KR20230000031A - Dust collection system - Google Patents

Abstract

The present invention provides a dust collection system. A dust collection system of the present invention comprises: a horizontal cyclone dust collector which extends in a horizontal direction and primarily collects dust while the incoming air rotates around the horizontal direction; a bag-filter dust collector which includes a plurality of bag filters inside a main body and an inflow port connected to a discharge pipe of the horizontal cyclone dust collector at one upper portion of the main body so as to enable the air, from which dust has been primarily collected, flowing from the horizontal cyclone dust collector to form a downward airflow such that dust is secondarily collected by the bag filters; and a dust exhaust means which is disposed above the bag filters inside the main body to exhaust dust from the bag filters. According to the configuration of the dust collection system, the lifespan of the bag filters may be extended while improving the utilization of an installation space and dust-collecting efficiency.

Description

Dust collection system {DUST COLLECTION SYSTEM}

The present invention relates to a dust collection system, and more particularly, to a dust collection system for improving dust collection efficiency by using a horizontal cyclone dust collector and a bag filter dust collector.

In general, dust collection systems are used to remove solid or liquid particles such as dust contained in flue gas generated from power plants, steel mills, boilers, waste incineration processes, metal melting, smelting, heat treatment facilities, petroleum refining, petrochemical manufacturing processes, etc. It is a system.

These dust collection systems are mainly divided into electric precipitators and filter dust collectors. Here, in the filter dust collector, the dust in the exhaust gas is collected through a bag filter in the middle while the exhaust gas is generally introduced into the lower part of the filter dust collection chamber and flows upward, and then the dust in the exhaust gas is collected. emits Here, depending on the dust collecting environment, if there is dust or sparks of large particles among the exhaust gas flowing into the filter, damage such as puncture may occur in the bag filter in the filter when dust collection is performed without a separate pretreatment device. In addition, since the dedusting device that exhausts the bag filter exhausts the bag filter in the direction from the top of the bag filter toward the bag filter, that is, in the downward direction opposite to the upward flow of the exhaust gas, the collected dust is the dust contained in the hopper at the bottom of the filter bag filter. Re-entrainment and re-attachment of dust falling from the bag filter may occur.

Republic of Korea Patent Publication No. 10-2021-0025418 (2021.03.09)

An object of the present invention is to provide a dust collection system that improves installation space utilization and dust collection efficiency and extends the lifespan of a bag filter.

In order to achieve the above object, according to an embodiment of the present invention, a horizontal cyclone dust collector that extends in the horizontal direction and primarily collects dust while the incoming air rotates and flows around the horizontal direction; A plurality of bag filters are disposed inside the main body, and an inlet connected to the discharge pipe of the horizontal cyclone dust collector is formed on an upper part of one side of the main body so that the primarily collected air flowing in from the horizontal cyclone dust collector forms a downward airflow. , Bag filter dust collector that is secondary dust collected by the bag filter; and an exhaustion means disposed above the bag filter inside the main body to exhaust the bag filter.

According to the configuration of the dust collection system according to an embodiment of the present invention, the horizontal cyclone dust collector is connected to the bag filter dust collector in the horizontal direction, so that there is little need for additional installation space, and large particles of dust or sparks in the air are removed from the bag. Since it is pre-filtered through a horizontal cyclone dust collector before it enters the filter dust collector, it is possible to effectively prevent damage such as puncture of the bag filter from occurring, prolonging the life of the bag filter, and furthermore, it is possible to operate an economical dust collection system. .

In addition, according to the configuration of the dust collection system according to the embodiment of the present invention, the inlet of the bag filter dust collector is formed on the upper part of the bag filter dust collector, so that the air introduced from the inlet of the bag filter dust collector flows downward to the upper side of the bag filter. By matching the dedusting direction of the dedusting means and the direction in which the dust falls, re-dispersion of the dust collected at the bottom of the bag filter dust collector and re-attachment of the dust falling from the bag filter can be effectively prevented, thereby improving the dust collection efficiency.

