KR102327163B1 - Oilmist condensation recovery system of electrostatic precipitator type - Google Patents

Abstract

The present invention relates to an electrostatic precipitation type oil vapor condensing and recovery device composed of an electric dust collector and a cooling condenser integrated, wherein a discharge electrode to which a (-) voltage is applied is installed at the front end, and a dust collecting electrode to which a (+) voltage is applied is installed at the rear end, It relates to an electrostatic precipitation type oil vapor condensing and recovery device that allows the refrigerant to flow through the dust collecting pole of the rear stage, so that the oil vapor charged at the discharge electrode part of the front stage is collected at the dust collecting pole of the rear stage and collided with the discharge electrode part and cooled and condensed.

Description

OILMIST CONDENSATION RECOVERY SYSTEM OF ELECTROSTATIC PRECIPITATOR TYPE

The present invention relates to an electrostatic precipitation type oil vapor condensing and recovery device composed of an electric dust collector and a cooling condenser integrated, wherein a discharge electrode to which a (-) voltage is applied is installed at the front end, and a dust collecting electrode to which a (+) voltage is applied is installed at the rear end, It relates to an electrostatic precipitation type oil vapor condensing and recovery device that allows the refrigerant to flow through the dust collecting pole of the rear stage, so that the oil vapor charged at the discharge electrode part of the front stage is collected at the dust collecting pole of the rear stage and collided with the discharge electrode part and cooled and condensed.

In the past, biomaterials such as waste wood, sawdust, agricultural and fishery residues, and organic sludge were recycled using the heat generated by simple incineration to produce steam. Many technologies have been disclosed in which the carbon component in the material is vaporized in the form of droplets, cooled and condensed, and recovered as bio-oil for use as fuel.

In addition, waste plastics and vinyl are also pyrolyzed and vaporized at 300° C. to 400° C. in the same manner as the above thermal decomposition method, and then cooled and condensed to recover the oil as oil.

On the other hand, when drying in a dryer to recycle waste such as sludge or soybean dregs, the moisture or oil contained in the waste evaporates and turns into water vapor or oil vapor. Therefore, it is necessary to suppress the generation of white smoke by collecting moisture or oil vapor.

Therefore, as described above, it is necessary to develop a technology capable of collecting and recovering oil vapor or moisture in the form of droplets generated during thermal decomposition or drying of biomaterial-derived waste with high efficiency.

In order to collect and recover the high-temperature droplet or mist-like oil vapor that is generated in various ways as described above, the temperature of the exhaust gas containing the oil vapor is lowered to condense the oil vapor, and the particle size is increased while the oil vapor is agglomerated. The cooling condensate recovery method is often used.

As one of the condensation methods, there is a water spray cooling condensation method. This method is a method of collecting and removing oil vapor by cooling and condensing it by directly spraying water on the exhaust gas. A separate oil-water separation device is required, and when the oil vapor component is water-soluble oil, it is not separated from water and the sprayed water is generated as a large amount of wastewater, so a separate wastewater treatment is required.

As another cooling condensing recovery method, there is a heat exchange cooling condensing ash method using a heat exchanger. In this method, the exhaust gas passes through the inner pipe of the heat exchanger, and the oil vapor in the exhaust gas is cooled and condensed in the pipe cooled by the water contained in the outer cylinder. As a method of collecting and removing the vapor, the internal pipe is often clogged as the collected oil vapor solidifies in the pipe, which makes continuous operation difficult and requires frequent cleaning of the internal pipe.

On the other hand, a method of collecting oil vapor contained in exhaust gas by using the electrostatic power of an electric dust collector is also used. Such an electric dust collector uses a high voltage of 20,000 to 60,000 V between a (+) pole dust collector and a (-) pole discharge electrode. When applied, a lot of electrons are emitted from the discharge electrode, which is the (-) pole, and electrons are filled in the dust or droplets in the exhaust gas flowing between the dust collecting plate and the discharge electrode, turning the dust or droplets into (-), and eventually they are attracted and attached to the dust collecting plate, which is the (+) pole. It is a dust collector using the electrostatic force that is collected and collected. In particular, in the case of droplets, they are quickly aggregated with each other after being collected on a dust collecting plate and flow down the dust collecting plate as the particle size increases.

