KR101031356B1 - Installation having paddle type rotational impact device for volume reduction and separation of radionuclide from dismantled concrete wastes - Google Patents

Abstract

The present invention relates to a radioactive concrete waste reduction and nuclide removal facility having a paddle-type rotary impactor, comprising: a pulverizing unit including a paddle-type rotary impactor for pulverizing the radioactive concrete waste and separating the radioactive contaminant into paste and aggregate; and And a sorting part to accommodate the paste and the aggregate discharged through the sample discharge gate provided in the paddle-type rotary impactor, and to separate the separated fine powder and the aggregate; And an exhaust gas treatment unit connected to the paddle-type rotary impactor of the crushing unit and configured to purify the exhaust gas containing particulates present in the paddle-type rotary impactor.

Radioactive concrete waste, reduction, nuclide removal, paddle-type rotary impactor, exhaust gas treatment

Description

Installation having paddle type rotational impact device for volume reduction and separation of radionuclide from dismantled concrete wastes}

The present invention crushes concrete waste contaminated with various radioactive materials generated during the dismantling and operation of a nuclear power plant to a certain aggregate size, and then improves the surface granularity and removes the mortar enriched with radioactive materials using only physical methods. Reducing non-radioactivity to dispose of itself by drastically reducing the amount of radioactive waste, and completely removing volatilized particulate contaminants and particulate and gaseous exhaust gas contaminants to discharge only clean aggregate and exhaust gas, while improving aggregate particle size and A device for producing high quality aggregates.

Conventionally, the radioactive concrete waste has been used to compress the waste by putting the waste into compression containers by 'ultra high pressure compression' or 'ultra high pressure compression' with a compressive force of 1,000 tons or more, and compressing the container or pellets into other containers by using 'repacking' technology. . However, it is not suitable for the treatment of wastes containing hazardous substances, because the hazards themselves cannot be reduced, and compression has been difficult to apply to wastes with low porosity, dense or bulky volumes.

However, many examples of radioactive contamination of dismantled concrete that occurs in large quantities when dismantling facilities dealing with radioactive materials, typically nuclear power plants, reveal that most concrete surfaces are mainly contaminated. Therefore, in order to remove radioactive material from demolition concrete waste, it is a key requirement to remove cement mortar or paste attached to the surface of the aggregate.

Therefore, in the conventional method of decontamination of concrete, techniques such as abrasive decontamination and surface peeling are used, but wastes that are not easy to remove pollutants and cannot be reused are generated. There are disadvantages, such as the potential for presence. Due to this inefficient technology, radioactive concrete waste, which is incompressible solid waste, is still stored in storage containers.

However, if the concrete surface contaminated with radioactive material is removed, the remaining uncontaminated parts can be recycled and a considerable amount of concrete waste can be reduced. Usually, 30% of concrete is porous cement, and the remaining 70% is made up of rich aggregates, such as quartz or limestone, so if the contaminated concrete is separated into cement and aggregates (quartz or limestone), a significant amount of radioactive waste is reduced. Because it is available.

If dismantled concrete can be efficiently separated into cement and aggregate, this is a huge advantage from an economic and environmental point of view. This technology can be achieved only if the separation of decontaminated concrete contaminated with radioactive material into cement and aggregate must meet very strict conditions. The treatment technology of decomposed concrete based on such strict conditions is currently 15 million tons per year in Korea. This is because it can be spread to the recycled aggregate recovery technology for recycling the waste concrete generated in general.

This spread to the general environmental industry contributes to solving the problem of the disposal of waste concrete waste, which is expected to increase rapidly in the future, with about 60% of construction concrete accounting for 34% of the total industrial waste generation. It will also contribute to the protection of natural resources by reducing the collection of new raw materials.

The present invention has been made to solve such a conventional problem, an object of the present invention is to crush a concrete waste contaminated with various radioactive materials generated during the dismantling and operation of nuclear facilities to a certain aggregate size, and then the surface particle size thereof Significantly reduce the amount of radioactive waste by improving self-disposal and clean aggregates by eliminating concentrated mortar with radioactive material and completely eliminating volatilized fine powder, particulate and gaseous contaminants, thereby reducing the radioactivity of radioactive concrete waste. In addition, the present invention provides a device for improving aggregate surface granularity and producing high quality aggregates.

