KR102053376B1 - Fine dust reducing apparatus - Google Patents

Abstract

According to the present invention, a fine dust reduction apparatus comprises: a housing having a cylinder body through which air or oil mist containing fine dust are introduced and discharged; an inflow fan configured in an inlet communicating with the inside of the housing for the air or oil mist to be introduced into the inside of the housing; a cooling means configured in a rear end portion of the inflow fan and cooling the hot air or oil mist; a moisture removal means configured in a rear end portion of the cooling means and condensing and sinking moisture of the air or oil mist cooled by the cooling means to remove the moisture; and an electrostatic cohesion means configured in a rear end portion of the moisture removal means, adsorbing and removing fine dust contained in the air or oil mist in which the moisture is removed by the moisture removal means by using an electrostatic characteristic, and then discharging the air or oil mist with reduced fine dust through a discharge port.

Description

Fine dust reducing apparatus

The present invention relates to an apparatus for reducing fine dust, and more particularly, in an apparatus for reducing fine dust by using an electrostatic coagulation method, a bent condensing plate in which fine dust is aggregated is configured to increase the total area while minimizing a cross-sectional area. The present invention relates to a fine dust reduction device capable of reducing the explosion risk while having the same cohesive efficiency as that of a conventional flat plate aggregate by widening the space between the aggregate plates.

Recently, as the interest in the environment has rapidly increased, there is an increasing demand for a device for removing or reducing fine dust such as air or oil vapor, and thus, a fine dust reduction apparatus for removing or reducing the fine dust has been disclosed. have.

Here, the fine dust reduction device, after the air or vapor containing the fine dust flows into the housing of the tubular structure, the discharge portion and the discharge space after the discharge portion and the discharge space portion is formed in the flat plate-like aggregate plate arranged inside the housing The fine dust particles are ionized by the negative discharge process and then electrically adsorbed onto the flat plate aggregate.

However, the oil vapor in the air containing the fine dust, as it is mainly generated in an industrial facility contains a high temperature and a large amount of water and volatile substances.

Therefore, when the fine dust of the oil vapor is removed by using the conventional fine dust reduction device, the phenomenon that the fine dust of the vapor or volatile matter adheres to the side wall of the aggregation plate frequently, and the discharge portion formed in the aggregation plate There is a problem that a fire occurs due to volatile materials when exposed to strong heat and flames due to discharge.

In addition, the fine dust reduction apparatus using the electrostatic agglomeration method as described above increases the fine dust removal efficiency according to the area between the agglomerated plate and the space between the agglomerated plates, thus increasing the area of most flat plate agglomerated plates and between the agglomerated plates. It has a configuration that narrows the interval of.

Therefore, the conventional fine dust reduction device is expensive to increase the volume of the housing when simply increasing the area of the flat plate aggregate plate, and when the space between the plate is narrowed by the air or moisture in the vapor Short or flame is generated, there is a problem that a fire occurs as described above.

(Patent Document 0001) Published Patent 10-2016-0068116

(Patent Document 0002) Registration Utility 20-0343967

Accordingly, an object of the present invention is to construct a cohesive plate in which fine dust is agglomerated to minimize the cross-sectional area while increasing the total area and to increase the spacing of the coagulated plates, thereby having the same cohesive efficiency as that of a conventional flat plate agglomerate plate and explosion risk. It is to provide a fine dust reduction device that can reduce.

In addition, an object of the present invention is to provide a fine dust reduction device that can improve the fine dust removal efficiency of the aggregation plate by cooling and removing the water containing air or oil vapor in the front of the aggregation plate.

On the other hand, the object of the present invention is not limited to the above-mentioned object, other objects that are not mentioned will be clearly understood by those skilled in the art from the following description.

