JP3009828B2 - High volume solidification method for high level radioactive liquid waste - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a highly reduced volume of high-level radioactive liquid waste (hereinafter abbreviated as "high-level liquid waste") generated in the process of reprocessing spent nuclear fuel by vitrification or the like. The present invention relates to a solidification treatment method capable of forming a solidified solid.

[0002]

2. Description of the Related Art Spent nuclear fuel generated from a nuclear power plant or the like contains fissile materials such as plutonium and uranium. In order to reuse them, spent nuclear fuel is reprocessed to separate and recover plutonium and uranium, and in this process, a high-level waste liquid as a nitric acid aqueous solution containing fission products and the like is generated. This high-level liquid waste has a high calorific value (decay heat) and radioactivity level due to radioactive material decay, and has a long radioactive material life. Need to be isolated from living area. At present, high-level waste liquid is stored in the form of an aqueous solution, but a part thereof is stored in the form of a more stable solidified material such as glass. By storing such solids such as high-level liquid waste for several decades for cooling, and then disposing them in a deep formation several hundred meters below the ground,
It can be safely isolated from human spheres for a long time.

[0003] Generally, glass has a property of changing its properties by crystallization when kept at a high temperature for a long period of time. Therefore, during storage, the vitrified body is air-cooled so as not to exceed a control target temperature. The cooling capacity depends on the cooling method such as forced air cooling or natural air cooling of the storage facility, or the design of the cooling capacity of the storage facility. Therefore, it is necessary to limit the upper limit of the waste content in the vitrified body so that the maximum temperature of the vitrified body does not exceed the target control temperature according to the cooling capacity. The maximum temperature control target value of the vitrified body currently manufactured is 6
There is an example of about 00 ° C.

[0004] After storage as described above, the vitrified waste is further disposed of in the formation, but thermal effects on the disposal site such as thermal stress, thermal convection of groundwater flow, and alteration of surrounding materials are minimized. In order to limit the density, it is necessary to limit the density of the vitrified waste at the disposal site (books / m ² ) to a certain value or less.

[0005]

Much of the radioactivity and calorific value of high level effluents is due to the radioactive isotopes of fission products cesium (Cs) and strontium (Sr) and their daughter nuclides. For example, burnup 4
Taking as an example the high-level effluents generated by reprocessing of spent nuclear fuel at 5,000 MWd / tU and having passed 4 years after removal from the reactor, Cs and Sr and Ba in their radiation equilibrium The ratio of the calorific value of Y and Y to the total calorific value is about 65%. This ratio approaches 90% 30 years after the removal from the reactor.

Therefore, if Cs and Sr are preliminarily separated and removed from the high-level waste liquid to solidify the high-level waste liquid containing no Cs and Sr, the calorific value of the solidified body can be reduced. Therefore, the amount of waste can be reduced, and the volume can be reduced.

[0007] As a technique for separating Cs and Sr from a high-level waste liquid, solvent extraction,
A method has been considered in which each nuclide is separated into three or four groups by combining an ion exchange method and a precipitation method. However, the main purpose of this method is to separate and recover useful elements such as platinum group elements. Cs and Sr are separated by being adsorbed on an inorganic ion exchanger at a time, and Cs and Sr from high-level waste liquid are separated. It cannot be said that this method is necessarily an efficient separation method from the viewpoint of separation and removal.

Therefore, an object of the present invention is to increase the content of waste in the solidified body by efficiently separating and removing exothermic elements Cs and Sr from the high-level waste liquid in advance and then performing solidification treatment. To provide a high-volume solidification treatment method for high-level waste liquid, which can reduce the amount of waste generated to achieve high volume reduction, and as a result, can reduce the size of the solidified material storage facility and disposal site. It is.

[0009]

That is, according to the present invention, there is provided a method for solidifying a high-level waste liquid with a high volume reduction by adding formic acid to a high-level radioactive waste liquid as an aqueous nitric acid solution to adjust the pH to a neutral range of 6 to 8. In this way, elements other than Cs and Sr in the high-level radioactive waste liquid are substantially precipitated and removed, and Cs and Sr are removed.
a denitration step of obtaining a denitration waste liquid containing a high concentration of r, by passing the denitration waste liquid obtained in the denitration step through a first column filled with an adsorbent for selectively adsorbing Cs, The step of adsorbing and separating Cs, the Sr in the denitration waste liquid is passed through a second column filled with an adsorbent that selectively adsorbs Sr, by passing the denitration waste liquid from which Cs removed from the first column is removed. A step of performing adsorption separation, and a step of removing Cs and Sr from the second column by removing Cs and Sr from the denitrification waste liquid,
And a step of solidifying together with a precipitate of an element other than Sr.

