KR20070056576A - Process and system for the gasification of very low radioactive waste water - Google Patents

Abstract

A gasification method and an apparatus for very low radioactive waste water is provided to exhaust a gasified result to the atmosphere by heating and gasifying the radioactive waste water to eliminate radioactive substance from the waste water. A forcibly circulating evaporator(200) has a bubble cap tray(230) dividing very low radioactive waste water into vapor having no radioactive nuclide and liquid with condensed radioactive nuclide, and a spray eliminator(240) completely eliminating fine water particle from the vapor. A heat exchanger(220) supplies the very low radioactive waste water heated by a circulation pump(210). A blower(300) injects natural air into the vapor to dilute the vapor.

Description

Process and system for the gasification of very low radioactive waste water

1 shows a schematic diagram showing a conventional apparatus for treating radioactive wastewater,

2 shows a schematic view showing an apparatus for treating radioactive wastewater according to one embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: ultra-low level radioactive wastewater storage tank 110: pump

120: evaporation cloth 130: blower

200: forced circulation evaporator 210: circulation pump

220: heat exchanger 225: steam

230: seed end 240: spray eliminator

250: extremely low level radioactive wastewater 260: discharge pipe

300: blower 400: chimney

The present invention relates to a method and apparatus for gasifying extremely low-level radioactive wastewater generated in a nuclear power plant, a research reactor, a nuclear research facility, an isotope use facility, and more safely and effectively to the atmosphere.

Nuclear power plants, research reactors, nuclear research institutes, and isotope-use facilities inevitably produce radioactive wastewater. Radioactive wastewater is classified into high level radioactive wastewater, low and medium level radioactive wastewater and very low level radioactive wastewater according to the radioactive level determined by the amount of radioactive material in the wastewater.

Although there are differences in the classification criteria for each country, the radioactive concentrations of high-level radioactive wastewater are usually 0.1 Ci / m3 or higher, the low- and low-level radioactive wastewater is 0.1-5 × 10 ^-5 Ci / m3, and the very low level radioactive wastewater is 5 × ^10-6. It refers to waste water of Ci / m 3 or less. High-level radioactive wastewater is converted into low- and low-level radioactive wastewater by appropriate treatment methods, and the low-level radioactive wastewater is lowered back to an extremely low level.

Extremely low level radioactive wastewater may be obtained after treatment of low or low level radioactive wastewater, or may result from contamination of the radioactive material with very little water used during the process. In general, very low-level radioactive wastewater has a very low concentration of radioactive material in the wastewater, and if it is below the legal limit value, it is drained as it is, or diluted with general water to lower the radioactive concentration, and then drained into abundant river or sea.

However, when there are no rivers or seas with abundant water nearby, the discharge of extremely low-level radioactive wastewater is extremely limited. This is because, if discharged in a place where the quantity is not abundant, in some cases, extremely low-level radioactive wastewater may be stagnated, and a very small amount of radioactive material may be deposited nearby to contaminate the surroundings. Therefore, in this case, the very low level radioactive wastewater has to be evaporated and exhausted into the atmosphere. Therefore, there is a need for a technique for efficiently gasifying extremely low level radioactive wastewater.

Korea Atomic Energy Research Institute also currently has only to evaporate a polar low-level radioactive waste in the world to exhaust the atmosphere equipped with amenities such as: 1. In this facility, a very low level of radioactive wastewater flows down the surface of the evaporation spring 120 installed vertically, and a lot of water is evaporated by forcibly blowing air through the evaporation spring 120.

The collected ultra-low level radioactive wastewater was stored in the underground storage tank 100 of 860 m3 and then evaporated by 1.2 m x 5.4 m in size through 1,032 water distribution pipes by a circulation pump with a capacity of 120 m3 / hr. 120) supplied to the surface. About 900 evaporation springs 120 are used. At the same time, 10 blowers with a blowing capacity of 96,500 m3 / hr installed at the top of the facility are allowed to flow out of the wastewater, and the air flowing from the lower part of the facility flows from the bottom to the top between the evaporation springs 120. Moisture will evaporate. At this time, the amount of evaporation varies depending on the flow rate, flow rate, relative humidity, temperature, etc. of the incoming air, and when the relative humidity is operated under the above conditions at 70% or less and 10 ° C. or higher, about 500 to 600 kg of water is evaporated per hour. Is being reported.

