KR20220053986A - Apparatus for collecting radioactive concrete dust - Google Patents

Abstract

The present invention provides an apparatus for collecting radioactive concrete dust, in which a radioactive material is removed by primarily collecting radioactive particles based on a center of gravity, secondarily collecting large radioactive particles by using a cyclone, and tertiarily collecting fine radioactive particles through a multi-filter structure, so that radioactive removal efficiency is improved. According to the present invention, the apparatus for collecting the radioactive concrete dust, which is an apparatus for decontaminating and collecting dust of concrete polished by a scrubber, includes: a first collection unit connected to the scrubber through a first pipe, and configured to collect a portion of the dust introduced from the scrubber based on a center of gravity; a suction fan connected to a second pipe to provide a suction force into the first pipe; a second collection unit connected to the first collection unit through the second pipe with the suction fan interposed between the first collection unit and the second collection unit, and configured to collect fine dust in the dust from the first collection unit by concentrating the fine dust in a bottom portion of a collection tank by a cyclone effect; and a third collection unit connected to an outlet of the second collection unit, and configured to collect the fine dust in the dust by multi-stage filter units, wherein the first collection unit includes a storage container having an inlet connected to the first pipe and an outlet connected to the second pipe, and configured to collect and store the portion of the dust introduced from the scrubber based on the center of gravity, and the suction force of the suction fan varies from 5 m/s to 30 m/s based on a wind speed within the first pipe.

Description

Radioactive Concrete Dust Collecting Device {APPARATUS FOR COLLECTING RADIOACTIVE CONCRETE DUST}

The present invention relates to a radioactive concrete dust collecting device for collecting radioactive concrete dust generated from radioactively contaminated concrete structures.

Nuclear facility buildings contain radioactive substances such as epoxy painted on concrete surfaces such as internal walls, floors, and ceilings, concrete used as a building body, oil paint attached to the surface of metal materials, and grease. Decontamination devices are being used to remove the material.

Conventional decontamination equipment uses SUS 316 series, glass glass, sodium bicarbonate, etc. as a projection agent to spray high-pressure on radioactive contaminants to remove radioactive materials. Rather, there is a problem in spreading radiation.

In order to prevent secondary radioactive contamination due to the scattering of dust, the applicant constructed a suction line that sucks air again in addition to the discharge line that sprays high-pressure gas to the decontamination head in Korean Patent Application No. 10-2002-77656. A device for decontamination and dust collection of surface radioactive materials using high pressure to prevent scattering has been proposed.

However, the decontamination and dust collector is a high pressure generator, a dust collector, a centrifuge, a storage tank, a drum, and a liquid filtration filter, etc. There was this, and since the entire facility is composed of one device, it is impossible to distribute only the dust collector part separately.

Therefore, when the configuration of the suction side or the discharge side is different depending on the dust collection target, the dust collection facility, and the dust collection place, it cannot be applied, so there is a problem in that the field of use is limited.

In addition, radioactive particles separated from the decontamination object by the suction force of the vacuum pump flow into the dust collector through the suction line. There is a problem in that the operation of the device is frequently stopped.

In addition, since the vacuum pump applies pressure in the water stored inside the water dust collector to collect fine radioactive particles, the air flow rate is weak in the upper part of the water dust collector, so the dehumidification efficiency in the dehumidifier is lowered, and the discharge power of the dehumidified air is lowered. There is a problem that the filtration efficiency is reduced at the same time.

Accordingly, there is a growing demand for a radioactive material dust collector that overcomes the problems of the conventional radioactive material decontamination and dust collector, improves the radioactive dust collection efficiency, improves the operation rate, and has low operating and maintenance costs.

The present invention has been derived to solve the problems of the prior art described above, and the object of the present invention is to collect firstly by the center of gravity, collect large radioactive particles using a cyclone, and secondly collect fine radioactive particles through a multi-filter structure An object of the present invention is to provide a radioactive concrete dust collecting device that can improve radioactive removal efficiency by removing radioactive materials by thirdly collecting dust.

Another object of the present invention is to minimize the volume of the device by optimizing the individual structure of the multi-level dust collecting units as well as the connection structure between the dust collecting units to prevent scattering of radioactive concrete dust generated when the surface of the radioactive concrete structure is polished into the atmosphere. An object of the present invention is to provide a radioactive concrete dust collecting device that can effectively prevent and thereby prevent secondary exposure by discharging only clean air that is not contaminated by radioactivity into the atmosphere.

Another object of the present invention is to effectively separate, decontaminate and collect radioactive concrete structure dust generated when dismantling facilities such as nuclear power plants, and at the same time to facilitate clean treatment of air discharged into the atmosphere. To provide a dust collection device.

In order to achieve the above object, the present invention is an apparatus for decontamination and collecting dust of concrete polished by a scraper, and is connected to the scraper through a first pipe, and among the dust introduced from the scraper side A first collecting unit for collecting a portion of the center of gravity: an intake fan connected to the second pipe to provide a suction force in the first pipe; a second collecting unit arranging the intake fan and connected to the first collecting unit through the second pipe and collecting fine dust in the dust from the first collecting unit at the bottom of the collecting tank by a cyclone effect; and a third collecting unit connected to the outlet of the second collecting unit and collecting fine dust in the dust by multi-stage filter units, wherein the first collecting unit includes an inlet to which a first pipe is connected and a second pipe. It has an outlet connected to it and includes a storage container in which some of the dust flowing in from the scraper side is collected and stored by the center of gravity, and the suction power of the intake fan is 5 ㎧ to 30 ㎧ based on the wind speed in the first pipe. It is characterized by a radioactive concrete dust collection device that can be varied.

