KR102493672B1 - Foreign body separating apparatus using fluidized bed by wind power - Google Patents

Abstract

The present invention provides a sorting apparatus using a wind power fluidized bed, comprising: a sorting duct providing a space for sorting foreign substances as aggregate falls; a first blower and a second blower installed on one side of the sorting duct to be spaced apart in a vertical direction and blowing wind to the aggregate falling within the sorting duct to separate foreign substances from the sorting duct; a first cyclone sorter and a second cyclone sorter installed on the opposite side of the first blower and the second blower and sorting foreign substances from the aggregate through centrifugal force from air containing the foreign substances separated from the aggregate; a first circulation duct and a second circulation duct for circulating exhaust air from the first cyclone sorter and the second cyclone sorter to the inflow side of the first blower and the second blower without discharging the exhaust air to the outside; a first blowing duct and a second blowing duct respectively connecting the first blower and the second blower to the sorting duct to blow wind in a direction perpendicular to the sorting duct; and a first inflow duct and a second inflow duct formed between the first cyclone sorter/the second cyclone sorter and the sorting duct and suppressing the generation of flying dust by being formed so that the inlet volume is larger than the outlet volume of the first blowing duct and the second blowing duct configured between the first blower/the second blower and the selecting duct.

Description

Wind power fluidized bed separator {Foreign body separating apparatus using fluidized bed by wind power}

The present invention relates to a wind power fluidized bed sorting device, and more particularly, in the process of extracting recycled aggregate from construction waste generated during the demolition of a building or civil engineering structure, foreign substances mixed in construction waste are separated using wind power and It relates to a wind power fluidized bed separator capable of improving regeneration efficiency.

Many structures, that is, bridges, roads, and various buildings that have been created in the process of urbanization and industrialization, are gradually deteriorating over time. In particular, recently, reconstruction and redevelopment are actively promoted in many areas to improve residential culture. There is a situation.

A lot of construction waste is generated in the process of dismantling, reconstruction, and redevelopment of these old structures. If such construction waste is buried as it is, it is difficult to secure a landfill site, the landfill cost is high, and it has a huge impact on the environment. Various countermeasures for recycling and processing construction wastes have been devised in two aspects, protection of the natural environment and recycling of resources, and various treatment devices for construction wastes are being developed in Korea.

Therefore, in terms of environment-friendliness and recycling of resources, construction waste generated during the dismantling of construction and building structures is not landfilled, but is collected in a designated place and then deposited in the crushing process, the foreign matter sorting process, the recycled aggregate and mortar sorting process, and the surface of the recycled aggregate. It is produced as a high-quality resource through a series of intermediate processes such as the attached mortar peeling process.

On the other hand, construction waste contains mixed impurities including waste wood, waste synthetic resins such as Styrofoam, metals such as reinforcing bars, waste paper, and waste fibers used as cement reinforcing agents. As a method of sorting and separating them, , A wind power fluidized bed sorting device is mainly used that separates some foreign substances by a vibrating screen and then separates light foreign substances from the falling recycled aggregate using the wind power of a blower.

Here, as shown in FIGS. 1 and 2, the conventional wind power fluidized bed sorting device drops the conveying conveyor 3 for conveying the aggregate 1 and the aggregate 1 dropped from the conveying conveyor 3 Winds in opposite directions are installed on both sides of the sorting duct 10, which provides a space for sorting out foreign substances, and the aggregate 1 that is installed vertically and falls in the sorting duct 10. The first and second blowers 20 and 30, which sequentially blow air to separate foreign substances, and the air installed on the opposite side of the first and second blowers 20 and 30 and containing foreign substances separated from the aggregate 1 The first and second cyclone separators 40 and 50 that separate foreign substances from the air through centrifugal force, and the first and second blowers 20 and 30 without discharging the exhausted air of the first and second cyclone separators 40 and 50 to the outside. ), the first and second circulation ducts 60 and 70 for circulation to the inlet side, the first and second blowing ducts 80 and 90 connecting the first and second blowers 20 and 30 and the sorting duct 10, respectively. ), etc.