As described above, in the electric dust collection method, a discharge electrode is installed at the front end and a dust collector plate is placed at the rear end to apply electrons generated from the discharge electrode to the exhaust gas flowing into the electrostatic precipitator to turn (-) dust or droplets contained in the exhaust gas and then to the rear end In the ionizing electric dust collecting method that collects from the dust collecting plate of There is a flat electric field-type electric dust collection method collected in It is widely used to remove the generated smoke, and the flat electric field type electrostatic precipitator is widely used to collect dust in places where a lot of dust is generated such as thermal power plants or cement factories. .

However, until now, in the case of collecting droplets using an electric dust collector alone, if the temperature of the exhaust gas flowing into the electric dust collector is high, the temperature does not drop significantly even while the exhaust gas passes through the electric dust collector. There is a problem in that the collection efficiency is gradually lowered when the oil vapor is used for a long period of time because there is a case where the oil vapor evaporates and scatters again due to the high temperature of the exhaust gas. In order to solve this problem, a device that performs cooling and condensation at the same time as dust collecting at the dust collecting plate of an electric precipitator has been developed. An electrostatic precipitator having a sufficient cooling and condensation effect has not been developed.

According to the circumstances as described above, the present invention sufficiently prevents the oil vapor collected on the dust collecting plate from evaporating and re-scattering due to the high-temperature exhaust gas by fusion of the electric dust collector and the cooling condenser, and at the same time, despite the fusion of the electric dust collector and the cooling condenser We would like to present a technology for a new electrostatic precipitation type oil vapor condensing recovery device that can maximize the practical use rate in industrial sites because the volume of the entire device can be configured very compactly.

Next, the prior art existing in the field to which the technology of the present invention pertains will be briefly described, and then the technical matters that the present invention intends to achieve differently compared to the prior art will be described.

First, Patent Publication No. 10-2018-0069430 (published on June 25, 2018) relates to an electric dust collecting oil vapor dust collector and an electric dust collecting oil vapor dust collecting method using the same, and an intake port through which oil vapor is introduced, and oil vapor in the oil vapor a housing having an intake port for discharging the removed cleaning air; a plurality of metal pipes installed in the housing; a discharge unit installed in the pipe and collecting the oil vapor in the metal pipe by a discharge phenomenon; a power supply unit for supplying power to the discharging unit; a flow path formed outside the metal pipe; and a refrigerant supply unit that supplies a refrigerant to the flow path and causes a condensation phenomenon by cooling the oil vapor in the pipe.

In addition, Japanese Laid-Open Patent Application Laid-Open No. 2006-167853 (published on June 29, 2006) discloses a casing through which a gas containing mist flows, a discharge electrode provided in the casing to generate a discharge, and a dust collecting electrode that absorbs the mist and the dust collector A technology related to a mist collector comprising a cooling means for cooling the pole and a drain for recovering the mist adhering to the dust collecting pole is described.

The prior art document Laid-Open Patent Publication No. 10-2018-0069430 and Japanese Patent Application Laid-Open No. 2006-167853 are a fusion of an electric dust collector and a cooling condenser, and form a flow path through which the refrigerant formed in the cylindrical space where the oil vapor is collected. Although it is a technology that performs cooling condensation and electrostatic precipitation at the same time, as described above, since the cylindrical electric field type electrostatic precipitation method is used, there is a limit to the compact configuration of the device. There was a problem in that the effect of cooling and condensing the oil vapor was not great because the dust collecting plate was arranged in the lateral direction of the direction.

In addition, Patent Publication No. 10-2013-0106479 (published on September 30, 2013) relates to an apparatus and method for recovering a mist solution containing catalyst particles, and more specifically, to a mist having dielectric properties using an electric field. and a mist agglomeration unit to agglomerate; a low-temperature mist charging unit configured to charge the mist coagulated in the mist agglomeration unit, so that evaporation does not occur during charging; The mist charged in the low-temperature mist charged part is collected by using an electric field on the dust collecting plate, but it includes a low-temperature mist dust collecting part equipped with a cooling means so that evaporation does not occur during dust collection, to prevent evaporation of mist generated in the scrubber A technology related to a mist solution recovery device configured to recover catalyst particles contained in mist is described.

