view of the vibration unit for the specific gravity sorting device according to an embodiment of the present invention.

As shown in FIGS. 1 to 2, in the specific gravity sorting apparatus 1000 according to the present embodiment, when two or more particles having different specific gravity are mixed and supplied, the mixture is selected by specific gravity by using blowing and vibration. The blowing direction discharged in the direction opposite to the supply direction of is passed through a plurality of airflow forming nets and distributed and discharged in a perpendicular direction, so that the specific gravity of the mixture is sorted together with vibration, and for this purpose, a specific gravity sorting device ( 1000 is configured to include a main body 100, a first deck 210, a guide 220, a mixture supply unit 300, an air blowing fan 400, and a vibration unit 500.

The main body 100 is formed in a rectangular parallelepiped shape that becomes wider toward the upper side, and the upper surface is formed as an inclined surface 110 inclined from left to right while the upper surface is inclined from front to rear, and the center of the inclined surface 110 is opened, A plurality of support members 120 are arranged and formed on the edge of the inclined surface 110.

In this case, the inclined surface 110 is preferably formed in a shape inclined from the left to the right while inclined from the front side to the rear side, but the present invention is not limited thereto, and the inclined surface 110 has one side in the front-rear direction and one side in the left-right direction. Any inclined shape can be applied.

The support member 120 is configured to support a component mounted on the inside of the inclined surface 110, and may be formed in a cylindrical shape, but the present invention is not limited thereto.

The first deck 210 is supported by the support member 120 while being inclined in the inclined direction of the inclined surface 110 on the inside of the inclined surface 110, and a plurality of first decks forming a plurality of airflow forming networks Perforation 211 is formed densely.

The first perforated hole 211 is formed in a direction perpendicular to the blowing direction of air through the air blowing fan 400 and is formed to guide a direction through which air is passed.

To this end, the first deck 210 includes a plurality of first perforation forming portions 210a and second perforation forming portions 210b.

That is, the specific gravity sorting apparatus 1000 according to the present embodiment includes an airflow forming net forming the first deck 210, and the airflow forming net includes a first perforation forming part 210a and a first perforating forming part ( A second hole forming portion 210b having the same shape as 210a) is provided.

Here, as shown in FIG. 3A, the first perforation forming part 210a is formed repeatedly along the length direction in the inner side of the inclined surface 110 in which the protruding region A and the depressed region B are repeated. Is done.

In addition, the second perforation forming portion 210b is formed in the same shape as the first perforated forming portion 210a, has the same direction, and protrudes between the plurality of first perforated forming portions 210a disposed adjacent to each other. The region A and the recessed region B are disposed to cross each other.

In other words, the first perforation 211 formed through the first perforation forming portion 210a and the second perforation forming portion 210b is, as shown in FIG. 3B, the first perforation forming portion 210a. ) Of the plurality of recessed regions (B) and the plurality of protruding regions (A) of the second perforation forming portion 210b, and a plurality of protruding regions (A) of the first perforating forming portion 210a and the second perforation It may be formed as a space that is repeatedly generated between the plurality of recessed regions B of the forming part 210b.

Accordingly, after the air blown through the air blowing fan 400 with respect to the flow direction of the supplied mixture, for example, the raw coal pulverized material, the first perforation 211 moves to the side along the first perforation 211, As shown in FIGS. 3C to 3D, since the guide can be directed toward the pulverized raw coal, the flow rate of the pulverized raw coal can be made constant through supply of air at a constant air volume.

Here, in the present embodiment, the supplied mixture is limited to pulverized raw coal, but this is not defined, and may be made of a variety of mixtures in which two or more particles having different specific gravity are mixed.

In addition, since the first perforation 211 is formed on the side surface with respect to the supply direction of the pulverized raw coal by the structure as described above, the first Compared to the perforated structure, clogging by the crushed raw coal can be prevented, and thus clogging of the first perforated hole 211 is prevented, so that a certain amount of blowing air can be supplied to the upper surface of the first deck 210.

In addition, since the first perforation 211 has a curved structure formed by repeating the protruding region A and the depressed region B, it is possible to indirectly control the flow rate of the supplied raw coal pulverized material.

