RU2309472C1 - Method and device for case-hardening liquid radioactive wastes - Google Patents

Abstract

FIELD: environment protection; immobilization of liquid radioactive wastes in stable solid medium.

SUBSTANCE: proposed method for case-hardening liquid radioactive wastes includes following procedures: liquid radioactive wastes are fed to tank and their level is measured; liquid radioactive wastes are mixed up within tank; metered amount of gas is supplied to tank from external source; liquid radioactive wastes are discharged to batcher through discharge tube and their level within batcher is measured; batcher content is mixed up; liquid radioactive wastes are discharged from batcher while raising pressure therein by conveying gas from external gas supply; cement and additives are fed to container through tube and each batch of compound is mixed up within container. Proposed device implementing this method has tank 1 and batcher 5 equipped with mixers and level gages, as well as container 14 accommodating mixer. Assembly 13 for feeding cement and additives is connected to container. External gas pressure supplies 4 and 9 are connected to tank and batcher. First discharge tube provides communication between tank and batcher 7; second one is mounted to provide communication between batcher and container 11. Discharge tube is provided with expansion units 8 and 12. Tank has pipes for feeding liquid radioactive wastes.

EFFECT: ability of case-hardening liquid radioactive wastes of different salt content and viscosity at a time, setting optimal proportion of cement compound ingredients in each container, ensuring production of stable water-proof cement blocks.

13 cl, 1 dwg

Description

The invention relates to the field of environmental protection, and more specifically to the field of processing of radioactive waste (RW) by fixing it in a stable solid environment.

A known method and device for cementing liquid radioactive waste (LRW) [RU patent 2132095. BI No. 17, 1999], which consists in the fact that cement is supplied with additives to the tank with an agitator from consumable hoppers through dispensers with jet pumps, simultaneously fed into the tank LRW before filling the working volume of the mixing unit, the cement compound is prepared by mixing cement with additives and liquid radioactive waste. Unload the mixing unit through the drain device into containers for long-term storage.

A device for cementing liquid radioactive waste contains a mixing unit, consisting of a tank with a mixer, a drain device, a vortex device, the input of which is connected to the output of the tank with a mixer, and the output with a drain device, a pipeline for supplying LRW, a hopper for cement, bunkers for solid additives, cement feeders and solid additives, each of which consists of a series-connected jet pump connected to cement and solid waste bins, a pipeline, a feed hopper and a batcher a connected to the input of the container with a stirrer, a circulation line provided with a pump and connected to the input of a stirred tank.

The disadvantages are:

the impossibility of the simultaneous use of LRW with different salt concentration and viscosity;

- clogging of the drain device with a radioactive compound, which leads to the need for periodic replacement;

- the need for periodic cleaning of the mixing unit from the radioactive cement compound;

- it is difficult to rebuild the device during the transition from one liquid radioactive waste to another.

A known method of cementing liquid radioactive waste [RU patent 2218618 BI No. 34, 2003] consisting in the fact that after it is docked with the loading unit, sensors of lower and upper levels are installed, the lengths of which correspond, depending on the salinity of the liquid radioactive waste, the volume of liquid radioactive waste and the volume of the cement compound; liquid radioactive waste is supplied to the container; using the lower level sensor, the achievement of a predetermined value of the volume of liquid radioactive waste is recorded in the contact ynere then supply is stopped to a container of liquid radioactive wastes and the cement feed is started and mixing of the cement compound, by upper level sensor register achieve setpoint volume cement compound, whereupon the supply of the cement in the container; the agitators are set and automatically controlled by a timer. At the end of the mixing of the cement compound, the container is undocked, the upper and lower level sensors are immersed in the container, it is closed and transported to the storage.

A device that implements a method for cementing liquid radioactive waste contains a container mounted on a trolley with an agitator installed therein, a device for feeding liquid radioactive waste and cement, an electric drive for the mixer, a device for controlling the means for supplying liquid radioactive waste and cement, a loading unit, a timer, solenoid valve, solenoid valve control device, level switch with lower and upper level sensors, working on changing the electrical conductivity of air dkie radioactive waste and air-cement compound. The inputs of the level switch are connected to the outputs of the sensors of the upper and lower levels; the output of the level switch corresponding to the low level sensor, providing a control signal through a normally closed contact of the level switch, is connected to the input of the control device of the electromagnetic valve and to the input of the control device of the device for supplying liquid radioactive waste; the output of the level switch corresponding to the low level sensor, providing a control signal through a normally open contact of the level switch, is connected to the input of the control device of the electric drive of the mixer, to the input of the control device of the cement supply device and to the timer start input; the output of the level switch corresponding to the upper level sensor, providing a control signal through a normally closed contact of the level switch, is connected to the input of the control device of the cement supply device; the output of the timer control channel is connected to the input of the agitator electric drive control device.

