KR100887326B1 - A gathering device of the acme dust - Google Patents

Abstract

A fine dust collecting apparatus is provided, where a screw is installed in a sucking unit located in a side of a back housing, thereby efficiently collecting fine dust which is not well collected by an existing dust collector. A fine dust collecting apparatus comprises the following units. A back housing(10) is equipped with an sucking unit(11) and a discharging unit(12). A plurality of back filters(20) collect fine dust included in air. A plurality of venturi tubes(30) linked with each back filter to be fixed transfer the filtered air supplied by the back filters. An adaptor(40) has a plurality of through-holes(41) in which air is passed from the venturi tubes. A screw(50) is mounted inside a sucking pipe(13) in a longitudinal direction so that fine dust particles can collide with inflow air.

Description

A dusting device of the acme dust}

The present invention is a fine dust collecting device, in particular through the inlet pipe connected to the other side of the bag housing by the drive of the suction connected to the exhaust port of one side of the bag housing to collect the fine dust in the air, the inside of the bag housing, It is for collecting the fine dust contained in the air while passing through the outside, the predetermined portion inside the inlet pipe is provided with a screw consisting of a body portion and a spiral blade air containing fine dust is primarily the spiral of the screw The fine dust contained in the air collides with the blade and falls to the loading unit located at the bottom of the bag housing, and the air introduced into the inside of the bag housing is filtered by the bag filter provided inside the bag housing. As a result, the present invention relates to a fine dust collecting device capable of efficiently collecting fine dust through the inside and the outside of the back housing.

In general, in the process of crushing to obtain dust for producing products at industrial sites, there is a lot of fine dust in the air and it is often leaked to the outside.In this case, it prevents waste of crushed raw materials and cleans the air of the workplace Facing challenges

In general, the structure and principle of the filter dust collector is that when the air containing the dust is sucked into the dust inlet by the blower, the dust particles in the air is filtered by the filter cloth and the air after the filtered air is discharged to the atmosphere.

Therefore, in order to continuously collect dust particles in the air, a cleaning operation to periodically shake off the filtered dust is required, so the dust collector is provided with a hopper so that dust collected by the filter cloth is collected by gravity, and collected in the hopper. Dust is sent to a designated place by a separate feeder.

However, the above-mentioned conventional dust collector has a low dust collection efficiency compared to these installation areas since circular filter cloths are installed in a constant arrangement, and in particular, each suction cloth is provided with a suction part for forming a negative pressure, that is, a nozzle and a venturi duct. The uniform negative pressure cannot be formed on all the filter cloths, therefore, the dust collection efficiency is relatively low and the pressure loss is large during the cleaning operation, and the cleaning frequency is high because the cleaning pressure of the filter cloth is uneven, which shortens the service life of the filter cloth. Therefore, the maintenance cost of the dust collector is high, and the energy loss is large due to the relative pressure loss.

A number of prior arts have been disclosed as prior art of dust collectors for solving the above problems.

1 is a vertical cross-sectional view showing a structure of a conventional dust collector 100, which has a housing 100 inside and outside sealed and having a partition 112 installed therein. The interior of the housing 100 is the partition wall 112. ) Is divided into an intake chamber 115 through which air containing dust is sucked and an exhaust chamber 117 which is a passage of clean air from which dust is removed, and the air containing dust is sucked into the lower side of the intake chamber 115. Intake port 111 is provided for the purpose, and the exhaust chamber 117 is provided with an exhaust port 113 for discharging clean air from which dust is removed to the outside.

A bag filter 130 for filtering air containing dust is vertically installed in the intake chamber 115, and an upper end of the bag filter 130 is suspended on the partition wall 112.

In such a filter dust collector, a filter cleaning operation that frequently shakes off the dust attached to the bag filter 130 by filtration is required to continuously collect dust in the air. That is, the dust filtered by the bag filter 130 is attached to the outer surface of the bag filter 130 to reduce the filtering efficiency and shorten the life of the bag filter 130, so it is necessary to shake off the dust attached very frequently labor productivity This has the disadvantage of falling.

The bag filter dust collecting means has a spray nozzle 170 formed in the nozzle tube 160 through which compressed air is supplied from the compressed air reservoir or the compressor 150 to correspond to the bag filter 130, and a bag cage on the bag filter. 131 is provided, and the venturi 133 is provided at the inlet. The compressed air is blown through the venturi 133 in an intermittent pulse type in a direction opposite to the filtration direction of the bag filter 130. As a result, the dust or filter cake stuck to the outer surface of the bag filter 13 is filtered. The cake is dropped and falls to the collecting part 120 disposed below the filter.

