KR102508360B1 - Cyclone falling objects disposal device - Google Patents

Abstract

The present invention relates to a cyclone falling object disposal device, and more specifically, to a cyclone falling object disposal device which solves the problem of exceeding disposal capacity caused by a rapid increase in falling objects when sorted landfill waste to be disposed is finally sorted by cyclone, and at the same time, reduces time due to the reprocessing of the falling objects. In addition, the cyclone falling object disposal device can improve the efficiency of fine powder separation, to enable disposal in a separated manner without air pulsing, and can perform large-capacity disposal, to shorten disposal time to contribute to productivity improvement.

Description

Cyclone falling objects disposal device}

The present invention relates to a cyclone falling object processing device, and more particularly, solves the problem of exceeding the handling capacity caused by the rapid increase of falling objects when the sorted landfill waste to be treated is finally sorted by a cyclone, and at the same time It is an improved cyclone falling object treatment device that reduces time waste due to reprocessing, improves the separation efficiency of fine particles, enables separation processing without air pulsing, and contributes to productivity improvement by shortening processing time by enabling large-capacity processing. it's about

In general, garbage landfills (sanitary, unsanitary) are usually located near large cities in consideration of the transport efficiency of garbage. In particular, in the case of unsanitary garbage landfills, garbage is randomly buried, so for the utilization of soil and incombustibles or incineration of combustibles A sorting process by type is inevitable.

In particular, the excavated waste is mixed with incombustible materials that can be recycled but difficult to burn, such as soil and concrete lumps, bricks, and stones, as well as combustible materials that are difficult to recycle and must be incinerated, such as vinyl cloth or wood chips. There is a need for a sorting device for accurately sorting the entire waste by type.

As a sorting device related to this, there is a cyclone type sorting device that sucks wastes of 30 mm or more that are lifted and transported on a conveyor or disk screen and sorts them into combustibles and non-combustibles or combustibles and incombustibles by the difference in specific gravity.

However, in the conventional cyclone-type sorting device, the sorting efficiency is extremely low due to the fact that the perforated net for the sorting function is easily clogged in the process of separating the fine particles, resulting in a drop in suction pressure.

In addition, while falling in a pivoting manner, there is a disadvantage in that the efficiency of fine powder separation rapidly decreases while falling vertically due to the inhibition of suction pressure in the interior where the fine powder separation is to occur.

In addition, there is a disadvantage in that time and money are wasted because if a network clogging phenomenon occurs due to differentiation, it is necessary to set up facilities to solve the problem.

A bag filter can be used as one way to solve this problem, but this is not only difficult and difficult to maintain and repair, but also causes the problem of dust, vinyl, garbage, etc. polluting the surroundings as the flying products generated during air pulsing spread widely. It was serious.

In particular, since the separated and fallen objects are stored in the collection box, the capacity is small, so the operation of the facility must be stopped every time, so the treatment efficiency is rapidly reduced.

Domestic Patent No. 10-1268565 (2013.05.22.) Cyclone Dust Collector

The present invention was created in order to solve these problems in view of the various problems in the prior art as described above, and solves the problem of exceeding the processing capacity caused by the rapid increase in falling objects when the sorted landfill waste to be treated is finally sorted with a cyclone. At the same time, it is improved to reduce time waste due to reprocessing of falling objects, improve the separation efficiency of fine particles, enable separation processing without air pulsing, and reduce processing time by reducing processing time by contributing to productivity improvement. Its main purpose is to provide a cyclone falling object handling device.

The present invention is a means for achieving the above object, a cyclone (200); A suction blower 220 installed at the top of the cyclone 200 to suck in the crushed materials and then eject them radially into the cyclone 200; One end penetrates the upper end of the cyclone 200 so as not to interfere with the suction blower 220 and is disposed in the inner center, and the other end extends to the storage table 300 to accommodate the separated fine powder Separation pipe 230 ; A suction blower 310 installed on a portion of the length of the singi differential sorting pipe 230; A casing 250 connected to the lower end of the cyclone 200 and having a screw feeder 260 built into the casing 250 for feeding and compressing the falling objects;

At this time, one end of the differential sorting pipe 230 is disposed at a position extending downward from the upper end of the cyclone 200 to 1/2 of the upper length of the entire cyclone 200; A cylindrical separator 232 is detachably screwed to the end of the separator tube 230, and a plurality of suction holes 234 are formed in the circumferential direction in the separator 232; An outlet 252 is formed at the other end of the casing 250, and a sealed door 280 is installed on an outer surface of the outlet 252, and the sealed door 280 is a door cylinder controlled by a controller. It is also characterized by being configured to open and close the outlet 252 while moving by 282.