Further, the first deck 210 may also be formed of a mesh plate, but the present invention is not limited thereto.

The first corner 212, the second corner 213, the third corner 214, and the fourth corner 215 in the order in which the corners of the first deck 210 are positioned higher, respectively, the guide ( 220 is formed to be elongated in a direction toward the fourth corner 215, and a plurality of them are arranged in a direction toward the third corner 214 from the second corner 213 to the upper surface of the first deck 210. Are combined.

The mixture supply unit 300 supplies the crushed raw coal to a portion of the upper surface of the first deck 210 adjacent to the second corner 213, wherein the first perforations 211 are the first deck 210 It is preferable that the area is formed narrower than the particles contained in the pulverized raw coal so that the pulverized raw coal supplied to the upper surface of the pulverized material is not intruded.

The air blowing fan 400 may be configured as an air blowing fan, and is installed inside the main body 100 to blow air into the first perforated hole 211.

As shown in FIG. 4, the vibration unit 500 may be composed of a vibrator hinged to one end of the first deck 210, and applies horizontal vibration to the first deck 210 to provide the first deck 210 with vibration in a horizontal direction. 1 Of the raw coal pulverized material supplied to the upper surface of the deck 210, the solid coal particles having a flow force by the air passing through the first perforated holes 211 and the second corner 213 and the second corner 213 along the guide 220 The first corner 212 and the third corner 214 are discharged between the fourth corner 215 and have a higher specific gravity than the solid coal particles, so that they do not have a flow force, and are fine and plate-shaped gangue particles along the guide 220. ) It plays a role of being discharged between.

Here, the specific gravity of the fine coal particles is 1.9kg/㎥ or less, and the specific gravity of the gangue particles is 2.2kg/㎥ or more.

Accordingly, the specific gravity sorting apparatus 1000 according to the present invention has an effect that the refined coal particles and gangue particles contained in the raw coal pulverized material are dryly selected from each other by the difference in specific gravity, so that a post-treatment process of dehydration and drying is not required.

On the other hand, the vibration unit 500 may be composed of a piston (not shown) for generating vibration by applying a horizontal pushing force to the first deck 210 and a crankshaft (not shown) coupled to the piston. have. At this time, the raw coal pulverized material supplied to the upper surface of the first deck 210 is subjected to vibration only by the force pushed in the horizontal direction by the piston, so that the probability of the particles contained in the pulverized raw coal colliding with each other decreases the probability of being broken. .

In addition, the specific gravity sorting apparatus 1000 according to the present invention includes the second corner 213 and the fourth corner 215 so that the fine coal particles discharged between the second corner 213 and the fourth corner 215 are guided downward. ) The first guide member 610 installed between the first corner 212 and the third corner so that the gangue particles discharged between the first corner 212 and the third corner 214 are guided downward. It may be configured to further include a second guide member 620 installed between (214).

In addition, it is preferable that the guide 220 is not formed adjacent to the fourth corner 215. When the guide 220 is formed adjacent to the fourth corner 215, the fine coal particles mixed with a trace amount of gangue particles move between the second corner 213 and the fourth corner 215 along the guide 220. Because it can be discharged.

Hereinafter, FIG. 5 is an exploded perspective view of a first deck, a second deck, and a frame for a specific gravity sorting device according to an embodiment of the present invention.

As shown in FIG. 5, the specific gravity screening apparatus 1000 according to the present invention can be blown into the first perforated hole 211 after the air blown by the air blowing fan 400 is divided into a uniform size. The second deck 230 and the frame 240 may be further included to be configured.

The second deck 230 is formed in a plate shape and is provided between the first deck 210 and the air blowing fan 400, and divides the air blown from the air blowing fan 400 into a uniform size. A plurality of second perforations 231 are densely formed, and at this time, the second perforations 231 have an area larger than the first perforations 211 so that the air blown from the air blowing fan 400 can pass smoothly. It is formed widely.

The frame 240 is formed in a plate shape opened in the vertical direction, and the first deck 210 and the second deck 230 are respectively fitted to the upper and lower surfaces, so that the inclined surface ( 110) in the inclined direction.