According to the present invention, a housing having a tubular structure through which air or oil vapor containing fine dust flows in and out; An inlet fan configured at an inlet communicated with the inside of the housing and allowing air or vapor to flow into the housing; Cooling means configured to cool the hot air or the steam at a rear end of the inlet fan; A water removal means configured at a rear end of the cooling means and condensing and sedimenting the water of air or steam vapor cooled by the cooling means; And the air or oil vapor having reduced dust is discharged through the exhaust port after being removed at the rear end of the water removing means and adsorbing and removing the fine dust contained in the air or the steam removed by the water removing means through the electrostatic property. There is provided a fine dust reduction apparatus comprising an electrostatic agglomeration means.

Here, the cooling means includes a cooling cycle that is installed on the inner front end surface of the housing to allow movement of air or oil vapor, and the cooling cycle includes a compressor configured at an outer side of the housing and one side of the compressor. It is preferable to include a condenser located at, an expansion valve located at one side of the condenser, and an evaporator installed at the front end surface of the housing in a coil shape, a zigzag, and a mesh structure inside the housing.

In addition, the refrigerant circulating in the cooling cycle, together with the cooling water for cooling, high thermal conductivity platinum powder having 5 to 10 parts by weight based on 100 parts by weight of the cooling water and anion powder having 3 to 5 parts by weight based on 100 parts by weight of the cooling water. It is preferable to include.

In addition, the refrigerant circulation pipe corresponding to the evaporator 124 located inside the housing, the composite polymer composition is coated on the surface of the refrigerant circulation pipe, the composite polymer composition, 50 to 60 parts by weight of the filler is added to 100 parts by weight of the polymer And the polymer is selected from the group consisting of a silicone resin, an epoxy resin, an acrylic resin, a mixture thereof and a copolymer thereof, and the filler has a first average particle size. A first filler, a second filler having a second average particle diameter, and a third filler having a third average particle diameter, wherein the first average particle size is 10 to 30 µm, which is larger than the remaining average particle values, and the second average particle size. The value obtained by dividing the value by the first average particle diameter value is 0.17 to 0.26, and the value obtained by dividing the third average particle size value by the first average particle size value is 0.09 to 0.11, and the volume of the first filler, the second filler, and the third filler. Resistance is more than 10 ⁴ Ωcm The first filler, the second filler, and the third filler have an average value of shorter diameter / longer diameter of 0.6 to 0.8, and the sum of the sum of the mass of the second filler / the sum of the mass of the first filler is 11 to 16 or the sum of the mass of the third filler. The percentage of the sum of the first filler mass is 4.2 to 5.2, and the first filler, the second filler, and the third filler are alumina (Al 2 O 3), boron nitride (BN), aluminum nitride (AlN), silicon nitride (Si 3 N 4), and magnesia. It is preferably selected from the group consisting of (MgO), berylia (BeO), zinc oxide (ZnO), silicon carbide (SiC), zirconia (ZrO2) and mixtures thereof.

In addition, the water removal means is preferably composed of a plurality of eliminators or chevrons and demister filters which are installed on the inner shear surface of the housing to allow movement of air.

In addition, the electrostatic agglomeration means, the inside of the housing is configured to be parallel to the direction of movement of air or steam and bent panel-like aggregate plate of the opposite polarity is arranged repeatedly with a predetermined separation interval; A discharge space portion formed while having a rectangular shape by cutting of the bent panel type agglomerated plate; A discharge unit comprising a discharge needle protruding integrally with the bent panel type aggregation plate on the discharge space part; And a dust collecting part corresponding to a region other than the discharge part and the discharge space part on the bent panel type agglomerate plate and collecting fine dust particles during discharge of the discharge part.

Therefore, according to the present invention, by forming a coagulation plate in which fine dust is agglomerated to minimize the cross-sectional area while increasing the total area and to increase the separation interval of the coagulation plate by the same cohesive efficiency as the conventional flat plate coagulation plate The risk of explosion due to electrical shorting can be reduced by the interval.