In addition, according to the configuration of the dust collection system according to an embodiment of the present invention, a rocket-shaped nozzle capable of injecting compressed air at a high flow rate with a small pressure by inducing the inflow of ambient air using the Venturi principle through a rocket-shaped nozzle It can be used to improve the degassing efficiency.

1 is a structural schematic diagram of a dust collection system according to an embodiment of the present invention.
2 is a structural schematic diagram of a dust collection system equipped with a conveyor belt according to an embodiment of the present invention.
3 is a structural schematic diagram of a dust collection system equipped with a dust box according to another embodiment of the present invention.
Figure 4 is a partial structural schematic diagram showing the dedusting process of the bag filter using the dedusting means of the dust collecting system according to an embodiment of the present invention.

Hereinafter, it will be described in detail through exemplary drawings of the present invention. Note that in adding reference numerals to components of each drawing, the same components have the same reference numerals as much as possible, even if they are displayed on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

In addition, throughout the specification, 'including' a certain element means that other elements may be further included, not excluding other elements unless otherwise stated.

In the prior art, the dust collector generally discharges dust-collected air after dust in the air is collected through a bag filter in the middle while air is introduced into the lower part of the dust-collecting chamber and flows upward. Here, depending on the dust collecting environment, if there is dust or sparks of large particles among the exhaust gas flowing into the filter, damage such as puncture may occur in the bag filter in the filter when dust collection is performed without a separate pretreatment device. In addition, since the dedusting device that exhausts the bag filter exhausts the bag filter in the direction from the top of the bag filter toward the bag filter, that is, in the downward direction opposite to the upward flow of the exhaust gas, the collected dust is the dust contained in the hopper at the bottom of the filter bag filter. Re-entrainment and re-attachment of dust falling from the bag filter may occur.

In order to solve these problems, the present invention provides a dust collection system that improves installation space utilization and dust collection efficiency and extends the lifespan of a bag filter.

Below, the dust collecting system of the present invention will be described in connection with the drawings.

1 is a structural schematic diagram of a dust collection system according to an embodiment of the present invention.

Referring to FIG. 1, the dust collection system according to an embodiment of the present invention includes a horizontal cyclone dust collector 10 that primarily collects incoming air, and secondarily collects the air primarily collected by the horizontal cyclone dust collector 10. It includes a bag filter dust collector 20 and a dedusting means 30 for exhausting the bag filter 22 of the bag filter dust collector 20.

The horizontal cyclone dust collector 10 extends in the horizontal direction, and collects primary dust while the incoming air rotates and flows around the horizontal direction. Here, the horizontal cyclone dust collector 10 is connected to the bag filter dust collector 20 in the horizontal direction, so that large particles of dust or sparks in the air flowing in are removed from the bag filter dust collector 20 without the need for additional installation space. Since it is pre-filtered through the horizontal cyclone dust collector 10 before inflow, it is possible to effectively prevent damage such as puncture of the bag filter 22 from occurring, thereby extending the lifespan of the bag filter 22, and furthermore, economical dust collection. system can be operated.

The horizontal cyclone dust collector 10 may be configured in various forms, and as a specific example, the horizontal cyclone dust collector 10 includes an inlet pipe 11, an expansion pipe 12, and an outlet pipe ( 13); A swirler 14 disposed inside the expansion pipe 12; and a first hopper unit 15 disposed under the expansion pipe 12 adjacent to the discharge pipe 13. Here, the expansion pipe 12 is formed larger than the hole diameter of the inlet pipe 11 so that the swirler 14 is accommodated and the air introduced into the inlet pipe 11 is centrifugally driven by the rotational drive of the swirler 14. Allow sufficient rotational flow. The swirler 14 is disposed inside the expansion pipe 12 to rotate the air introduced from the inlet pipe 11 toward the discharge pipe 13 in a horizontal direction. In other words, the air introduced into the inlet pipe 11 of the horizontal cyclone dust collector 10 is rotated by the swirler 14, and dust or sparks of large particles are scattered on the outer wall of the horizontal cyclone dust collector 10 by the centrifugal force. While rotating and moving forward along the horizontal direction, they gather in the first hopper unit 15.