However, in the conventional wind power fluidized bed sorting device, when the aggregate 1 is input from the transfer conveyor 3 to the sorting duct 10, the dust or foreign matter of the aggregate 1 is blown vertically into the sorting duct 10 by the wind. The phenomenon of reverse flow to the outside of the sorting duct 10, that is, in the opposite direction of input, generates scattering dust, which requires a separate configuration to collect scattering dust as the environment is polluted, which requires a lot of cost. there is

In addition, since the conventional wind power fluidized bed sorting device has a configuration in which the aggregate 1 introduced into the sorting duct 10 from the conveying conveyor 3 falls to the sorting duct 10 at the conveying speed of the conveying conveyor 3 , Aggregate 1 falls quickly down the sorting duct 10, so even if wind is blown perpendicularly to the sorting duct 10, the contact time between the aggregate 1 and the wind is short, which reduces the effect of sorting foreign substances.

In addition, in the conventional wind power fluidized bed sorting device, when the pressure of the wind blown perpendicularly to the sorting duct 10 is high, the aggregate 1 does not fall along the sorting duct 10 and the first and second cyclone separators together with foreign substances (40, 50), there is a problem that the screening effect of foreign substances is lowered.

In addition, in the conventional wind power fluidized bed sorting device, as the first and second cyclone separators 40 and 50 for sorting foreign substances separated from the aggregate 1 are installed on opposite sides of each other, workers are frequently required to remove foreign substances or during maintenance. Since the first and second cyclone separators 40 and 50 separated by a predetermined distance have to be frequently moved, there is a problem in that efficiency of foreign matter removal and maintenance is lowered.

(Patent Document 0001) Registered Patent No. 10-2295856

Therefore, an object of the present invention is to increase the volume of the inlet duct formed between the sorting duct and the cyclone separator compared to the volume of the outlet part of the blowing duct formed between the blower and the sorting duct, so that the inlet part of the sorting duct into which aggregate is introduced A wind-powered fluidized bed sorting device capable of suppressing scattering dust by having a negative pressure compared to the inlet of the inlet duct so that the scattering dust generated at the inlet of the sorting duct when the aggregate is introduced quickly flows into the inlet of the inlet duct. is to provide

In addition, an object of the present invention is to have an input hopper connected to the inlet of the sorting duct and into which aggregate is introduced from the transfer conveyor has an upper and lower narrow structure, so that the aggregate falling into the sorting duct is temporarily stopped in the input hopper and then falls into the sorting duct It is to provide a wind power fluidized bed sorting device capable of improving the foreign matter sorting effect through a long contact time with wind blown vertically to the sorting duct through free fall rather than the speed of the transfer conveyor.

In addition, an object of the present invention is to increase the lower volume of the screening duct, which communicates with the outlet of the blowing duct and the inlet of the inlet duct, compared to the upper volume, so that the aggregate is introduced into the inlet of the inlet along with foreign substances by the pressure of the blown wind. It is to provide a wind-powered fluidized bed sorting device capable of minimizing the foreign matter sorting effect to be improved.

In addition, an object of the present invention is to remove foreign matter and improve maintenance efficiency by ensuring that the first and second cyclone separators, in which foreign matter separated from the aggregate are sorted, are configured together on one side rather than at a position facing each other Wind-powered fluidized bed sorting device that can improve efficiency is to provide

Meanwhile, the object of the present invention is not limited to the above-mentioned object, and other objects not mentioned above will be clearly understood by those skilled in the art from the description below.