In addition, in the present invention, a first motor driving coupling unit for coupling the inlet of the first collecting unit and the first pipe; and a second motor driving coupling part coupling the outlet of the first collection unit and the second pipe, wherein the first and second motor driving coupling parts are controlled to control the first and second motor driving coupling parts when the storage container is replaced. Release the coupling between the first pipe, release the coupling between the outlet and the second pipe, and the inside of the storage container is characterized by a radioactive concrete dust collecting device that is hermetically closed by a radioactive leakage prevention cap.

In addition, in the present invention, the length of the outlet of the first collecting unit extending inside the storage container is longer than the length of the inlet of the first collecting unit extending inside the storage container To the radioactive concrete dust collecting device There is a characteristic.

In addition, in the present invention, there is a feature in the radioactive concrete dust collecting device further comprising a cart for accommodating the storage container of the first collecting unit, and wheels installed on the bottom surface of the cart to enable movement of the cart. .

According to the radioactive concrete dust collecting device of the present invention as described above, the dust generated by a scraper, etc. is first collected by the center of gravity, the second is collected by a cyclone method, and the third is collected through a multi-layer filter box. , it is possible to effectively decontaminate and collect radioactive dust generated by demolition of nuclear power plants, etc.

In addition, according to the present invention, the first collection unit for the primary collection, the second collection unit for the secondary collection, and the tertiary collection are used to effectively secure the internal suction power or the blowing force while using the minimum number of dust fans. By improving the dust flow structure by the third collection unit or a combination thereof for there is.

In addition, according to the present invention, when the collection capacity of each collection unit is filled, the storage container or filter is configured to be easily replaced. It is possible to provide a radioactive concrete dust collection device that is very useful for collection.

1 is a view for explaining the overall configuration of the radioactive concrete dust collecting device according to an embodiment of the present invention.
FIG. 2 is a view for explaining a first collecting unit in the radioactive concrete dust collecting device of FIG. 1 .
FIG. 3 is a view for explaining a first motor and a first motor driving coupling unit in the first collecting unit of FIG. 2 .
FIG. 4 is a view for explaining a second collecting unit in the radioactive concrete dust collecting device of FIG. 1 .
FIG. 5 is a view for explaining a third collecting unit in the radioactive concrete dust collecting device of FIG. 1 .
6 is a graph showing the dust ingress and dust removal efficiency for each treatment wind speed of the first collecting unit in the radioactive concrete dust collecting device of the present invention.

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

1 is a view for explaining the overall configuration of the radioactive concrete dust collecting device according to an embodiment of the present invention. FIG. 2 is a view for explaining the first collecting unit in the radioactive concrete dust collecting device of FIG. 1 . FIG. 3 is a view for explaining a first motor and a first motor driving coupling unit in the first collecting unit of FIG. 2 . FIG. 4 is a view for explaining a second collecting unit in the radioactive concrete dust collecting device of FIG. 1 . And FIG. 5 is a view for explaining the third collecting unit in the radioactive concrete dust collecting device of FIG.

1, the radioactive concrete dust collecting device 100 according to the present invention is a dedicated tool equipped with at least one scraper roller to polish the surface of a concrete structure (RCW) contaminated with radioactivity (Scrabber, 200) It is a device that is connected to and can decontaminate and collect concrete dust generated by the scraper 200 . At least one radioactive concrete dust collecting device 100 may be fixed or mounted on a structure 300 installed for collecting concrete dust.

The radioactive concrete dust collecting device (hereinafter referred to as 'dust collecting device') 100 is a device for decontamination and collecting the dust of concrete polished by the scraper 200, the first collecting unit 10, the intake fan ( 20), the second collecting unit 30 and the third collecting unit 50 are included, and may further include an exhaust fan unit 60 (refer to FIG. 5 ) depending on the implementation form.

The first collecting unit 10 of the dust collecting device 100 has an inlet and an outlet, and mainly collects dust of a first size or more among the concrete dust polished by the scraper 200 . The inlet (or intake port) of the first collecting unit 10 is connected to the scraper 200 . The second collection unit 30 is connected to the first collection unit 10 with the intake fan 20 interposed therebetween, and collects dust by accumulating the dust at the bottom of the collection tank by the cyclone effect. The third collection unit 50 includes multi-stage filter units that are provided to remove radioactive materials contained in the collected radioactive concrete dust. The inlet of the third collecting unit 50 is connected to the outlet of the second collecting unit 30 . In addition, the exhaust fan unit 60 may be connected to the exhaust port side of the third collecting unit 50 as shown in FIG. 5 . In this embodiment, the dust may have a particle size of at most 1000 μm to at least 0.1 μm.

Specifically, when each component is described, the scraper 200 is a device for grinding the outer surface of the radioactive concrete wall by a grinding roller as one of the dry treatment devices for radioactive concrete waste. The distal end of the first pipe connected to the inlet of the first collecting unit 10 is connected to the casing of the scraper 200 . A negative pressure atmosphere by the intake fan 20 is formed in the scraper casing. Dust generated according to the operation of the scraper 200 is sucked into the first collection unit 10 through the first pipe in a negative pressure atmosphere.

The first collecting unit 10 is connected to the scraper 200 through a first pipe, and is connected to the intake fan 20 through a second pipe. The first collecting unit 10 is configured to collect the incoming dust with a center of gravity. As shown in FIG. 2 , the first collecting unit 10 includes a cart 11 , a storage container 13 , a first motor 15 , a second motor 16 , a first motor driving coupling unit 17 and A second motor drive coupling portion (18) is provided.

The cart 11 accommodates the storage container 13 and has a movable form. On the bottom surface of the cart 11, the wheels 12 may be coupled and installed. The wheel 12 may include a connection part connected to the bottom surface of the cart 11 , a rotating part coupled to the connection part to rotate, and a ring-shaped elastic part surrounding the rotating part. Also, the wheel 12 may be an electric wheel operated by a driving motor. In addition, the wheel 12 may further include a communication module for remote control in the form of a wheel assembly, and may operate to move the first collection unit 10 according to a remote control signal from a user terminal or the like. Of course, depending on the implementation, the wheel 12 may be directly coupled to the storage container 13 without being coupled to the cart 11 .