The above-mentioned Patent Publication No. 10-2013-0106479 uses an ionizing electric dust collection method in which oil vapor is charged at the front end and then dust is collected on a dust collecting plate at the rear end, and a cooling device is provided in addition to the electric dust collector in the dust collecting unit to perform cooling and condensation. Although there are some similarities with the present invention in that it is carried out, there is a limit to the compact configuration of the device as a whole because the dust collecting plate and the cooling device are provided in separate configurations in the above-mentioned Prior Document Publication No. 10-2013-0106479, In addition, since the cooling device is located at the rear end of the dust collecting plate, there is a problem in that the oil vapor condensed by the dust collecting plate cannot be prevented from being re-scattered by the continuously supplied high-temperature oil vapor.

The present invention was created to solve the above problems, and the electrostatic precipitation type oil vapor condensation in which the electric dust collector and the cooling condenser are integrated in order to solve and supplement the various problems caused by recovering oil vapor by washing with water, heat exchange method, and single electrostatic precipitation method It relates to a recovery device, which is provided at the front end to charge the oil vapor contained in the exhaust gas at the discharge electrode part to which a (-) voltage is applied, and is provided at the rear end to apply a (+) voltage and is opposite to the flow direction of the exhaust gas. The charged oil vapor is electrically collected and collided on the collision condensing plate disposed as An object of the present invention is to provide an electrostatic precipitation type oil vapor condensing recovery device capable of preventing re-flying due to the high temperature of the gas.

The electrostatic precipitation type oil vapor condensing and recovery device in which an electric dust collector and a cooling condenser are integrally configured according to an embodiment of the present invention is an inlet duct through which exhaust gas containing oil vapor is introduced, and is connected to the inlet duct and faces the inlet duct an inlet including an inlet hood having a shape in which the cross-sectional area increases in the direction; A discharge plate connected to the inlet hood in a direction opposite to the inlet duct, to which a negative voltage is applied to charge oil vapor in the exhaust gas introduced from the inlet, is opposed to the direction in which the exhaust gas passes, and a predetermined interval at least one discharge electrode part disposed with; A collision condensing plate that is connected to the discharge electrode in a direction opposite to the inlet hood and is cooled by a refrigerant while a positive voltage is applied to collect oil vapor in the exhaust gas charged by the discharge electrode, through which the exhaust gas passes at least one dust collecting pole unit facing the direction and having a predetermined interval; An outlet hood connected to the dust collecting pole in a direction opposite to the discharge electrode and having a shape in which a cross-sectional area decreases in a direction opposite to the dust collecting pole, and connected to the outlet hood in a direction opposite to the dust collecting pole, the dust collecting pole an outlet including an outlet duct through which exhaust gas passing through the unit is discharged; and a high voltage generator for applying a (-) voltage to the discharge electrode part and a (+) voltage to the dust collecting electrode part.

In addition, as an embodiment, the electrostatic precipitation type oil vapor condensing recovery device includes: a hopper connected to a lower portion of the dust collecting pole; and an outlet connected to the lower part of the hopper, through which the oil collected by the hopper is discharged after being aggregated and descending from the dust collecting pole.

Also, as an embodiment, a perforated plate having a plurality of holes having a predetermined diameter formed in a predetermined pattern is provided between the dust collecting pole portion and the discharge portion.

In addition, as an embodiment, the discharge electrode unit, the discharge electrode housing connected to the inlet hood in a direction opposite to the inlet duct; and at least one or more discharge plates arranged at predetermined intervals inside the discharge electrode housing and to which a (-) voltage is applied to charge the oil vapor in the exhaust gas introduced from the inlet. .

In addition, as an embodiment, the discharge plate, a support in the form of a rectangular frame; and a plurality of discharge wires extending vertically to the upper and lower sides of the support, or extending in a horizontal direction to the inner left and right sides of the support, a plurality of discharge wires disposed inside the support at predetermined intervals.