The radioactive concrete waste reduction and nuclide removal equipment according to the present invention includes a pulverizing unit including a paddle rotary impactor for pulverizing the radioactive concrete waste and separating it into a paste and aggregate which is a radioactive pollutant; and the paddle rotary impactor A sorting unit to accommodate the paste and aggregate discharged through the sample discharge gate, and to separate the separated fine powder and aggregate; And an exhaust gas treatment unit connected to the paddle-type rotary impactor of the crushing unit and configured to purify the exhaust gas containing particulates present in the paddle-type rotary impactor.

The paddle-type rotary impactor according to the present invention, the hopper to which the radioactive concrete waste is injected; and a pair of shafts meshed with gears; and a motor for rotating any one of the pair of shafts; A plurality of paddles each coupled to a pair of axes; And a bearing supporting one end of the pair of shafts.

In this case, the pair of axes rotate in opposite directions, and the plurality of paddles have the same direction and phase as paddles coupled to adjacent axes.

The paddles coupled to the one axis are arranged to have a phase difference of 90 ° with adjacent paddles.

Preferably the paddles are coupled to allow separation.

On the other hand, the paddle-type rotary impactor further includes a control unit, the control unit may periodically change the rotation direction of the motor.

In particular, the control unit monitors the current supplied to the motor, and if it is determined that the motor is overloaded because the current exceeds a predetermined value, it is preferable to change the rotation direction of the motor.

The paddle-type rotary impactor includes at least one transparent observation window for observing the inside thereof.

In addition, the present invention may further include a sample input unit for continuously supplying the radioactive concrete waste in front of the hopper of the paddle-type rotary impactor.

In this case, the sample input portion is composed of a hermetic feeder having a conveyor for transporting the radioactive concrete waste, and a double hermetic door for temporarily storing the radioactive concrete waste transferred to the conveyor in the air lock state before being introduced into the hopper. .

In addition, the hermetic filler may further include a nitrogen purge apparatus for injecting and evacuating nitrogen to prevent explosion and fire caused by foreign substances included in the input when the radioactive concrete waste is introduced into the hopper.

On the other hand, the paddle-type rotary impactor further comprises a control unit, the control unit monitors the current supplied to the motor, if it is determined that the motor is overloaded because the current exceeds a predetermined value the conveyor To reduce the feed rate or stop the conveyor.

In addition, the sorting unit of the present invention further comprises at least one vibrating screen device, the radioactive concrete waste crushed by the vibrating screen device is separated by the size of the particles.

An exhaust fan for sucking exhaust gas inside the paddle-type rotary impactor is installed at an end of the exhaust gas treatment unit, and the paddle-type rotary impactor maintains a negative pressure state by the operation of the exhaust fan.

The exhaust gas treatment unit includes a cyclone having a collection tank at a lower portion thereof, a particulate remover into which exhaust gas passed through the cyclone flows, and a filter unit into which exhaust gas passed through the particulate remover flows in.

The fine particle remover is made up of a vertical cylindrical container, and the inside of the container is provided with a chevron plate and a mesh plate, exhaust gas passing through the cyclone enters the lower portion of the container and passes through the chevron plate and then through the mesh plate Ejected to the top of the container.

At this time, the chevron plate is formed so that the plurality of plates bent in a wave shape in parallel to each other, the exhaust gas flows into the space between the plurality of bent plates, in particular a plurality of chevron plate It is preferable that the bent plates are arranged in the vertical direction.

In addition, the particles collected in the chevron plate and the mesh plate is collected to the lower portion of the container and then transferred to the cyclone collection tank for processing.

The filter unit includes a prestage filter, a first hepa filter, an activated carbon filter, and a second hepa filter, which are sequentially disposed from the inlet.

The prefilter is made of glass microfibers.

The first hepa filter and the second hepa filter are nuclear grade hepa filters, and have a dust collection efficiency of 99.97% or more for particles of 0.3 μm or more.

In addition, the activated carbon filter is made of nuclear grade carbon.

Preferably, a DOP test unit is further included between the activated carbon filter and the second HEPA filter.

Each of the prefilter, the first hepa filter, and the second hepa filter is provided with a relative pressure sensor for measuring a pressure difference before and after.

In an embodiment of the present invention, the filter unit is composed of at least two filter units connected in parallel, the exhaust gas passing through the particulate remover is introduced into each of the plurality of filter units.

Meanwhile, separate dampers are provided at front and rear ends of the filter unit.

Downstream of the exhaust fan, a radiation measuring unit for measuring the radiation level of the exhaust gas discharged to the atmosphere is disposed.

