RU2286612C1 - Method of reprocessing of the liquid nuclear wastes - Google Patents

Abstract

FIELD: technology of handling of the liquid nuclear wastes of the nuclear fuel and power cycle; methods of reprocessing of the liquid nuclear wastes.

SUBSTANCE: the invention is pertaining to the procedure of the liquid nuclear wastes handling of the nuclear fuel and power cycle and may be used during reprocessing of the liquid nuclear wastes (LNW). The method includes the preliminary concentration, ozonization, microfiltration of the vat residue with fractionation of the permeate and the concentrate and the ion-selective purification of the permeate using the ion-selective a sorbent. At that the microfiltration is conducted at least in two stages: the permeate of each previous stage of the microfiltration is directed to the microfiltration as the source solution for the subsequent stage of the microfiltration, and at the final stage of the permeate from the microfiltration is sent to the utilization. The concentrate produced at each next stage of the microfiltration is mixed with the source solution of the previous stage of the microfiltration. The concentrate produced at the first stage of the microfiltration is directed to the conditioning and dumping. The ion-selective sorbent is added in the permeate of the previous stage of the microfiltration before the final stage of the microfiltration. The invention ensures: reduction of the volume of the liquid nuclear wastes due to the deep purification of the LNW with the high saline share from the radionuclides and extraction of the radionuclides in the compact form of the sparingly soluble compounds at the corresponding increase of the factor of purification of the salts extracted at the stage of the vat residue treatment; reduction and optimization of the consumption of the permeate and concentrate interacting with the source solution as well as produced at the further stages.

EFFECT: the invention ensures: reduction of the volume of the liquid nuclear wastes; the deep purification of the LNW with the high saline share from the radionuclides and extraction of the radionuclides in the compact form of the sparingly soluble compounds at the corresponding increase of the factor of purification of the salts extracted at the stage of the vat resudue treatment; reduction and optimization of the consumption of the permeate and concentrate interacting with the source solution ands produced at the further stages.

Description

The invention relates to a technology for the management of liquid radioactive waste of the nuclear fuel and energy cycle and can be used in the process of processing liquid radioactive waste (LRW) to minimize their volume and remove radionuclides with their concentration in the solid phase and / or release of radionuclides in the form of sparingly soluble compounds , the processing of which by existing methods ensures reliable localization of radioactive substances from the environment.

The processing of liquid radioactive waste is aimed at solving two main problems: cleaning the bulk of the waste from radionuclides and concentrating the latter in a minimal amount.

The solution is known according to patent RU 2066493, IPC G 21 F 9/08, 11/13/1995, "METHOD FOR PROCESSING LIQUID RADIOACTIVE WASTE OF NPPs".

- the method includes their preliminary evaporation to obtain condensate and bottoms, ozonation of bottoms, separation of the resulting radioactive sludge and concentration of the filtrate by deep evaporation. In this case, the ozonation of the bottom residue is carried out immediately after preliminary evaporation at a solution pH of from 12 to 13.5. After separation of the radioactive sludge, the filtrate is passed through a filter container with a cesium selective inorganic sorbent, then the spent filter container is sent for storage or disposal.

The technical solution according to the patent RU 2226726, IPC G 21 F 9/08, G 21 F 9/12, 04/27/2002 is also known. "METHOD FOR PROCESSING LIQUID RADIOACTIVE WASTE OF A NUCLEAR POWER PLANT"

- the method includes their preliminary evaporation to obtain condensate and bottoms, ozonation of bottoms, separation of the resulting radioactive sludge and concentration of the filtrate by deep evaporation. In this case, the ozonation of the bottom residue is carried out immediately after preliminary evaporation of the solution. After separation of the radioactive sludge, the filtrate is passed through a filter container with a cesium selective inorganic sorbent, then the spent filter container is sent for storage or disposal.

The disadvantages of this method include the low coefficient of purification of salts released at the stage of processing the bottom residue, a significant and irrational flow rate interacting with the initial solution, as well as with the further obtained permeate and concentrate reagents.

The objective of the invention is the reduction of the volume of radioactive waste due to the deep purification of LRW with high salinity from radionuclides and the isolation of the latter in a compact form of insoluble compounds, with a corresponding increase in the coefficient of purification of salts released at the stage of processing the bottom residue, reduction and optimization of the flow rate interacting with the initial solution, and also with the further obtained permeate and reagent concentrate. This problem is solved using the necessary and sufficient combination of essential features, namely:

a method for processing liquid radioactive waste, including pre-concentration to obtain condensate and bottoms, ozonation, microfiltration of bottoms with separation of permeate and concentrate fractions and ion-selective purification of permeate with ion-selective sorbent, and microfiltration is carried out at least in two stages,

the permeate of each previous microfiltration stage is sent to microfiltration as a starting solution for the subsequent microfiltration stage, and at the final stage of microfiltration, the permeate from microfiltration is sent for disposal,

the concentrate obtained at each subsequent microfiltration stage is mixed with the initial solution for the previous microfiltration stage, and the concentrate obtained at the first microfiltration stage is sent for conditioning and disposal, the ion-selective sorbent is added to the permeate of the previous microfiltration stage before the final microfiltration stage.