In addition, as an embodiment, the discharge electrode unit includes a discharge frame that bundles and connects a plurality of the discharge plates on the upper portion of the discharge electrode unit; and the support rod protrudes out of the upper surface of the discharge electrode unit housing and is fixed, so that the discharge frame is installed in a suspended form inside the discharge electrode unit housing.

In addition, as an embodiment, in the coupling structure of the support rod and the discharge electrode housing, an insulating insulator is provided on the upper portion of the discharge electrode housing to insulate the support rod and the discharge electrode housing, and the support rod is insulated. It is installed through the insulator and characterized in that it has a structure in which the support rod protruding above the insulator is fixed with a fixing pin.

In addition, as an embodiment, the collision condensing plate may include: a support pipe part having a rectangular frame shape provided with a refrigerant inlet and a refrigerant outlet; Refrigerant in which a plurality of pipes extending vertically to the upper and lower sides of the support pipe part or extending in a horizontal direction to the inner left and right sides of the support pipe part in a structure through which the refrigerant flows are disposed inside the support pipe part at predetermined intervals pipe part; and a wing part attached to the outer surface of each pipe in the refrigerant pipe part along the longitudinal direction of the pipe and having a plurality of blades having ends bent or bent in the direction in which the exhaust gas flows. characterized.

In addition, in an embodiment, the dust collecting pole unit may include: a dust collecting pole housing connected to the discharge electrode unit in a direction opposite to the inlet hood; and at least one collision condensing plate disposed at a predetermined interval inside the dust collecting electrode housing and cooled by a refrigerant while applying a positive voltage to collect oil vapor in the exhaust gas charged from the discharge electrode. characterized in that

In addition, as an embodiment, the refrigerant inlet and the refrigerant outlet are provided on the upper part of the support pipe, and the refrigerant inlet and the refrigerant outlet protrude out of the upper surface of the dust collecting pole housing and are fixed, so that the collision condensing plate It is characterized in that it is installed in the form of hanging inside the dust collecting pole housing.

In addition, as an embodiment, the refrigerant inlet connected to the refrigerant inlet for supplying the refrigerant to the collision condensing plate; and a refrigerant outlet connected to the refrigerant outlet through which the refrigerant flows from the collision condensing plate.

The present invention relates to an electrostatic precipitation type oil vapor condensing and recovery device in which an electric dust collector and a cooling condenser are integrated. +) voltage is applied and the charged oil vapor is electrostatically collected and collided on the collision condensing plate disposed in the direction opposite to the traveling direction of the exhaust gas, thereby increasing the particle size of the oil vapor and recovering it as oil. There is an effect of preventing the oil vapor condensed in the collision condensing plate from re-flying due to the high heat of the exhaust gas by being cooled by the

Further, in the present invention, in configuring the electrostatic precipitation type oil vapor condensing recovery device as described above, the discharge electrode part is configured such that the surface of the discharge plate faces in a direction opposite to the flow direction of the exhaust gas, and the dust collecting electrode part is configured to move the exhaust gas By configuring the surface of the collision condensing plate to face in the direction opposite to the direction, the entire device can be installed compactly. It has the effect of maximizing the oil vapor condensation recovery efficiency.

In addition, the present invention has a structure in which, in configuring the collision condensing plate, the collision blades in which the oil vapor in the exhaust gas collides are formed on the outer surface of the pipe through which the refrigerant flows densely arranged in the vertical or horizontal direction, the collision blades By having at least one in each of the inflow and outflow directions of the exhaust gas around the pipe, the oil vapor passing through the collision condensing plate without colliding with the collision wing is minimized, thereby maximizing the efficiency of condensing and recovering the oil vapor. there is

In addition, the present invention does not generate waste water because the cooling water used in the collision condensing collector does not come into direct contact with the oil vapor. Also, by combining the electric dust collection method and the cooling condensation inertial collision method in an integrated manner, the operation and maintenance is convenient and the oil vapor recovery efficiency is high. It works.

