KR102503093B1 - Filter module of the air purification apparatus - Google Patents

Abstract

An embodiment of the present invention relates to a filter module of an air purification device disposed in a work area of nuclear power plant dismantling. The filter module of the air purification device reduces particles or aerosol-type radioactive substances included in dust. The filter module comprises: a filter chamber having the inside in a hollow type and having an inlet on one side and an outlet on the other side; a first filter inclinedly disposed inside the filter chamber; a second filter disposed to be spaced apart from the first filter in the filter chamber; and a fluid spraying unit configured to eliminate dust of the first filter by spraying a fluid toward the first filter.

Description

Filter module of air purifier {FILTER MODULE OF THE AIR PURIFICATION APPARATUS}

Embodiments of the present invention relate to a hydraulic valve device and a hydraulic circuit thereof, and more particularly, to a hydraulic valve device usable for a construction machine and a hydraulic circuit thereof.

In general, when dismantling a nuclear power plant, work such as cutting metal or concrete is performed. At this time, there is a problem in that the operator is exposed to and exposed to radioactive contaminants remaining inside the nuclear power plant as well as dust from the components inside the nuclear power plant.

Specifically, there is a problem in that workers are exposed to radioactive materials remaining in the air and dust from metal or concrete cutting of exposed structures when working in the inside of a nuclear power plant according to a special environment. During this cutting operation inside the dismantled nuclear power plant, radioactive material is exposed to the air in the form of an aerosol, and an air purifying device capable of reducing the radioactive material in the form of aerosol is required to reduce it.

In addition, when working in a dismantled nuclear power plant, there is a limitation of a working space or a limitation of power supply, and an air purifier capable of responding variably from such a working space and working environment is required. Specifically, a filter module of an air purifier capable of reducing the service life of a filter and a separate process for cleaning thereof is required as much as the work is performed inside the nuclear power plant.

An embodiment of the present invention provides a filter module of an air purifier capable of improving the service life of the filter and its efficiency by treating dust by spraying the filter with fluid.

According to an embodiment of the present invention, a filter module of an air purifier for reducing particles or aerosol-type radioactive substances contained in dust has a hollow interior and a filter chamber having an inlet on one side and an outlet on the other side, A first filter disposed obliquely in the filter chamber, a second filter disposed spaced apart from the first filter in the filter chamber, and a fluid ejection unit capable of discharging the first filter by injecting a fluid toward the first filter. do.

In addition, the filter module of the above-described air purifier communicates with one area of the filter chamber, has a filter chamber inclined portion protruding obliquely toward the outside on one side of the lower portion of the filter chamber, and is disposed on the lower portion of the filter chamber inclined portion. The chamber may further include a collection unit capable of collecting substances exhausted from the first filter.

In addition, one surface of the first filter may be inclined so as to face a region of the filter chamber communicating with the inclined portion of the filter chamber.

In addition, the filter module of the above-described air purifier may further include a vibrating unit installed on an inclined portion of the filter chamber to move dust exhausted from the first filter to the chamber collecting unit.

In addition, the fluid injection unit may include a fluid supply member for supplying fluid, and a spray nozzle disposed between the first filter and the second filter to jet the fluid supplied from the fluid supply member toward the first filter. can

Also, the fluid supply member may supply fluid to the vibration unit.

In addition, it may further include a pressure detector for measuring the pressure of the front and rear of the first filter.

Also, the chamber collection unit may be detachably installed from the filter chamber inclination unit.

In addition, one side of the chamber collection unit may further include an inspection window installed to check the inside of the chamber collection unit from the outside.

Alternatively, the filter module of the air purifier for reducing particles or aerosol-type radioactive substances contained in dust according to an embodiment of the present invention has a hollow interior, and a filter chamber having an inlet on one side and an outlet on the other side. And, a first filter disposed inside the filter chamber in a direction crossing the parallel direction connecting the inlet and the outlet, and disposed between the first filter and the outlet to inject fluid toward the first filter and a fluid ejection unit capable of exhausting the first filter.

According to an embodiment of the present invention, the filter module of the air purifier may dedust the dust attached to the filter by spraying a fluid. Accordingly, it is possible to improve the efficiency of the filter installed in the filter module and increase its service life.

In addition, the filter module of the air purifier according to the embodiment of the present invention can be disposed in the dismantling work area of the nuclear power plant, so that the filter module can be cleaned without removing the filter from the filter module for dust containing radioactive materials. Since dust can be effectively cleaned, the risk of workers being exposed to radioactive materials can be effectively reduced.