In one embodiment, the connection portion A between the inlet pipe 11 and the extension pipe 12 may be formed in a tapered shape so as to realize a smooth flow of air to the extension pipe 12 and an effect of increasing the flow rate. .

In the bag filter dust collector 20, a plurality of bag filters 22 are disposed inside the main body 21, and the primary dust collected air flowing from the horizontal cyclone dust collector 10 forms a downward airflow of the main body 21. An inlet 23 connected to the discharge pipe 13 of the horizontal cyclone dust collector 10 is formed on the upper side of one side, and secondary dust is collected by the bag filter 22. Here, a partition wall 28 is formed on the upper surface of the bag filter 22, and the dust extraction unit 30 may be disposed above the partition wall 28. In addition, a guide member for guiding the primarily collected air introduced from the inlet 23 of the bag filter dust collector 20 to flow downward may be installed inside the main body 21 . For example, a guide plate spaced apart from the partition wall 28 and located below the inlet 23 and passing through the bag filter 22 may be formed inside the main body 21, and also, the upper end of the bag filter 22 may be formed. A blocking wall may be formed around the periphery, so that the primary dust-collected air flowing in from the inlet 23 is not directly discharged through the upper end of the bag filter 22, but the main body 21 through the structure of the guide plate and the blocking wall. It is possible to implement a guide effect so that secondary dust can be collected by flowing downward from the inside.

The dust removal unit 30 is disposed above the bag filter 22 inside the main body 21 of the bag filter dust collector 20 to exhaust the bag filter 22 .

According to the configuration of the bag filter dust collector 20, the inlet 23 is formed on the upper part of the bag filter dust collector 20, so that the air introduced from the inlet 23 of the bag filter dust collector 20 flows downward, By matching the dedusting direction of the dedusting means 30 disposed above the bag filter 22 and the direction in which dust falls, the dust collected in the lower part of the bag filter dust collector 20 is re-dispersed and falls from the bag filter 22. Reattachment of dust can be effectively prevented to improve dust collection efficiency. Specifically, the initial flow direction of the primary dust-collected air introduced from the inlet 23 located on the upper side of the bag filter dust collector 20 is directed downward, but passes through the bag filter 22 in the process of flowing downward to the main body. It moves to the upper part of (21). At this time, since dust and contaminants of a certain size or more do not pass through the bag filter 22 and are attached, clean air is discharged. Therefore, the dust collection system according to an embodiment of the present invention installs the horizontal cyclone dust collector 10 and the bag filter dust collector 20 to improve installation space utilization and dust collection efficiency and extend the lifespan of the bag filter 22 effect can be realized.

Here, the bag filter 22 may be made of polyethylene (PE), NOMEX, or Teflon, and may be configured in a cylindrical shape, a pleated bag, or an expanded bag filter shape, but is not limited thereto. In one embodiment, when the bag filter 22 is configured in a cylindrical shape, pleated bag, bag filter extension shape, etc., the bag filter 22 may be implemented as a long bag filter having a length of 10 m or more, but is limited thereto Rather, it can be configured in various lengths and shapes according to the actual application environment and needs.

The main body 21 may include an installation part 24 located on the upper part and a second hopper part 25 located on the lower part. The installation part 24 is formed in a cylindrical shape on the upper part of the main body 21, and a plurality of bag filters 22 may be disposed extending in a height direction in a cylindrical shape therein. Here, the dedusting means 30 is disposed above the bag filter 22 in the installation part 24 to de-dust the bag filter 22 . The second hopper part 25 is formed in a conical shape at the lower part of the main body 21 and can collect falling dust.