Accordingly, the specific gravity screening device 100 according to the present invention further includes a second deck 230 and a frame 240, so that the air blown from the air blowing fan 400 is transmitted to the second perforation ( After being divided into uniform sizes through 231, there is an effect of being supplied to the first perforated hole 211.

At this time, among the pulverized raw coal supplied to the upper surface of the first deck 210, the solid coal particles are distributed on the upper surface of the first deck 210 by air of a uniform size passing through the first perforations 211 Each area has a uniform flow force.

Meanwhile, referring to FIGS. 1 to 2, the specific gravity sorting apparatus 1000 according to the present invention may further include a first ripple 250, a second ripple 260, and a blocking wall 270.

The first ripple 250 is arranged between the upper end of the second corner 213 and the upper end of the fourth corner 215, and is discharged between the second corner 213 and the fourth corner 215 It guides the static bullet particles in one direction. In the drawings, an embodiment in which the first ripple 250 guides the solid particles toward the fourth corner 215 is illustrated, but the present invention is not limited thereto.

The second ripple 260 is arranged between the upper end of the first corner 212 and the upper end of the third corner 214, and is discharged between the first corner 212 and the third corner 214 It guides the gangue particles in one direction. In the drawings, an embodiment in which the second ripple 260 guides the gangue particles in a direction toward the third corner 214 is illustrated, but the present invention is not limited thereto.

The blocking wall 270 is configured to surround between the upper end of the first corner 212 and the upper end of the second corner 213, and the pulverized raw coal supplied to the upper surface of the first deck 210 is It serves to block so as not to go out between the first corner 212 and the second corner 213.

Hereinafter, Figure 6 is an operation diagram of the specific gravity sorting apparatus according to an embodiment of the present invention.

As shown in Fig. 6, the operating principle of the specific gravity sorting apparatus 1000 according to the present invention will be described.

First, the mixture supply unit 300 supplies the pulverized raw coal to a portion of the upper surface of the first deck 210 adjacent to the second corner 213, wherein the pulverized raw coal is It does not come out between the first corner 212 and the second corner 213.

Next, the air blowing fan 400 blows air into the second perforations 231. In this case, the air blown by the air blowing fan 400 is divided into a uniform size in the second perforations 231 and then blown into the first perforated holes 211.

At this time, by the air passing through the first perforations 211, the particles contained in the pulverized raw coal supplied to the first deck 210 have a high flow force in the order of low specific gravity.

In more detail, due to the air passing through the first perforations 211, the fine coal particles among the raw coal pulverized material have the highest flow force due to the lowest specific gravity, and the fine coal particles mixed with a trace amount of gangue particles are Due to the second lowest specific gravity, the second highest flow force is obtained, and the gangue particles mixed with a trace amount of static coal particles have the third highest flow force due to the third lowest specific gravity, and the gangue particles have a specific specific gravity. It is the highest relationship and does not have fluidity.

At this time, in FIG. 6, in order to more easily show the movement path of the particles contained in the pulverized coal, the solid coal particles are shown in a circle, and the solid coal particles mixed with a small amount of gangue particles are shown in a circle in which a triangle is bonded to the surface. , The gangue particles mixed with a trace amount of normal coal particles are shown as triangles in which a circle is bonded to the surface, and the gangue particles are shown as triangular particles.

Next, the vibrating unit 500 applies horizontal vibration to the first deck 210 so that the static coal particles having the highest flow force are transferred to the second corner 213 and the second corner 213 along the guide 220. The refined coal particles discharged between the 4 corners 215 and mixed with a trace amount of gangue particles having the second highest flow force pass through the guide 220 and the third corner 214 and the fourth corner 215 Among them, gangue particles mixed with a trace amount of solid coal particles that are discharged to a place close to the fourth corner 215 and have the third highest flow force pass through the guide 220 and the third corner 214 The gangue particles, which are discharged between the and the fourth corner 215, close to the third corner 214, and do not have a flow force, follow the guide 220, the first corner 212 and the third corner ( 214).