The storage container 13 is accommodated on the cart 11 . The storage container 13 is a case, tank or drum for drum disposal by collecting the grinding by-product W1 of radioactive concrete waste in the inner space 13s with the center of gravity. A first opening and a second opening are installed on the upper surface of the storage container 13 .

The first opening includes a first inlet pipe 21a having a flange on the upper side, and the second opening includes a first outlet pipe 22a having a flange on the upper side. The first inlet pipe 21a corresponds to the inlet or the first inlet, and the first outlet pipe 22a corresponds to the outlet or the first outlet. The first inlet pipe 21a sucks dust from a scraper, and the first outlet pipe 22a discharges a part of the dust sucked into the second collecting device or the next component (B part). .

One end of the lower side of the first inlet pipe (21a) is installed to protrude into the interior of the storage container (13) by a first length, and one end of the lower side of the first outlet pipe (22a) is inserted into the interior of the storage container (13). It is extended and installed so as to protrude by a second length. The second length is longer than the first length. The second length is more than twice as long as the first length, whereby the dust sucked through the first pipe 21 is directly blocked from flowing out through the second pipe (22). The diameter (ie, the second inner diameter) of the inner hollow of the first outlet pipe 22a is greater than the first inner diameter of the first inlet pipe 21a. The first inner diameter has a size of 3/4 of the second inner diameter, whereby the suction force of the intake fan 20 is properly transmitted through the storage container 13 to the scraper casing connected to the first pipe 21 . .

The first motor 15 is installed on a flange or protrusion extending outward from the top surface of the cart 11 . The first motor 15 is coupled to the first coupling unit 17 connecting the first inlet pipe 21a and the first pipe 21 . The first coupling unit 17 engages the flange of the first inlet pipe 21a and the flange of the first pipe 21 by the driving force of the first motor 15 and is configured to tightly support it.

Similarly, the second motor 16 is mounted on a flange or protrusion extending outward from the top surface of the cart 11 . The second motor 16 may be disposed to face or symmetrically face the first motor 15 on the upper surface of the cart 11 from the opposite side of the first motor 15 . The second motor 16 is coupled to the second coupling unit 18 connecting the first outlet pipe 22a and the second pipe 22 . The second coupling unit 18 is configured to engage the flange of the first outlet pipe 22a and the flange of the second pipe 22 by the driving force of the second motor 16 and tightly support it.

The first coupling unit 17 may maintain or release the coupling between the first pipe 21 and the storage container 13 by the first motor 15 as shown in FIG. 3 . Similarly, the second coupling unit 18 may maintain or release the coupling between the second pipe 22 and the storage container 13 by the second motor 16 .

In addition, in another implementation form, the first and second coupling units 17 and 18 operate as a motor-driven coupling part in which coupling with the pipe is supported by the motor, as well as opening or closing the opening inside the pipe. It can be provided with a controllable structure.

As an example, the first coupling unit 17 is connected to the blocking unit 17a installed in the coupling unit body so as to be able to open and close the opening, as shown in FIG. 3, and the blocking unit 17a, the first motor ( 15) and a gear unit (17b) that is coupled to the drive shaft and transmits a driving force to the blocking unit (17a) according to the rotation of the drive shaft. Here, the drive shaft may have a rod shape and may have a drive gear on its surface. And, the gear unit (17b) has a pair of nut bars and is coupled to the drive shaft at a predetermined distance, so that when the drive shaft rotates in the first direction, the distance between the pair of nut bars is narrowed and the blocking unit ( 17a) operates to open the opening, and when the drive shaft rotates in the second direction opposite to the first direction, the separation distance between the pair of nut bars is widened so that the blocking unit 17a can operate to close the opening there is.

According to the configuration of the motor drive coupling unit described above, when the grinding by-product of the radioactive concrete wall of a certain weight or a certain pressure is collected in the storage container 13, the operation of the intake fan 20 is stopped, and the first pipe 21 and the 2 In a state in which the pipe 22 is closed with the coupling units 17 and 18, the first inlet pipe 21a and the first outlet pipe 22a are separated, and the first inlet pipe 21a and the first outlet pipe are separated. (22a) it is possible to quickly replace the combined storage container 13 with a new empty storage container (13). The new empty storage container 13 may be replaced with the cart while being loaded into the new cart.

According to the configuration of the motor-driven coupling unit described above, the radioactive concrete dust collecting device controls the operation or state of the first and second coupling units 17 and 18 when the storage container 13 is replaced to the first pipe In the state in which the opening degree of (21) is blocked, the coupling between the first inlet pipe (21a) and the first pipe (21) is released, and the first outlet pipe (22a) and the second pipe (22a) and the The coupling between the two pipes 22 may be released. In that case, it is possible to prevent the radioactive concrete dust from being dispersed in the work space through the first pipe 21 or the second pipe 22 . Conversely, in a state in which the inlet and outlet of the storage container 13 are closed by the first and second coupling units 17 and 18, the coupling with the pipes is released to keep the inside of the storage container 13 airtight. It may be made to replace the storage container 13 in the closed state. In this case, the first and second coupling units 17 and 18 may function as a radiation leakage prevention cap.

As shown in FIG. 4 , the second collecting unit 30 according to the present embodiment has an intake fan 20 and is connected to the first collecting unit 10 through a second pipe. The downstream end portion 22b of the first pipe is connected to the intake port of the intake fan 20, and the exhaust port of the intake fan 20 is connected to one side of the upper end of the cylindrical body 31 of the second collection unit 30. The body lower end 31a of the cylindrical body 31 has an inverted triangular shape or a funnel shape. A valve 32 is installed at the lower end of the body lower end 31a. The valve 32 may be a rotary value. A second storage container 33 is connected to the lower side of the cylindrical body 31 . The cylindrical body 31 may be supported and protected by the support frame 34 .