In addition, the moisture of the air or oil vapor containing fine dust at the front end of the agglomerated plate can be cooled and condensed to remove the fine dust removal efficiency of the agglomerated plate.

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

1 is a view showing a fine dust reduction apparatus according to a preferred embodiment of the present invention;
2 to 4 is a view showing the configuration of the cooling means in the fine dust reduction device of FIG. And
5 is a view showing the configuration of the aggregation plate of the electrostatic agglomeration means in the fine dust reduction device of FIG.

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

As shown in Figure 1 to 5, the fine dust reduction device according to a preferred embodiment of the present invention, the housing 110, the housing 110 having a tubular structure in which the air or oil vapor containing fine dust flows in and out Inlet (111) is communicated to the inside of the inlet fan (not shown) and the inlet fan (not shown) for allowing air or steam to flow into the housing 110, and the high temperature air or vapor Cooling means 120 for cooling the cooling means 120 is formed in the rear end of the cooling means 120 and the water removal means 130 and the water removal to remove the condensation and sedimentation of the water or air of the steam cooled by the cooling means 120 The air or vapor which is configured at the rear end of the means 130 and ionized fine dust contained in the water or the oil vapor removed by the water removing means 130 and is removed by adsorption through electrostatic properties Through the vent 112 Include electrostatic condensing means such that the exhaust 140, and the like.

The housing 110 is a means for providing a flow path through which air or oil vapor containing fine dust flows in and out, and has a tubular structure that provides a space in which the above-described components are compactly installed. ) And an exhaust port 112.

The inlet fan (not shown) is installed at the inlet 111 formed at one side of the housing 110 and is a means for introducing air or vapor into the housing 110, and thus may have a known configuration. Omit.

The cooling means 120 is configured at the rear end of the inflow fan (not shown) and is a means for cooling hot air or steam to reduce the risk of water removal and fire. It includes a cooling cycle that is installed on the surface to enable the movement of air or oil vapor.

Here, the cooling cycle, the compressor 121 is configured on the outside of the housing 110, the condenser 122 located on one side of the compressor 121, the expansion valve 123 located on one side of the condenser 122 and The evaporator 124 is installed inside the housing 110 in a shear shape inside the housing 110 in a coil shape, a zigzag and a mesh structure.

The compressor 121 is driven by a drive motor, the condenser 122 is a heat exchanger between the refrigerant and the outside by the condensation fan, the evaporator 124 is configured inside the housing 110, the air or steam to be introduced to a high temperature state Is heat-exchanged and cooled, and a cooling cycle operation including the compressor 121, the condenser 122, the expansion valve 123, and the evaporator 124 is a well-known technique, and thus a detailed description thereof will be omitted.

On the other hand, in the cooling cycle of the present invention, the refrigerant activator 125 is further installed between the condenser 122 and the expansion valve 123.

Here, the refrigerant activator 125 is a means for activating the refrigerant molecules entangled by heat exchange by allowing the refrigerant discharged from the condenser 122 to flow into the front end of the expansion valve 123 at a constant speed and a constant amount. , An inlet pipe corresponding to an input terminal of the body 125a and the body 125a having a space in which the refrigerant is stored, and allowing the refrigerant moving from the condenser 122 to be sprayed toward the inner wall surface of the body 125a. 125b is formed on the inner wall of the inner space of the body 125a, and the refrigerant injected toward the inner wall surface of the body 125a through the inlet pipe 125b moves to the lower end of the body 125a while swirling or vortex rotating. Spiral guide 125c to move toward the inner central space of the 125a phase by the condenser 122 to activate the refrigerant having an unstable state, the body 125a in the inner central space of the body 125a Discharge pipe 125d and discharge configured to have a pipe shape to communicate to the lower end so that the refrigerant moved to the upper end of the body 125a is discharged to the outside by the internal pressure generated as the refrigerant flows into the body 125a. The discharge pipe 125e communicates with an end of the pipe 125d and corresponds to the discharge end of the body 125a and discharges the refrigerant discharged from the discharge pipe 125d to the front end of the expansion pipe of the expansion valve 123.

