RU40113U1 - DEVICE FOR CLEANING GAS-RADIOACTIVE WASTE FROM RADIOACTIVE IODINE - Google Patents

Abstract

The utility model relates to devices for the purification of gaseous radioactive waste (GD) from radioactive iodine and can be used in nuclear energy industry.

The problem to which the proposed utility model is directed is to create a device for the purification of gaseous radioactive waste from radioactive iodine. Only the spent sorbent is replaced in the device without dismantling the device itself from the iodine gas treatment system. At the same time, the main and connecting dimensions are preserved, since the re-installation of gas ducts at existing nuclear power plants and other industrial enterprises is difficult, and in some cases impossible.

To solve this problem, a device for cleaning gaseous radioactive waste from radioactive iodine contains a housing with inlet and outlet nozzles, inside which there is a sorbent element, and the sorbent element is made in the form of modules equipped with a sorbent, installed with the possibility of replacement on a mobile platform and placed in horizontal sockets gas-tight panels, the modules are made in the form of a rectangular case with upper removable and lower gas-permeable partitions, while the upper The partition is attached to the rectangular casing with the possibility of adjusting its height position and fixing the sorbent inside the module.

Description

The utility model relates to devices for the purification of gaseous radioactive waste (GD) from radioactive iodine and can be used in nuclear energy and industry.

A device for cleaning air from a radioiodine is known, consisting of a housing with a cover, nozzles for air inlet and outlet, three cartridges with a nozzle from the sorbent. (“Environmental protection at the enterprises of the nuclear industry”, under the editorship of B.N. Laskorin, M., Energoizdat, 1982, p. 63, Fig. 2.5).

The disadvantage of this device is that it can only be used in an emergency, short-term situation, when the total number of radioiodine is small. This is due to the fact that the layer thickness is insufficient for long-term operation. In addition, the vertical arrangement of the sorbent layer leads to the fact that the sorbent during operation of the device is compacted. In this regard, gaps may form on top of the layer through which conditions are created for the passage of a part of the gas stream without purification and thereby a decrease in the efficiency of the adsorber. In addition, the vertical placement of the sorbent has another drawback - this is an uneven distribution of bulk density along the height of the layer, which also leads to a decrease in the efficiency of the apparatus due to the uneven velocity of the gas stream along the height of the layer.

The closest technical solution to the proposed utility model, selected for the prototype, is a device consisting of a housing with inlet and outlet pipes, two gratings and grids, between which there is a sorbent - activated carbon. (“Environmental Protection at the Enterprises of the Nuclear Industry”, under the editorship of B.Ch. Laskorin, M., Energoizdat, 1982, p. 63, Fig. 2.5). This device (adsorber

AU-1500) is currently used for trapping radioactive iodine in nuclear power plants (NPPs). It has a gas throughput of 1500 nm ³ / h.

The disadvantage of the prototype is that after the life of the resource or its failure for other reasons, the adsorber must be completely dismantled from the iodine gas purification system with subsequent disposal, which leads to the loss of expensive metal products, irrational use of solid radioactive waste storage volumes, given that at nuclear power plants a very large number of iodine adsorbers are used.

The proposed utility model solves the problem of creating a device for cleaning gaseous radioactive waste (GD) from radioactive iodine, in which only the spent sorbent is replaced without removing the device from the iodine gas treatment system. At the same time, the main overall and connecting dimensions are preserved, since the re-installation of gas ducts at existing nuclear power plants and other industrial enterprises is very difficult, and in some cases impossible.

To solve this problem, a device for cleaning gaseous radioactive waste from radioactive iodine contains a housing with inlet and outlet nozzles, inside which a sorbing element is placed, and the sorbing element is made in the form of modules equipped with a sorbent, installed with the possibility of replacement on a mobile platform and placed in horizontal sockets gas-tight panels, the modules are made in the form of a rectangular case with upper removable and lower gas-permeable partitions, while the upper The partition is attached to the rectangular casing with the possibility of adjusting its height position and fixing the sorbent inside the module.

In a particular embodiment, for loading and unloading modules, the housing is equipped with hatches that can be closed with quick-release clamps.

In another particular embodiment, two lever-screw mechanisms are placed on opposite sides for removing and lifting the modules from the sockets inside the case, which are fixed on the panel with the lower part and on the platform with the upper part, the modules being located on lodges and roller bearings.

In another particular embodiment, in order to control the tightness of the installation of the modules in the slots, a continuous groove is made along the perimeter of each slot, hermetically connected to the pipeline brought to the outer surface of the housing and closed by a removable cap.

The essence of the utility model is illustrated by the following drawings.

Figure 1 shows the appearance of the device.

AA - section on the upper part of the housing, which shows the location of the modules with the sorbent;

BB - the vertical section of the device.

Figure 2 presents the module with the sorbent

I - fixing the upper grille in the module;

II - fixing the lower grill in the module;

Figure 3 presents the position of the modules in preparing the device for operation and during its operation. The position of the groove and the pipe connected to it is shown for tightness control.

a - the position of the modules during installation of the modules in the slots;

b - working position of the modules;

Figure 4 presents the position of the modules when unloading them from the device.

c - modules in working position;

g - modules in the raised position with the open loading and unloading hatch of the device;

d - modules in the extended position from the device for their replacement.