1 is an overall assembly view showing a discharge electrode part, a dust collecting electrode part and the inside of the discharge part by partially cutting the surface of the electrostatic precipitation type oil vapor condensing recovery device according to an embodiment of the present invention.
Figure 2 is an assembly view showing the discharge electrode of the electrostatic precipitation type oil vapor condensing recovery device according to an embodiment of the present invention.
3 is an assembly view showing a dust collecting pole of the electrostatic precipitation type oil vapor condensing recovery device according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment of the electrostatic precipitation type oil vapor condensing recovery device according to the present invention according to the present invention is described in detail so that those of ordinary skill in the art can easily practice the present invention. let me explain

In each drawing of the present invention, the size or dimensions of the structures are enlarged or reduced than the actual size for clarity of the present invention, and well-known components are omitted to reveal the characteristic configuration, so it is not limited to the drawings. .

In the detailed description of the principle of the preferred embodiment of the present invention, if it is determined that a detailed description of a related well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

The present invention relates to an electrostatic precipitation type oil vapor condensing and recovery device composed of an electric dust collector and a cooling condenser integrated, wherein a discharge electrode to which a (-) voltage is applied is installed at the front end, and a dust collecting electrode to which a (+) voltage is applied is installed at the rear end, It relates to an electrostatic precipitation type oil vapor condensing and recovery device that allows the refrigerant to flow through the dust collecting pole of the rear stage, so that the oil vapor charged at the discharge electrode part of the front stage is collected at the dust collecting pole of the rear stage and collided with the discharge electrode part and cooled and condensed.

Hereinafter, an electrostatic precipitation type oil vapor condensing recovery device according to an embodiment of the present invention will be described with reference to the accompanying drawings.

1 is an overall assembly view showing the interior of the discharge electrode 200, the dust collecting electrode 300, and the discharge unit 500 by partially cutting the surface of the electrostatic precipitation type oil vapor condensing recovery device according to an embodiment of the present invention to be exposed. am.

As shown in Fig. 1, the electrostatic precipitation type oil vapor condensing recovery device according to the present invention is an electrostatic precipitation type oil vapor condensing recovery device in which an electrostatic precipitator and a cooling condenser are integrated.

To this end, the electrostatic precipitation type oil vapor condensing recovery device according to the present invention includes an inlet part 100 through which exhaust gas is introduced from the outside, a discharge electrode part 200 for charging oil vapor in the exhaust gas, and collision cooling and cooling of the charged oil vapor in the exhaust gas. The dust collecting pole part 300 for collecting and condensing in an electric dust collecting method, the outlet part 400 from which the exhaust gas from which the oil vapor is removed is discharged, the discharge (-) voltage and the dust collection (-) voltage and dust ( +) is configured to include a high voltage generator 207 for applying a voltage and a discharge unit 500 for discharging the oil vapor (oil) condensed in the dust collecting pole 300 .

More specifically, the inlet 100 includes an inlet duct 102 and an inlet hood 103, and the inlet duct 102 is to which the exhaust gas containing oil vapor is introduced, and the inlet hood 103 ) is connected to the inlet duct 102 and has a shape in which the cross-sectional area increases in a direction opposite to the inlet duct 102 .

The discharge electrode part 200 is connected to the inlet hood 103 in a direction opposite to the inlet duct 102, and a (-) voltage is applied to charge the oil vapor in the exhaust gas introduced from the inlet 100. It has a structure in which at least one discharge plate 203 to be applied is disposed to face a direction in which exhaust gas passes, and to have a predetermined interval.

The dust collecting electrode part 300 is connected to the discharge electrode part 200 in a direction opposite to the inlet hood 103, and in order to collect oil vapor in the exhaust gas charged by the discharge electrode part 200, a (-) voltage is applied. It has a structure in which at least one collision condensing plate 304, which is applied and cooled by the refrigerant, is disposed at a predetermined interval to face the direction in which the exhaust gas passes.

The outlet 400 includes an outlet hood 401 and an outlet duct 402 , and the outlet hood 401 is connected to the dust collecting pole 300 in a direction opposite to the discharge electrode 200 and the It has a shape in which the cross-sectional area decreases in a direction opposite to the dust collecting pole 300 , and the outlet duct 402 is connected to the outlet hood 401 in a direction opposite to the dust collecting pole 300 to the dust collecting pole 300 . ), the exhaust gas is discharged.

In addition, the high voltage generator 207 includes a cathode wire 211 for applying a (-) voltage to the discharge electrode unit 200 and an anode wire 210 for applying a (+) voltage to the dust collecting electrode unit 300 . .