According to the present invention, when the sorted landfill waste to be treated is finally sorted by a cyclone, the problem of exceeding the processing capacity caused by the rapid increase of falling objects is solved, and at the same time, time waste due to reprocessing of the falling objects is reduced, and differential separation Efficiency is improved, so separation processing is possible without air pulsing, and large-capacity processing is possible, so that improved effects can be obtained to contribute to productivity improvement by shortening processing time.

1 is a schematic configuration diagram of a cyclone falling object treatment device according to the present invention.
Figure 2 is an exemplary perspective view showing the main parts of the cyclone falling object treatment device according to the present invention.
3 is an exemplary side view of FIG. 2 .
4 is an exemplary view of a storage stand constituting the cyclone falling object treatment device according to the present invention.

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

Prior to the description of the present invention, the following specific structural or functional descriptions are only exemplified for the purpose of explaining embodiments according to the concept of the present invention, and embodiments according to the concept of the present invention may be implemented in various forms, It should not be construed as limited to the embodiments described herein.

As shown in FIGS. 1 to 3 , the cyclone falling object treatment device according to the present invention includes a cyclone 200 .

The cyclones 200 are fixed on the installation frame 210, and a plurality, preferably four, are configured to form a set to enable large-capacity processing.

In addition, a suction blower 220 is installed at the upper end of the cyclone 200, and a fine separator tube 230 is assembled and installed by penetrating the upper end of the cyclone 200 at a position that does not interfere with the suction blower 220. do.

At this time, the suction blower 220 sucks in 30 mm or more crushed sorted material and then sprays and discharges it radially from the inside of the upper end of the cyclone 200 so that the discharged crushed sorted material rotates in the radial direction and descends.

In this process, as the pulverized sorted materials collide, the fine particles that have not yet been separated are completely separated, and among them, the heavy particles fall down along the inner wall surface, and the light particles ride the fine separator tube 230 provided in the center and are separated. It is discharged out of the clone 200.

Here, one end of the fine separator tube 230 is located inside the cyclone 200, and in particular, the entire cyclone 200 is moved from the upper end of the cyclone 200 to increase the separation efficiency while facilitating the suction of the fine particles. It should be placed in a position extending downward by 1/2 the length of the top.

Otherwise, if it is at a higher position, a problem arises in that some of the crushed materials are sucked out without being separated into fine powder by the suction pressure sucked through the fine separator tube 230.

In addition, when located at 1/2 length, the crushed sorted materials introduced are gradually dropped while rotating in the radial direction. won't go out

In addition, a cylindrical separator 232 is detachably screwed to the end of the separator tube 230, and a plurality of suction holes 234 are formed in the circumferential direction in the separator tube 232. .

This lowers the separation efficiency due to a lot of resistance in which the falling fine powder is turned 180° and sucked up through the end hole of the fine separator tube 230. This is because the separation efficiency of the fine powder is very excellent because the separated fine powder can be sucked in directly through the suction hole 234 after gradually reducing the radius while turning.

In particular, the end of the fine separator pipe 230 exposed to the cyclone 200 and the fine separator inhaler 232 continue to collide with and rub against the fine powders and crushed materials, so that impact resistance, scratch resistance, durability, Corrosion resistance must be very good.

To this end, in the present invention, a protective coating layer is formed on the end of the fine separation tube 230 exposed to the cyclone 200 and the outer surface of the fine separation inhaler 232.

At this time, the protective coating layer is based on 100 parts by weight of polycarbonate resin, 20 parts by weight of Teflon, 15 parts by weight of diphenyldimethoxysilane, 20 parts by weight of methyl 2-methylprop-2-enoate, 5 parts by weight of zinc oxide, calcium It is formed by spray coating a mixture of 10 parts by weight of sulfoaluminate and 15 parts by weight of chromium oxide.

Here, Teflon is added to increase the wear resistance of the protective coating layer, and diphenyldimethoxysilane is added to enhance surface strength, increase waterproofness, and improve wear resistance and durability.

In addition, methyl 2-methylprop-2-enoate (CH ₂ C (CH ₃ ) COOCH ₃ ) is added to increase the bonding strength at the bonding center and increase the wear resistance on the outer surface when the compound is combined, and zinc oxide It is added to promote curing and increase the binding force of the bond during curing, and calcium sulfoaluminate is added to suppress shrinkage and prevent cracking.

In addition, chromium oxide is added to prolong life while inhibiting corrosion of the protective coating layer and increasing hardness to suppress abrasion.

Meanwhile, a cylindrical casing 250 bound by a 'U' shaped band 240 is further provided at the lower end of the cyclone 200, and a screw feeder 260 is built into the casing 250.