In this case, the radiation measuring unit sounds an alarm when the radiation level of the exhaust gas discharged to the atmosphere exceeds a predetermined value, or the radiation measuring unit sets the radiation level of the exhaust gas emitted to the atmosphere in advance. If the value is exceeded, an alarm signal is transmitted to a control unit further included in the paddle-type shock absorber, and the control unit receiving the alarm signal stops the operation of the conveyor and the motor.

According to the present invention described above, the radioactive concrete waste is supplied to the crushing unit, and then crushed to an appropriate size by a paddle-type rotary impact machine to self-dispose and recycle through the removal of the radioactive contaminant paste of the radioactive concrete waste. It can also have the advantage of obtaining aggregate equivalent to natural aggregate.

In addition, secondary waste is not generated during the production of aggregates, and the secondary pollution can be prevented by completely removing dust by negative pressure operation.

In addition, due to the drastic reduction in the amount of radioactive concrete waste generated, the economic ripple effect is not only large, but also contributes to the advancement of recycled aggregate recovery technology for the recycling of general waste concrete, which currently generates more than 15 million tons per year. Ripple effect is relatively large. This will contribute to the protection of natural resources by reducing the collection of new raw materials, and to solve the problem of disposal of waste concrete waste, which accounts for about 60% of construction waste, which is expected to increase rapidly in the future.

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

The radioactive concrete waste reduction and nuclide removal facility 1 according to the present invention illustrated in FIG. 1 includes a crushing unit 10, a sorting unit 20, and an exhaust gas treatment unit 30.

The crushing unit 10 includes a paddle-type rotary impactor 11 for pulverizing the radioactive concrete waste 2 to separate the radioactive pollutant paste and aggregate, and the sorting unit 20 includes a paddle-type rotary impactor ( 11) The paste and the aggregate are discharged in a state of being closely adhered to the sample discharge gate 17 provided in 11) so as to prevent external leakage of the fine powder, and to separate the separated fine powder and aggregate. In addition, the exhaust gas processing unit 30 is connected to the paddle-type rotary impactor 11 of the crusher 10 to purify the exhaust gas containing particulates present in the paddle-type rotary impactor 11. .

The paddle-type rotary impactor 11 according to the present invention, as shown in detail in Figs. 2 and 3, a pair of hoppers 12 into which the radioactive concrete waste 2 is introduced, and meshed with gears 13 '. A shaft 13, a motor 14 for rotating one of the pair of shafts 13, a plurality of paddles 15 and the pair coupled to the pair of shafts 13, respectively. It comprises a bearing 16 for supporting one end of the shaft (13).

At this time, since the pair of shafts 13 are meshed with the gears 13 ', in particular spur gears, when one of the shafts is rotated by the motor 14, the other shafts rotate in the opposite direction. do.

The paddles 15 are arranged to have the same direction and phase as the paddles coupled to adjacent axes, and the paddles coupled to one axis have a phase difference of 90 ° with the adjacent paddles. Since the pair of shafts 13 rotate in opposite directions, the paddles 15 rotate smoothly without interfering with each other and pulverize the radioactive concrete waste 2 that enters therebetween. In the exemplary embodiment of the present invention, the paddles 15 may have a shape such as a paddle or spatula, but the shape of the paddle 15 is not limited thereto. Since the paddle 15 is a part for impacting and crushing the radioactive concrete waste 2, it is preferable that the paddle 15 is detachably coupled to the shaft 13 so that it can be exchanged when the wear increases after a long time. . In the embodiment of the present invention, the threaded end of the paddle 15 is configured to be fixed by a nut after passing through the shaft 13.

On the other hand, the paddle-type rotary impactor 11 further includes a control unit 18, the control unit 18 to change the rotational direction of the motor 14 periodically so that the radioactive concrete waste (2) is evenly crushed. Can be. In particular, the controller 18 monitors the current supplied to the motor 14, and when it is determined that the motor 14 is overloaded by exceeding a predetermined value, the motor ( It is preferable to immediately change the direction of rotation of 14) to the opposite direction.

In addition, the paddle-type rotary impactor 11 may include at least one transparent observation window 19 for observing the inside thereof, the grinding state of the radioactive concrete waste (2) through the observation window 19 Or other malfunctions can be checked.

In the present invention having the configuration as described above, the sample input unit 50 for continuously supplying the radioactive concrete waste 2 may be further included in front of the hopper 12 of the paddle-type rotary impactor (11).