The spiral guide 125c allows the refrigerant introduced through the inlet pipe 125b to the upper end of the body 125a to move at a high speed toward the lower end of the body 125a while vortexing along the inner wall of the body 125a. The heat of the refrigerant is heat-exchanged by the wall surface or the guide and is discharged to the outside by friction with the wall or the spiral guide 125c of the body.

At this time, the coolant is moved again through the inner center space of the body 125a. As the vortex rotates as described above, the coolant moves to the center space having a low pressure inside the vortex of the coolant flowing into the upper end of the body 125a. The heat is lost by the heat exchange with the vortices passing through the inner wall of the body 125a while being easily moved with entering and moving through the central space.

As a result, the refrigerant may pass through the spiral guide 125c and may be heat-exchanged by vortex movement without using a separate power consumption, and thus the refrigerant may have a low temperature even when the condensation efficiency of the condenser 122 is reduced. It may be to be introduced into the expansion valve 123 in the excited state.

The discharge pipe 125d is flowed in the vortex along the wall surface of the body 125a, and the refrigerant moved to the lower end is moved to the upper end along the central space again, and then flows in and out at a constant amount and constant speed through the inlet end. It provides an internal pressure to be discharged, thereby providing a buffer function to ensure that the refrigerant discharged through the discharge pipe (125e) connected to the end flows with a constant amount and speed at all times regardless of the driving efficiency of the compressor 121 It is possible to provide, and through this, it is possible to keep the overall efficiency of the cooling cycle constant by preventing overload or congestion of the refrigerant.

Therefore, according to the refrigerant activator 125, the refrigerant flowing into the body 125a from the condenser 122 in a state configured at the front end of the expansion valve 123 in a state where the refrigerant is stored in the body 125a is the body ( 125a) It is rotated inside and discharged to the outside of the tank with a constant speed and a certain amount through the discharge pipe 125d configured in the center space, thereby activating the molecules of the tangled refrigerant to stabilize the pipe of the cooling cycle in a stable state. It can always be moved with a constant amount and speed so that the overall efficiency of the cooling cycle is kept constant.

In addition, in the cooling cycle of the present invention, the refrigerant amount controller 126 is further provided between the evaporator 124 and the compressor 121.

Here, the refrigerant amount regulator 126 is configured in the refrigerant inlet pipe 126a between the compressor 121 and the evaporator 124 and the refrigerant supplied from the evaporator 124 to the compressor 121 has a pressure equal to or lower than a constant pressure. Intake pressure regulating valve 126b and refrigerant inlet pipe 126a in which the refrigerant supply amount is set to prevent an overload of the compressor 121 and to supply a refrigerant having a lower capacity than the compression capacity of the compressor 121. An unloading bypass pipe 126c configured in parallel with 126b and having a refrigerant supply amount corresponding to the difference between the refrigerant supply amount corresponding to the compression capacity of the compressor 121 and the refrigerant supply amount of the suction pressure control valve 126b; On and off valve 126d for opening and closing the bypass pipe (126c), and during the initial startup or restart of the compressor 121, the bypass pipe 126c through the on-off valve 126d to close the compressor 121 The compressor 121 only through the suction pressure regulating valve 126b. The refrigerant is supplied in a lower amount than the compression capacity of the to enable the unloading start, and when the compressor 121 is normally started after a certain time, the bypass pipe 126c is opened through the on-off valve 126d to suction pressure Through the control valve 126b and the bypass pipe 126c, the refrigerant corresponding to the compression capacity of the compressor 121 is supplied to enable normal starting.