In addition, one end of the screw feeder 260 is exposed to the outside of the casing 250, and in that state, the driven sprocket 262 is key-fixed to form an integral body. ) Is provided, the drive sprocket 272 is connected to and fixed to the screw driving motor 270 and configured to be rotatably driven, the screw driving motor 270 is fixed on the installation frame 210 through a bracket, , The drive sprocket 272 and the driven sprocket 262 are assembled to enable power transmission by a drive chain 274.

At this time, the screw driving motor 270 is driven and controlled by a controller.

In particular, a discharge port 252 is formed at the other end of the casing 250, and a sealed door 280 is installed on an outer surface of the discharge port 252, and the sealed door 280 is controlled by a controller. The outlet 252 is opened and closed while being moved by the door cylinder 282 .

In this configuration, since the falling objects fall in a sufficiently compressed state so as to be conveniently used as solid fuel by the screw feeder 260, the handling efficiency of the falling objects is also improved.

In addition, the other end of the differential separator tube 230 extends to the upper end of the storage stand 300, and a suction blower 310 driven and controlled by a controller is installed on a part of the length to generate suction force through the differential separator tube 230. will make

Also, as shown in the example of FIG. 4 , the storage table 300 has a built-in load cell to measure the weight of stored objects, so that the storage box 320 can be replaced after always storing a certain amount.

In particular, a storage frame 330 in the shape of a square frame is provided on all sides of the storage table 300, a plurality of hangers 332 are further installed in the storage frame 330, and the storage table 300 has the A hook 334 hooked to the hook 332 may be further provided.

In addition, the storage table 300 is a structure having a flexible spout 336 with a narrow entrance at the top, and a flange flap 231 sliding up and down is formed at the other end of the fine separator tube 230, and the spout After the 336 is inserted into the lower end of the differential sorting tube 230 and the flange flap 231 is pressed down in a state where the flange flap 231 is folded once outward, the spout 336 is naturally fixed while engaging up and down as shown.

That is, since the top of the flange flap 231 is always made to receive downward force by the spring 233, when inserting the spout 336, slightly push up the flange flap 231 and then insert the spout 336. When the flange flap 231 is placed in a state of being laid outward once, the flange flap 231 is pushed down by the elastic reaction force of the spring 233 and completely bites the spout 336.

Thus, the usability is increased.

200: cyclone 210: installation frame
220: suction blower 230: fine separator tube
240: U-shaped band 250: casing
260: screw feeder 270: screw driving motor
280: sealed door 300: storage stand

Claims (2)

Cyclone (200); A suction blower 220 installed at the top of the cyclone 200 to suck in the crushed materials and then eject them radially into the cyclone 200; One end penetrates the upper end of the cyclone 200 so as not to interfere with the suction blower 220 and is disposed in the inner center, and the other end extends to the storage table 300 to accommodate the separated fine powder Separation pipe 230 ; A suction blower 310 installed on a portion of the length of the singi differential sorting pipe 230; A casing 250 connected to the lower end of the cyclone 200 and having a screw feeder 260 built into the casing 250 for feeding and compressing the falling objects;
One end of the differential sorting tube 230 is disposed at a position extending downward from the upper end of the cyclone 200 to 1/2 of the upper length of the entire cyclone 200; A cylindrical separator 232 is detachably screwed to the end of the separator tube 230, and a plurality of suction holes 234 are formed in the circumferential direction in the separator 232; An outlet 252 is formed at the other end of the casing 250, and a sealed door 280 is installed on an outer surface of the outlet 252, and the sealed door 280 is a door cylinder controlled by a controller. configured to open and close the outlet 252 while moving by 282;
A protective coating layer is formed on the end of the differential separation tube 230 exposed to the cyclone 200 and the outer surface of the differential separator 232,
The protective coating layer is based on 100 parts by weight of polycarbonate resin, 20 parts by weight of Teflon, 15 parts by weight of diphenyldimethoxysilane, 20 parts by weight of methyl 2-methylprop-2-enoate, 5 parts by weight of zinc oxide, calcium sulfoaluminum It is formed by spray coating a mixture of 10 parts by weight of nate and 15 parts by weight of chromium oxide;
The storage table 300 is a structure having a flexible spout 336 with a narrow entrance at the top, and square frame-shaped storage frames 330 are provided on all sides of the storage table 300, and the storage frame 330 has a number of The hanger 332 is further installed, and the holder 300 is further provided with a hook 334 caught on the hanger 332;
A flange flap 231 that slides up and down is formed at the other end of the differential separator tube 230, a spring 233 is provided on the top of the flange flap 231, and the spout 336 is attached to the differential separator tube ( 230) and then press down on the flange flap 231 in a folded outward state once so that the spout 336 is engaged and fixed up and down. delete

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