According to the present invention, the sorting duct for providing a space for the foreign matter to be sorted out while the aggregate is falling; A first blower and a second blower installed at one side of the sorting duct to be spaced apart in the vertical direction and blowing wind to the aggregate falling in the sorting duct to separate foreign substances from the sorting duct; a first cyclone separator and a second cyclone separator installed on opposite sides of the first blower and the second blower and sorting foreign matter from the air containing the foreign matter separated from the aggregate through centrifugal force; a first circulation duct and a second circulation duct for circulating exhaust air from the first cyclone separator and the second cyclone separator to inlets of the first blower and the second blower without discharging it to the outside; a first blowing duct and a second blowing duct connecting the first blower and the second blower and the selection duct to blow wind in a direction perpendicular to the selection duct; and an inlet volume larger than the outlet volume of the first blowing duct and the second blowing duct constructed between the first and second cyclone separators from the sorting duct and between the first and second blowers and the sorting duct. There is provided a wind power fluidized bed separator comprising a first inlet duct and a second inlet duct configured to suppress scattering dust generation.

Here, the wind power fluidized bed sorting device is configured to be connected to the aggregate input portion of the sorting duct in an upper and lower narrow structure, and further includes an input hopper that allows the aggregate dropped from the conveyor conveyor to transfer the aggregate to fall into the sorting duct after being put in and temporarily stopped. It is preferable to include

In addition, the sorting duct includes a hopper coupling part communicating with the lower portion of the input hopper; A first communication part having one side communicated with the outlet of the first blowing duct and the other side communicating with the inlet of the first inlet duct in a state of being communicated with the lower part of the hopper coupling part; an extension part communicating with the lower part of the first communication part; a second communication part having one side in communication with the outlet of the second blowing duct and the other side in communication with the inlet of the second inlet duct in a state of being in communication with the lower part of the extension; and a dust collection unit communicating with the lower portion of the second communication unit to collect aggregates sorted and dropped along the hopper coupling unit, the first communication unit, the extension unit, and the second communication unit.

In addition, in the selection duct, the volumes of the lower part of the first communication part communicating with the extension and the lower part of the second communication part communicating with the dust collection unit communicate with the upper part of the first communication part communicating with the hopper coupling part and the second communication part communicating with the extension. It is desirable to have a relatively large volume compared to the volume of the top of the section.

Therefore, according to the present invention, the inlet volume of the inlet duct constructed between the sorting duct and the cyclone separator is increased compared to the volume of the outlet part of the blowing duct constructed between the blower and the sorting duct, so that the inlet part of the sorting duct into which the aggregate is injected is formed. By having a negative pressure compared to the inlet of the inlet duct, scattering dust generated at the inlet of the sorting duct when the aggregate is introduced can be rapidly introduced into the inlet of the inlet duct to suppress scattering dust.

In addition, the input hopper connected to the inlet of the sorting duct and into which aggregate is input from the transfer conveyor has an upper and lower structure, so that the aggregate falling into the sorting duct is temporarily stopped in the input hopper and then falls to the sorting duct, thereby increasing the speed of the transfer conveyor. It is possible to improve the foreign matter screening effect through a long contact time with the wind blown perpendicular to the screening duct through non-free fall.

In addition, by increasing the lower volume of the sorting duct, which communicates with the outlet of the blowing duct and the inlet of the inlet duct, compared to the upper volume, the inflow of aggregates together with foreign substances into the inlet of the inlet duct due to the pressure of the blowing wind is minimized to sort out foreign substances. effect can be improved.

In addition, the first and second cyclone separators for sorting out foreign substances separated from the aggregate may be configured together on one side instead of facing each other, so that foreign substance removal and maintenance efficiency may be improved.

On the other hand, the effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description of the claims.

1 and 2 are views showing a conventional wind power fluidized bed separator; and
3 to 6 are views showing a wind power fluidized bed separator according to a preferred embodiment of the present invention.