Therefore, according to the refrigerant amount regulator 126, when the compressor 121 is initially started or restarted after the operation is stopped, the bypass pipe 126c is closed so that only a small amount of refrigerant enters the compressor 121 through the suction pressure regulating valve 126b. The compressor 121 can be unloaded by being supplied, and the bypass pipe 126c is opened at the normal startup of the compressor 121, so that both the suction pressure regulating valve 126b and the bypass pipe 126c are opened. The refrigerant corresponding to the compression capacity of the compressor 121 may be supplied to enable normal startup of the compressor 121.

On the other hand, in the present invention, the refrigerant circulating the cooling cycle, platinum powder having a high thermal conductivity and 100 parts by weight of cooling water having 5 to 10 parts by weight based on 100 parts by weight of cooling water together with a known cooling water for cooling such as R-22 or the like. It is preferably provided by an anionic powder having 3 to 5 parts by weight as a standard.

Herein, the coolant has 5 to 10 parts by weight of platinum powder based on 100 parts by weight of cooling water. When platinum powder is less than the weight part, a synergistic effect of thermal conductivity is insufficient, and when platinum powder exceeds the weight part. The thermal conductivity is high, but compared to the cooling water having a phase change, platinum powder having a particle structure may cause problems such as settling or slowing down of moving speed depending on the phase change state of the cooling water. Therefore, it is preferable to have the above critical significance. .

In addition, the refrigerant has an anion powder of 3 to 5 parts by weight based on 100 parts by weight of the cooling water, when the anion powder is less than the weight part, the refrigerant circulated in the evaporator 124 heat exchanged with hot air or water vapor As the amount of negative ions released to the outside of the evaporator 124 when the state changes, a lot of loads are caused in the ionization process of the electrostatic agglomeration means 140 described below, and when the anion powder exceeds the weight part, the negative ions release effect is increased. However, the negative ion powder having a particle structure compared to the cooling water having a phase change may cause problems such as precipitation or decrease in the moving speed according to the phase change state of the cooling water. Therefore, it is preferable to have the critical significance as described above.

On the other hand, according to the present invention, the refrigerant circulation pipe corresponding to the evaporator 124 located inside the housing 110, the corrosion occurs due to the moisture condensation of air or vapor during long-term use is cooled when the refrigerant leaks to the corrosion occurrence site Since there is a problem that the efficiency is lowered, it is preferable that the composite polymer composition for preventing corrosion is coated on the refrigerant circulation pipe surface.

The composite polymer composition, 50 to 60 parts by weight of the filler is added and mixed to 100 parts by weight of the polymer, the polymer is a silicone resin (Si resin), epoxy resin (acrylic resin), acrylic resin (acrylic resin), mixtures thereof and their The filler is selected from the group consisting of copolymers, and the filler includes a first filler having a first average particle diameter, a second filler having a second average particle diameter, and a third filler having a third average particle diameter, wherein the first average particle size Is 10 to 30㎛ larger than the remaining average particle size, the second average particle value divided by the first average particle value is 0.17 to 0.26, the third average particle value divided by the first average particle value is 0.09 To 0.11, the volume resistance of the first filler, the second filler and the third filler is 10 ⁴ Ωcm or more, the first filler, the second filler and the third filler is the average value of the short diameter / long diameter is 0.6 to 0.8, Sum of the sum of the mass of the second filler / sum of the mass of the first filler Is 11 to 16 or the sum of the sum of the third filler mass / sum of the sum of the first filler mass is 4.2 to 5.2, and the first filler, the second filler, and the third filler are alumina (Al 2 O 3), boron nitride (BN), and nitride. Aluminum (AlN), silicon nitride (Si3N4), magnesia (MgO), beryllia (BeO), zinc oxide (ZnO), silicon carbide (SiC), zirconia (ZrO2) and mixtures thereof.

Here, to add 50 to 60 parts by weight of the filler to 100 parts by weight of the polymer, the thermal conductivity efficiency is lowered when the filler is less than the weight part, when the filler exceeds the weight part, the viscosity range can not be maintained, the surface of the pipe Since there is a problem that the workability when coating, it is good to have the critical significance as described above.