Figure 3 is a structural schematic diagram of a dust collection system equipped with a dust box according to another embodiment of the present invention, Figure 4 is a bag filter 22 using the dust extraction means 30 of the dust collection system according to an embodiment of the present invention It is a partial structural schematic diagram showing the exhaustion process. As shown in FIGS. 3 and 4, the dust collected through the first and second rotary valves 40a and 40b below the horizontal cyclone dust collector 10 and the bag filter dust collector 20, respectively. A conveyor belt 50 or first and second dust boxes 60a and 60b discharging the dust may be disposed. Specifically, referring to FIG. 3, the horizontal type cyclone dust collector 10 has a first rotary valve 40a installed at the lower end of the first hopper part 15 located at the bottom, and the bag filter dust collector 20 A second rotary valve 40b may be installed at the lower end of the second hopper unit 25 located at the lower portion. Therefore, by opening the first and second rotary valves 40a and 40b, the horizontal cyclone is passed through the conveyor belt 50 disposed across the lower side of the horizontal cyclone dust collector 10 and the bag filter dust collector 20. Dust or sparks filtered by the dust collector 10 and dust, pollutants, etc. filtered by the bag filter dust collector 20 may be automatically moved and treated. Alternatively, instead of the conveyor belt 50, as shown in FIG. 4, the first dust box 60a and the second dust box are placed under the horizontal cyclone dust collector 10 and the bag filter dust collector 20, respectively (60b) can be installed to collect them individually.

The horizontal cyclone dust collector 10 may be detachably connected to the inlet 23 of the bag filter dust collector 20 in order to be selectively mounted on the bag filter dust collector 20 or replaced only when necessary. .

In the case of the horizontal cyclone dust collector 10, the discharge pipe 13 is disposed perpendicular to the main body 21 of the bag filter dust collector 20, and the inlet 23 is positioned to correspond to the upper end of the bag filter 22. It can be.

In addition, a discharge port 26 may be formed at an upper portion of the main body 21 of the bag filter dust collector 20 . The outlet 26 may be formed to be located higher than the inlet 23 in the height direction on the top of the other side opposite to one side of the main body 21 . In one embodiment of the present invention, the dust collecting system may include a blower that is connected to the discharge port 26 through the discharge duct 27 and sucks the air collected secondarily. Here, the blower may be a manned blower, a general blower equipped with an inverter for controlling rotational speed, and the like, for example, a manned blower. In this case, the dust collection system according to an embodiment of the present invention may further include an electric panel for controlling the dust extraction means 30 and the blower.

According to the above configuration, the initial flow direction of the primary dust-collected air introduced from the inlet 23 located on the upper side of the bag filter dust collector 20 is directed downward, but is forcedly sucked into the blower from the discharge duct 27. It passes through the bag filter 22 and moves to the upper end of the main body 21 . At this time, since dust and contaminants of a certain size or more do not pass through the bag filter 22 and are attached, clean air flows through the discharge duct 27. If such dust and contaminants continue to adhere to the bag filter 22, it becomes difficult for air to pass through, so the pressure inside the main body 21 naturally rises. The means 30 sprays high-pressure air to shake off dust and contaminants attached to the bag filter 22 .

According to one embodiment of the present invention, a plurality of dedusting means 30 for degassing the bag filter 22 are mounted on the upper side of the bag filter 22 to correspond to each other and inject compressed air into the bag filter 22. two nozzles (31); and a blow tube 32 connected to a compressed air supply source and formed with a flow path so that compressed air is supplied to the nozzle 31 . Here, the air valve 37 is installed at the front end of the blow tube 32 connected to the compressed air supply source, and can control the supply, blocking, compressed air supply amount, and the like of the compressed air. According to the above configuration, the compressed air supplied from the compressed air supply source to the blow tube 32 is injected to the bag filter 22 through the plurality of nozzles 31 to implement the dust removal effect of the bag filter 22 . In addition, when the primarily collected air is introduced into the inlet 23 located at the top, a lot of dust and contaminants are intensively attached to the top of the bag filter 22. When the nozzle 31 is used for dedusting, the top of the bag filter 22 Since the negative pressure is small, the negative pressure area can be reduced and dust and contaminants accumulated throughout the bag filter 22 can be dropped evenly, so that a uniform dedusting effect can be implemented. Furthermore, since the flow direction (dedusting direction) of the injected compressed air and the flow direction of the air introduced from the inlet 23 are matched downward, the dust collected in the lower part of the bag filter dust collector 20 is re-dispersed and the bag filter It is possible to effectively prevent re-attachment of dust falling from (22) to improve dust collection efficiency.