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

As shown in FIGS. 3 to 6, the wind power fluidized bed sorting device according to a preferred embodiment of the present invention includes a sorting duct 110 that provides a space for foreign substances to be sorted while the aggregate 1 falls, a sorting duct ( 110), the first blower 120 and the second blower 120 are installed to be spaced apart in the vertical direction on one side and blow wind to the aggregate 1 falling in the sorting duct 110 so that foreign substances are separated from the sorting duct 110. A first cyclone separator 140 installed on the opposite side of the blower 130, the first blower 120 and the second blower 130 and sorting foreign substances from the air containing foreign substances separated from the aggregate 1 through centrifugal force and the second cyclone separator 150, the first cyclone separator 140, and the exhaust air of the second cyclone separator 150 are circulated to the inlet side of the first blower 120 and the second blower 130 without discharging the air to the outside The first circulation duct 160, the second circulation duct 170, the first blower 120 and the second blower 130, and the selection duct 110 are connected to each other in a direction perpendicular to the selection duct 110. The inlet volume ( V3) is larger than the outlet volume V4 of the first blowing duct 180 and the second blowing duct 190, which are configured between the first blower 120 and the second blower 130 and the sorting duct 110. The first inlet duct 210, the second inlet duct 220, and the sorting duct 110, which are composed of a volume and suppress the generation of scattering dust by allowing the aggregate input portion of the sorting duct 110 to have a relatively negative pressure state. The aggregate (1) dropped from the transfer conveyor (not shown) that is configured to be connected to the aggregate input portion in an upper and lower narrow structure and transports the aggregate (1) is input and temporarily stopped, and then falls to the sorting duct (110). and an input hopper 230 for improving a sorting effect by increasing a contact time with wind blown from the blowing duct 180 and the second blowing duct 190.

The sorting duct 110 is a means for providing a space for foreign substances to be sorted out while the aggregate 1 transported by the transfer conveyor (not shown) falls, and the hopper coupling part communicating with the lower part of the input hopper 230 ( 111), a first communication portion having one side communicated with the outlet of the first blowing duct 180 and the other side communicated with the inlet portion of the first inlet duct 210 in a state of being communicated with the lower part of the hopper coupling part 111 112, an extension part 113 communicating with the lower part of the first communication part 112, and one side communicating with the outlet part of the second blowing duct 190 in a state of being communicated with the lower part of the extension part 113, and The second communication part 114 communicating with the other side of the inlet of the 2 inlet duct 220 and the lower part of the second communication part 114 communicating with the hopper coupling part 111, the first communication part 112, and extension It includes a dust collecting part 115, etc. in which the aggregate 1 sorted and dropped along the part 113 and the second communicating part 114 is collected.

Here, the selection duct 110 has a first communication between the outlet portions of the first blowing duct 180 and the second blowing duct 190 and the inlet portions of the first inlet duct 210 and the second inlet duct 220. The lower volume of the communication part 112 and the second communication part 114, that is, the lower part of the first communication part 112 communicating with the extension part 113 and the second communication part 114 communicating with the dust collecting part 115 The volume V1 of the lower part of the upper part of the first communication part 112 communicating with the hopper coupling part 111 and the upper part of the second communication part 114 communicating with the extension part 113 (V2) has a relatively large volume compared to

Accordingly, according to the sorting duct 110, the aggregate 1 is moved together with foreign substances by the pressure of the wind blown to the inlets of the first inlet duct 210 and the second inlet duct 220. It is possible to minimize the inflow of foreign matter into the inlet of the second communication unit 114 so as to improve the foreign matter screening effect.

On the other hand, a discharge conveyor (not shown) may be configured in the dust collection unit 115 so that the aggregate 1 from which foreign substances are sorted is discharged to the outside.

The first blower 120 and the second blower 130 are provided on one side of the first communication part 112 and the second communication part 114 of the sorting duct 110, respectively. It is installed to be spaced apart in the vertical direction through the blowing duct 190 and blows wind to the aggregate 1 falling in the sorting duct 110 to separate foreign substances from the sorting duct 110, a known configuration Since it may have a detailed description will be omitted.