In addition, the first filler, the largest of the fillers, has an average particle diameter in the range of 10 to 30㎛, if outside the above range can maintain a suitable viscosity range when mixing with the polymer coating on the surface of the pipe Since the workability can be secured and the surface of the pipe can be maintained smoothly, it is preferable to have the above critical significance.

In addition, the second filler is to fill the space between the polymer and the first filler, the second average particle diameter divided by the first average particle size has an average particle diameter corresponding to 0.17 to 0.26, the average as described above If the particle size does not have a particle size, the thermal conductivity may be deteriorated due to being in contact with the first filler and thus having the critical significance as described above.

In addition, the third filler, filling the space between the first filler and the second filler, the third average particle value divided by the first average particle value has an average particle diameter corresponding to 0.09 to 0.11, If it does not have an average particle size, such as the contact with the first filler can be spaced apart and the thermal conductivity may be degraded, it is preferable to have the critical significance as described above.

In addition, the volume resistance of the first filler, the second filler and the third filler is preferably 10 ⁴ Ωcm or more, and if the volume resistance is less than 10 ⁴ Ωcm, the current according to the spark generation of the electrostatic agglomeration means 140 in the pipe Since there is a problem that a short circuit occurs when it is applied, it is good to have the critical significance as described above.

In addition, the first filler, the second filler and the third filler is preferably the average value of the short diameter / long diameter is 0.6 to 0.8, when the average value of the short diameter / long diameter does not have the above space between the large filler particles is completely filled Since the heat conduction characteristics may be lowered since it is not supported, it is preferable to have the critical meaning as described above.

In addition, the sum of the sum of the second filler mass / the sum of the first filler mass is 11 to 16, or the percentage of the sum of the sum of the third filler mass / the first filler mass is preferably 4.2 to 5.2, the mass ratio as described above In the case of not having a small filler, only a small filler may be added to fill a space formed by a large filler, but a large filler may be added or a small filler may be spaced apart, thereby degrading the thermal conductivity.

Therefore, when the above-mentioned composite polymer composition is coated on the refrigerant circulation pipe, the corrosion of the pipe can be prevented by preventing moisture in air or vapor from condensing or condensing on the surface of the pipe without degrading the heat conduction function of the pipe. have.

Therefore, according to the cooling means 120, while cooling the hot air or steam and at the same time so that the water has a saturated state to improve the water removal efficiency of the water removal means 130 described later, and further described electrostatic agglomeration means ( By reducing the risk of fire at 140, the fine dust removal efficiency can also be improved.

The water removing unit 130 is configured at the rear end of the cooling unit 120 and is a means for condensing and sedimenting the water of air or vapor vapor cooled by the cooling unit 120 and removing the inside of the housing 110. It is composed of a plurality of eliminators or chevrons and demister filters which are installed on the end face and allow the movement of air.

Here, the plurality of eliminators or chevrons are continuously arranged with a pitch of 50 mm, but when the distance is less than 50 mm, the air or vapor vapor is impaired and the speed of air or vapor is reduced. And the inflow of air or vapor into the housing 110 is difficult, and in the case of exceeding the interval of 50 mm, the contact area with the air or the vapor decreases, so that the moisture in the air or the vapor condenses and precipitates. Since there is a problem of deterioration, it is preferable to have a critical significance according to the numerical limitation as described above.

On the other hand, according to the present invention, the eliminator or chevron has a problem that corrosion occurs due to the condensation of moisture in the air when used for a long time, so that the water removal efficiency during the formation of the perforation decreases, the coating layer for preventing corrosion It is preferably formed in.

Here, the coating layer may be configured in the same manner as the composite polymer composition applied to the refrigerant circulation pipe.