In this case, the sample input unit 50, the conveyor 51 for transporting the radioactive concrete waste (2), and the radioactive concrete waste (2) transferred to the conveyor 51 is introduced into the hopper 12. It consists of an airtight injector 52 having a double hermetic door 53 for temporarily storing in an air lock state before. The hermetic filler 52 is installed to prevent the radioactive material from spreading to the outside when the radioactive concrete waste 2 is injected into the hopper 12. Since the hermetic injector 52 is provided with a double hermetic door 53, the radioactive concrete waste 2 is completely accommodated in the double hermetic door 53 and then radioactively safer by opening the door connected to the hopper 12. The concrete waste 2 can be supplied to the paddle-type rotary impactor 11.

In addition, the hermetic filler 52 has a nitrogen purge device for injecting and exhausting nitrogen to prevent explosion and fire caused by foreign substances included in the input when the radioactive concrete waste 2 is introduced into the hopper 12 ( It is further preferred to further include 54) to allow the radioactive material to remain in the paddle-type rotary impactor 11 to remain in the airtight introducer 52.

On the other hand, the control unit 18 included in the paddle-type rotary shock 11, monitors the current supplied to the motor 14, the current exceeds the predetermined value to overload the motor 14 If it is determined that the jam is caught may be configured to reduce the conveying speed of the conveyor 51 or to stop the conveyor (51).

And the sorting unit 20 of the present invention may include at least one or more vibrating screen device 21, the radioactive concrete waste (2) crushed by the vibrating screen device 21 is filtered by the size of the particles To be separated. The vibrating screen device 21 may be referred to as a sieve (vibrating sieve) as it is, and serves to separate the crushed radioactive concrete waste (2) into paste to be discarded and aggregates that can be recycled. The number of the vibrating screen device 21 and the size of the eye are appropriately selected according to the size and type of particles to be classified.

An exhaust fan 31 for sucking exhaust gas inside the paddle-type rotary impactor 11 is installed at an end of the exhaust gas processing unit 30, and the paddle-type rotary impactor is operated by the operation of the exhaust fan 31. 11) The inside is kept under negative pressure. When the inside of the paddle-type rotary impactor 11 maintains the negative pressure state, it is possible to effectively prevent the radioactive particles and the exhaust gas generated during the crushing of the paddle-type rotary impactor 11 to the outside.

Here, the exhaust gas processing unit 30 includes a cyclone 32 having a collecting tank 33 at a lower portion thereof, a fine particle remover 34 into which exhaust gas having passed through the cyclone 32 flows, and the fine particles. It consists of a filter portion 40 through which the exhaust gas passing through the eliminator 34 is introduced.

The cyclone 32 is a separator using centrifugal force generated by the swirling flow of the fluid. Since the cyclone 32 is a widely used device for separating particles from the fluid, a detailed description thereof will be omitted. The collection tank 33 is for collecting the particles separated by the swirl flow inside the cyclone 32.

The fine particle remover 34 is composed of a vertical cylindrical container 35, and a chevron plate 36 and a mesh plate 37 are provided inside the container 35 and pass through the cyclone 32. Exhaust gas enters the lower part of the container 35, passes through the chevron plate 36, and is discharged to the upper part of the container 35 via the mesh plate 37.

As shown in FIG. 1, the chevron plate 36 is arranged such that a plurality of plates bent in a wave shape are spaced in parallel to each other. The chevron plate 36 is a separation device using an inertial collision of particles flowing along a fluid, and in particular, a plurality of bent plates provided in the chevron plate 36 are arranged in a vertical direction, and exhaust gas is bent in the plurality of bends. Flows into the space between the plates. Accordingly, the fine particles contained in the exhaust gas are separated from the flow of the exhaust gas while colliding with the bent surface of the chevron plate 36 that is bent in a wave shape while having a bending angle of about 90 °.

In addition, the particles collected in the chevron plate 36 and the mesh plate 37 are collected in the lower portion of the container 35 by an impact method or the like, and then transferred to the collection tank 33 of the cyclone 32. Is processed.

The filter part 40 includes a pre-filter 41, a first hepa filter 42, an activated carbon filter 43, and a second hepa filter 45 sequentially arranged from the inlet thereof.

Here, the prefilter 41 is installed for the purpose of collecting particulates from the exhaust gas, and is made of glass microfibers.