In addition, the cylindrical body 31 is inserted from the upper end of the cylindrical body 31 is connected to the exhaust pipe 35 having a double tube shape in the inner space of the cylindrical body (31). One end (35a) of the exhaust pipe (35) extends across the inner space of the cylindrical body (31) to just an upper portion of the lower end (31a) of the funnel-shaped body. The other end of the exhaust pipe 35 is connected to the third collecting unit 50 which is another component (C part) downstream.

The inner diameter of the exhaust pipe 35 is preferably about 1/3 to 1/2 of the inner diameter of the cylindrical body 31 . The length in the direction of gravity or the vertical direction of the cylindrical body 31 is longer than the length in the vertical direction of the lower end of the body 31a. This size is for preventing backflow from occurring in the second collecting unit 30 .

The structure of the above-described second collection unit 30 is to separate solid or liquid dust or dust from gas or air by using centrifugal force. That is, when the impregnated fluid flowing in through the intake fan 20 performs a screw motion in the inner space of the cylindrical body 31 , relatively heavy dust or dust moves to the inner wall side of the cylindrical body 31 and then the lower body part 31a ), the relatively light gas or air is discharged to the outside of the second collection unit 30 through the exhaust pipe 35 after completing the screw movement. As such, the second collection unit 30 operates as a dust collector using a cyclone type or a rotation type, and a tangential flow type or an axial flow type may be used as the cyclone type.

In the above-described structure of the second collecting unit 30 , the cylindrical body 31 and the lower body 31a correspond to the body frame of the second collecting unit 30 , and the second storage container 33 is detachable from the body frame. It can be combined as possible and can correspond to a dust storage unit or dust discharge unit for storing and processing dust or dust that is deposited on the lower inner part of the body frame and discharged through the valve 32, and is referred to as a nuclear waste collection box (BX), etc. can be

The third collecting unit 50 according to this embodiment, as shown in FIG. 5, has a cylindrical or rectangular box-shaped cross-sectional area and a hollow main frame 51 having a first length extending by a predetermined length. , and a pre filter having the same cross-sectional area as the cross-sectional area in the direction orthogonal to the longitudinal direction of the main frame 51 and detachably installed in the order described in the fluid flow direction at the middle or end of the main frame 51 ) unit 53 , a membrane filter unit 54 , and a HEPA filter unit 55 .

The main frame 51 is a housing or casing of the third collecting unit 50, and the end portion 35b of the second pipe is connected to an intake port thereof. The intake port or the intake port portion 51a may have a cone-shaped inner space in which the inner diameter gradually increases from the same inner diameter as the distal end portion 35b of the second pipe. The first inner diameter of one side of the intake port portion 51a may have a size of half or less of the second inner diameter of the other side. According to the configuration of the intake port portion (51a), the speed of the impregnated gas flowing into the third collection unit (50) through the second pipe is slowed down in the inner space of the main frame (51) of the third collection unit (50). The impregnated gas can be diffused.

The inner space of the main frame 51 following the intake port portion 51a has a diffusion space portion 51b in the longitudinal direction at least corresponding to the diameter size so that the impregnated gas can be effectively diffused. The first sensor 52 is installed in the diffusion space 51b, which is a partial internal space of the main frame 51 . The first sensor 52 may detect the speed of the impregnated gas diffused in the diffusion space 51b, the amount of dust contained in the gas, and the like.

On the downstream side of the diffusion space portion 51b, a pre-filter 53a, a membrane filter 54a, and a HEPA filter 55a are disposed along the flow of the impregnated gas in the order described.

The pre-filter 53a is formed integrally with a part of the main frame 51 and is directly and detachably installed on the main frame 51 . The pre-filter 53a may be prepared using a material necessary to collect dust of 5 μm or less. The pre-filter 53a may be a fiber filter. The width of the pre-filter 53a in the flow direction of the impregnated gas may be about 50 μm.

The pre-filter 53a is a first filter having a multi-stage filter structure and includes a fiber material or a fiber material and a metal material. The fiber material of the pre-filter 53a may be supported by a metal mesh. The metal mesh prevents the pre-filter 53a from being damaged by the radioactive concrete dust flowing at high speed to the strong wind generated by the pressure of the intake fan or exhaust fan. The metal mesh is preferably made of stainless steel. In addition, it is preferable that the outer diameter of the iron wire of the metal mesh is 1.6 mm, and the interval between the adjacent iron wires is about 6 mm. The metal mesh may be formed in the form of zinc or chrome plating on the surface of a general iron (Fe) material in addition to the stainless material.

The membrane filter 54a is formed integrally with a part of the main frame 51 and is directly and detachably installed on the main frame 51 . The membrane filter 54a may be installed to collect dust of 1 μm or less. The width of the membrane filter 54a in the flow direction of the impregnated gas may be about 50 μm.

In addition, the HEPA filter 55a is formed integrally with a part of the main frame 51 and is directly and detachably installed on the main frame 51 . A HEPA filter (High Efficiency Particulate Air filter, 55a) is a high-performance filter that filters fine particles to the level of a clean room. The HEPA filter 55a may be installed to filter dust of 0.3 μm or less. The width of the HEPA filter 53 in the flow direction of the impregnated gas may be about 50 μm.

An exhaust space 56 is installed on a downstream side of the HEPA filter unit 55 , and the exhaust fan unit 60 may be coupled to the exhaust space 56 . In addition, a second sensor 58 is installed in the exhaust space 56 to measure the amount of dust in the air that has passed through the multi-stage filters, and the measured signal or data can be configured to be transmitted from the second sensor 58 to the control device. there is.