Therefore, according to the water removing means 130, when the air or the oil introduced into the housing 110 is in contact with the moisture in the air or steam can be condensed and sedimentation removal, through which the particles of volatile substances contained in the water at the same time It can be removed to reduce the risk of fire in the electrostatic agglomeration means 140 described below and to improve the fine dust removal efficiency.

On the other hand, according to the present invention, the coolant circulation pipe corresponding to the section of the evaporator 124 of the cooling means 120 through the eliminator, chevron or demister filter of the water removal means 130 penetrates zigzag It may be, through this, to improve the saturation of water in the air or oil vapor so as to maximize the effect of removing the condensation.

The electrostatic agglomeration means 140 is configured at the rear end of the water removing means 130 and ionized fine dust contained in air or oil vapor from which water is removed by the water removing means 130 to be removed by electrostatic properties. After the fine dust is reduced air or vapor is exhausted through the exhaust port 112, the housing 110 is arranged in parallel to the direction of movement of air or vapor and repeatedly arranged with a predetermined separation interval Discharge space portion formed by cutting the bending panel-type agglomeration plate 141 and the bending panel-type agglomeration plate 141 of opposite polarity and having a rectangular shape in a longitudinal direction perpendicular to the moving direction of air or oil vapor. 142, the discharge portion (1) formed integrally with the bent panel-type agglomeration plate 141 on the discharge space portion 142 and is arranged to be perpendicular to the moving direction of air or oil vapor, and formed of a discharge needle 143 protruding 44) and a dust collecting part 145 corresponding to a region other than the discharge part 144 and the discharge space part 142 on the bent panel type aggregation plate 141 and collecting fine dust particles during discharge of the discharge part 144. do.

Therefore, according to the electrostatic agglomeration means 140, as the bent panel-type agglomeration plate 141 is bent, it may have a configuration that has the same cross-sectional area as the conventional flat plate agglomeration plate, but the total area is increased, thereby, The spaced distance between the agglomerate plate having the opposite polarity as the increased area is arranged to be wider, and the electric short is generated in the space between the agglomerate plate by the moisture in air or steam while having the same cohesive efficiency as the conventional flat agglomerate plate. The problem can be prevented.

Hereinafter, the operation of the fine dust reduction device having the configuration as described above is as follows.

First, air or vapor containing fine dust is introduced into the housing 110 from an industrial facility or the outside.

Thereafter, the air or the steam having a high temperature is cooled by the cooling means 120 configured in the housing 110 and the water of the air or the steam is saturated.

Thereafter, the moisture in the air or the vapor is condensed and settled by the eliminator, the chevron, or the demister filter of the water removing means 130 configured at the rear end of the cooling means 120.

Thereafter, the discharge portion 144 and the discharge space portion 142 formed in the bent panel type aggregation plate 141 of the electrostatic agglomeration means 140 formed at the rear end of the water removing means 130 are discharged from the air or vapor. After the fine dust has an ionic state, the fine particles are adsorbed and removed by the electrostatic property.

Thereafter, air or oil vapor having reduced dust is exhausted to the outside of the housing 110.

Therefore, according to the fine dust reduction device of the present invention, the aggregation plate 141 is agglomerated to fine particles can be configured to increase the total area even if the cross-sectional area is minimized, the aggregate plate 141 as the total area is increased It is possible to widen the spacing interval of the, it can have the same cohesive efficiency as the conventional flat plate aggregation plate.

In addition, the moisture of the air or vapor containing fine dust at the front of the agglomeration plate 141 is cooled and condensed to remove the volatile particles in the water at the time of removal of moisture, thereby reducing the risk of explosion due to electrical short It is prevented, and the fine dust removal efficiency of the aggregation plate 141 can also be improved.

In the above-described invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the invention. Therefore, the scope of the invention should not be defined by the described embodiments, but should be defined by the claims and their equivalents.