The first HEPA filter 42 and the second HEPA filter 45 are nuclear grade HEPA filters, and have a dust collection efficiency of 99.97% or more for particles of 0.3 μm or more. The maximum operating temperature can withstand 93 ° C at 100% relative humidity.

The exhaust gas which has passed through the first hepa filter 42 enters into a charcoal filter 43. The activated carbon filter 43 is installed to filter harmful particulates such as volatile organic mixtures or mercury and gaseous pollutants, and is made of nuclear grade carbon. Nuclear grade carbon impregnates specially activated carbon to absorb radioactive gases, with a maximum operating temperature of 93 ° C.

In addition, a di-octyl-phtalate (DOP) test unit 44 may be further included between the activated carbon filter 43 and the second HEPA filter 45. The DOP test unit 44 is for checking the dust collection efficiency of the first and second HEPA filters 42 and 45, and the dust collection efficiency of the first and second HEPA filters 42 and 45 is 99.97% or more. Since the test is measured at 100%, the performance is more precisely measured by using DOP particles having a diameter of 0.3 μm.

Preferably, each of the prefilter 41, the first hepa filter 42, and the second hepa filter 45 is provided with a relative pressure sensor 46 for measuring the pressure difference before and after. This is to determine the replacement timing of each filter by measuring the pressure applied to the front and rear ends of each of the prefilter 41 and the first / second HEPA filters 42 and 45.

Meanwhile, in the embodiment of the present invention, the filter unit 40 is composed of at least two filter units 40 connected in parallel, the exhaust gas passing through the particulate remover 34 is the plurality of filter units 40 ) Can be introduced into each. The number of the filter unit 40 may be appropriately selected according to the flow rate of the exhaust gas to be treated.

In addition, each of the front and rear ends of the filter unit 40 may be provided with a separate damper 47, which is to prevent the exhaust gas from flowing back during the filter replacement.

In addition, a radiation measuring unit 48 may be disposed downstream of the exhaust fan 31 to measure the radiation level of the exhaust gas emitted into the atmosphere. The radiation measuring unit 48 is a device for continuously detecting and monitoring the radiation level in the air of the designated area to enable the operator to detect the occurrence of radioactive accidents, by taking a sample of the exhaust gas emitted to the atmosphere through the chimney Continuously monitor and monitor the concentration of radioactive material.

At this time, the radiation measuring unit 48 sounds an alarm when the radiation level of the exhaust gas discharged to the atmosphere exceeds a predetermined value, that is, the allowable value of the emission nuclide concentration, and further, the paddle-type rotary impactor 11 By transmitting the alarm signal to the control unit 18 included in the control unit 11 receives the alarm signal of the motor 14 of the conveyor 51 and the paddle-type rotary shock 11 of the sample input unit 50 It is desirable to stop driving.

The technical configuration of the present invention has been described with reference to one embodiment shown in the accompanying drawings, but this is merely exemplary, and those skilled in the art may have various modifications and equivalents thereto. It will be appreciated that examples are possible. Therefore, the true scope of protection of the present invention should be defined by the appended claims, and should not be limited to the illustrated embodiments.

1 is a view schematically showing the overall configuration of the radioactive concrete waste reduction and nuclide removal equipment according to the present invention.

Figure 2 is a plan view of a paddle-type rotary shock machine provided in the present invention.

Figure 3 is a side view of the paddle-type rotary shock machine provided in the present invention.

4 is a view of the configuration of the filter unit provided in the present invention.

DESCRIPTION OF REFERENCE NUMERALS

1: Treatment of radioactive concrete waste and removal of nuclides

2: radioactive concrete waste

10: crushing unit 11: paddle type rotary shock machine

12: Hopper 13: Shaft

13 ': gear 14: motor

15: Paddle 16: Bearing

17: sample discharge gate 18: control unit

19: observation window 20: selection unit

21: vibration screen device 30: exhaust gas treatment unit

31: exhaust fan 32: cyclone

33: collection tank 34: particulate remover

35: container 36: chevron plate

37: mesh plate 40: filter unit

41: prefilter 42: first hepa filter

43: activated carbon filter 44: DOP test unit

45: second HEPA filter 46: relative pressure sensor

47: separation damper 48: radiation measuring unit

50: sample input section 51: the conveyor

52: hermetic feeder 53: double hermetic door

54: nitrogen purge device

Claims (19)