By the way, the facility uses a very large evaporation stream 120 to increase the evaporation efficiency, after a certain time, the evaporation stream 120 is damaged and must be replaced periodically. Since the replaced evaporation stream 120 is contaminated with radioactive material, it is classified as radioactive waste and has to be treated or stored according to strict standards.

In addition, the above method has a limitation in increasing the speed of the air flowing between the evaporation stream 120 above the limit in order to increase the amount of evaporation because the evaporation stream 120 is thin and long. This is because, as the air velocity increases, the evaporation stream 120 vibrates and a splash entrainment occurs to lower the decontamination coefficient. Therefore, the number of installation of the evaporation stream 120 is increased, the area of the entire facility is increased.

Therefore, the present inventors have reduced the need for a device that can effectively treat the ultra low level radioactive wastewater, and by using a forced circulation evaporator and a blower to gasify the ultra low level radioactive wastewater to be safely and effectively exhausted to the atmosphere The method and apparatus for realizing the same have been developed and the present invention has been completed.

Accordingly, an object of the present invention is to provide a gasification treatment method and apparatus for ultra low level radioactive wastewater which can be vaporized to the atmosphere by safer and more effective gasification of the ultra low level radioactive wastewater by using a forced circulation evaporator and a blower. have.

In order to achieve the above technical problem, the present invention comprises the steps of: (a) vaporizing a very low-level radioactive wastewater and classifying the radionuclide into concentrated liquid and pure water vapor; (b) leaving the liquid containing the radionuclide concentrated in the sorted evaporator and remaining in the evaporator and supplementing the extremely low level radioactive wastewater as much as evaporated to make it into a low and medium level radioactive wastewater; (c) completely removing and discharging fine water particles remaining in the fractionated steam; And (d) distilling natural air to completely vaporize the discharged water vapor below the dew point of the atmosphere and exhaust it to the outside.

In order to achieve the above another technical problem, the present invention, the ultra low-level radioactive wastewater and the seed end 230 for separating the radioactive radionuclide containing pure water and radionuclide concentrated liquid, and the seed end 230 Forced circulation evaporator 200 which is provided at the top and the top of the spray eliminator 240 for completely removing even fine water particles contained in a small amount of water vapor separated through the; Heat exchanger 220 for supplying the ultra low-level radioactive wastewater 250 that is in communication with the circulation pump 210 from the lower opening of the forced circulation evaporator 200 to one side injection port is heated through the circulation pump 210 ; And a blower (300) for injecting natural air for diluting the water vapor from which the fine water particles discharged from the forced circulation evaporator (200) is removed to convert it to a state below the dew point of the atmosphere and exhausting it to the outside. Provided is a gasification treatment apparatus for extremely low level radioactive wastewater.

According to the present invention, the ultra low level radioactive wastewater is evaporated by a forced circulation evaporator which is currently found to have the best evaporation effect to become water vapor, and the generated water vapor is again below the dew point of the atmosphere by the air introduced by the blower. Diluted and fully gasified, it can be safely vented to the outside.

Hereinafter, the present invention will be described in detail.

According to the present invention, a gasification treatment method for a very low level radioactive wastewater comprises (a) evaporating a very low level radioactive wastewater and classifying the radionuclide into concentrated liquid and pure water vapor, and (b) radionuclide in the classified evaporator. The concentrated liquid is left in the evaporator and supplemented with the low level radioactive wastewater as much as evaporated to make it into a low and low level radioactive wastewater, and (c) completely removed and discharged the fine water particles remaining in the classified water vapor. Next, (d) to make the discharged water vapor below the dew point of the atmosphere and dilute with natural air to exhaust to the outside to completely gasify.

Hereinafter, an apparatus of the present invention for performing the above method will be described with reference to the drawings.

FIG. 2 is a schematic view showing an apparatus for treating radioactive wastewater in accordance with an embodiment of the present invention . Referring to FIG. 2 , an apparatus for gasifying the ultra low-level radioactive wastewater of the present invention and evacuating it into the atmosphere is greatly forced-circulated. It consists of an evaporator 200 and a blower 300.