Claims (6)

A housing (110) having a tubular structure through which air or vapor containing fine dust flows in and out;
An inlet fan (not shown) configured at an inlet 111 communicating with the inside of the housing 110 and allowing air or vapor to flow into the housing 110;
Cooling means 120 is configured at the rear end of the inlet fan (not shown) to cool the hot air or steam;
A water removal means (130) configured at the rear end of the cooling means (120) to condense and settle and remove moisture of air or oil vapor cooled by the cooling means (120); And
After the adsorption and removal of the fine dust contained in the air or oil vapor is removed by the water removal means 130 and the moisture is removed by the moisture removal means 130 through the electrostatic properties of the air or oil vapor is reduced It includes an electrostatic agglomeration means 140 to be exhausted through the exhaust port 112,
The electrostatic agglomeration means 140,
A bent panel type agglomeration plate 141 of opposite polarity, which is configured to be parallel to the moving direction of air or vapor in the housing 110 and is repeatedly arranged at a predetermined interval;
A discharge space portion 142 having a rectangular shape by cutting of the bent panel type agglomerated plate 141;
A discharge part 144 formed of a discharge needle 143 protruding integrally with the bent panel type aggregation plate 141 on the discharge space part 142; And
And a dust collecting part 145 corresponding to a region other than the discharge part 144 and the discharge space part 142 on the bent panel type agglomerating plate 141 and collecting fine dust particles during discharge of the discharge part 144. Fine dust reduction device. The method of claim 1, wherein the cooling means 120,
It is installed on the inner shear surface of the housing 110, and includes a cooling cycle to enable the movement of air or oil vapor,
The cooling cycle,
Inside the housing 110 of the compressor 121, the condenser 122 located on one side of the compressor 121, the expansion valve 123 located on one side of the condenser 122, and the housing 110 configured outside the housing 110. Fine dust reduction device, characterized in that it comprises an evaporator (124) is installed in the front shear surface of the housing 110 in a coil shape, zigzag and mesh structure. The method of claim 2, wherein the refrigerant circulating in the cooling cycle,
With cooling water for cooling,
Fine dust reduction device comprising a platinum powder having a high thermal conductivity having 5 to 10 parts by weight based on 100 parts by weight of cooling water and an anion powder having 3 to 5 parts by weight based on 100 parts by weight of cooling water. According to claim 2, Refrigerant circulation pipe corresponding to the evaporator 124 located inside the housing 110,
The composite polymer composition is coated on the refrigerant circulation pipe surface,
The composite polymer composition,
50 to 60 parts by weight of the filler is added and mixed to 100 parts by weight of the polymer,
The polymer is
Si resin, epoxy resin, acrylic resin, mixtures thereof and copolymers thereof, and the filler is a first filler having a first average particle diameter, a second average A second filler having a particle diameter and a third filler having a third average particle diameter,
The first average particle size is 10 to 30 μm, which is larger than the remaining average particle sizes, the second average particle value divided by the first average particle size is 0.17 to 0.26, and the third average particle value is divided by the first average particle value. The value divided by 0.09 to 0.11, the volume resistance of the first filler, the second filler and the third filler is more than 10 ⁴ Ωcm, the first filler, the second filler and the third filler is the average value of short diameter / long diameter 0.6 to 0.8, the sum of the sum of the second filler / the sum of the first filler mass is 11 to 16, or the percentage of the sum of the sum of the third filler / the sum of the first filler mass is 4.2 to 5.2, the first filler, The secondary filler and the third filler include alumina (Al 2 O 3), boron nitride (BN), aluminum nitride (AlN), silicon nitride (Si 3 N 4), magnesia (MgO), beryllia (BeO), zinc oxide (ZnO), and silicon carbide ( SiC), zirconia (ZrO2) and fine dust, characterized in that selected from the group consisting of Device. The method of claim 1, wherein the water removal means 130,
Fine dust reduction device, characterized in that composed of a plurality of eliminators or chevron and the demister filter is installed on the inner shear surface of the housing 110 to enable the movement of air. delete

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