At this time, the first ripple 250 serves to quickly discharge the fine coal particles discharged between the second corner 213 and the fourth corner 215 from the upper surface of the first deck 210, and The 2 ripple 260 serves to quickly discharge gangue particles discharged between the first corner 212 and the third corner 214 from the upper surface of the first deck 210, and thus the first deck 210 It is possible to reduce the energy consumption by increasing the throughput of the refined coal particles and waste-rock particles supplied to the upper surface of the.

Accordingly, the specific gravity sorting apparatus 1000 according to the present invention can select the raw coal pulverized material into the normal coal particle and the gangue particle using the difference in specific gravity, as well as the normal coal particle mixed with a trace amount of gangue particles and a trace amount of raw coal particle. There is an effect that gangue particles mixed with can also be selected using the difference in specific gravity.

Hereinafter, Figure 7 is a plan view of an embodiment of a specific gravity sorting device according to an embodiment of the present invention, Figure 8 is an operation diagram of an embodiment of the specific gravity sorting device according to an embodiment of the present invention.

As shown in FIG. 7, in the embodiment of the specific gravity sorting apparatus 1000 according to the present invention, the first partition wall 280 and the upper end of the third corner 214 are separated from the upper end of the fourth corner 215 and the upper end of the third corner 214. The second partition wall 290 is divided into a first discharge space 216 adjacent to the fourth corner 215 and a second discharge space 217 adjacent to the third corner 214.

The first partition wall 280 is formed in a direction from the fourth corner 215 toward the first corner 212 and is coupled to an upper end of the fourth corner 215, wherein the first partition wall ( The lower end of the 280 may be hinged to the upper end of the fourth corner 215.

The second partition wall 290 is formed in a direction from the third corner 214 toward the second corner 213 and between the upper end of the fourth corner 215 and the upper end of the third corner 214. In this case, the lower end of the second partition wall 290 may be hinged between the upper end of the fourth corner 215 and the upper end of the third corner 214.

As shown in Fig. 8, a description will be made of the operating principle of an embodiment of the specific gravity sorting apparatus 1000 according to the present invention.

As described in the principle of operation of the specific gravity sorting device according to the present invention, the vibration unit 500 applies horizontal vibration to the first deck 210 to obtain the highest flow force. It is discharged between the second corner 213 and the fourth corner 215 along 220, and the fine coal particles mixed with a trace amount of gangue particles having the second highest flow force pass over the guide 220 The gangue particles, which are discharged between the third corner 214 and the fourth corner 215, and mixed with a trace amount of solid coal particles having the third highest flow force, pass through the guide 220, and the third corner ( The gangue particles that are discharged between 214 and the fourth corner 215 and have no flow force are discharged between the first corner 212 and the third corner 214 along the guide 220.

At this time, the refined coal particles mixed with the trace amount of gangue particles having the second highest flow force are discharged between the third corner 214 and the fourth corner 215, It is discharged to 1 discharge space 216.

In addition, the gangue particles mixed with the trace amount of solid coal particles having the third highest flow force are discharged between the third corner 214 and the fourth corner 215, and are lower than the fine coal particles mixed with a trace amount of gangue particles. It has a flow force and is discharged to the second discharge space 217 adjacent to the third corner 214.

At this time, when the angle or position of the first partition wall 280 and the second partition wall 290 is adjusted, a trace amount of fine coal particles mixed with a trace amount of gangue particles discharged to the first discharge space 216 The mixing amount of gangue particles can be adjusted.

In the present invention, in order to sort the supplied mixture by mixing two or more particles having different specific gravity by the difference in specific gravity, the air supplied from the air blowing fan passes through a plurality of perforations formed along a direction perpendicular to the supply direction, and It is possible to adjust the amount of air blown toward the deck to be uniform by allowing the divided and mixed mixture to be fed to the deck, and since the plurality of perforated areas have a curved structure, it is possible to indirectly control the flow rate of the selected particles. Has an effect.

Further, in the present invention, since the flow direction of the particles is formed in a direction perpendicular to the supply direction of air, the problem of clogging of the perforation by the particles that are sorted and flowed can be prevented in advance.