Outside the forced circulation evaporator 200, a heat exchanger 220 for heating the wastewater and a circulation pump 210 for circulating the wastewater are installed in communication with each other. Inside the forced circulation evaporator 200, a bubble cap plate 230 and a spray remover 240 are installed at the top and the top thereof, respectively.

Outside the forced circulation evaporator 200, the circulation pump 210 is communicated from the bottom opening of the forced circulation evaporator 200 to one side injection port, the ultra-low level radioactive wastewater 250 is heated through the circulation pump 210 The heat exchanger 220 for supplying) is installed.

The upper end of the forced circulation evaporator 200 is provided with a seed end 230 for separating pure water vapor containing no radionuclide into a liquid in which the radionuclide is concentrated, and the water vapor separated through the seed end 230. Spray eliminators 240 for completely removing even fine water particles contained in the trace amount are respectively installed at the top.

At this time, the forced circulation evaporator 200 is mixed with the ultra-low-level radioactive wastewater 250, which is supplemented by the evaporated liquid inside the radionuclide classified as described above into the evaporator to make a low-low-level radioactive wastewater and then treated separately. Means (not shown) for doing so may be additionally installed.

The forced circulation evaporator 200, the upper discharge pipe 260 is connected to the blower 300, the blower 300 is a device for injecting natural air, fine discharged from the forced circulation evaporator 200 The water vapor from which the water particles have been removed is diluted to natural air to be converted to a state below the dew point of the atmosphere, and is installed to exhaust to the outside via the chimney 400.

It will now be described with reference to the process steps for embodiments using a vaporizing apparatus of the preferred pole low-level radioactive waste water of the present invention as described above with reference to FIG. 2.

As shown in FIG. 2 , the ultra low level radioactive wastewater 250 passes through the heat exchanger 220 through the circulation pump 210. Wastewater heated by the heat exchanger 220 is injected into the evaporator 200.

The heated and vaporized waste water is passed through the seed end 230 installed on the top of the evaporator 200. The radioactive waste water 250 passed through the seed end 230 is pure water vapor and radioactive containing almost no radionuclides. The nuclide is separated into a concentrated liquid.

The water vapor passing through the bubble end 230 is completely removed by the spray remover 240 positioned at the top of the evaporator to fine water particles contained in the water vapor and then discharged along the discharge pipe 260.

Wastewater in the evaporator 200 continues to circulate and is replenished with extremely low level radioactive wastewater 250 continuously as it is evaporated. After a certain period of time, the wastewater in the evaporator is higher than the supplied ultra-low level radioactive wastewater.

Water vapor discharged from the evaporator 200 is in a state in which the level is lowered to 1/10 to 1 / 1,000 as compared to the initial ultra low level radioactive wastewater. However, if this water vapor is exhausted to the outside as it is, it may be condensed in the atmosphere, slow down the diffusion into the surrounding atmosphere, and settle to the ground depending on the wind direction. In addition, the condensation of water vapor also occurs in the piping and the chimney for the exhaust, so the possibility of corrosion.

Therefore, the water vapor discharged from the evaporator 200 is mixed with the natural air introduced through the blower 300 and diluted to be below the dew point of the air, thereby making it not condensed in the air and then exhausting it to the outside.

Hereinafter, operating conditions according to an exemplary embodiment of the present invention will be described. However, the following examples are provided to illustrate the present invention, and the exemplary embodiments of the present invention are not limited or limited to the following examples.

< Example  1>

Extremely low level radioactive wastewater 250 was prepared. Table 1 below shows the composition of simulated radioactive wastewater at the 6 × 10 −7 Ci / m ³ level used in this example process.

ingredient Composition (wt%) Co-60 1 x 10 ^-7 Ci / m ³ CS-137 5 x 10 ^-7 Ci / m ³

The simulated radioactive wastewater passes through the heater 220 through the circulation pump 210, and vaporizes inside the forced circulation evaporator 200 and passes through the seed end 230 installed at the top. The water vapor passing through the bubble end 230 is completely removed to fine water particles contained in a small amount of water by the spray remover 240 (Demister) located at the top of the evaporator, and then discharged along the discharge pipe 260. The operating conditions of the forced circulation evaporator 200 are shown in Table 2 below.