The device for cleaning the gas distribution system includes a housing 1 and four modules 2 filled with a sorbent.

The device is a rectangular metal structure, the internal cavity of which is divided into two parts by a horizontal dividing gas-tight panel 3, which has slots for installing modules. In the side, divided parts of the housing, there are inlet 4 and outlet 5 nozzles for the passage of the gas to be cleaned. Two hatches 6 for loading and unloading modules from the housing. Each of the hatches is pressed to the body using seven eccentric clamps 7. The tightness of the hatches in relation to the body is achieved using seals 8 located around the perimeter of the hatch. Two lever-screw mechanisms 9 with the help of inserted keys provide vertical movement of the platform 10, which in turn raises the modules for replacement and lowers and presses the modules to the separation panel when installing new modules in the housing. The horizontal movement of the platform with the modules is carried out using the rollers 11 on the plates 12, while the emphasis limits the extension of the platform from the housing to only half. Thus, through each of the hatches with an extended platform, two modules are replaced. For lifting work, four transport eyes are installed on the device case 13. The module is a rectangular metal case 14, on the sides of which there are two lodges 15 for installing the module on the platform and two ears 16 for transport and lifting operations. Inside the casing there is a fixed lower lattice 17 with a grid and a removable upper lattice 18 with a grid attached to the casing with screws 19 passing through the grooves of the casing and nuts 20. Between the lattices there is a sorbent 21. The upper lattice for compressing the sorbent can move in height within the length of the grooves. A seal 22 is located around the entire perimeter of the lower base of the module to ensure a tight installation of the module in the slot 23 of the separation panel. By

the perimeter of each socket is made of a continuous groove 24, hermetically connected to the pipeline 25.

Preparation for operation of the device is carried out in the following sequence:

- with open hatches 6, two modules 2 are installed on the platform 10 extended with open hatches (Fig. 3), for which purpose the tool cradles 15 of the modules are inserted into the platform all the way, holding the platform from moving;

- on the rollers 11 on the plates 12 move the platform with two installed modules in the direction of the opposite hatch to the stop and install two other modules on the platform;

- close the hatch on the opposite side of the hull;

- push the platform with four modules into the housing 1 until it stops;

- lower the platform with the modules before installing the modules in the slots 23 of the separation panel 3, rotating the keys alternately, avoiding the distortions of the platform, the screws of the two lever-screw mechanisms 9;

- press the modules to the sockets, continuing to rotate the screws of the lever-screw mechanisms to the stop;

- remove the keys from the screws of the lever-screw mechanism and close the hatch;

- they check the tightness of the installation of the modules by supplying compressed air through a pipe 25 to the groove 24 and control the absence of pressure drop in the groove.

To replace the modules in the adsorber filter, open the hatch, lift the platform with the modules by rotating the elevator screws, push the platform out of the housing through the side hatch and remove the modules from the platform, moving their tool holders along the platform guides. Modules are replaced in pairs through opposite hatches.

The modular version of the device allows you to more evenly distribute the sorbent over the cross section in the modules, since their cross section is smaller than that of the AU-1500 adsorber. In addition, for the same reason, the probability of the sorbent moving during operation (for example, due to vibration) is less likely, which is observed in practice with AU-500 adsorbers. The ability to remove the module from the housing allows periodic monitoring of the state of the sorbent during operation of the device.

Thus, the proposed device is structurally simple, technologically advanced to manufacture, reliable in operation, allows you to mount and dismantle modules with a sorbent at the installation site, which increases the service life of the main equipment. The horizontal gas-tight panel provides sealing of the modules in the slots due to the pressure drop across the sorbent layer.

Tests of the prototype of the proposed device for the purification of gaseous radioactive waste from radioactive iodine presented the following technical characteristics:

- Nominal gas output

with a relative humidity of not more than 90%, nm ³ / h 1500 - Purification factor for molecular iodine, not less 1000 - Purification coefficient for methyl iodide, not less 100 Maximum inlet gas temperature, ° С 60

Maximum inlet gas temperature at

short-term operation, ° С 90 - Working aerodynamic drag, kPa 2.4-2.6

- Sorbent - activated carbon of the SKT-ZIK brand

- TU 7837-090-048387-99

- The main structural material is steel 12X18H1 OT

Claims (4)

1. A device for cleaning gaseous radioactive waste from radioactive iodine, comprising a housing with inlet and outlet nozzles, inside which a sorbent element is placed, characterized in that the sorbent element is made in the form of modules equipped with a sorbent, installed with the possibility of replacement on a mobile platform and placed in nests of a gas-tight panel, and the modules are made in the form of a rectangular case with upper and lower stationary gas-tight partitions, while the upper partition is attached replen to a rectangular body with the ability to adjust its position in height and fix the sorbent inside the module. 2. The device according to claim 1, characterized in that for loading and unloading the modules, the housing is equipped with hatches that are closed with quick-release clamps. 3. The device according to claim 1, characterized in that for removing and lifting the modules from the sockets inside the housing from opposite sides there are two lever-screw mechanisms, which are attached to the panel with the bottom and the movable platform with the top, and the modules are located on tool holders and roller bearings. 4. The device according to claim 1, characterized in that for monitoring the tightness of the installation of the modules in the sockets along the perimeter of each socket, a continuous groove is made, hermetically connected to the pipeline brought to the outer surface of the housing and closed by a removable cap.