The order of the step of adsorbing and separating Cs by the first column and the step of adsorbing and separating Sr by the second column can be reversed. Further, the denitrification waste liquid obtained in the denitration step is passed through a column filled with a mixed adsorbent in which an adsorbent that selectively adsorbs Cs and an adsorbent that selectively adsorbs Sr are mixed, so that Cs and Sr Can be collectively adsorbed and separated, and the step of adsorbing and separating Cs and Sr can also be simplified.

Hereinafter, the present invention will be described in detail with reference to a preferred embodiment of the present invention shown in FIG. The high-level waste liquid which is a nitric acid aqueous solution to be treated in the present invention is an extraction waste liquid discharged from a co-decontamination cycle in which uranium and plutonium are separated from fission products by solvent extraction from a nitric acid solution of spent nuclear fuel. , Extraction residues, fission products, actinoids, alkali salts, corrosion products and the like. The nitric acid concentration of such a high level waste liquid is usually about 2.
It is about 5N, and always shows 0 in the pH value actually measured by the pH meter.

In the present invention, in order to separate and remove radioactive isotopes of exothermic elements Cs and Sr contained in the high-level waste liquid, formic acid is first added to the high-level waste liquid to adjust the pH of the waste liquid to 6-8. Neutral region, preferably pH 7
Perform a denitration process to adjust back and forth. By setting such a neutral region, most of Cs and Sr in the high-level waste liquid can be left in the liquid, and other radionuclides, particularly, most of lanthanoids and actinoids can be coprecipitated and separated.

The amount of formic acid to be added may be an amount necessary for the pH of the high-level waste liquid to reach the above-mentioned predetermined pH.
The molar ratio of the general guideline and nitric acid in a high level liquid waste and formic acid _{([HCOOH] / [HNO 3} ]) of about 1.9
It should be about 2.1.

In carrying out the denitration step, formic acid is added while heating to about 90 to 95 ° C. lower than the boiling temperature of the high-level waste liquid to adjust the pH of the high-level waste liquid to a neutral range, and then the temperature is raised to room temperature. The cooling is allowed to stand for about 15 hours to complete the denitration reaction. The precipitate is separated and removed by filtering the high-level waste liquid after the denitration to obtain a denitration waste liquid as a filtrate.

The denitrification waste liquid is analyzed and the residual ratio of the elements in the high-level waste liquid to the denitrification waste liquid ([element concentration in the denitration waste liquid] /
As a result of examining [element concentration in high-level waste liquid before denitration], for example, about 70% for ¹³⁷ Cs and about 80% for ⁸⁵ Sr
Where Y and Ce, Pr, Nd, Sm,
Lanthanoid elements such as Eu, U, ²³⁷ Np, ²³⁸ Pu,
^{2 41} Am, ²⁴⁴ Cm actinide elements, such as, verify that Tc and Ru, platinum group elements such as Pd, Fe, Zr, the elements such as Mo almost a few percent 0 is present in the precipitate did. The high-level effluent also contains Na, an alkali metal element homologous to Cs, and Ba, an alkaline earth metal element homologous to Sr.
Most of them, like s and Sr, remain in the denitration waste liquid.

The denitrification waste liquid containing Cs and Sr obtained in the denitration step is then passed through a Cs adsorption column filled with an adsorbent for selectively adsorbing Cs, whereby Cs in the denitration waste liquid is selected as an adsorbent. It is adsorbed and separated and removed. As the Cs adsorbent, ferrierite, which is a kind of commercially available synthetic zeolite, can be preferably used. In addition, mordenite, clinoptilolite, chabazite, etc., which are zeolites having high selectivity for Cs, may be used. Can be. Further, an inorganic ion exchanger such as zirconium phosphate having high selectivity for Cs can be used.

In order to elute and recover the Cs adsorbed on the adsorbent, distilled water is passed through the adsorbent column after passing the denitrification waste liquid to wash it, and then NH ₄ Cl or NH ₄ NO ₃ or the like is washed. By flowing an eluent comprising an aqueous solution of ammonium salt, Cs can be eluted and recovered from the adsorbent. If NH ₄ Cl, which easily sublimates, is used as the eluent, it can be recycled and reused.