A crushing unit including a paddle-type rotary impact machine for crushing radioactive concrete waste and separating the radioactive contaminants into paste and aggregate; A sorting part for accommodating the paste and aggregate discharged through a sample discharge gate provided in the paddle-type rotary impactor, and selecting the separated contaminated fine powder and aggregate; It is connected to the paddle-type rotary shock impactor of the crushing unit, and configured to include an exhaust gas processing unit for purifying the exhaust gas containing the particulates present in the paddle-type rotary impactor, The paddle-type rotary impactor, A hopper into which the radioactive concrete waste is injected; A pair of axes engaged in gears, A motor for rotating one of the shafts of the pair; A plurality of paddles each coupled to the pair of axes and A radioactive concrete waste reduction and nuclide removal facility comprising a bearing for supporting one end of the pair of shafts. delete The method according to claim 1, And said pair of shafts rotate in opposite directions, said plurality of paddles having the same direction and phase as the paddles coupled to adjacent shafts. The method of claim 3, Paddles coupled to the one shaft is disposed so as to have a phase difference of 90 ° with the adjacent paddles. The method according to claim 4, And said paddles are coupled to separate the radioactive concrete waste reduction and nuclide removal facility. The method according to claim 1, The paddle-type rotary impactor further comprises a control unit, the control unit for reducing radionuclide and nuclide removal facility, characterized in that for periodically changing the rotation direction of the motor. The method according to claim 1, The paddle-type rotary impactor is radioactive concrete waste reduction and nuclide removal facility, characterized in that it comprises at least one transparent observation window that can observe the inside. The method according to claim 1, Sample input unit for continuously supplying the radioactive concrete waste radioactive concrete waste reduction and nuclide removal equipment characterized in that it is further included in front of the hopper of the paddle-type rotary impactor. The method according to claim 8, The sample input unit comprises a hermetic feeder including a conveyor for transporting the radioactive concrete waste, and a double hermetic door for temporarily storing the radioactive concrete waste transferred to the conveyor in an air lock state before being introduced into the hopper. Radioactive concrete waste removal and nuclide removal equipment. The method according to claim 9, The hermetic filler includes a nitrogen purge device for injecting and evacuating nitrogen to prevent explosion and fire caused by foreign substances contained in the input when the radioactive concrete waste is introduced into the hopper. Reduction and Nuclide Removal Facility. The method according to claim 9, The paddle-type rotary shock machine further includes a control unit, the control unit monitors the current supplied to the motor, and if it is determined that the motor is overloaded because the current exceeds a predetermined value, the conveyance of the conveyor A radioactive concrete waste reduction and nuclide removal facility, characterized in that the speed is reduced or the conveyor is stopped. The method according to claim 1, The sorting unit further comprises at least one vibrating screen device, radioactive concrete waste reduction and nuclide removal facility, characterized in that the crushed radioactive concrete waste is separated by the size of the particles. The method according to claim 1, An exhaust fan for sucking exhaust gas inside the paddle-type rotary impactor is installed at an end of the exhaust gas treatment unit, and the inside of the paddle-type rotary impactor maintains a negative pressure state by the operation of the exhaust fan. Waste reduction and nuclide removal plant. 14. The method of claim 13, The exhaust gas treatment unit comprises a cyclone having a collection tank at a lower portion thereof, a particulate remover into which exhaust gas passes through the cyclone, and a filter unit into which exhaust gas passes through the particulate remover is introduced. Waste reduction and nuclide removal plant. The method according to claim 14, The fine particle remover is made up of a vertical cylindrical container, and the inside of the container is provided with a chevron plate and a mesh plate, exhaust gas passing through the cyclone enters the lower portion of the container and passes through the chevron plate and then through the mesh plate Radioactive concrete waste reduction and nuclide removal equipment, characterized in that discharged to the top of the container. The method according to claim 14, The filter unit is a radioactive concrete waste reduction and nuclide removal equipment, characterized in that consisting of a pre-filter, a first hepa filter, an activated carbon filter, and a second hepa filter disposed sequentially from the inlet. 18. The method of claim 16, Front and rear ends of the filter unit, the radioactive concrete waste reduction and nuclide removal facility, characterized in that each provided with a separate damper. 14. The method of claim 13, Downstream of the exhaust fan radioactive concrete waste reduction and nuclide removal facility, characterized in that the radiation measuring unit for measuring the radiation level of the exhaust gas discharged to the atmosphere is disposed. delete

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