Technical requirements related to this are to maximize the injection pressure and injection speed of the pulse air, the prior art is the injection nozzle which is installed in the nozzle tube (160) in the injection of the pulse air (Pulse air) to the bag filter 130 ( 170) has a problem that the injection speed and the cleaning efficiency is lowered by the simple exit form.

Figure 2 relates to another prior art utility model No. 0321528 ("Ejector for dust collector bag filter") proposed as an alternative to the above problem, the dust collector bag filter ejector 200 is compressed air in the nozzle tube Ejector 270 for refracting injection in two stages is provided.

The ejector 270 firstly injects the air supplied from the nozzle tube 260 and refracts the first injection unit 271 to form a flow path that is refracted in a "b" shape and close to a right angle again from the first injection unit. It is composed of a second injection unit 272 is formed, the ejector of this configuration is the first injection unit 271 is formed by including the horizontal portion (h) in the form of "b" by the injection resistance in this horizontal portion (h) As a result, the blowing speed of the compressed air and the power to eliminate the dust are reduced (in the drawing, reference numeral 230 denotes a bag filter and '233' denotes a venturi).

Therefore, the dust collecting efficiency of the bag filter is insufficient in the state that the bag filter has to be limited within a certain length, and thus a large number of bag filters must be installed. There is a problem to increase, and also because the air pulse power must be strong, there is a problem that a relatively large capacity is accompanied by an air compressor and its operating cost is wasted.

The present invention has been made in view of the above-mentioned point, and an object of the present invention is to collect the fine dust in the air generated at the industrial site in which the crushing operation is performed in order to obtain dust. An object of the present invention is to provide a fine dust collecting device that can efficiently collect fine dust in the air passing through the inside and the outside using less energy.

In order to achieve the above object, the present invention is a fine dust collecting device side to collect the fine dust mixed in the air flowing out to the outside during the shredding operation to make the fine dust required for the production of the product to discharge the air to the outside A bag housing having an inlet and an exhaust port formed therein, a plurality of bag filters installed in the bag housing to collect fine dust in the air, and fixedly connected to the respective bag filters to filter fine dust from the bag filter. And a plurality of venturi tubes for delivering air, and adapters fixed to the inner circumferential wall of the back housing with the respective venturi tubes attached thereto, the adapter having a plurality of through holes through which air from the venturi tubes passes. The inlet pipe is connected to an outer side of the inlet, and the inner side of the inlet pipe is along the lengthwise direction. The screw is installed fine dust particles in the air to move into the space inside the housing so that they collide with each other while eonggi.

Between the inlet and the inlet pipe is provided with an inclined connecting pipe narrowing the inner width from the inlet to the inlet pipe, the inclined connecting pipe is downward based on the central axis of the inlet pipe connected to the inclined connecting pipe. It is formed to be more inclined, the inlet is provided with a baffle plate spaced apart from the inner circumferential surface of the inlet so that dust particles in the air introduced through the inlet pipe hits and falls below the back housing. In addition, the screw is made of a body portion and a spiral blade, the spiral blade is in close contact with the inner peripheral wall of the inlet pipe.

The fine dust collecting device according to the present invention

First, by installing a screw in a certain part of the inlet pipe located on one side of the back housing, the fine dust particles in the air flowing through the inlet pipe are collected and agglomerated into large particle dust, which was not collected by the existing dust collector. There is an advantage in that fine dust can be collected efficiently.

Second, as described above, the fine dust is first filtered through the screw, so that the replacement time of the bag filter that secondly collects the fine dust in the air can be prolonged.

Third, as the above, the first step of collecting the fine dust in the air through the screw and the second step of collecting again in the bag filter, there is less resistance of the air through the bag filter flows air into the bag housing Since the driving load of the suction unit which is driven to be reduced, there is a useful effect that can be expected to reduce the fuel for driving the suction unit.

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

Figure 3 is a general schematic view of the fine dust collecting device according to the present invention, Figure 4 is a side view of the main portion of Figure 3 separated, the fine dust collecting device according to the present invention to make the fine dust required for production Bag housing 10 formed with an inlet 11 and an exhaust 12 at the side to collect the fine dust mixed in the air flowing out to the outside during the shredding operation to discharge the air to the outside, and A plurality of bag filters 20 installed inside the bag housing 10 to collect fine dust in the air, and fixedly connected to the respective bag filters 20 to form fine particles from the bag filter 20. A plurality of venturi tubes 30 for delivering dust-filtered air, and fixed to the inner circumferential wall of the bag housing 10 with the venturi tubes 30 attached thereto, A plurality of through holes 41 through which air is formed In the collecting device including the adapter 40, the inlet pipe 13 is extended to the outside of the inlet 11, the inside of the inlet pipe 13 along the longitudinal direction of the back housing 10 Screw 50 is installed so that the fine dust particles of the air flowing into the inside of the impingement and collide with each other.