According to the above-described multi-stage filter structure, each of the pre-filter unit 53, the membrane filter unit 54, and the HEPA filter unit 55 can be simply separated from the third collection unit 50 to effectively replace or clean the filter. . In addition, radioactive concrete dust and radioactive material by diffusing the dust-containing gas that has passed through the dust collecting step of the center of gravity and the dust collecting step by the cyclone effect in the third collecting unit 50 to collect the dust step by step through the multi-stage filter structure This filtered clean air can be exhausted.

The principle of operation of the radioactive concrete dust collecting device (hereinafter, simply referred to as 'dust collecting device') according to this embodiment will be briefly described as follows.

First, when the surface of the concrete structure (RCW) contaminated with radioactivity is scraped off with a dedicated tool such as a scraper, the dust generated by the scraper by the suction force by the intake fan 20 of the dust collector is collected by the first collection unit. (10) is introduced. The suction power of the intake fan 20 may be installed to variably implement 5 m/s to 30 m/s based on the wind speed in the first pipe. In addition, the first pipe 21 may be installed to extend 10m to 20m in a vertical direction, and may be installed to be extendable 10m to 20m in a horizontal direction as well.

Among the inhaled dust, dust having a relatively large particle size is primarily collected by the center of gravity in the first collecting unit 10 , and the remaining dust is moved to the second collecting unit 30 through the second pipe 22 . will do Dust having a relatively large particle size may have a particle diameter of several tens to hundreds of micrometers or more. And the particle size of the dust moving to the second collection unit 30 may be a maximum of 1000㎛. The maximum particle size of the dust may be controlled to some extent by the extension length of the second pipe 22 inserted deeper than the first pipe 21 in the first collecting unit 10 .

In addition, the length of the first pipe 21 , that is, the collection pipe and the suction power of the intake fan 20 may be controlled differently depending on the size of the dust to be collected according to the working environment. For example, at a wind speed of 5 m/s or more in the collection pipe, suspended dust having a particle diameter of 10 μm or less can be collected, and when a wind speed of 10 m/s is expressed in a 40M collection pipe, suspended dust having a particle diameter of 40 μm or less can be collected. As such, the dust collector according to the present embodiment may control the length of the collection pipe and the suction power of the intake fan according to the working environment. In addition, depending on the implementation, it may be made to be automatically controlled with a preset suction force according to the maximum particle size of the dust generated in the early, middle and late stages of the operation or according to the length of the collection pipe.

With reference to the following Tables 1 to 16, the collection efficiency of the first collection unit according to the dust treatment wind speed and the dust ingress degree will be described.

Tables 1 to 4 show the dust suppression characteristics according to each dust under the condition that 500 g of dust of 1 to 100 micrometers is generated per second when high-concentration dust-containing air generated from the scraper is processed at a medium-low speed of 5 ㎧ per second. it has been shown

Behavior analysis result of dust ingress of 1㎛, 5㎛ based on dust treatment wind speed of 5㎧ particle size 1micron 5micron Analysis result

Average dust retention time 5.2 seconds 3.5 seconds

As can be seen from Table 1, fine dust of 1-5 μm continuously flows in the first collection unit due to an increase in inertial force according to the speed of the fluid, and a considerable part escapes. In addition to the large amount of dust escaping from the actual outlet, the average residence time in the first collection unit was 5.2 s for 1 μm and 3.5 s for 5 μm.

Behavior analysis result of 10㎛, 20㎛ particle ingress based on dust treatment wind speed of 5㎧ particle size 10micron 20micron Analysis result

Average dust retention time 3.1 seconds 2.7 seconds

As shown in Table 2, in the case of medium-sized dust of 10-20㎛, the motion performance of the dust according to the flow velocity and the effect of gravity according to the weight of the dust were simultaneously expressed, and the dust flowing near the inlet was The speed is reduced by the frictional resistance of However, in the case of the dust located in the central part of the inlet, it was found that, due to the influence of the velocity field, it scatters and moves within the first collection unit and is discharged through some outlets, thereby weakening the collection performance.

Based on dust treatment wind speed of 5 ㎧, dust ingress 30㎛, 50㎛ behavior analysis result particle size 30micron 50micron Analysis result

Average dust retention time 2.2 seconds 1.2 seconds

As shown in Table 3, most of the medium-sized dust of 30-50㎛ is settled by gravity, but some dust whose inertial force is increased according to the speed of the fluid escapes through the outlet, but the amount is insignificant compared to the low particle size. appear.

In the case of dust having a particle diameter of 30㎛, the average residence speed was 2.2s, and in the case of a particle diameter of 50㎛, 1.2s, the dust residence time was significantly shortened.

Behavior analysis result of 80㎛, 100㎛ particle ingress based on dust treatment wind speed of 5㎧ particle size 80micron 100micron Analysis result

Average dust retention time 0.5 seconds 0.1 second

As shown in Table 4, in the case of large-sized dust of 80-100㎛, it was found that sedimentation by gravity was possible quickly when it reached the first collection unit from the inlet side, and it was found that the flow rate was not sufficient to move the dust of the corresponding size. was judged

In the case of 80㎛, the average residence time was 0.5s, and in the case of 100㎛, the average residence time was within 0.1s.

Through this behavioral analysis, the dust removal efficiency for each particle size at a set flow rate of 5 ㎧ is shown in the graph of FIG. As shown, it was found that 100% of large dust over 50㎛ can be treated in the first collection unit, and when the particle size is small, the number of escape dust due to increase in kinetic force increases, and in the case of 20㎛, 62%, It was analyzed that the dust of 30㎛ had a dust removal efficiency of 92%, and in the case of small fine dust of 1-10㎛, it was found that it was possible to obtain a dust removal efficiency of less than 50%.