The denitrification waste liquid from which Cs is adsorbed and removed from the Cs adsorption column is then passed through an Sr adsorption column filled with an adsorbent for selectively adsorbing Sr, so that Sr in the denitration waste liquid is selected as an adsorbent. It is adsorbed and separated and removed. As the Sr adsorbent, A-type zeolite, which is a kind of commercially available synthetic zeolite, can be preferably used. In addition, X-type zeolite having high selectivity for Sr, hydrous titanium oxide, and the like can also be used.

In order to elute and recover the Sr adsorbed on the adsorbent, distilled water is passed through the adsorbent column after passing the denitration waste liquid to wash it, and then EDTA, CyDTA, and Methy.
Sr can be eluted from the adsorbent and recovered by flowing an eluent composed of a chelating reagent having a large stability constant of a chelate complex with Sr such as l-EDTA.

The Cs adsorption column and Sr illustrated in FIG.
In each of the adsorption columns, two columns are arranged in parallel,
It is possible to select which column to pass the denitration waste liquid or which column to pass the eluent by switching the valve. With such a configuration, while the adsorption operation is performed in one column, the elution operation is performed in the other column, and if the elution operation is performed alternately, a continuous operation can be performed.

In the example shown in FIG. 1, the effluent is first passed through the Cs adsorption column, and then the effluent is passed through the Sr adsorption column.
The effluent can be passed through an adsorption column and the effluent can be passed through a Cs flow-through column.

Further, in order to simplify the adsorption / separation step using a column, a column filled with a mixture of a Cs adsorbent and a Sr adsorbent is used to collectively adsorb both Cs and Sr. Can be removed. In this case, in order to collectively elute and recover the adsorbed Cs and Sr, a mixed eluent of a Cs eluent and a Sr eluent may be used.

In FIG. 1, the denitration waste liquid from which Cs and Sr flowing out of the Sr adsorption column have been adsorbed and removed is subjected to vitrification, cement solidification, asphalt solidification or ceramic solidification by a conventionally known method. Solidified. Of these, vitrification treatment can be preferably employed from the viewpoint of safety and economy. The denitrification waste liquid to be solidified is exothermic elements Cs and Sr
Since most of the solids have been removed, it is possible to increase the waste content in the solidified body, and as a result, it is possible to achieve a higher volume reduction as compared with a conventional solidified body in which the waste content is limited.

The Cs and Sr eluted and recovered from the Cs adsorbent and the Sr adsorbent can be subjected to a solidification treatment as required and stored as a solid, or can be effectively used as a radiation source or a heat source. . At the time of this solidification treatment, Na contained in the denitration waste liquid obtained in the denitration step together with Cs and Sr is not adsorbed by the Cs adsorption column and the Sr adsorption column. , The volume of the solidified body can be reduced, and as a result, volume reduction solidification can be performed.

[0025]

EXAMPLES The method of the present invention will be described in more detail with reference to the following examples. Simulated high-level waste liquid with a nitric acid concentration of 2.5N was used as the high-level waste liquid to be treated in the denitration process , and this was a radioisotope
¹³⁷ Cs 2.14 g / l, ⁸⁵ Sr 7.69 × 10
⁻¹ g / l and ¹⁵² Eu were added at 1.21 × 10 ⁻¹ g / l.

While heating this high-level waste liquid to 95 ° C., formic acid was added at a constant addition rate of 0.4 ml / min. To adjust the pH to 7.03. At this time, the amount of formic acid added was determined by the molar ratio to the nitric acid in the waste liquid ([HCOOH] /
[HNO ₃ ]) to 1.95. After heating was continued for 6 hours, the mixture was cooled at room temperature for 15 hours to complete the denitration reaction. The precipitate generated by this denitration reaction was filtered using a 0.025 μm Millipore filter, and the radioisotope in the filtrate (denitrification waste liquid) was analyzed by radioactivity analysis (count measurement by pure Ge MCA). Table 1 shows the results.

[0027]

Elements other than radioisotopes were analyzed by emission spectroscopy. As a result, Na, which is an alkali metal element homologous to Cs, and Ba, which is an alkaline earth metal element homologous to Sr, were similar to Cs and Sr. Most were present in the denitration wastewater, but the abundance of other elements in the denitration wastewater was 0 to several percent
Met.