1 shows an air conditioner in which a filter module according to an embodiment of the present invention is installed.
FIG. 2 shows a filter module of the air conditioner of FIG. 1 .
FIG. 3 shows the fluid ejection unit of FIG. 2 .
4 shows an air conditioner in which a filter module according to another embodiment of the present invention is installed.
5 shows a control module.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. This invention may be embodied in many different forms and is not limited to the embodiments set forth herein.

It is advised that the drawings are schematic and not drawn to scale. Relative dimensions and proportions of parts in the drawings are shown exaggerated or reduced in size for clarity and convenience in the drawings, and any dimensions are illustrative only and not limiting. In addition, the same reference numerals are used to indicate similar features in the same structural elements or parts appearing in two or more drawings.

The embodiments of the present invention specifically represent ideal embodiments of the present invention. As a result, various variations of the diagram are expected. Therefore, the embodiment is not limited to the specific shape of the illustrated area, and includes, for example, modification of the shape by manufacturing.

Hereinafter, referring to FIGS. 1 to 5 , the filter module 200 of the air purifier 101 according to an embodiment of the present invention is installed in the air purifier 101 for reducing radioactive substances.

As shown in FIGS. 1 and 2, the filter module 200 of the air purifier 101 for reducing radioactive substances according to an embodiment of the present invention includes a filter chamber 201 and a first filter 210 and a second filter 220 and a fluid ejection unit 250.

The inside of the filter chamber 201 is hollow. In addition, an inlet 202 is formed on one side of the filter chamber 201 and an outlet 203 is formed on the other side of the filter chamber 201 .

Specifically, the filter chamber 201 is formed long in one direction, and the inlet 202 and the outlet 203 may be formed on both sides along the longitudinal direction of the filter chamber 201 .

Dust containing particles or aerosol-type radioactive materials generated during the dismantling of the nuclear power plant may be introduced into the inlet 202 . In addition, air containing dust passing through the filter chamber 201 may be discharged through the discharge port 203 .

The first filter 210 is inclined inside the filter chamber 201 . Specifically, the first filter 210 may be inclined toward the bottom of the filter chamber 201 . That is, the height direction of the first filter 210 may be disposed to cross the height direction of the filter chamber 201 .

The first filter 210 may filter an aerosol-type radioactive material. For example, the first filter 210 may be a metal filter.

The second filter 220 is spaced apart from the first filter 210 in the filter chamber 201 . Specifically, the second filter 220 may be disposed relatively adjacent to the outlet 203 than the first filter 210 . That is, the first filter 210 and the second filter 220 may be spaced apart from each other along the longitudinal direction of one direction of the filter chamber 201 .

The second filter 220 may filter out aerosol-type radioactive substances that are not filtered by the first filter 210 . The second filter 220 may filter finer radioactive aerosol than the first filter 210 . For example, the second filter 220 may be a HEPA filter.

The fluid spraying unit 250 may spray fluid toward the first filter 210 . In addition, the fluid ejection unit 250 may eject the fluid to purify the first filter 210 by separating dust accumulated in the first filter 210 from the first filter 210 .

Accordingly, the filter module 200 according to an embodiment of the present invention can be used by exhausting the first filter 210 through the fluid injection unit 250, thereby improving the lifespan of the first filter 210 and its Maintenance time and cost for replacement can be reduced.

In addition, the filter module 200 of the air purifier according to an embodiment of the present invention may further include a filter chamber inclined portion 230 and a chamber collection portion 240.

The filter chamber inclined portion 230 may be protruded from one side of the lower portion of the filter chamber 201 to be inclined toward the outside. One side of the filter chamber inclined portion 230 may be installed to communicate with one lower area of the filter chamber 201 . Specifically, the filter chamber inclined portion 230 may be formed in a hopper shape inclined in a direction that becomes narrower as it protrudes from the filter chamber 201 . Also, the filter chamber inclined portion 230 may be disposed relatively adjacent to the inlet 202 rather than the outlet 203 .

For example, an open lower area of the filter chamber 201 is disposed to face one surface of the first filter 210, and dust sprayed from the fluid spraying unit 250 and separated from the first filter 210 is filtered. It may be formed to be introduced into the chamber inclined portion 230 . That is, the first filter 210 is inclined toward a lower portion of the filter chamber 201 in open communication with the filter chamber inclined portion 230, and the first filter 210 is formed through the filter chamber inclined portion 230. Dust dropped from the filter chamber 201 can be effectively moved to the outside.