Next, Tables 5 to 8 show the dust suppression characteristics according to each dust under the condition that 500 g of dust of 1 to 100 micrometers is generated per second when high concentration of dust-containing air generated from the scraper is processed at a medium speed of 10 m/s. it has been shown

Behavior analysis result of dust ingress of 1㎛, 5㎛ based on dust treatment wind speed of 10㎧ particle size 1micron 5micron Analysis result

Average dust retention time 2.7 seconds 1.8 seconds

As shown in Table 5, fine dust of 1-5 μm flows continuously as in the case of a treatment wind speed of 5 m/s due to an increase in the inertia force according to the speed of the fluid and escapes to a considerable extent, and the average residence time is shortened.

The average residence time for the dust injected into the inlet side to actually escape to the outlet side is 2.7s for 1㎛ and 1.8s for 5㎛, which is expected to shorten the flow path due to the increase in mobility. was judged

Behavior analysis result of 10㎛, 20㎛ particle ingress based on dust treatment wind speed of 10㎧ particle size 10micron 20micron Analysis result

Average Dust Retention Time 1.4 seconds 1.3 seconds

As shown in Table 6, in the case of medium-sized dust of 10-20㎛, the kinetic properties of the dust according to the flow velocity and the effect of gravity according to the weight of the dust were simultaneously expressed. In particular, the residence times of 10㎛ and 20㎛ were similar, and in the case of the 20㎛ dust at the corresponding speed, the mobility was increased and it was analyzed as the effect of preventing sedimentation due to gravity.

Behavior analysis result of 30㎛, 50㎛ particle ingress based on dust treatment wind speed of 10㎧ particle size 30micron 50micron Analysis result

Average dust retention time 1.0 second 0.6 seconds

As shown in Table 7, medium-sized dust of 30-50㎛ can be expected to improve the vibration suppression efficiency due to gravity sedimentation, which is the effect of many of the systems. .

In the case of dust having a particle diameter of 30㎛, the average residence speed was 1.3s, and in the case of a particle diameter of 50㎛, 0.6s, the dust residence time was significantly shortened.

Behavior analysis result of 80㎛, 100㎛ particle ingress based on dust treatment wind speed of 10㎧ particle size 80micron 100micron Analysis result

Average dust retention time 0.3 seconds 0.2 seconds

As shown in Table 8, in the case of large dust with a size of 80-100㎛, when reaching the collecting device from the inlet side, most of the dust can quickly settle through gravity. It was found that some of the dust escaped through the outlet. In the case of 80㎛, the average residence time was 0.3s, and in the case of 100㎛, the average residence time was within 0.2s.

Through this behavioral analysis, the dust removal efficiency for each particle size at a set flow rate of 10 ㎧ is shown in the graph of FIG. As indicated, it is possible to remove 98% or more of large-sized dust over 50㎛, but it is necessary to take countermeasures for this because efficiency is expected to decrease due to partial escape due to flow in turbulent flow among 50-80㎛ dust. In the particle size range of small and medium dust, it was shown that more than 85% of dust of 30㎛ size could be removed, but the dust removal efficiency for 20㎛ dust was rapidly reduced.

The cause of this is considered to be that the particle size of the dust generated by the movement of the dust increased with the increase of the flow rate.

In the case of small fine dust of 1-10㎛, it was found that a vibration removal efficiency of less than 40% can be obtained.

Next, Tables 9 to 12 show the vibration suppression characteristics according to each dust under the condition that 500 g of dust of 1 to 100 micrometers is generated per second when the high-concentration dust-containing air generated from the scraper is processed at a high speed of 15 ㎧ per second. it has been shown

Behavior analysis result of 1㎛, 5㎛ particle ingress based on dust treatment wind speed of 15㎧ particle size 1micron 5micron Analysis result

Average dust retention time 0.8 seconds 1.0 second

As shown in Table 9, as the speed of the fluid increases, fine dust of 1-5 μm flows toward the outlet and escapes to a significant extent, and the average residence time in the dust collecting device is shortened. The average residence time for dust injected into the inlet side to actually escape to the outlet side was 0.87s for 1㎛ and 1.6s for 5㎛, which was expected to shorten the flow path due to the increase in mobility compared to the medium and low speed environment.

Behavior analysis result of 10㎛, 20㎛ particle ingress based on dust treatment wind speed of 15㎧ particle size 10micron 20micron Analysis result

Average dust retention time 1.6 seconds 1.8 seconds

As shown in Table 10, in the case of medium-sized dust of 10-20㎛, the kinetic properties of the dust according to the flow rate and the effect of gravity according to the weight of the dust were simultaneously expressed. In particular, the residence times of 10㎛ and 20㎛ were 1.8s and 1.6s, respectively, and the residence time increased compared to the medium and low velocity fluid velocity, which was judged to be due to the increase in the inertia force in the primary collection device according to the increase in the fluid velocity.

It was found that the amount of escaped dust increased because the energy dissipation according to the behavior of the introduced dust was not sufficiently achieved.

Behavior analysis result of dust ingress of 30㎛, 50㎛ based on dust treatment wind speed of 15㎧ particle size 30micron 50micron Analysis result

Average dust retention time 2.3 seconds 2.0 seconds

As shown in Table 11, for medium-sized dust of 30-50㎛, the vibration suppression efficiency due to gravity sedimentation due to the increase in inertia caused by the flow rate was judged to be lower than that in the case of securing the medium and low speed flow rate. In the case of dust having a particle size of 30㎛, the average residence speed was 1.6s, and in the case of a particle size of 50㎛, the average residence time was 1.8s, indicating that the dust residence time increased, and the amount of dust escaping to the outlet increased.