The air containing the fine dust is introduced through the inlet pipe 13 by the driving of the suction unit S extending to the exhaust port 12 formed at one side of the back housing 10, the inlet pipe 13 The fine dust is agglomerated while falling in the screw 50 installed in a predetermined portion of the fall down to the bottom of the back housing 10, is loaded on the loading portion (L) located at the lower end of the back housing (10).

The air in which the fine dust is primarily filtered through the screw 50 is introduced into the inside of the bag housing 10, and the air thus introduced is collected in the surface of the bag filter 20. Then, the inside of the bag filter 20 is introduced, the air introduced into the bag filter 20 through the venturi tube 30, the fine dust is filtered through the through hole 41 of the adapter 40 To the exhaust vent 12.

Inside the bag filter 20 is provided with a back cage 21 for holding the bag filter 20 in a cylindrical tension, the back cage 21 is fixed to the outer surface of the venturi tube (30) The venturi tube 30 is inserted into and fixed to the through hole 41 of the adapter 40.

The back housing 10 has an inclined downward portion 15 so that the diameter of the lower portion thereof gradually narrows downward in order to prevent the dust mass falling through the inlet 11 from re-emergizing upward. ) Is formed to prevent the dust lumps falling down the back housing 10 through the inlet 11 to be bounced back by lift.

Figure 5 is a perspective view showing a screw according to the present invention, Figure 6 shows a state diagram showing the flow of air through the screw of the present invention, the screw 50 is the body portion 51 and the spiral blade It consists of 52, the spiral blade 52 is preferably installed in close contact with the inner circumferential wall of the inlet pipe 13, the fine dust contained in the air flowing through the inlet pipe 13 is the screw This is to move while hitting along the spiral blade 52 of (50).

The air introduced through the inlet pipe 13 hits the spiral blade 52 of the screw 50, and the fine dust particles contained in the air are entangled with each other by electrostatic attraction, so that the mass becomes large. When the large dust mass reaches the inlet 11, the free dust falls freely below the back housing 10 by gravity.

The screw 50 is preferably made of aluminum in order to prevent particles of the dust mass from adhering to the surface of the spiral blade 52 of the screw 50 due to the electrostatic attraction caused by the numerous collisions with the dust mass. . In addition, the use of the screw 50 as an aluminum material has the advantage of preventing corrosion due to moisture contained in the air, thereby improving durability.

7 is a perspective view showing a baffle plate according to the present invention, Figure 8 is a view showing the installation state of the baffle plate according to the present invention, the inlet 11 is dust in the air introduced through the inlet pipe 13 The baffle plate 60 is installed to be spaced apart from the inner circumferential surface of the inlet 11 so that the mass falls to the lower side of the back housing 10, the baffle plate 60 filters the dust lumps in the air, but the flow of air A plurality of through-holes 61 are formed for the dust particles formed by colliding with the spiral blades 52 of the screw 50 by the fine dust in the air introduced through the inlet pipe 13 and the baffle plate 60. This is to fall to the lower portion of the back housing 10 directly without hitting the inside of the back housing 10. Especially when the dust mass is large, the effect is much larger.

In addition, the back housing due to the phenomenon that the dust mass formed by the fine dust in the air introduced through the inlet pipe 13 hits the spiral blade 52 of the screw 50 hits the baffle plate 60 as described above. 10) As the dust mass enters the inner side of the bag housing 10, the drop rate naturally decreases, so the baffle plate 60 is re-emergised upward of the dust mass dropped in the downward direction of the back housing 10 ( It is to prevent the upset.

Between the inlet 11 and the inlet 13 is formed inclined connecting pipe 14 is narrow in the inner width from the inlet 11 to the inlet pipe 13, the inclined connecting pipe 14 It is formed to be further inclined downward with respect to the central axis of the inlet pipe 13 connected to the inclined connecting pipe 14, the air passing through the screw 50 in the inlet pipe 13 and the dust contained in the air The mass is intended to allow the dust mass to fall easily to the inner lower portion of the back housing 10 due to the pressure lower than the pressure in the inlet tube 13 due to the sudden widening of the inclined connecting tube 14.

The baffle plate 60 is preferably made of aluminum in order to prevent the particles of the clumps from sticking to the surface of the baffle plate 60 due to electrostatic attraction caused by a myriad of collisions with the clumps of dust. In addition, by using the baffle plate 60 as an aluminum material, there is an advantage of preventing corrosion due to moisture contained in the air, thereby improving durability.