Cs adsorption / elution step The denitrification waste liquid 99 cm ³ obtained in the denitration step is used as ferrite (0.26Na ₂ O · 0.74K ₂ O · A) as a Cs adsorbent.
1 ₂ O ₃ 1 12.3 SiO ₂ 6.5 6.5 H ₂ O, cation exchange capacity 1.63 meq / g, particle size 48-65 mesh) 3 g of Cs adsorption column packed at a flow rate of 0.45 cm ³ / min. Cs is adsorbed on the column, and then distilled water 3
After washing by passing through 6 cm ³ , 5M NH ₄ eluent was used.
Cs adsorbed on the adsorbent was eluted and recovered by passing Cl through. FIG. 2 shows the results of the continuous test of adsorption-washing-elution.
As can be seen from the graph of FIG.
cm ³ until the leakage rate C / C ₀ of Cs ([Cs in the effluent
[Count] / [count of Cs in first simulated waste liquid]) is 0.05 or less, and up to this point, Cs is completely adsorbed on the adsorbent. On the other hand, Sr began to flow out immediately after the passage of the denitrification waste liquid, and the amount of Sr adsorbed was as extremely small as 0.005 mmol per 1 g of the adsorbent.

After passing the denitrification waste liquid and subsequently washing with distilled water, the eluate is passed after the radioactivity of the effluent from the column reaches the background level.
Eluted immediately. The maximum of the elution peak is the retention volume V _R =
It was observed at around 12.5 cm ³ , and the final elution rate was 9
9.7%. The amount of Cs that could be eluted and recovered was 1 g of adsorbent
0.33 mmol / m. Here retention volume V _R
Is a _{V R = V m + ρV a} K d ( where, [rho is the density of the adsorbent packed into the column, the V _m air gap total volume, the V _a sorbent volume of net, the K _d represents the distribution coefficient ).

Sr Adsorption / Elution Step The effluent fraction before the breakthrough of Cs was started in the Cs adsorption operation was collected, and this was used as a denitration waste liquid from which Cs had been removed and supplied to the Sr adsorption column. A type zeolite (Na) is used as the Sr adsorbent in the Sr adsorption column.
_{2 O · Al 2 O 3 ·} 2SiO 2 · 4.5 H 2 O, cation exchange capacity 5.52 meq / g, was charged particle size 48-65 mesh) 3 g. The denitrification waste liquid from which Cs has been removed is passed through a Sr adsorption column, and then distilled water is passed through the column for washing. After that, 0.05M EDTA as an eluent is passed through the column to remove the Sr adsorbed on the adsorbent. Was eluted and recovered. FIG. 3 shows the results of the continuous adsorption-wash-elution test. As can be seen from the graph of FIG. 3, no breakthrough of Sr was observed at all until the liquid flow rate reached 81 cm ³ , and all were adsorbed to the Sr adsorbent.

After passing the denitration waste liquid from which Cs has been removed,
After washing with distilled water, the radioactivity of the effluent from the column reached the background level. Then, when the eluent was passed, Sr was eluted immediately. The maximum of the elution peak is V
_R was found around 18.0 cm ³ , and the final elution rate was 97.4%. The amount of Sr that could be eluted and recovered was Adsorbent 1
It was 0.19 mmol per g.

Solidification treatment step The denitrification waste liquid obtained by separating and removing Cs and Sr from the Sr adsorption column in the Sr adsorption / elution step and the precipitate filtered in the denitration step are heated at a high temperature of about 1125 ° C. The molten glass material was poured and mixed. The mixing ratio at this time was such that the waste component (as oxide) in the vitrified product to be produced was 45% by weight, and the glass raw material component (as oxide) was 55% by weight. The denitrification waste liquid and the water in the precipitate evaporate by being injected into the glass material heated to a high temperature.

After the injection, the mixture is kept at a high temperature for several hours and then solidified by cooling at room temperature to obtain a high-volume vitrified product. The conventional vitrified material has a waste content of about 25% by weight, but the vitrified material obtained above can increase the waste content rate to 45% by weight, and as a result, is about twice as high. Volume reduction can be achieved.

[0035]

As described above, according to the method of the present invention, Cs and Sr occupying a large part of the calorific value from the high level waste liquid.
Is separated in advance, and a solidification treatment such as vitrification is performed with a high-level waste liquid not containing Cs and Sr as a residue, so that the calorific value of the solidified body can be reduced. Therefore, even if the content of the waste in the solidified product is increased, the temperature of the solidified product during storage can be suppressed from being higher than the upper limit for preventing crystallization. Further, by increasing the waste content of the solidified body, the amount of the solidified body formed without separating Cs and Sr can be reduced, and the volume of the solidified body can be reduced.