The discharge unit 500 includes a discharge unit 501 and an outlet port 502 , the discharge unit 501 is sealed and connected to the lower portion of the dust collecting pole unit 300 , and the discharge port 502 is the discharge port 502 . It is hermetically connected to the lower part of the unit 501 , and the oil collected by the discharge unit 501 is discharged after being aggregated and descending from the dust collecting pole unit 300 .

At this time, there is provided a porous plate in which a plurality of holes 503 having a predetermined diameter are formed in a predetermined pattern between the dust collecting pole part 300 and the exhaust part 500, so that the exhaust gas is discharged from the exhaust part ( 500), and only the oil that is condensed by dust collection/collision/cooling in the dust collecting pole part 300 and flows downward is discharged to the discharge part 500 through the hole 503.

2 is an assembly view showing the discharge electrode unit 200 of the electrostatic precipitation type oil vapor condensing recovery device according to an embodiment of the present invention.

1 and 2, the discharge electrode unit 200 in the electrostatic precipitation type oil vapor condensing recovery device according to the present invention is a discharge electrode housing 206 covering the outside of the discharge electrode unit 200 and oil vapor in the exhaust gas. It is configured to include a discharge plate 203 for charging.

The discharge electrode housing 206 has a structure connected to the inlet hood 103 in a direction opposite to the inlet duct 102 .

In addition, the discharge plate 203 has a flat plate shape and is disposed at a predetermined interval inside the discharge electrode unit housing 206 to charge oil vapor in the exhaust gas introduced from the inlet unit 100 ( -) Voltage is applied.

To this end, the discharge plate 203 has a structure in which the discharge wire part is formed inside the support 201 in the form of a rectangular frame. In more detail, the discharge wire unit includes a discharge wire 202 extending in a vertical direction on the inner upper and lower sides of the support 201 or horizontally extending on the inner left and right sides of the support 201 inside the support 201 . It has a structure in which a plurality are arranged at a predetermined interval in the .

In addition, the discharge electrode unit 200 includes a discharge frame 204 for connecting a plurality of the discharge plates 203 at the upper portion of the discharge electrode unit 200 , and the upper portion of the discharge frame 204 is (- ) A plurality of support rods 205 to which voltage is applied are provided, and the support rods 205 protrude out of the upper surface of the discharge electrode housing 206 and are fixed, so that the discharge frame 204 is connected to the discharge electrode housing ( 206) is installed in the form of hanging inside.

In addition, in the coupling structure of the support rod 205 and the discharge electrode housing 206 , the upper portion of the discharge electrode housing 206 is insulated to insulate the support rod 205 and the discharge electrode housing 206 . An insulator 208 is provided.

The support rod 205 is installed through the insulating insulator 208 , and the support rod 205 protruding above the insulating insulator 208 has a structure in which it is fixed with a fixing pin 212 .

3 is an assembly view showing the dust collecting pole part 300 of the electrostatic precipitation type oil vapor condensing recovery device according to an embodiment of the present invention.

1 and 3, the dust collecting pole part 300 in the electrostatic precipitation type oil vapor condensing recovery device according to the present invention covers the outside of the dust collecting pole part 300. The dust collecting pole housing 303 and the discharge electrode part 200 ) is configured to include a collision condensing plate 304 that collects / collides / cools and condenses oil vapor in the charged exhaust gas.

The dust collecting electrode housing 303 has a structure connected to the discharge electrode 200 in a direction opposite to the inlet hood 103 .

In addition, at least one collision condensing plate 304 is disposed inside the dust collecting pole housing 303 at a predetermined interval, and in order to collect oil vapor in the exhaust gas charged by the discharge electrode 200 , a (+) voltage It is applied and cooled by the refrigerant at the same time.

By installing a plurality of collision condensing plates 304 at regular intervals as described above, the exhaust gas is collided and condensed several times to lower the temperature of the exhaust gas and further increase the efficiency of collecting oil vapor, and multiple collision condensing plates ( By applying (+) electricity to 304 , the collision condensing plate 304 may collect negatively charged oil vapor particles by electrostatic force.