9 is a state diagram showing that the air is circulated through the fine dust collecting device according to the present invention, the process of moving the air in the fine dust collecting device as follows.

First, air containing fine dust flows into the inlet pipe 13 by driving of the suction unit S.

Second, the air introduced into the inlet pipe 13 hits the spiral blade 52 of the screw 50 to form agglomerates of particles of fine dust contained in the air, through the inclined connection pipe 14. It hits the baffle plate (60) installed in 11), and the dust particles in the air are dropped to the lower part of the back housing 10 and loaded in the loading part L located at the lower part of the back housing 10.

Third, the air in which the mass of fine dust is primarily filtered while passing through the screw 50 and the baffle plate 60 is introduced into the back housing 10.

Fourth, the air introduced into the bag housing 10 is secondarily filtered by the bag filter 20, that is, after the fine dust is collected through the surface of the bag filter 20, the air is filtered through the bag filter ( 20) flows into the inside.

Fifth, the fine dust is filtered and the air introduced into the bag filter 20 is discharged to the exhaust port 12 through the vent hole 41 of the adapter 40 through the venturi tube 30.

As described above, in the fine dust collecting device according to the present invention, the particles of the fine dust in the screw primarily collide with the spiral blades of the screw, and are made up of dust masses and fall downward in the back housing, and again the secondary bag filter. Particles of fine dust are collected on the outer surface of the fuel, and thus, the resistance of the air passing through the bag filter is low, and the driving load of the suction unit driven to enter the air into the bag housing is reduced. It can be expected to reduce the energy consumption, and the air passing through the inside and outside of the bag housing by collecting the fine dust particles in the air generated at the industrial site where the crushing work is performed in order to obtain dust in the first and second stages. Fine dust can be efficiently collected by using less energy, and it is pleasant to workers in industrial sites. Providing air also has the beneficial advantage of significantly reducing workers' respiratory diseases.

1 is a longitudinal cross-sectional view showing the configuration of a conventional conventional dust collector,

Figure 2 is a longitudinal cross-sectional view showing the configuration of another conventional dust collector,

3 is an overall schematic view of a fine dust collecting device according to the present invention;

4 is a side view of the main portion of FIG.

5 is a perspective view showing a screw according to the present invention,

Figure 6 is a use state showing the flow of air through the screw of the present invention,

7 is a perspective view showing a baffle plate according to the present invention,

8 is an installation state of the baffle plate according to the present invention,

9 is a state diagram showing that the air is circulated through the fine dust collecting device according to the present invention.

※ Explanation of symbols for main parts of drawing

10: back housing 11: inlet

12 exhaust port 13 inlet pipe

14: inclined connector 15: downward slope

20: bag filter 21: back cage

30: Venturi tube 40: adapter

41: through hole 50: screw

51: body 52: spiral blade

60: baffle plate 61: through hole

62: fixing hole 63: fixing rod

S: suction part L: loading part

Claims (7)

delete Bag housing formed with inlet 11 and exhaust 12 at the side to collect the fine dust mixed in the air flowing out to the outside during the shredding process to produce the fine dust required for the production of the product to discharge the air to the outside 10, a plurality of bag filters 20 installed inside the bag housing 10 to collect fine dust contained in the air, and fixedly connected to the respective bag filters 20, 20 is a plurality of venturi tube 30 for delivering fine air filtered from the dust, and each of the venturi tube 30 is fixed to the inner circumferential wall of the back housing 10, the venturi tube ( Adapter 40 having a plurality of through-holes 41 through which air from 30 is formed, and an inlet pipe 13 is extended and connected to an outer side of the inlet port 11, and a lengthwise direction is formed inside the inlet pipe 13. Of the air flowing into the back housing 10 and moving along the In the collecting device comprising a screw 50 so that the fine dust particles collide with each other, tangling, Between the inlet 11 and the inlet pipe 13, fine branch collecting device, characterized in that the inclined connecting pipe 14 is formed to narrow the inner width from the inlet 11 to the inlet pipe (13). The method according to claim 2, The inclined connecting pipe 14 is fine dust collecting device, characterized in that formed further inclined downward based on the central axis of the inlet pipe (13) connected to the inclined connecting pipe (14). The method according to claim 2, A baffle plate 60 is installed at the inlet 11 so as to be spaced apart from the inner circumferential surface of the inlet 11 so that dust particles in the air introduced through the inlet tube 13 collide with each other and fall below the back housing 10. Fine dust collecting device, characterized in that. delete The method according to claim 4, The baffle plate (60) is a fine dust collecting device, characterized in that a plurality of through-holes (61) are formed to filter the dust lump in the air flow. delete

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