The chamber collection unit 240 may be detachably installed below the filter chamber inclined unit 230 . In addition, the chamber collecting unit 240 may collect dust, which is a material exhausted from the first filter 210 .

Therefore, the operator can remove the chamber collection part 240 from the filter chamber inclined part 230 to effectively dispose of the dust containing the radioactive material collected therein.

In addition, the chamber collection unit 240 is detachably installed at the bottom of the filter chamber inclination unit 230, so that when processing the dust containing the radioactive material exhausted from the first filter 210, contamination is diffused for the treatment thereof. and minimize waste disposal.

In addition, the filter module 200 according to an embodiment of the present invention may further include a vibration unit 260.

The vibration unit 260 may be installed on the filter chamber inclined unit 230 . In addition, the vibrator 260 generates vibration and transfers it to the inside of the filter chamber inclined part 230 so that the exhausted dust remaining inside the filter chamber inclined part 230 moves to the chamber collecting part 240. can

Therefore, when the dust containing the radioactive material remains in the filter chamber inclined portion 230 by the vibration unit 260, it is prevented from being adsorbed to the first filter 210 by the air flowing into the inlet 202 again. effectiveness can be prevented.

In addition, the filter module 200 according to an embodiment of the present invention may further include an inspection window 241 .

The inspection window 241 is installed on one side of the chamber collecting unit 240 and may be formed of a transparent material so that an operator can check the inside of the chamber collecting unit 240 .

In addition, the fluid ejection unit 250 according to an embodiment of the present invention may further include a fluid supply member 251 and a spray nozzle 252 as shown in FIGS. 2 and 3 .

The fluid supply member 251 may supply fluid. Specifically, the fluid supply member 251 may be a device for storing or generating compressed air.

For example, the fluid supply member 251 may be a device provided inside a dismantled nuclear power plant or a separate compressed air storage device.

The spray nozzle 252 may be disposed between the first filter 210 and the second filter 220 . In addition, the fluid supplied from the fluid supply member 251 may be injected to the other surface of the first filter 210 . That is, the injection nozzle 252 may remove dust accumulated in the first filter 210 by injecting the fluid from the rear of the first filter 210 toward the front of the first filter 210 .

For example, as shown in FIG. 3 , a plurality of spray nozzles 252 may be spaced apart from each other on the other surface of the first filter 210 . In addition, the plurality of spray nozzles 252 may be connected to a distribution pipe 253 that transfers the fluid from the fluid supply member 251 to spray the fluid. That is, one side of the plurality of spray nozzles 252 is connected to the distribution pipe 253 and the other side is spaced apart from the other surface of the first filter 210 to spray the fluid.

In addition, the vibration unit 260 of the filter module 200 according to an embodiment of the present invention may generate vibration by supplying fluid from the fluid supply member 251 .

The fluid supply member 251 may be connected to the vibrating unit 260 to supply fluid so that the vibrating unit 260 may generate vibration. Specifically, the vibrator 260 may move dust remaining on the inclined portion 230 of the filter chamber by forming a vibration while the turbine wheel rotates by the supplied air.

In addition, the filter module 200 according to an embodiment of the present invention may further include pressure detectors 281 and 282 .

The pressure detectors 281 and 282 may detect a pressure inside the filter chamber 201 in front of the first filter 210 and a pressure inside the filter chamber 201 behind the first filter 210 .

In addition, the filter module 200 according to an embodiment of the present invention may further include a pressure gauge 283.

The pressure gauge 283 may be installed in the filter chamber 201 to display a difference in pressure detected by the pressure detectors 281 and 282 to the operator. The operator can check the degree of dust adsorbed on the first filter 210 based on differential pressure information displayed by the pressure gauge 283 .

Specifically, when dust is adsorbed to the first filter 210, it interferes with the flow of air passing through the inside of the filter chamber 201, thereby increasing the pressure in the front of the first filter 210 and the rear of the second filter 220. the difference in pressure increases. An operator may recognize the state of dust contamination of the first filter 210 through the pressure gauge 283 .

In addition, the filter module 200 according to an embodiment of the present invention may include a filter transfer unit 270 .

The filter transfer unit 270 may be installed below the filter chamber 201 to allow the filter module 200 to move. For example, the filter transfer unit 270 may be a wheel.