In addition, the collision condensing plate 304 has a structure in which a refrigerant pipe portion is provided inside the support pipe portion 305 , and a wing portion is formed in each pipe 301 of the refrigerant pipe portion.

More specifically, the support pipe part 305 has a rectangular frame shape provided with a refrigerant inlet and a refrigerant outlet.

The refrigerant pipe portion extends vertically to the upper and lower sides of the inner side of the support pipe or extends horizontally to the inner left and right sides of the support pipe portion 305 to form a pipe 301 having a structure in which the refrigerant flows inside the support pipe. It has a structure in which a plurality are arranged at a predetermined interval in the .

The wing portion is attached to the outer surface of each pipe 301 in the refrigerant pipe portion along the longitudinal direction of the pipe 301 and has a plurality of wings 302 having ends bent or bent in the direction in which exhaust gas flows. It has a dog-formed shape.

On the other hand, the refrigerant inlet and the refrigerant outlet are provided on the upper part of the support pipe, and the refrigerant inlet and the refrigerant outlet protrude out of the upper surface of the dust collecting pole housing 303 and are fixed, so that the collision condensing plate 304 ) has a structure in which the dust collecting pole housing 303 is installed in a suspended form.

On the other hand, the electrostatic precipitation type oil vapor condensing recovery device according to the present invention is located outside the dust collecting pole housing 303 and is connected to the refrigerant inlet through the refrigerant supply pipe 105 to supply the refrigerant to the collision condensing plate 304 . A refrigerant inlet tube 104 and a refrigerant outlet tube 106 located outside the dust collecting pole housing 303 and connected to the refrigerant outlet through a refrigerant discharge pipe 107 through which the refrigerant flows out from the collision condensing plate 304 . ) is included.

On the other hand, the high voltage generator 207 is a device for supplying 20,000 to 60,000 V of high voltage (-) electricity to the discharge electrode unit 200 , and a 220 V single-phase supply from the power receiving unit 209 to the high voltage generator 207 . Converts 60Hz AC to DC over 20,000 V. In addition, in order to apply the high voltage produced to the device, (-) electricity generated from the cathode wire 211 is connected to the support rod 205, and (+) electricity generated from the anode wire 210 is applied to the dust collecting pole part 300 . The dust collecting pole 300 may be connected to a separate electrical transmission rod connected to a dust collecting plate, or directly connected to the dust collecting pole housing 303 .

As described above, the present invention has been described with reference to the embodiments shown in the accompanying drawings, which are merely exemplary, and various modifications and equivalent other embodiments may be made by those of ordinary skill in the art. You will understand that it is possible. Therefore, the technical protection scope of the present invention should be defined by the following claims.

100: inlet
102: inlet duct
103: inlet hood
104: refrigerant inlet
105: refrigerant supply pipe
106: refrigerant outlet
107: refrigerant discharge pipe
200: discharge electrode part
201: support
202: discharge wire
203: discharge plate
204: discharge frame
205: support bar
206: discharge electrode housing
207: high voltage generator
208: insulator
209: power receiver
210: positive wire
211: cathode ray
212: pin
300: dust collecting pole
301: pipe
302: wings
303: dust collecting pole housing
304: collision condensing plate
305: support pipe part
400: outlet
401: spill hood
402: outlet duct
500: discharge unit
501: Hopper
502: outlet
503: Hall
504: perforated plate

Claims (9)