Behavior analysis result of 80㎛, 100㎛ particle ingress based on dust treatment wind speed of 15㎧ particle size 80micron 100micron Analysis result

Average dust retention time 4.0 seconds 2.3 seconds

As shown in Table 12, in the case of large dust with a size of 80-100㎛, most of the dust was found to settle similarly to the medium-low speed environment described above, but among some of the 80㎛ dust, the dust belonging to the turbulent layer is continuously collected It was found that collisions within the device increase the residence time and some dust escapes through the outlet. In the case of 80㎛, the average residence time was 4.0s, and in the case of 100㎛, the average residence time was 2.3s.

Through this behavioral analysis, the dust removal efficiency for each particle size at a set flow rate of 15 ㎧ is shown in the graph of FIG. As shown, it is possible to remove more than 99% of large dust with a size of 100 µm or more, but the dust removal efficiency of 50-80 µm dust by the first collecting unit is 90-98%, which is lower than the medium-low speed condition.

For dust with a size of 20-30㎛, the dust removal efficiency is about 50-70%, and it was observed that the dust movement increased with the increase of the flow rate and the dust removal efficiency decreased. appeared to be effective.

Next, Tables 13 to 16 show the vibration suppression characteristics according to each dust under the condition that 500 g of dust of 1 to 100 micrometers is generated per second when high-concentration dust-containing air generated from the scraper is processed at a high speed of 30 ㎧ per second. it has been shown

Behavior analysis result of dust ingress of 1㎛, 5㎛ based on dust treatment wind speed of 30㎧ particle size 1micron 5micron Analysis result

Average dust retention time 0.62 seconds 0.82 seconds

As shown in Table 13, fine dust of 1-5㎛ has a small particle size and high velocity, flows toward the outlet and escapes, and the average residence time of the dust in the first collection unit is shortened. The average residence time for the dust injected at the inlet side to actually escape to the outlet side is 0.62s for 1㎛ and 0.82s for 5㎛, which is a decrease in the flow path due to the increase in mobility compared to the medium and low speed environment, resulting in lower dust removal efficiency. was judged to be

Behavior analysis result of 10㎛, 20㎛ particle ingress based on dust treatment wind speed of 30㎧ particle size 10micron 20micron Analysis result

Average dust retention time 1.4 seconds 0.7 seconds

As shown in Table 14, in the case of medium-sized dust of 10-20㎛, the kinetic properties of the dust according to the flow rate and the effect of gravity according to the weight of the dust were simultaneously expressed. In particular, the residence time of 10㎛ and 20㎛ is 0.8s and 1.4s, respectively, which increases the residence time compared to the medium and low speed fluid velocity. It was found that the movement time in the collection device was prolonged due to the weight of the dust body even if the speed of

Behavior analysis result of dust ingress of 30㎛, 50㎛ based on dust treatment wind speed of 30㎧ particle size 30micron 50micron Analysis result

Average Dust Retention Time 0.4 seconds 1.2 seconds

As shown in Table 15, for medium-sized dust of 30-50㎛, the vibration suppression efficiency due to gravity sedimentation due to the increase in inertia due to the flow velocity was judged to be lower than that in the case of securing the medium and low velocity flow velocity. In the case of dust having a particle diameter of 30㎛, the average residence speed was 0.4s, and in the case of a particle diameter of 50㎛, the average residence time was 1.2s.

Behavior analysis result of 80㎛, 100㎛ particle ingress based on dust treatment wind speed of 30㎧ particle size 80micron 100micron Analysis result

Average dust retention time 2.0 seconds 1.3 seconds

As shown in Table 16, in the case of large-sized dust of 80-100㎛, most of the dust was found to settle similarly to the medium-low-speed dust processing speed environment described above. It was found that collisions within the device increase the residence time and some dust escapes through the outlet. In the case of 80㎛, the average residence time was 4.0s, and in the case of 100㎛, the average residence time was 1.3s.

Through this behavioral analysis, the dust removal efficiency for each particle size at a set flow rate of 30 ㎧ is shown in the graph of FIG. As shown, it is possible to remove more than 99% of large-sized dust over 100㎛, but the dust removal efficiency by the primary collecting device for 50-80㎛ dust is 90-98%, which is lower than the medium-low speed condition.

The dust removal efficiency of 10-30㎛ size dust was observed to be about 40-70%, and as the flow rate increased, the dust removal efficiency decreased. It was found that the damping efficiency could be obtained.

As described above, in the case of the first collection unit, sedimentation by gravity is the main vibration suppression mechanism, and it becomes effective when the particle diameter of the particle is large and the inertial force due to the speed is low. appear.

In addition, as a result of examining the dust removal efficiency according to the processing wind speed of the dust-containing air from 5 ㎧ (low speed) to 30 ㎧ (high speed), when the target dust is composed of three parts, large dust (80-100㎛), small dust ( 20-50㎛) and fine dust (1-10㎛) in common showed that the vibration suppression efficiency decreased as the wind speed increased, and the particle size of the dust behavior increased as the wind speed increased.

As shown in the graph showing the dust ingress and dust removal efficiency by treatment wind speed in FIG. 6, it is understood that more than 98% of dust treatment is possible at all speeds in the case of large dust, and in the case of small dust, the dust removal efficiency decreases as the speed increases In the case of fine dust, a dust removal efficiency of up to about 40% (based on 5 ㎧) could be expected.

In addition, the treatment wind speed is expected to vary depending on the particle size and amount of dust generated from the scraper. It was judged to be suitable for improving the vibration suppression efficiency.

Next, the relatively heavy dust among the dust introduced into the second collection device 30 is deposited along the inner wall of the cylindrical body 31 by centrifugal force and is accumulated in the lower part of the cylindrical body 31, and through the valve 32 It is periodically or intermittently stored separately in the second storage container (33). The operating environment of the second collecting device 30 may be set to precipitate particles having a particle size of about 3 μm or more in the dust. The operating environment may be determined by the suction power of the intake fan 20 , the inner diameter of the cylindrical tank 31 , the vertical length of the cylindrical tank 31 , the inner diameter of the exhaust pipe 35 , and the like.