Therefore, by moving the filter module 200 to a working space desired by the operator, dust containing radioactive materials generated during dismantling of a nuclear power plant can be reduced, and cutting of metal or cement can be effectively performed while reducing the risk of exposure. .

In addition, in the filter module 200 according to an embodiment of the present invention, as shown in FIGS. 1 and 2 , a transparent window 209 is installed on the side of the filter chamber 201 in front of the first filter 210. It can be. Through the transparent window 209 , an operator can check the accumulated state of dust in the inclined portion 230 of the filter chamber 201 from the outside of the filter chamber 201 .

In addition, the filter module 200 according to an embodiment of the present invention may further include a first filter damper 291 and a second filter damper 292 .

A first filter damper 291 may be installed on one side of the filter chamber 201 , and a second filter damper 292 may be installed on the other side of the filter chamber 201 . The first filter damper 291 may selectively block the inflow and discharge of dust air flowing into the filter chamber 201 .

Also, the second filter chamber 201 may selectively block the discharge of air passing through the filter chamber 201 .

Accordingly, when the filter chamber 201 is moved, the first filter damper 291 and the second filter damper 292 are closed to prevent the radioactive material remaining inside the filter module 200 from being discharged to the outside.

Therefore, the air purifier 101 for reducing radioactive substances according to an embodiment of the present invention can be moved to the space where the work is performed, so it can be manufactured compactly. That is, the air purifier 101 for reducing radioactive substances according to an embodiment of the present invention does not purify the entire large space, but can be moved and operated adjacent to the work environment where the dismantling work is performed, so it is compactly manufactured Even if it is, it can reduce radioactive materials effectively.

The air purifier 101 for reducing radioactive substances in which the filter module 200 is installed according to an embodiment of the present invention may further include a preprocessing module 100 as shown in FIG. 1 .

The preprocessing module 100 processes particles or aerosol-type radioactive dust contained in the air. Specifically, such air is dust containing particles or aerosol-type radioactive substances according to processes such as decontamination, cutting, and waste treatment following the dismantling of nuclear power plants. In other words, it is the air generated according to the work in the work area where the work according to the dismantling of the nuclear power plant is performed.

The preprocessing module 100 reduces particles or aerosol-type radioactive substances generated in accordance with the dismantling of nuclear power plants. Air containing radioactive substances in the form of picticles or aerosols passes through the pretreatment module 100 and the radioactive substances are reduced, thereby reducing the risk of exposure to workers.

Also, as shown in FIG. 1 , the preprocessing module 100 according to an embodiment of the present invention may include a preprocessing chamber 110, a preprocessing filter 120, and a preprocessing collector 130.

The pretreatment chamber 110 may include a pretreatment inlet 112 and a pretreatment outlet 113 . In addition, air may be introduced through the pretreatment inlet 112 , and air passing through the inside of the pretreatment chamber 110 may be discharged through the pretreatment outlet 113 .

For example, in the pre-processing module 100 according to an embodiment of the present invention, as shown in FIG. 1 , the pre-processing inlet 112 may be formed on the side of the pre-processing chamber 110 .

Specifically, the pretreatment inlet 112 may be formed in a direction adjacent to the lower portion of the pretreatment chamber 110 .

The pre-treatment outlet 113 may be formed at an upper portion of the pre-treatment chamber 110 .

A pre-processing filter 120 may be installed inside the pre-processing chamber 110 to filter radioactive substances contained in the air of the work environment. For example, the preprocessing filter 120 may be a bag filter. Such a bag filter can be used to remove large particles of aerosol-type radioactive material.

The pretreatment module 100 including such a bag filter may be utilized during metal cutting work.

The pretreatment collection unit 130 is installed in the lower part of the pretreatment chamber 110 to collect particles such as relatively heavy particles contained in the air introduced into the pretreatment chamber 110 or large particles among aerosol-type radioactive substances. . The pretreatment collection unit 130 is detachably disposed from the pretreatment chamber 110, and particles and large particles of radioactive material collected therein can be removed.

Alternatively, the preprocessing module 100 of the air conditioner 102 according to another embodiment of the present invention, as shown in FIG. ) may be included.

The pretreatment chamber 110 may include a pretreatment inlet 112 and a pretreatment outlet 113 . In addition, air may be introduced through the pretreatment inlet 112 , and air passing through the inside of the pretreatment chamber 110 may be discharged through the pretreatment outlet 113 .