The practical implementation of the claimed method for processing liquid radioactive waste (LRW) consists in pre-concentration of LRW with condensate and bottoms, ozonation, microfiltration on membrane filters of stage-by-stage bottoms with separation of permeate and concentrate into fractions, as well as ion-selective purification of permeate by ion-selective sorbent .

When carrying out the indicated technological operations, it is optimal to carry out microfiltration in at least two stages, the permeate of each previous microfiltration stage is then sent to microfiltration as the initial solution for the subsequent microfiltration stage, and at the final microfiltration stage, the permeate from microfiltration is sent for recycling.

The concentrate obtained at each subsequent microfiltration stage is mixed with the initial solution for the previous microfiltration stage, and the concentrate obtained at the first microfiltration stage is sent for conditioning and disposal, the ion-selective sorbent is added to the permeate of the previous microfiltration stage before the final microfiltration stage.

The indicated sequence and content of technological methods make it possible to solve the technical problem and contribute to the reduction of the volume of radioactive waste due to the deep purification of LRW with high salinity from radionuclides, the release of the latter in a compact form of insoluble compounds, with a corresponding increase in the coefficient of purification of salts released at the stage of processing the bottom residue also reduces and optimizes the flow rate interacting with the initial solution, as well as obtained with further reagents permeate and concentrate.

Examples of the method for using, for example, three stages of purification.

1. The activity of the initial liquid radioactive waste (LRW) for Cs is 2.1 × 10 ⁵ Bq / liter. When starting up the installation, an ion-selective sorbent at a rate of 2 g / liter is introduced already at the first stage of purification, while the activity of the permeate of the first stage is reduced to a value of 6 × 10 ² Bq / liter. In the second stage, a fresh sorbent is also introduced at a rate of 2 g / liter, while the activity of the second stage permeate decreases to 11 Bq / liter, which is lower than the standard value in accordance with current legislation, and it is sent for conditioning, for example, evaporation to dry salts, and storage as chemical waste. The concentrate of the second stage of microfiltration (approximately 10% of the initial volume) is mixed with the initial LRW and microfiltration is carried out. The permeate activity of the first stage is 6 × 10 ² Bq / liter. The concentrate is sent for conditioning (e.g. cementing) and disposal. Fresh sorbent is introduced into the permeate and microfiltration is carried out. The activity of the permeate of the second stage is 11 Bq / liter, then the process is repeated.

2. The activity of the initial LRW for Cs is 2.1 × 10 ⁷ Bq / liter. When the installation is started, an ion-selective sorbent at a rate of 2 g / liter is introduced already at the first stage of purification, while the permeate activity of the first stage is reduced to a value of 3 × 10 ⁴ Bq / liter. In the second stage, a fresh sorbent is also introduced at a rate of 2 g / liter, while the activity of the permeate of the second stage is reduced to 2 × 10 ² Bq / liter. With the introduction of fresh sorbent into the permeate of the second stage of microfiltration, the activity of the permeate of the third stage decreases to 9 Bq / liter. Concentrates of the first and second stages of microfiltration are sent for conditioning and disposal, the concentrate of the third stage is mixed with the initial LRW and sent to the first stage of microfiltration. The activity of the permeate of the first stage is reduced to a value of 3 × 10 ⁴ Bq / liter. To continue the start-up procedure, a fresh sorbent is added to the second stage permeate, while the activity of the second stage permeate is 2 × 10 ² Bq / liter. The concentrate of the second stage is mixed with the initial solution and sent to the first stage of microfiltration. Fresh sorbent is added to the permeate of the second stage of microfiltration and sent to the third stage of microfiltration. The activity of the permeate of the third stage is 9 Bq / liter. The concentrate of the third stage of microfiltration (approximately 10% of the volume) is mixed with the permeate of the first stage and sent to the second stage of microfiltration. The activity of the permeate of the second stage is 2x10 ² Bq / liter. The concentrate of the second stage of microfiltration is mixed with the original LRW, fresh sorbent is added to the permeate and sent to the third stage of microfiltration. The activity of the permeate of the third stage is 9 Bq / liter, and it is sent for conditioning and disposal as chemical waste, the concentrate of the third stage of microfiltration is mixed with permeate of the first stage of microfiltration.

Further, the cleaning process is repeated, but fresh sorbent is introduced only in the permeate of the second stage of microfiltration.

In the examples, the indicated expenditure data on the sorbent have a rather wide range of possibilities, however, with subsequent study to solve particular problems, it is possible to specify the values mentioned.

Claims (1)

A method of processing liquid radioactive waste, including pre-concentration to obtain condensate and bottoms, ozonation, microfiltration of bottoms with separation of permeate and concentrate fractions and ion-selective purification of permeate by ion-selective sorbent, characterized in that microfiltration is carried out in at least two stages , permeate of each previous microfiltration stage is sent to microfiltration as a starting solution for the subsequent microfiltration stage, and of the microfiltration stage, microfiltration permeate is sent for disposal, the concentrate obtained at each subsequent microfiltration stage is mixed with the initial solution for the previous microfiltration stage, and the concentrate obtained at the first microfiltration stage is sent for conditioning and disposal, the ion-selective sorbent is added to the permeate of the previous stage microfiltration before the final stage of microfiltration.