The nozzle 31 may be formed in various shapes. Figure 4 is a partial structural schematic diagram showing the dedusting process of the bag filter 22 using the dedusting means 30 of the dust collection system according to an embodiment of the present invention. For example, referring to FIG. 4 , the nozzle 31 is fastened by a discharge pipe 33 and a fixing piece 34 that protrude from the blow tube 32 toward the nozzle 31 and are connected thereto. 31 may be configured in a rocket shape including an upper venturi part 35 that contracts downward and a lower venturi part 36 that extends downward from the upper venturi part 35. In this embodiment, the dust removal efficiency is improved by using the rocket-shaped nozzle 31 capable of injecting compressed air at a high flow rate with a small pressure by inducing the inflow of ambient air using the Venturi principle through the rocket-shaped nozzle 31. can make it In other words, compared to conventional hole-shaped or rod-shaped nozzles, in the embodiment of the present invention, in addition to the compressed air discharged from the discharge pipe 33, the air around the inlet of the upper venturi unit 35 is also included in the upper venturi unit 35. ), it is possible to implement the effect of increasing the flow rate through the inflow, and since a high flow rate of air can be injected into the bag filter 22 at a relatively low pressure, the power cost is reduced and the dust removal efficiency is improved, and the bag filter 22 The service life is increased and the operating cost of the dust collection system can be reduced.

In the following Comparative Examples and Examples, performance evaluation experiments were conducted at a flow rate of air used at 50 m ³ /min and a concentration of dust introduced into the air at a concentration of 5,000 mg/m ³ for the differential pressure measurement of the dust collector.

In Comparative Example 1, air is introduced into an inlet formed on one lower side of the bag filter dust collector, flows upward, and passes through the bag filter. In Example 2, air flows downward through an inlet formed on one side of the bag filter dust collector and passes through the bag filter, and the horizontal cyclone dust collector of the present invention and a rocket-shaped nozzle are not provided. Air is introduced into the inlet formed at the lower part of one side of the bag filter dust collector, flows upward, passes through the bag filter, and applies the horizontal cyclone dust collector of the present invention and a structure equipped with a rocket-shaped nozzle, and the embodiment is a bag according to the present invention A structure equipped with a filter dust collector, a horizontal cyclone dust collector, and a rocket-type nozzle was applied, and the experimental results are shown in [Table 1] below.

Comparative Example 1 Comparative Example 2 Comparative Example 3 Example bottom-up bag filter dust collector Downward Bag Filter Dust Collector Bottom-up bag filter dust collector + horizontal cyclone dust collector + rocket-shaped nozzle Bag filter dust collector of the present invention + horizontal cyclone dust collector + rocket-shaped nozzle 154 mmH ₂ O 116 mmH ₂ O 111 mmH ₂ O 32 mmH ₂ O

As can be seen from [Table 1], in Comparative Examples 1 to 3, the differential pressure of the dust collector was 154 mmH ₂ O, 116 mmH ₂ O, and 111 mmH ₂ O, respectively, and it was confirmed that all were 100 mmH ₂ O or more, whereas , In the embodiment according to the present invention, the differential pressure of the dust collector was 32 mmH ₂ O, and it was confirmed that there was a significant differential pressure reduction effect compared to Comparative Examples 1 to 3.

Therefore, the dust collection system according to the embodiment of the present invention can effectively improve the dust collection efficiency and extend the life of the bag filter 22 without being significantly limited by space in installing the horizontal cyclone dust collector.

As a result, according to the configuration of the dust collection system according to the embodiment of the present invention, the horizontal cyclone dust collector 10 is connected to the bag filter dust collector 20 in a horizontal direction, and the air introduced therein hardly requires additional installation space. Since large particles of dust or sparks in the bag filter are pre-filtered through the horizontal cyclone dust collector 10 before being introduced into the bag filter dust collector 20, damage such as puncture of the bag filter 22 is effectively prevented from occurring, thereby effectively preventing the bag filter from occurring. (22) can be extended, and furthermore, it is possible to operate an economical dust collection system.