The presence of a level switch with lower and upper level sensors, working on changing the electrical conductivity of the media, air-liquid radioactive waste and air-cement compound, control devices for supplying liquid radioactive waste and cement, a timer, an electromagnetic valve, an electromagnetic valve control device complicates the device. In addition, the presence of solenoid valves and automatic controls make them unreliable. False positives are possible, which can lead to spills of LRW or deterioration of the properties of the cement compound.

Closest to the claimed are a method and device for cementing liquid radioactive waste [Davydov V.I. et al. "Installations for curing liquid waste of low and medium levels of activity." Atomic energy, 1995, T. 79, v.6, p. 431]. The method consists in supplying liquid radioactive waste and cement with additives to the measuring devices, supplying the contents of the measuring devices to the mixer, and then unloading the compound from the mixer into the container. The container is closed with a lid and transported to the mixing mechanism, where the compound is finally homogenized by rotating the container.

A device that implements a method for cementing liquid radioactive waste contains measuring devices for liquid radioactive waste and cement with additives, a mixer connected to measuring devices, pipes for unloading the compound into a container.

The device works as follows: cement and additives are fed into the measuring device. Liquid radioactive waste is supplied to the measuring device. The contents of the measuring devices are fed into the mixer. Serve under loading container. The container is loaded from the mixer through a tube for unloading with a mixture of liquid radioactive waste and cement with additives. Then they transport it to the mixing mechanism for final homogenization.

The disadvantages of the method and device are:

- the need for periodic cleaning of the mixer from the hardened mixture of LRW and cement, since otherwise the mixer will fill with the hardened mixture and cease to fulfill its functions, which reduces the reliability of the device;

- the lack of control over the preparation of the cement compound can lead to a poor quality cement compound (its low mechanical strength and high leachability);

- the impossibility of the simultaneous use of LRW with different salt concentration and viscosity.

The technical result that can be obtained using the proposed inventions is that it allows the use of LRW with different salinity and viscosity, i.e. it is universal, it allows you to set the optimum ratio of the components of the cement compound in each container, guaranteed production of durable waterproof cement blocks, which is achieved by portioning the LRW into the container while increasing reliability and simplifying the design of the cementing device.

The technical result is achieved by the fact that in the proposed method of cementing liquid radioactive waste, liquid radioactive waste is fed into a container, liquid radioactive waste is measured therein, liquid radioactive waste is mixed into a container, a calculated volume of gas from an external gas source is supplied to a container, liquid radioactive waste is unloaded into the measuring device through the discharge pipe, measure the level of liquid radioactive waste in the measuring device and, if necessary, remove the excess of settled liquid by increasing the pressure measuring cylinder, mix the contents of the measuring tank, liquid radioactive waste is discharged from the measuring tank, increasing the pressure therein from the external gas source into the container through the tube for discharging directly or through a feeder, fed into a container with cement additives mixed in each portion of the compound container.

Unload liquid radioactive waste in portions from the tank and the measuring device.

Stirring in the container allows the use of liquid radioactive waste with different salinity and average their activity.

The advantage of the proposed solutions are:

Lack of fittings and moving parts (such as screws, etc.), where mechanical breakdowns are possible, and hence the need to work in severe radiation conditions to eliminate the malfunction;

passivity of the system after putting it into action, minimizing personnel errors;

the simplicity of the algorithm for setting the required portion of LRW, eliminating the possibility of failure both in the actuators and in the control circuits of the batch feeding process, which leads to a sharp decrease in possible emergency situations;

the applicability of this method of metered transportation to a wide range of LRW (pulps, sorbents, KCO, etc.);

the convenience of applying this method to a two-stage supply scheme: capacity-measuring device-container for cementing.

Unloading liquid radioactive waste from the tank and the measuring device by increasing the pressure, with the possibility of interrupting the flow of liquid radioactive waste due to pressure equalization, allows the formation of portions of specified volumes and minimizes the surface where precipitation and siltation may occur.