Item Operating conditions RPM and Capacity of Circulation Pump 1,750 rpm, 120 m ³ / hr Heating steam pressure and temperature 3 bar, 133 ℃ Processing capacity 1000 kg / hr

According to the operating conditions shown in Table 2, water vapor having a water content of 5% or less is discharged along the discharge pipe 260. Although a heating temperature higher than 133 ° C. may be used, it is not preferable because it causes a problem that heat transfer is hindered by boiling in terms of heat transfer. Therefore, heating temperatures in the range from 130 to 140 ° C. are most suitable.

The water vapor discharged from the forced circulation evaporator 200 has a level of 5 × 10 ⁻¹¹ Ci / m ³ , which is lowered to about 1 / 10,000 as compared to the initial ultra low level radioactive wastewater.

In addition, the water vapor discharged from the forced circulation evaporator 200 is mixed with air introduced at a flow rate of 300,000 m 3 / hr through the blower 300 and diluted to be below the dew point of the atmosphere. As a result, the discharged water vapor is not condensed in the atmosphere and then exhausted to the outside.

When using the method and apparatus of the present invention as described above, it is possible to significantly reduce the installation area compared to the existing ultra low-level evaporation equipment. In addition, secondary waste is also minimized since no evaporative spring is used. In addition, in the method according to the present invention, when using the evaporator 200 capable of evaporating the ultra-low level radioactive wastewater of 500 kg per hour, the air flow rate for dilution below the dew point of the atmosphere, the relative humidity in the atmosphere is 70% or less, 10 ℃ It is about 270,000 m3 / hr, which is only about 1/4 of the existing evaporation plant.

While the invention has been shown and described with reference to specific embodiments, it is common practice in the art that various modifications and variations can be made therein without departing from the spirit and scope of the invention as indicated by the claims. Anyone who has a can easily know.

According to the gasification treatment method and apparatus of the ultra-low level radioactive wastewater according to the present invention, the ultra-low level radioactive wastewater generated in a nuclear power plant, a research reactor, a nuclear research facility, an isotope using facility, etc. is gasified and safely and effectively into the atmosphere. Compared with the existing ultra low-level evaporation facilities, the installation area can be greatly reduced, and since the use of an evaporation spring is not used, the amount of secondary wastes is also minimized.

Claims (4)

Vaporizing the extremely low level radioactive wastewater to classify the radionuclides into concentrated liquid and pure water vapor; Leaving the liquid in which the radionuclide concentrated in the sorted evaporator remains in the evaporator and simultaneously replenishing the extremely low level radioactive wastewater as much as evaporated to produce a low and medium level radioactive wastewater; Completely removing and discharging fine water particles remaining in the fractionated water vapor; And diluting with natural air to completely vaporize the discharged water vapor to below the dew point of the air and exhaust it to the outside. 2. The method of claim 1, wherein the liquid and pure water vapor in which the radionuclide is concentrated are classified by a foaming stage (230). Micropore 230 for separating extremely low-level radioactive wastewater into pure water containing no radionuclides and a liquid enriched in radionuclides, and fine water particles contained in a small amount in the water vapor separated through the seed end 230. Forced circulation evaporator 200 which is provided at the top and the top of the spray eliminator 240 for completely removing until; Heat exchanger 220 for supplying the ultra low-level radioactive wastewater 250 that is in communication with the circulation pump 210 from the lower opening of the forced circulation evaporator 200 to one side inlet, and is heated through the circulation pump 210. ; And A blower 300 for diluting the water vapor from which the fine water particles discharged from the forced circulation evaporator 200 is removed and converting it into a state below the dew point of the air and then injecting natural air to exhaust it to the outside. Apparatus for gasification of extremely low level radioactive wastewater. According to claim 3, wherein the forced circulation evaporator 200 is mixed with the low-level radioactive wastewater 250, which is supplemented by the evaporated inside the evaporator 200, the concentrated radionuclide concentrated medium and low-level radioactive wastewater And gasification treatment apparatus for ultra-low level radioactive wastewater, characterized in that additional means for additional treatment.

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