Here, the first blower 120 and the second blower 130 may have a configuration in which the blowing pressure of a preset value is controlled based on the pressure measured through the pressure gauge, and the size of the aggregate 1 or foreign matter to be sorted Depending on the size or weight of the set value may be controlled step by step.

The first cyclone separator 140 and the second cyclone separator 150 are connected to the first communication part 112 of the sorting duct 110 corresponding to the opposite side of the first blower 120 and the second blower 130. It is installed on the other side of the second communication part 114 through the first inlet duct 210 and the second inlet duct 220, respectively, and means for separating foreign substances from the air containing foreign substances separated from the aggregate 1 through centrifugal force. As a, foreign matter and dust are removed by centrifugal force from the air containing foreign matter separated from the aggregate 1, and since it may have a known configuration, a detailed description thereof will be omitted.

Meanwhile, in the first cyclone separator 140 and the second cyclone separator 150, as the air entering through the first inlet duct 210 and the second inlet duct 220 spirals downward, foreign substances and dust are removed. It moves towards the wall by centrifugal force and then is discharged to the lower part. The air from which foreign substances and dust are removed is discharged to the first circulation duct 160 and the second circulation duct 170, respectively, by spiraling upward after completing the spiral motion.

Here, in the first cyclone separator 140 and the second cyclone separator 150, a foreign matter discharge pipe (not shown) is installed at the lower part, and a collection box (not shown) for collecting foreign matter may be installed at the lower part, It may be accommodated in a casing (not shown) for protecting equipment from the outside and blocking dust outflow.

The first circulation duct 160 and the second circulation duct 170 do not discharge the exhaust air of the first cyclone separator 140 and the second cyclone separator 150 to the outside, and the first blower 120 and the second circulation duct 120 As a means for circulating to the inlet side of the blower 130, one end is connected to the first cyclone separator 140 and the second cyclone separator 150, and the other end is connected to the first blower 120 and the second blower 130. Connected.

The first blower duct 180 and the second blower duct 190 are the first blower 120 and the second blower 130 and the first communication part 112 and the second communication part of the selection duct 110 ( 114) is connected to each other so that wind is blown in a direction perpendicular to the sorting duct 110, so that air containing foreign substances passes through the first inlet duct 210 and the second inlet duct 220 to the first cyclone separator ( 140) and the second cyclone separator 150, as a means for inflow, an inspection window for checking the inside with the naked eye and an air volume control damper for controlling the air volume are installed so that the air volume can be adjusted while checking the movement of foreign substances, and vibration can be reduced. A vibrator that generates a vibrator may be installed to prevent or separate foreign matter from being attached to the inner wall surface, and a magnet may be configured to separate metal from foreign matter to separate the metal.

The first inlet duct 210 and the second inlet duct 220 are connected to the first cyclone separator 140 and the second inlet duct 220 from the other side of the first communication part 112 and the second communication part 114 of the selection duct 110. It is configured between the 2 cyclones separators 150 so that air containing foreign substances flows into the first cyclone separator 140 and the second cyclone separator 150 from the first blowing duct 180 and the second blowing duct 190. As a means for doing so, an air volume control damper may be installed to control the volume of air introduced into the first cyclone separator 140 and the second cyclone separator 150.

Here, the first inlet duct 210 and the second inlet duct 220 have an inlet volume V3 communicating with the other side of the first communication part 112 and the second communication part 114 of the sorting duct 110. Compared to the outlet volumes V4 of the first blowing duct 180 and the second blowing duct 190, which are formed on one side of the first communication part 112 and the second communication part 114 of the selection duct 110 have a large volume

Accordingly, according to the first inlet duct 210 and the second inlet duct 220, the aggregate input part of the sorting duct 110, that is, the inside of the hopper coupling part 111 coupled to the input hopper 230 described later. Since the space has a relatively negative pressure state compared to the first inlet duct 210 and the second inlet duct 220, when the aggregate 1 is put into the sorting duct 110 from the transfer conveyor (not shown), the aggregate 1 It is possible to suppress the generation of scattering dust by preventing dust or foreign matter from flowing backward to the outside of the sorting duct 110, that is, in the opposite direction of the input direction, by the wind blown perpendicularly to the sorting duct 110.

