RU184350U1 - COMBINED FILTER FOR CLEANING RADIOACTIVE STEAM-GAS MIXTURE - Google Patents

Abstract

The utility model relates to the field of atomic energy and can be used in ventilation systems at nuclear power plants to localize volatile forms of radioactive iodine and radioactive aerosols in order to prevent radioactive contamination of the environment.

Combined filter for cleaning radioactive gas mixture is divided into identical cylindrical sections. Each section has an upper lid for installing variable surface spiral filter elements (SPEPP) and a lower lid with a grid for holding sorbents. The first and closing sections along the flow of gas to be purified are filled with a sorbent from an inorganic material SiO ₂ -Cu ⁰ , or silica gel KSKG or their mixture. As a filler of each of the intermediate sections for capturing volatile forms of radioactive iodine, granulated sorbent based on activated carbon SKT-3I or inorganic granulated sorbent Fizchemin based on silica gel is used. The pore size of SPEPP decreases in the direction from the first section to the closing along the gas stream being cleaned, and the number of sections that are equipped with a sorbent for cleaning gases from radioactive iodine-containing impurities is at least three. To improve the quality of the filter, the number of sections that are equipped with a sorbent for cleaning gases from radioactive iodine-containing impurities, is at least three. The proposed combined filter has a new positive property, which consists in the fact that it is fire safe and allows localization of volatile compounds of radioactive iodine both during normal operation of nuclear power plants and in emergency depressurization of fuel elements.

Description

The utility model relates to the field of atomic energy and can be used in ventilation systems at nuclear power plants to localize volatile forms of radioactive iodine and radioactive aerosols in order to prevent radioactive contamination of the environment.

The problem of reliable environmental protection at nuclear power plants is one of the important factors hindering the development of nuclear energy. Currently, ventilation systems at nuclear power plants for the localization of volatile forms of radioactive iodine use filters of type AU-1500 based on activated carbon of the SKT-3 and SKT-3I grades. [one]. One of the main disadvantages of such filters is their high fire risk. Therefore, under the conditions of accidents associated with the depressurization of a large number of fuel rods and the release into the atmosphere of the protective shell of nuclear power plants by the volatile fission products accumulated in nuclear fuel, there is a high probability of ignition of activated carbon inside the AU-1500 filters as a result of their heating after localization of a noticeable amount of short-lived radionuclides on them iodine. In this regard, the problem of reducing the fire risk of filters AU-1500 is relevant.

This task can be solved by sharing new inorganic materials and SKT-3I coal as part of iodine adsorbing filters. However, these adsorbers are not intended to contain radioactive aerosols.

For the purpose of simultaneous purification from radioactive aerosols, and radioactive iodine compounds at NPPs, combined filtering installations [2] or special filters containing aerosol and sorption modules [3] are used. In all the systems described above, the aerosol and sorption modules are separated from each other, and sorbents based on impregnated activated carbon are used to localize volatile compounds of radioactive iodine [4]. The main disadvantage of devices is that in all systems the problem of fire hazard of sorption modules remains.

Closest to the claimed technical solution is a combined two-stage filter adsorber FAI-3000-2, designed for integrated air purification from radioactive aerosols and radioactive iodine and its compounds. The filter consists of a body that includes two stages arranged in series: a loading section for cleaning air from gaseous radioiodine forms and a fine cleaning stage for trapping aerosols. In the iodine part, the fibrous material SFM “Filosorb” containing activated carbon impregnated with potassium iodides (barium) or amino alcohols is used, in the fine section - filter package based on aerosol glass material. The FAI-3000-2 filter is installed instead of an aerosol filter in NPP-specific ventilation, where the project does not provide for the installation of radioactive iodine filter adsorbers, or in systems where radioactive iodine adsorber filters have been operated in continuous mode for more than five years [5, 6].

The disadvantage of this device is high fire risk due to the use of activated carbon as a sorbent material for trapping compounds of radioactive iodine.

The technical result of the proposed utility model is to increase the safety of filters intended for the localization of radioactive aerosols and volatile compounds of radioactive iodine, by creating conditions under which the filtering process of the radioactive vapor-gas medium will not cause the filter to ignite for any characteristics of the radioactive gas-vapor mixture.