For example, in the pre-processing module 100 according to another embodiment of the present invention, as shown in FIG. 4 , the pre-processing inlet 112 may be formed on the side of the pre-processing chamber 110 . Also, the pretreatment chamber 110 may have a circular cross section in a transverse direction.

Specifically, the pretreatment inlet 112 may be formed in a direction adjacent to an upper portion of the pretreatment chamber 110 . Accordingly, the air introduced into the pretreatment inlet 112 moves with a swirling flow along the inside of the pretreatment chamber 110 and forms a cyclone, so that particles included in the air can be separated by the action of centrifugal force.

The pre-treatment outlet 113 may be formed at an upper portion of the pre-treatment chamber 110 .

In the pretreatment chamber 110, a pretreatment inclined portion 150 may be formed such that one region has a narrower cross-sectional area toward the lower portion. The pretreatment inclined portion 150 may guide the air introduced into the pretreatment chamber 110 to move with a swirling flow, and the particles included therein to fall down the pretreatment chamber 110 .

The pretreatment collection unit 130 is installed in the lower part of the pretreatment chamber 110 to collect particles such as relatively heavy particles contained in the air introduced into the pretreatment chamber 110 or large particles among aerosol-type radioactive substances. . The pretreatment collection unit 130 is detachably disposed from the pretreatment chamber 110, and particles and large particles of radioactive material collected therein can be removed.

The pretreatment module 100 according to another embodiment of the present invention can be used as a cyclone module during cement cutting work.

The pretreatment module 100 detachably coupled to the filter module 200 according to an embodiment of the present invention may be selectively configured according to work conditions, and thus included in the air generated according to the characteristics of the work. radioactive substances can be effectively reduced.

In addition, the preprocessing module 100 of the air purifier 101 according to an embodiment of the present invention may further include a first preprocessing damper 191 and a second preprocessing damper 192 .

The first pre-processing damper 191 selectively blocks the inflow and discharge of air to one side of the pre-processing chamber 110 . Specifically, the first pretreatment damper 191 may selectively shield the pretreatment chamber 110 and the outside.

The second pre-processing damper 192 selectively blocks air passing through the pre-processing module 100 from being discharged to the other side of the pre-processing chamber 110 . Specifically, the second preprocessing damper 192 may selectively shield the preprocessing module 100 and the outside.

Specifically, a first flow path 810 is detachably disposed between the pretreatment outlet 113 and the inlet 202 to guide air passing through the pretreatment module 100 to flow into the filter module 200. . The second pretreatment damper 192 may block the pretreatment outlet 113 and the first filter damper 291 may block the inlet 202 .

As shown in FIG. 1 , the preprocessing module 100 may further include a preprocessing transfer unit 170 .

The pre-processing transfer unit 170 may be a wheel that is installed below the pre-processing chamber 110 and allows the pre-processing module 100 of the air purifier 101 to move around the work area.

In addition, the air purifier 101 for reducing radioactive substances according to an embodiment of the present invention closes the first pre-processing damper 191 and the second pre-processing damper 192 when the pre-processing module 100 is moved, thereby reducing the pre-processing module 100 ) can be shielded from the outside on both one side and the other side. Therefore, when the preprocessing module 100 is moved, it is possible to effectively solve the problem of increasing the risk of exposure to workers due to discharge of radioactive materials in the form of particles or aerosols remaining inside the preprocessing module 100 to the outside.

In addition, the air purifier 101 for reducing radioactive substances according to an embodiment of the present invention reduces particles or aerosol-type radioactive substances contained in the air of working environments such as decontamination, cutting, and waste treatment, thereby exposing workers can lower the risk.

For example, a first flow path 810 may be disposed between the preprocessing module 100 and the filter module 200 to connect the preprocessing module 100 and the filter module 200 .

Accordingly, since the air purifier 101 according to an embodiment of the present invention includes the preprocessing module 100 and the filter module 200, radioactive substances contained in the air can be effectively reduced.

In addition, the air purifier 101 for reducing radioactive substances according to an embodiment of the present invention includes an adsorption chamber 401, an adsorption filter 410, a first adsorption damper 491 and a second adsorption damper 492 It may further include an adsorption module 400 including.

The adsorption module 400 may be detachably coupled to the rear of the filter module 200 . The adsorption module 400 may treat harmful gases included in the air passing through the filter module 200 .

The adsorption chamber 401 may have a hollow interior. In addition, the adsorption chamber 401 may have an adsorption inlet 402 formed on one side and an adsorption outlet 403 formed on the other side.