In the electrostatic precipitation type oil vapor condensing recovery device composed of an electric dust collector and a cooling condenser integrally,
an inlet including an inlet duct through which the exhaust gas containing oil vapor is introduced, and an inlet hood connected to the inlet duct and having a cross-sectional area increasing in a direction opposite to the inlet duct;
A discharge plate connected to the inlet hood in a direction opposite to the inlet duct, to which a negative voltage is applied to charge oil vapor in the exhaust gas introduced from the inlet, is opposed to the direction in which the exhaust gas passes, and a predetermined interval at least one discharge electrode part disposed with;
A collision condensing plate that is connected to the discharge electrode in a direction opposite to the inlet hood and is cooled by a refrigerant while a positive voltage is applied to collect oil vapor in the exhaust gas charged by the discharge electrode, through which the exhaust gas passes at least one dust collecting pole unit facing the direction and having a predetermined interval;
An outlet hood connected to the dust collecting pole in a direction opposite to the discharge electrode and having a shape in which a cross-sectional area decreases in a direction opposite to the dust collecting pole, and connected to the outlet hood in a direction opposite to the dust collecting pole, the dust collecting pole an outlet including an outlet duct through which exhaust gas passing through the unit is discharged;
a high voltage generator for applying a negative voltage to the discharge electrode and applying a voltage to the dust collecting electrode;
a hopper connected to a lower portion of the dust collecting pole;
an oil discharge unit connected to the lower part of the hopper and including an outlet through which oil collected by the hopper is discharged after being aggregated and descending from the dust collecting pole;
and a perforated plate installed between the dust collecting pole part and the oil discharge part and having a plurality of holes having a predetermined diameter formed in a predetermined pattern;
The collision condensing plate,
a support pipe part having a rectangular frame shape provided with a refrigerant inlet and a refrigerant outlet;
a refrigerant pipe portion extending in a vertical direction to upper and lower sides of the inner side of the support pipe portion and having a structure in which a refrigerant flows therein; and
Electricity comprising a; a wing part attached to the outer surface of each pipe in the refrigerant pipe part along the longitudinal direction of the pipe and having a plurality of blades having ends bent in the direction in which exhaust gas is introduced; Dust-collecting oil vapor condensate recovery device.
According to claim 1,
The discharge electrode part,
a discharge electrode housing connected to the inlet hood in a direction opposite to the inlet duct; and
at least one or more discharge plates arranged at predetermined intervals inside the housing of the discharge electrode unit, and to which a (-) voltage is applied to charge oil vapor in the exhaust gas introduced from the inlet unit; Dust-collecting oil vapor condensate recovery device.
3. The method of claim 2,
The discharge plate is
support in the form of a square frame; and
Electrostatic precipitation type, characterized in that it comprises a; discharge wire portion extending in the vertical direction to the inner upper and lower sides of the support or extending in the horizontal direction on the inner left and right sides of the support is disposed in a plurality of discharge wires at a predetermined interval inside the support Oil vapor condensate recovery system.
4. The method of claim 3,
The discharge electrode part,
A discharge frame for connecting a plurality of the discharge plates in an upper portion of the discharge electrode unit by tying them together;
A plurality of support rods to which a (-) voltage is applied are provided on the upper portion of the discharge frame, and the support rods protrude out of the upper surface of the discharge electrode housing and are fixed, so that the discharge frame is suspended inside the discharge electrode housing. An electrostatic precipitation type oil vapor condensing recovery device, characterized in that it is installed.
5. The method of claim 4,
In the coupling structure of the support rod and the discharge electrode housing,
An insulating insulator is provided on the upper portion of the discharge electrode housing to insulate the support rod from the discharge electrode housing, the support rod is installed through the insulating insulator, and the support rod protruding from the top of the insulator is fixed with a fixing pin. Electrostatic precipitation type oil vapor condensing recovery device, characterized in that it has a structure.
delete According to claim 1,
The dust collecting electrode part,
a dust collecting electrode housing connected to the discharge electrode in a direction opposite to the inlet hood; and
At least one collision condensing plate disposed at a predetermined interval inside the dust collecting pole housing and cooled by a refrigerant while a positive voltage is applied to collect oil vapor in the exhaust gas charged by the discharge electrode part; Electrostatic precipitation type oil vapor condensing recovery device, characterized in that.
8. The method of claim 7,
The refrigerant inlet and the refrigerant outlet are provided at an upper portion of the support pipe,
The electrostatic precipitation type oil vapor condensing recovery device, characterized in that the refrigerant inlet and the refrigerant outlet protrude out of the upper surface of the dust collecting pole housing and are fixed, so that the collision condensing plate is installed in a suspended form inside the dust collecting pole housing.
8. The method of claim 7,
a refrigerant inlet connected to the refrigerant inlet to supply refrigerant to the collision condensing plate; and
and a refrigerant outlet connected to the refrigerant outlet through which the refrigerant flows out from the collision condensing plate.

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