The technical result is achieved in that the combined filter housing is divided into identical cylindrical sections. Each section has an upper lid for establishing variable surface spiral filter elements (SPEPP) [7] and a lower lid with a grid for holding sorbents. To reduce the likelihood of activated carbon ignition, the first and closing sections along the flow of gas to be purified are filled with a sorbent from an inorganic material SiO ₂ -Cu ⁰ [8]. An inorganic granular “Fischimin” sorbent based on silica gel is used as a filler in each of the intermediate sections for trapping volatile forms of radioactive iodine [9]. To increase filtration efficiency, the pore size of spiral filter elements with variable surface decreases in the direction from the first section to the closing along the gas stream being cleaned, and the number of sections that are equipped with a sorbent for cleaning gases from radioactive iodine-containing impurities is at least three to improve the quality of the filter .

The essence of the utility model is illustrated in FIG. one.

FIG. 1 shows the scheme of the proposed combined filter, where 1 is the inlet, 2 is the bottom cover of the filter, 3 is the bottom cover of the section with a mesh to hold the sorbing materials, 4 is the mounting device, 5 is the section body, 6 is the inorganic material SiO ₂ -Cu ⁰ , 7 - SPEPP, 8 - the top cover of the section with holes for the installation of the SPPE, 9 - the inorganic granular sorbent "Fizkhimin", 10 - the top cover of the filter, 11 - the outlet.

Depending on the required performance and efficiency, both the dimensions of the filter and the number of spiral filter elements with a variable surface with different pore sizes can be changed.

The proposed combined filter with respect to the previously known combined devices for cleaning the gas flow from radioactive aerosols and volatile compounds of radioactive iodine has a new positive feature, namely that it is fire safe and allows the localization of volatile compounds of radioactive iodine during normal operation of nuclear power plants, as well and during emergency depressurization of fuel elements.

The technical and economic effect is to improve the safety of nuclear power plants due to the prevention of accidental emissions of a radioactive gas mixture during emergency depressurization of fuel elements and to ensure the retention of radioactive substances in the size of the sanitary protection zone of the nuclear power plant.

Literature

1. Fedorova L.I., Poltinin P.Ya., Karnatsevich L.V., Kulko V.B. // Questions of Atomic Science and Technology. Series: Physics of Radiation Damage and Radiation Materials. 2002. № 3 (81). S. 99-100.

2. Komyshniy V.N., Yagodkin I.V., Martynov P.N. et al. // Abstracts. Int. scientific and practical conf. "Aerosols and safety", October 24-28, 2005. Obninsk, Russia. Pp. 218-219.

3. Design of Off-Gas and Air Cleaning Systems at NPP // IAEA Technical Reports Series N 274. Vienna: IAEA, 1987.

4. Ustinov O.A., Sukhanov L.P., Yakunin C.A., Rastunov L.N. // Ross.chemich. magazine. 2005. V. 49, No. 4. Pp. 54-60.

5. "Progress-Ecology" on guard of NPP safety // Internet resource: www.kuriermedia.ru/data/objects/1271/6163.pdf. Date of visit: 02/20/2017.

6. Kornienko V.N. Creating iodine filter adsorbers for nuclear power plants and radiochemical plants // Abstract of thesis. ... candidate of those. sciences. St. Petersburg. Federal State Unitary Enterprise "St. Petersburg Research and Development Design Institute" Atomenergoproekt ". 2005. 22 p.

7. Konovalova NA, Krapukhin VB, Kulemin VV et al. // Proceedings. 3 ^rd Inter. Conf. Various Fields on Research (RAD 2015), 2015. Budva, Montenegro. P. 21-22.

8. Kulyukhin C.A., Rumer I.A., Mizina L.V. et al. // Radiochemistry. 2017. V. 59, N1. Pp. 71-75.

9. Bessonov A.A., Kulyukhin S.A., Konovalova N.A. etal. // Journal of Power and Energy Engineering. 2015. V. 3, N 4. P. 29-34.

Claims (3)

1. Combined filter for cleaning radioactive gas-vapor mixture, consisting of a body and sequentially connected sections, characterized in that identical cylindrical sections have lower and upper covers for establishing spiral filter elements with variable surface and mesh for retaining sorbents, with the first and closing during the course of the gas stream being cleaned, the sections are filled with a sorbent made of inorganic material SiO ₂ -Cu ⁰ , and inorganic is used as a filler for each of the intermediate sections Anic granular sorbent "Fizkhimin". 2. Combined filter according to claim 1, characterized in that the pore size of the spiral filter elements with variable surface decreases in the direction from the first section to the closing along the flow of gas to be cleaned. 3. Combined filter according to claim. 1, characterized in that the number of sections that are equipped with a sorbent for cleaning gases from radioactive iodine-containing impurities is at least three.

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