The input hopper 230 is configured to be connected to the hopper coupling part 111 corresponding to the aggregate input portion of the sorting duct 110 so that the aggregate 1 dropped from the transfer conveyor (not shown) for transporting the aggregate 1 As a means to fall to the selection duct 110, it may have a volume of the upper and lower sides.

Accordingly, according to the input hopper 230, after the aggregate 1 dropped from the transfer conveyor (not shown) for transporting the aggregate 1 is input, it is dropped to the sorting duct 110 in a temporarily stopped state, and the first blowing duct The contact time with the wind blown from the 180 and the second blowing duct 190 can be increased and the screening effect can be improved.

On the other hand, in the present invention, a time difference opening and closing unit for minimizing the loss of internal pressure when foreign substances are discharged is installed in the foreign matter discharge pipes (unsigned) connected to the lower portions of the first cyclone separator 140 and the second cyclone separator 150. (240) may be additionally installed.

Here, the time difference opening/closing unit 240 includes a first flap 241, a second flap 242, a first flap 241, and a second flap 242 installed to be spaced apart in the vertical direction of the foreign matter discharge pipe (unsigned). ) Open the first flap 241 in the state where the first opening and closing unit 243 and the second opening and closing unit 244 and the first flap 241 and the second flap 242 are closed, respectively, to open and close the and a controller that controls the first opening/closing unit 243 and the second opening/closing unit 244 to close the first flap 241 and open the second flap 242 after a certain amount of time.

Accordingly, according to the time difference opening/closing unit 240, when the first flap 241 is opened while both the first flap 241 and the second flap 242 are closed, foreign substances are discharged to the position of the second flap 242. However, it is blocked by the second flap 242 and is not discharged to the outside, so that the internal pressure of the time difference opening/closing unit 240 is not lost, and after a preset time, the first flap 241 is closed and the second flap 241 is closed. The flaps 242 can be opened to allow the discharge of foreign matter without loss of pressure.

Hereinafter, the operation of the wind power fluidized bed separator having the above configuration will be described.

First, the aggregate 1 transferred from the transfer conveyor (not shown) is put into the sorting duct 110 through the input hopper 230.

Thereafter, the aggregate 1 falling down the selection duct 110 by the wind blown to the selection duct 110 from the first blower 120 and the second blower 130 installed at a predetermined interval in the selection duct 110 After the foreign substances contained in are introduced into the first cyclone separator 140 and the second cyclone separator 150, the foreign substances are sorted out through centrifugal force, and after the foreign substances are sorted out, the air is returned to the first blower 120 and the second blower The process supplied to 130 is repeated.

Thereafter, the aggregate 1 that has fallen to the lower portion of the sorting duct 110 is discharged to the outside through a discharge conveyor (not shown).

Here, the volume V3 of the inlet portion of the first inlet duct 210 and the second inlet duct 220 constructed between the sorting duct 110 and the first cyclone separator 140 and the second cyclone separator 150 is The first blower 120 and the second blower 130 and the selection duct 110 constituted between the first blower duct 180 and the second blower duct 190 have a larger size than the outlet portion volume V4 Therefore, the inlet portion of the sorting duct 110 into which the aggregate 1 is injected has a negative pressure state compared to the inlets of the first inlet duct 210 and the second inlet duct 220, and the aggregate 1 is injected. Scattering dust generated at the inlet of the screening duct 110 is quickly introduced into the inlets of the first inlet duct 210 and the second inlet duct 220, so scattering dust can be suppressed.

In addition, the input hopper 230 connected to the inlet of the sorting duct 110 and into which the aggregate 1 is input from the transfer conveyor 3 has an upper and lower structure, and thus, the aggregate falling into the sorting duct 110 After (1) is temporarily stopped in the input hopper 230, it falls into the sorting duct 110 and has a long relationship with the wind blown perpendicular to the sorting duct 110 through free fall rather than the speed of the transfer conveyor (not shown). The foreign matter screening effect can be improved through the contact time.