An adsorption filter 410 may be installed inside the adsorption chamber 401 . Specifically, the adsorption filter 410 may remove harmful gases of atmospheric environment standards included in the air passing through the filter module 200 . That is, the adsorption chamber 401 can remove harmful substances in a gaseous state.

For example, the adsorption filter 410 may adsorb and treat gaseous carbon monoxide, sulfur dioxide, and nitrogen dioxide. In addition, the adsorption filter 410 may be a carbon filter.

The first adsorption damper 491 may be installed on one side of the adsorption chamber 401 to selectively shield the adsorption inlet 402 . Specifically, the first adsorption damper 491 may selectively block the inflow and discharge of air into the adsorption chamber 401 .

The first adsorption damper 491 may selectively block the discharge of air passing through the adsorption chamber 401 . Specifically, the second adsorption damper 492 may be installed on the other side of the adsorption chamber 401 to selectively block the adsorption outlet 403 .

Specifically, the adsorption inlet 402 of the adsorption chamber 401 and the outlet 203 of the filter chamber 201 are connected through a second flow path 820, so that air containing dust passing through the filter chamber 201 is adsorbed. It may flow into the chamber 401 .

Accordingly, the air purifier 101 for reducing radioactive substances according to an embodiment of the present invention can also remove gaseous harmful substances contained in the air to purify the operator's working environment from contaminants.

In addition, the adsorption module 400 according to an embodiment of the present invention may further include an adsorption transfer unit 470 .

The adsorption transfer unit 470 may be a wheel installed in the lower portion of the adsorption chamber 401 . Accordingly, the adsorption module 400 can be moved together with the filter module 200 and the pretreatment module 100 to a working position desired by an operator.

At this time, the first adsorption damper 491 and the second adsorption damper 492 are closed to prevent gaseous harmful substances remaining inside the adsorption chamber 401 from being discharged to the outside of the adsorption chamber 401. there is.

In addition, the air purifier 101 for reducing radioactive substances according to an embodiment of the present invention may further include a blowing module 500.

The blowing module 500 is detachably coupled to the pretreatment module 100, the filter module 200, or the adsorption module 400, and air is blown into the pretreatment module 100, the filter module 200, or the adsorption module 400. A flow of air may be formed so as to be introduced. Specifically, the blower module 500 includes a blower 510 to control the flow of air so that air can be moved into the pretreatment module 100, the filter module 200, the adsorption module 400, and other modules connected thereto. can form

If there is a separate blower at the dismantling site, the on-site blower may be used. That is, the blower module 500 is detachably coupled with other modules when there is no blower that forms the flow of air into the module of the air purifier 101 at the dismantling site so that the air at the work site is introduced. flow can be formed.

Specifically, the blowing module 500 may be connected to the adsorption outlet 403 of the adsorption chamber 401 and the third flow path 830 . The blower 510 is operated through the third flow path 830 and the rotational force of the blower 510 forms a flow to move air to the pretreatment chamber 110, the filter chamber 201, and the adsorption chamber 401. can That is, the air that has passed through the pretreatment chamber 110, the filter chamber 201, and the adsorption chamber 401 may be treated with noxious gases and aerosol-type radioactive materials.

In addition, the blowing module 500 according to an embodiment of the present invention may further include a blowing transfer unit 570 .

The blower transfer unit 570 is formed as a wheel and can move the blower module 500 according to a variable work area.

In addition, the air purifier 101 for reducing radioactive substances according to an embodiment of the present invention may further include a control module 600.

As shown in FIG. 5 , the control module 600 may further include a battery 610, an environment detection unit 620, an alarm unit 630, and a control transfer unit 670.

Battery 610 may provide power. Such a battery 610 can provide power to the blower module 500 even in a special environment of a dismantled nuclear power plant or provide power to other electronic devices required by a worker during work.

The environment detector 620 may detect work environment information. Specifically, the environment detection unit 620 may detect radioactivity concentration of the work area where the control module 600 is located or harmful state information of the work area.

Information detected by the environment detection unit 620 may be transmitted to the alarm unit 630 . The alarm unit 630 may deliver the risk level of the information detected by the environment detection unit 620 to the operator through an alarm. The alarm unit 630 may inform a worker of a dangerous state of the working environment based on visual or auditory information.

The alarm unit 630 may be operated when the information detected by the environment detection unit 620 is equal to or greater than a set reference value.