Next, the third collecting device 50 filters the dust introduced through the exhaust pipe 35 in stages according to the size of the particles in the dust. Here, each of the pre-filter unit 53 , the membrane filter unit 54 , and the HEPA filter unit 55 installed in the third collecting device 50 is the housing of the third collecting device 50 , that is, the main frame 51 . Manufactured to constitute a part of the filter unit, thereby directly removing the filter unit from the outside of the third collecting device 50 and replacing it with a new filter unit or cleaning the inside of the filter of the filter unit, immediately after cleaning the filter unit again the third collecting device (50), it is possible to maximize work efficiency and greatly improve user convenience.

The air coming out through the HEPA filter 55a is clean air above a certain level, and this radiation-free clean air is discharged to the outside through the exhaust space 56 and the exhaust fan unit 60 . The second sensor 58 installed in the exhaust space 56 detects a state of the clean air, and the control device is an intake fan based on a detection signal of at least any one of the first sensor 52 and the second sensor 58 . The operation of ( 20 ) may be controlled, the filter unit may be replaced, or the filter unit may be cleaned.

According to the radioactive concrete dust collecting device according to this embodiment, it is possible to provide an optimal filter combination in consideration of the recovery rate, workability, and durability according to the filter combination, thereby decontamination and collecting treatment of the concrete structure surface by abrasive method It prevents the scattering of radioactive concrete dust into the air, regardless of the particle size of the concrete dust, and discharges clean air that is not polluted by radioactivity into the atmosphere to fundamentally prevent secondary exposure.

Meanwhile, in the above-described embodiment, the exhaust fan unit 60 has been described as a separate configuration, but the present invention is not limited thereto. It may be included as a part of the third collecting unit 50 .

According to the above-described embodiment, the present invention provides a dust collector having a structure in which the dust generated by the scraper 200 is primarily collected by the center of gravity, secondary collected in a cyclone method, and tertiary is collected through a multi-layer filter box. can do. In other words, when the surface of the radioactive concrete structure is decontaminated by grinding, it prevents the concrete powder from scattering into the air and discharges only clean air that is not contaminated by radioactivity into the atmosphere to fundamentally prevent secondary exposure. A radioactive concrete dust collection device that can do this can be provided.

In particular, in the dust collection device according to this embodiment, the first collection unit for primary collection of radioactive concrete dust, the second collection unit for secondary collection, and the third collection unit for tertiary collection By improving the structure, for example, the motor-driven coupling structure or the structure of partial casing integrated filter units, and the coupling structure between the collection units or between the collection unit and the connecting pipe, a practical 5-stage filtering structure according to the weight or particle size of the dust is provided. It is possible to provide a dust collector having excellent performance, excellent workability, and convenient maintenance, thereby.

That is, when the dust collector according to this embodiment is used, the storage container or filter of each collection unit can be easily replaced, and the work continuity is secured while minimizing the work stop time when working on the radioactive concrete dust, and the user It is possible to provide a radioactive concrete dust collecting device that is very effective for decontamination and collection of radioactive dust while increasing the working convenience of the site.

In addition, in the case of using the dust collecting device according to this embodiment, by effectively separating and removing the dust of radioactive concrete structures generated during the dismantling of concrete structures such as nuclear power plants, the economic burden of operators can be reduced from the viewpoint of disposal costs. There is this.

Although the present invention has been described with reference to the above-mentioned preferred embodiments, various modifications and variations are possible without departing from the spirit and scope of the invention. Accordingly, it is intended that the appended claims cover such modifications and variations as fall within the scope of the present invention.

10: first collecting unit 11: cart
12: wheel 13: storage container
17: first motor driving coupling unit 18: second motor driving coupling unit
20: intake fan 21: first pipe
22: second pipe 30: second collection unit
50: third collection unit 200: scraper

Claims (4)

As an apparatus for decontamination and collecting dust of concrete polished by a scraper,
A first collection unit connected to the scraper through a first pipe to collect some of the dust flowing from the scraper side with the center of gravity:
an intake fan connected to the second pipe to provide a suction force in the first pipe;
a second collecting unit arranging the intake fan and connected to the first collecting unit through the second pipe and collecting fine dust in the dust from the first collecting unit at the bottom of the collecting tank by a cyclone effect; and
and a third collecting unit connected to the outlet of the second collecting unit and collecting fine dust in the dust by multi-stage filter units,
The first collecting unit includes an inlet to which the first pipe is connected and an outlet to which the second pipe is connected, and a storage container in which some of the dust flowing in from the scraper is collected and stored with the center of gravity,
Radiated concrete dust collecting device, characterized in that the suction power of the intake fan can be varied from 5 ㎧ to 30 ㎧ based on the wind speed in the first pipe. The method according to claim 1,
a first motor driving coupling unit coupling the inlet of the first collecting unit and the first pipe; and
It further comprises a second motor driving coupling part for coupling the outlet of the first collecting unit and the second pipe,
When the storage container is replaced, the first and second motor driving coupling units are controlled to release the coupling between the inlet and the first pipe, and the coupling between the outlet and the second pipe is released,
The inside of the storage container is airtightly closed by a radioactive leak prevention cap, a radioactive concrete dust collecting device. The method according to claim 1,
The length in which the outlet of the first collecting unit extends inside the storage container is longer than the length in which the inlet of the first collection unit extends in the storage container, the radioactive concrete dust collecting device. The method according to claim 1,
The radioactive concrete dust collecting device further comprising: a cart for accommodating the storage container of the first collection unit; and wheels installed on the bottom surface of the cart to enable movement of the cart.

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