In addition, the lower volume of the selection duct 110 communicating with the outlets of the first blowing duct 180 and the second blowing duct 190 and the inlets of the first inlet duct 210 and the second inlet duct 220 ( V1) has a larger size than the upper volume V2, and thus, the flow of the aggregate 1 together with foreign substances into the inlet of the inlet duct is suppressed by the pressure of the wind blown from the blowing duct to the inlet duct, thereby preventing foreign substances from entering the inlet. The screening effect can be improved.

In addition, the first cyclone separator 140 and the second cyclone separator 150, in which foreign substances separated from the aggregate 1 are sorted, are configured together on one side instead of opposite positions to improve foreign matter removal and maintenance efficiency. can

Although specific embodiments have been described in the present invention described above, various modifications can be made without departing from the scope of the present invention. Therefore, the scope of the invention should not be determined by the described embodiments, but by the equality of the claims and claims.

Claims (4)

A sorting duct 110 providing a space for sorting out foreign substances while the aggregate 1 falls; A first blower 120 installed at one side of the sorting duct 110 to be spaced apart in the vertical direction and blowing wind to the aggregate 1 falling in the sorting duct 110 so that foreign substances are separated from the sorting duct 110 and a second blower 130; A first cyclone separator 140 and a second cyclone separator installed on opposite sides of the first blower 120 and the second blower 130 and separating foreign substances from the air containing foreign substances separated from the aggregate 1 through centrifugal force. (150); A first circulation duct 160 for circulating exhaust air from the first cyclone separator 140 and the second cyclone separator 150 to the inlet side of the first blower 120 and the second blower 130 without discharging the air to the outside and a second circulation duct 170; A first blowing duct 180 and a second blowing duct connecting the first blower 120 and the second blower 130 and the sorting duct 110 to blow wind in a direction perpendicular to the sorting duct 110 (190); It is configured between the first cyclone separator 140 and the second cyclone separator 150 from the selection duct 110, and the inlet volume V3 is the first blower 120 and the second blower 130 and the selection duct 110 The first inlet duct 210 and the second inlet duct 210, which have a larger volume than the outlet volumes V4 of the first blowing duct 180 and the second blowing duct 190, and suppress the generation of scattering dust. (220); And the sorting duct (110) after the aggregate (1) dropped from the transfer conveyor (not shown) connected to the aggregate input portion of the sorting duct (110) in an upper and lower structure and transporting the aggregate (1) is put in and temporarily stopped. ) Including an input hopper 230 to be dropped into,
The selection duct 110,
Hopper coupling part 111 communicating with the lower portion of the input hopper 230; A first communication part 112 having one side in communication with the outlet of the first blowing duct 180 and the other in communication with the inlet of the first inlet duct 210 in a state of being in communication with the lower part of the hopper coupling part 111 ; an extension part 113 communicating with the lower part of the first communication part 112; A second communication portion 114 having one side communicated with the outlet of the second blowing duct 190 and the other side communicated with the inlet portion of the second inlet duct 220 in a state of being communicated with the lower portion of the extension 113; And aggregate 1 communicated with the lower part of the second communication part 114 and sorted and dropped along the hopper coupling part 111, the first communication part 112, the extension part 113 and the second communication part 114 ) includes a dust collection unit 115 in which dust is collected,
The volume V1 of the lower part of the first communication part 112 communicating with the extension part 113 and the lower part of the second communication part 114 communicating with the dust collecting part 115 communicates with the hopper coupling part 111, respectively. The wind power fluidized bed separator, characterized in that it has a relatively large volume compared to the volume (V2) of the upper part of the second communication part 114 communicating with the upper part of the first communication part 112 and the extension part 113. delete delete delete

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