Specifically, a control unit (not shown) is installed in the control module 600 to receive information from the environment detection unit 620 and operate the alarm unit 630 . The control unit may determine the operation of the alarm unit 630 by comparing the information detected by the environment detection unit 620 with a predetermined reference value for each stage.

For example, the control unit may determine the degree of danger of the work environment in which the operator is located based on the predetermined step-by-step reference value of the information detected by the environment detection unit 620 and differently control the operating state of the alarm unit 630 according to the degree of danger. there is.

The control transfer unit 670 may allow the control module 600 to move. As an example, the control transfer unit 670 may be a wheel.

Therefore, an operator can move the control module 600 to a desired position.

Specifically, the operator may place the control module 600 in a work environment where the operator is located, receive work environment information and risk information thereof, and respond in case of danger.

In addition, the control module 600 of the present invention may further include a display unit 640.

The display unit 640 may output information detected by the environment detector 620 or state information of the battery 610 . Accordingly, the operator may recognize work environment information or state information of the battery 610 based on the information output by the display unit 640 .

With this configuration, the air purifier 101 for reducing radioactive substances according to an embodiment of the present invention can effectively reduce radioactive substances in the form of particles or aerosols included in dust generated during the process of dismantling nuclear power plants. .

In addition, since a plurality of modules can be detachably coupled to each other, a desired module can be selected and used according to the needs of the working environment for dismantling nuclear power plants.

In addition, the carpenter's module includes a movable transfer unit, so that the air purifier 101 for reducing radioactive materials is moved adjacent to the working environment in which the work is performed, thereby efficiently treating dust generated in the working environment. .

Hereinafter, with reference to FIGS. 1 and 4, the operation of the air purifiers 101 and 102 for reducing radioactive materials according to an embodiment of the present invention will be described.

The worker identifies the type of work for dismantling the nuclear power plant. The worker selects the preprocessing module 100 in which the bag filter is installed when the work for dismantling the nuclear power plant is cutting metal. Alternatively, the worker selects the cyclone-type preprocessing module 100 when the work for dismantling the nuclear power plant is cutting concrete.

Identify the available equipment in the working environment where nuclear power plant dismantling work is performed.

It is determined whether all of the filter module 200, adsorption module 400, blowing module 500, and control module 600 should be used, and whether there are other devices that can be replaced in the working environment.

After moving the modules (100, 200, 400, 500, 600) according to the work environment to the work area where the work is to be performed, the preprocessing module 100 and the selected module are connected.

Specifically, the preprocessing module 100 and the filter module 200 may be connected to the first flow path 810 . In addition, the suction unit 700 may be connected to one side of the pretreatment module 100 . The suction unit 700 may include a suction passage 710 connected to the pretreatment inlet 112 of the pretreatment module 100 and a suction nozzle 720 connected to the suction passage 710 . That is, dust containing particles or aerosol-type radioactive substances generated according to work through the suction nozzle 720 may be introduced into the air purifier 101 for reducing radioactive substances.

At this time, the operator can open the dampers installed on the modules 100, 200, 400, and 500 to allow air to move between the modules during work.

After operating the blower 510 or the on-site blower to form the flow of air, it is possible to perform a nuclear power plant disassembly operation such as a cutting operation.

After completing the work, the operator closes the dampers installed on the modules, and then separates each module to move it to another work area or a place for storing them. At this time, it is possible to effectively prevent a situation in which particles or aerosol-type radioactive substances remaining inside the module are discharged to the outside and threaten the safety of workers.

In addition, the air purifier 101 for reducing radioactive materials can move each module, so it can move compactly.

Hereinafter, the operation of the filter module 200 of the air purifiers 101 and 102 for reducing radioactive materials according to an embodiment of the present invention will be described with reference to FIGS. 1 to 4.

The operator checks the pressure difference between the front and rear sides of the first filter 210 through the pressure gauge 283 . Specifically, if the control unit is installed, clogging of the first filter 210 by dust may be determined based on information of the pressure gauge 283 .

The operator determines contamination by dust of the first filter 210 at a pressure higher than a predetermined standard based on information from the pressure gauge 283 . That is, the operator or the controller may determine the operation timing of the fluid ejection unit 250 .