In addition, according to the configuration of the dust collection system according to the embodiment of the present invention, the inlet 23 of the bag filter dust collector 20 is formed on the upper part of the bag filter dust collector 10, so that the inlet 23 of the bag filter dust collector 20 The air introduced from ) flows downward, and the dust collected in the lower part of the bag filter dust collector 20 is matched with the direction in which the dust falls and the direction in which the dust falls and the dust extraction direction of the dust extraction means 30 disposed above the bag filter 22. It is possible to improve dust collection efficiency by effectively preventing re-dispersion and re-attachment of dust falling from the bag filter 22.

In addition, according to the configuration of the dust collection system according to an embodiment of the present invention, the inflow of ambient air is induced using the Venturi principle through the nozzle 31 of the rocket shape, so that a high flow rate of compressed air can be injected with a small pressure. The dust removal efficiency can be improved by using the nozzle 31 of .

As described above, although the present invention has been described by the limited embodiments and drawings, the present invention is not limited thereto, and the technical spirit of the present invention and the following by those skilled in the art to which the present invention belongs Of course, various modifications and variations are possible within the equivalent scope of the claims to be described.

10: horizontal cyclone dust collector 11 inlet pipe
12 extension pipe 13 discharge pipe
14 swirler 15 first hopper part
20 Bag filter dust collector 21 Body
22 bag filter 23 inlet
24 installation part 25 second hopper part
26 exhaust 27 exhaust duct
28 Bulkhead 30 Exhaust means
31 nozzle 32 blow tube
33 discharge pipe 34 fixture
35 upper venturi part 36 lower venturi part
37 air valve 40a first rotary valve
40b second rotary valve 50 conveyor belt
60a first dust box 60b second dust box

Claims (8)

A horizontal cyclone dust collector that extends in the horizontal direction and primarily collects dust while the incoming air rotates and flows around the horizontal direction;
A plurality of bag filters are disposed inside the main body, and an inlet connected to the discharge pipe of the horizontal cyclone dust collector is formed on an upper part of one side of the main body so that the primarily collected air flowing in from the horizontal cyclone dust collector forms a downward airflow. , Bag filter dust collector that is secondary dust collected by the bag filter; and
Dust collection system comprising a; dedusting means disposed above the bag filter in the main body to exhaust the bag filter. The method of claim 1, wherein the horizontal cyclone dust collector comprises: an inlet pipe sequentially connected in a horizontal direction, an expansion pipe formed larger than a hole diameter of the inlet pipe, and the discharge pipe; a swirler disposed inside the expansion pipe to rotate and flow the air introduced from the inlet pipe toward the discharge pipe in a horizontal direction; And Dust collection system comprising a; first hopper portion disposed in the lower portion of the expansion pipe adjacent to the discharge pipe. The dust collecting system according to claim 2, wherein a connection portion between the inlet pipe and the extension pipe has a tapered shape. According to claim 1, wherein the main body is formed in a cylindrical shape at the top, and the plurality of bag filters are installed in a cylindrical shape extending in a height direction therein; And a second hopper unit formed in a conical shape at the bottom and collecting falling dust;
The dust collection system, wherein the dust extraction means is disposed above the bag filter in the installation part. The method of claim 1, wherein the dedusting means comprises: a plurality of nozzles mounted on the upper side of the bag filter to inject compressed air into the bag filter; and a blow tube connected to a compressed air supply source and having a flow path formed so that compressed air is supplied to the nozzle. The method of claim 5, wherein the nozzle is fastened to a discharge pipe protruding from the blow tube toward the nozzle and connected by a fixing piece, and the nozzle has an upper venturi part that contracts downward and an upper venturi part that extends downward from the upper venturi part. A dust collection system configured in the form of a rocket nozzle including a lower venturi. The dust collection system according to any one of claims 1 to 6, wherein the horizontal cyclone dust collector is detachably connected to the inlet of the bag filter dust collector. The dust collection according to any one of claims 1 to 6, wherein a conveyor belt or dust box for discharging dust collected through a rotary valve is disposed below the hopper part of the horizontal cyclone dust collector and the bag filter dust collector, respectively. system.

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