If necessary, excess liquid from the measuring device is removed through a drain pipe with a filter by increasing the pressure in the measuring device after settling liquid radioactive waste in the measuring device.

The supply of liquid radioactive waste in portions from the measuring unit to the container with mixing of each portion ensures controlled filling of the container and ensures uniformity of the mixture, which improves the quality of the blocks.

The settling of liquid radioactive waste by increasing pressure and the subsequent removal of excess water make it possible to obtain the necessary ratio of components in the container.

If necessary, liquid radioactive wastes are additionally mixed with gas bubbling while increasing the pressure of this gas to overload a portion of LRW.

A device for implementing the method comprises a container, a measuring device equipped with mixers and level gauges, a container with a mixer installed in it, a cement supply unit with additives, external gas pressure sources connected to the container and measuring device, discharge pipes, one of which connects the container to the measuring device, the second is installed with the possibility of connecting a measuring device with a container for storage or disposal, moreover, the pipes for unloading do not have horizontal sections, and in their upper parts contain an expander, the entrance of the pipes for unloading is I am at the bottom of the tank and the meter, the discharge tube connecting the tank to the meter has a narrowing at the outlet, and the tank is equipped with a nozzle for receiving liquid radioactive waste.

Mernik is also equipped with a drain pipe to remove excess fluid.

The discharge tube connects the meter to the container directly or via a loading device.

Using unloading tubes simplifies the device. The absence of valves and moving parts (such as screws), where mechanical breakdowns are possible, eliminates them.

Liquid radioactive waste is collected in containers, where they are kept in suspension by means of a mixer, and their level is measured. Attach the container to the cement supply unit with additives and a tube for unloading from the measuring unit or to the outlet of the loading device. The required volume of gas is calculated, it is supplied to the tank and a portion of LRW is discharged into the measuring device, squeezing through a tube for unloading. When equalizing the pressure in the tank and the tube expander for discharge, the jet breaks. Since the tube for unloading does not have horizontal sections, the residual waste is not retained in the tube for unloading, but, under the influence of gravity, slides into the container and the measuring device.

Based on the Mendeleev-Klaiperon equation and the condition for termination of LRW unloading, we can write an expression for finding mi for a given volume of extruded LRW:

where p ₁ , p _atm , p _ost - respectively, the initial pressure in the capacity of the external gas source, atmospheric pressure and residual pressure in the gas cavities at the time of termination of the discharge of LRW, Pa;

V _1, V _2, V _vyd - accordingly, the volume of the gas cavity external gas source vessel, LRW container volume dischargeable portions LRW m ^3;

h ₀ - the height of the tube for unloading relative to the level of LRW in the tank before overflow, m;

S is the horizontal sectional area of the tank (LRW mirror area), m ² ;

ρ _W - density transfused LRW, kg / m ³ ;

m ₁ , m ₂ - respectively, the initial mass of gas in the capacity of an external source, capacity with LRW, kg;

R is the universal (molar) gas constant, R = 8.31 J / (mol K);

M is the molar mass of the working gas, kg / mol;

T, T ₍₂₎ - respectively, the average initial temperature in gas cavities before and after discharge of LRW, K.

Assuming that the gas temperature in the tank after unloading changed only slightly (Т ₍₂₎ ≈Т), after finding m ₁ , we find the pressure in the tank of the external gas source p ₁ to which it is raised to ensure the discharge of a portion of LRW

Similarly, calculate the volume of gas by which portions of liquid radioactive waste are discharged from the measuring device.

By setting a different initial pressure p ₁ in the capacity of an external gas source with a volume of V ₁ , it is possible to control the volume of discharged LRW.

They increase the pressure in the meter, defuse LRW, remove excess liquid, measure the level, mix mechanically, and then unload, increasing pressure from an external gas source, through the discharge pipe into a container into which cement with additives is supplied. Loading into a container can be done through a loading device. When the container is full, it is closed and sent for storage.

If necessary, liquid radioactive waste is additionally mixed in a container and measuring device by gas bubbling.

Bubble gas of calculated volume can be used to create pressure and overload LRW.