When the worker determines that the first filter 210 is clogged due to dust contamination, the operator connects the fluid supply member 251 to the distribution pipe 253 so that the fluid is supplied through the spray nozzle 252 to the first filter. It is injected from the rear of the 210 and causes the first filter 210 to be exhausted. Specifically, if the control unit is installed, the control unit may supply fluid from the fluid supply member 251 to the spray nozzle 252 so as to be sprayed.

The exhaustion of the first filter 210 may be operated while the air purifier 101 is in operation or in a completed state.

When the exhaustion of the first filter 210 is completed based on the information from the pressure gauge 283, the operator may cause the fluid supply member 251 to stop the fluid injection through the spray nozzle 252. At this time, if the control unit is installed, the control unit may stop the fluid supply from the fluid supply member 251 to the injection nozzle 252. That is, pressure information when exhaustion of the first filter 210 is completed may be preset in the control unit.

Even in a state in which electricity supply is not smooth due to the working environment of nuclear power plant dismantling, the operator can manually determine the fluid supply for exhaustion of the first filter 210, thereby purifying the first filter 210 to increase its service life. can

With this configuration, the filter module 200 of the air purifier 101 according to an embodiment of the present invention can be used after purifying the first filter 210 by spraying a fluid, so that the first filter 210 ) can effectively solve the problem of removal to the outside of the filter chamber 201 for replacement and purification as the pressure inside the filter chamber 201 is increased due to clogging by dust.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. will be.

Therefore, the embodiments described above should be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the claims described below, the meaning and scope of the claims, and All changes or modified forms derived from the equivalent concept should be construed as being included in the scope of the present invention.

101,102: air conditioner 241: inspection window
200: filter module 210: first filter
220: second filter 201: filter chamber
202: inlet 203: outlet
230: filter chamber inclined portion 240: chamber collecting portion
250: fluid injection unit 251: fluid supply member
252: injection nozzle 260: vibration unit
270: filter transfer unit 281,282: pressure detection unit
291: first filter damper 292: second filter damper

Claims (10)

In the filter module included in the air purifier for reducing particles or aerosol-type radioactive substances contained in dust,
A filter chamber having a hollow interior and having an inlet on one side and an outlet on the other side;
a filter chamber inclined portion communicating with one area of the filter chamber and protruding obliquely toward the outside from one lower side of the filter chamber;
a first filter disposed inside the filter chamber and inclined so that one surface faces a region of the filter chamber communicating with the filter chamber inclined portion;
a second filter disposed spaced apart from the first filter in the filter chamber;
a fluid spraying unit configured to exhaust the first filter by spraying a fluid toward the first filter from a rear side of the first filter; and
A chamber collecting unit disposed below the inclined portion of the filter chamber and capable of collecting substances exhausted from the first filter by the fluid sprayed from the fluid dispensing unit.
A filter module of an air purifier comprising a. delete delete According to claim 1,
The filter module of the air purifier further includes a vibrating unit installed on the inclined portion of the filter chamber to move the dust exhausted from the first filter to the chamber collecting unit. According to claim 4,
The fluid injection unit,
a fluid supply member for supplying fluid; and
A spray nozzle disposed between the first filter and the second filter to spray the fluid supplied from the fluid supply member toward the first filter.
A filter module of an air purifier comprising a. According to claim 5,
The filter module of the air purifier, characterized in that the fluid supply member is capable of supplying fluid to the vibration unit. According to claim 1,
The filter module of the air purifier further comprises a pressure detector for measuring pressures in front and rear of the first filter. According to claim 1,
The filter module of the air purifier, characterized in that the chamber collection unit is detachably installed with the filter chamber inclination unit. According to claim 1,
The filter module of the air purifier further comprises an inspection window installed at one side of the chamber collection unit to check the inside of the chamber collection unit from the outside. In the filter module included in the air purifier for reducing particles or aerosol-type radioactive substances contained in dust,
A filter chamber having a hollow interior and having an inlet on one side and an outlet on the other side;
a filter chamber inclined portion communicating with one area of the filter chamber and protruding obliquely toward the outside from one lower side of the filter chamber;
a first filter disposed in the filter chamber inclined in a direction crossing the parallel direction connecting the inlet and the discharge port so that one surface faces a region of the filter chamber communicating with the inclined portion of the filter chamber;
a fluid ejection unit disposed between the first filter and the discharge port to eject fluid toward the first filter to exhaust the first filter; and
A chamber collecting unit disposed below the inclined portion of the filter chamber and capable of collecting substances exhausted from the first filter by the fluid sprayed from the fluid dispensing unit.
A filter module of an air purifier comprising a.

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