The present invention has been described with reference to the embodiment(s) shown in the drawings, but this is only exemplary, and various modifications may be made therefrom by those of ordinary skill in the art. It will be appreciated that all or part of (s) may be optionally combined and configured. Therefore, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

1000: specific gravity sorting device 100: main body
110: slope 210: first deck
210a: first hole formation portion 210b: second hole formation portion
211: first hole 212: first corner
213: 2nd corner 214: 3rd corner
215: fourth corner 216: first discharge space
217: second discharge space 218: stepped surface
220: guide 230: second deck
231: second perforation 240: frame
250: 1st ripple 260: 2nd ripple
270: barrier wall 280: first compartment wall
290: second partition wall 300: mixture supply unit
400: air blowing fan 500: vibration unit
610: first guide member 620: second guide member
700: suction unit

Claims (9)

A first perforation forming portion in which a plurality of depression regions and a plurality of protruding regions are alternately formed, and a second perforation forming portion having the same shape as the first perforation forming portion,
The first perforation forming part and the second perforating forming part,
Each of the depressed regions and the protruding regions are coupled to cross each other, and are continuously provided to form a surface, passing through a plurality of perforations repeatedly formed between the intersecting depressed regions and the protruding regions, and the direction in which the air is blown is at right angles. Air flow-forming network, characterized in that to be discharged in a distributed direction.
A body having an upper surface formed as an inclined surface inclined toward one side in the front-rear direction and one side in the left-right direction, and the inclined surface is opened;
A first deck seated on the inside of the inclined surface and having a plurality of first perforations forming an airflow forming network;
A guide coupled to the upper surface of the first deck in plurality;
A mixture supply unit supplying a mixture to the upper surface of the first deck;
An air blowing fan installed inside the main body and blowing air into the first perforation; And
Includes; a vibration unit for applying vibration in the horizontal direction to the first deck to discharge particles constituting the mixture through different paths; and
The first perforation,
Specific gravity sorting device, characterized in that it is formed in a direction perpendicular to the direction of blowing air through the air blowing fan to guide a direction in which air is supplied.
The method of claim 2,
The first deck,
A plurality of first perforation forming portions formed by repeatedly forming a curved region in which a protruding region and a depressed region are repeated along the length direction on the inside of the inclined surface; And
A plurality of second perforation forming portions formed in the same shape as the first perforation forming portion, having the same direction, and arranged to cross each of the protruding regions and the depressed regions between the plurality of first perforation forming portions disposed adjacent to each other. Specific gravity sorting device comprising;
The method of claim 3,
The first perforation,
A space that is repeatedly generated between the plurality of recessed areas of the first hole forming part, the plurality of protruding areas of the second hole forming part, and the plurality of protruding areas of the first hole forming part and the plurality of recessed areas of the second hole forming part Specific gravity screening device, characterized in that formed by.
The method of claim 2,
A second deck provided between the first deck and the air blowing fan and having a plurality of second perforations for dividing the air blown from the air blowing fan into a uniform size; And
And a frame in which the first deck and the second deck are respectively fitted on the upper and lower surfaces to be inclined to the inside of the inclined surface in the inclined direction of the inclined surface.
The method of claim 5,
The second deck,
The specific gravity sorting device, characterized in that the second hole is formed wider than the first hole.
The method of claim 2,
The corners of the first deck are defined as a first corner, a second corner, a third corner, and a fourth corner in the order of higher positions. The second corner is arranged between the upper end of the second corner and the fourth corner. 1 ripple;
A second ripple arranged between an upper end of the first corner and an upper end of the third corner; And
And a barrier wall surrounding an upper end of the first corner and an upper end of the second corner.
The method of claim 2,
The first corner, the second corner, the third corner, and the fourth corner are defined as the first corner, the second corner, the third corner, and the fourth corner in the order that the corners of the first deck are positioned higher. It is divided into a first discharge space adjacent to the fourth corner and a second discharge space adjacent to the third corner by a partition wall and a second partition wall, and is relatively high oil among the mixture supplied to the first deck. Specific gravity sorting device, characterized in that formed so that particles having power are discharged to the first discharge space, and particles having a relatively low flow force are discharged to the second discharge space.
The method of claim 2,
Specific gravity sorting device, characterized in that it further comprises a suction unit installed on the upper side of the body to suck the dust.

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