A device for implementing the method is presented in the drawing, where: 1 - capacity with a stirrer;

2 - level gauge;

3 - pipeline supply LRW into the tank;

4 - external gas source;

5 - measuring device with a stirrer;

6 - level gauge;

7 - a tube for unloading LRW into the meter;

8 - expander;

9 - external gas source;

10 - drain pipe to remove excess fluid;

11 - tube for unloading LRW into the container;

12 - expander;

13 - site supply of cement and additives to the container;

14 - container;

15, 16 - nozzles for supplying bubbling gas to the tank and measuring device, respectively.

The device operates as follows: LRW through the pipeline 3 is fed into the tank 1, where they are mixed using a mixer. The level is measured by a level gauge 2. The calculated volume of air is supplied from an external gas source 4 to the container, liquid radioactive waste is squeezed out through the discharge tube 7 into the meter 5. When pressure is equalized in the tank and expander 8, the jet breaks. Measure the level of waste in the meter by level gauge 6 and, if necessary, remove excess water through the drain pipe 10. Increase the pressure in the meter from an external gas source 9 and liquid radioactive waste through the discharge pipe 11 is sent to the container 14. When the pressure in the meter and expander 12 is equalized, jet break. Cement with additives from the cement supply unit and additives 13 is fed into the container, mixing each portion. If necessary, bubbler gas is supplied to the tank through the pipe 15 and the meter through the pipe 16. LRW can be supplied to the container through the loading device (not shown). When filling the container, it is closed and sent for storage.

Let us determine the necessary amount of gas for squeezing _Vout = 0.15 m ³ LRW from the tank (1.1 m high and 1.6 m in diameter, the horizontal section of the tank (liquid mirror area) S = 2.010624 m ² ), the gas volume in the tank V ₂ = 1.616339 m ³ , the height of the tube for unloading relative to the liquid level in the tank before the overflow h ₀ = 0.6 m, the volume of the gas cavity of the tank of the external gas source V ₁ = 0.099984 m ³ at atmospheric pressure p _ATM, = 10000 Pa, the density of the overflowing fluid ρ _W = 1000 kg / m ³ ; acceleration of gravity g = 9.8 m / s ² .

Substituting the above values into the formulas 1 and 2, we find that for extruding _vyd V = 0.15 m ³ necessary to raise the pressure in the external container ₁ p gas to a value p ₁ = 373427 Pa.

Claims (13)

1. A method of cementing liquid radioactive waste, characterized in that liquid radioactive waste is supplied to the vessel, their level is measured, liquid radioactive waste is mixed into the vessel, the calculated volume of gas is supplied to the vessel from an external source, liquid radioactive waste is discharged into the measuring device through a discharge pipe measure their level in the measuring device, mix the contents of the measuring device, unload liquid radioactive waste from the measuring device, increasing the pressure in it from an external gas source, into the container through the discharge pipe, cement with additives is fed into the container; each portion of the compound in the container is mixed. 2. The method according to claim 1, characterized in that, if necessary, liquid radioactive waste is defended in the measuring unit before unloading. 3. The method according to claim 1, characterized in that, if necessary, remove excess fluid from the measuring device through a drain pipe with a filter. 4. The method according to claim 1, characterized in that, if necessary, remove excess fluid by increasing the pressure in the measuring device. 5. The method according to claim 1, characterized in that, while stirring, additional liquid radioactive waste sparges with gas. 6. The method according to claim 5, characterized in that, if necessary, additionally mix the liquid radioactive waste by bubbling gas, while increasing the pressure of this gas to overload a portion of the liquid radioactive waste. 7. The method according to claim 1 or 5, characterized in that air is used as gas. 8. A device for implementing the method of cementing liquid radioactive waste, containing a container, a measuring device, equipped with mixers and level gauges, a container with a mixer installed in it, a cement supply unit with additives, an external gas pressure source connected to the container and a measuring device, discharge pipes, one tube for unloading connects the tank with the measuring device, the second is installed with the possibility of connecting the measuring device with the container, and the pipes for unloading are equipped with expanders, and the tank is equipped with a pipe for supplying adioaktivnyh waste. 9. The device according to claim 8, characterized in that the tubes for unloading do not have horizontal sections. 10. The device according to claim 8, characterized in that the inlets of the tubes for unloading are at the bottom of the tank and the measuring device. 11. The device according to claim 8, characterized in that the measuring device is equipped with a drain pipe to remove excess fluid. 12. The device according to claim 8, characterized in that the discharge tube connecting the container to the measuring device has a narrowing at the outlet. 13. The device according to claim 8, characterized in that the tank and the measuring device are equipped with nozzles for supplying bubble gas.