Further, when the solidified body is disposed in a deep geological formation, the calorific value per solidified body can be reduced, so that the interval between individual solidified bodies can be narrowed, and the density of the solidified body in the disposal site can be increased. As a result, the disposal site can be made smaller. Considering that the amount of the solidified body can be reduced by increasing the content of the waste in the solidified body, the size of the disposal site can be further reduced.

On the other hand, Cs and Sr eluted and recovered from the adsorbent
The half-life of radioactive isotopes, such as ¹³⁷ Cs and ⁹⁰ Sr, is about 30 years, and the half-life of long-lived nuclides such as other actinoid elements contained in high-level effluents (for example, ²³⁹ Pu is 2
(4,100 years), Cs and Sr separated and recovered from a high-level waste liquid are stored for a required period of time, so that the radioactivity level is reduced and low-level waste can be obtained. Since it is not necessary to dispose of low-level waste in deep geological formations, disposal costs are high and costs can be reduced. Alternatively, the separated and recovered Cs and Sr can be effectively used as a radiation source or a heat source as needed.

In the denitration step in the method of the present invention, most of the Cs and Sr contained in the high-level waste liquid remain in the denitrification waste liquid, while the other elements precipitate, so that the precipitate is removed by filtration. Then, Cs and Sr can be separated from other elements. That is, Cs and Sr can be separated and removed from the high-level waste liquid only by performing the denitration step, and the denitration waste liquid containing Cs and Sr may be solidified and stored as it is. However, the high-level waste liquid contains non-radioactive Na added in the reprocessing step of spent nuclear fuel (up to 30 kg of Na ₂ O is added to the reprocessing amount of 1 tU of spent nuclear fuel). This Na remains in the denitration waste liquid together with Cs and Sr in the denitration step. For this reason, when the denitration waste liquid containing Cs and Sr is directly solidified, Na coexisting with Cs and Sr in the denitration waste liquid must also be solidified, and Cs and Sr containing no Na are solidified. , The volume of the solidified body increases. In contrast, according to the present invention,
C in adsorption waste water by Cs adsorption column and Sr adsorption column
Since s and Sr are selectively adsorbed and separated for recovery, the recovered Cs and Sr do not contain Na. Therefore, N
When solidifying the recovered Cs and Sr containing no a,
The volume of the solidified body can be reduced, and the volume can be reduced.

[Brief description of the drawings]

FIG. 1 is a flow sheet showing a preferred embodiment of the present invention.

FIG. 2 is a graph showing the results of a continuous test of adsorption-separation-elution recovery of Cs in a denitration waste liquid according to the present invention.

FIG. 3 is a graph showing the results of a continuous test of adsorption-separation-elution recovery of Sr in a denitration waste liquid according to the present invention.

────────────────────────────────────────────────── ─── Continued on the front page (51) Int.Cl. ⁷ Identification code FI G21F 9/16 541 G21F 9/16 541B (72) Inventor Kenichi Akiba 2-1-1 Katahira, Aoba-ku, Sendai, Miyagi Tohoku University Inside the Materials Engineering Laboratory (72) Inventor Hitoshi Mimura 2-1-1 Katahira, Aoba-ku, Sendai City, Miyagi Prefecture Inside the Materials Engineering Laboratory, Tohoku University (56) References JP-A-62-176913 (JP, A) Japanese Patent Publication No. 47 -24800 (JP, B1) (58) Fields investigated (Int. Cl. ⁷ , DB name) G21F 9/06 G21F 9/10 G21F 9/12

Claims (7)

(57) [Claims] 1. An element other than Cs and Sr in a high-level radioactive waste liquid is substantially precipitated and removed by adding formic acid to a high-level radioactive waste liquid as an aqueous nitric acid solution to adjust the pH to a neutral range of 6 to 8. A denitration step of obtaining a denitration waste liquid containing a high concentration of Cs and Sr by passing the denitration waste liquid obtained in the denitration step through a first column filled with an adsorbent for selectively adsorbing Cs. A step of adsorbing and separating Cs in the denitrification waste liquid, and a step of passing the denitration waste liquid from which the Cs flowing out of the first column is removed through a second column filled with an adsorbent for selectively adsorbing Sr, A step of adsorbing and separating Sr in the denitrification waste liquid from which Cs and Sr flowing out from the second column have been removed together with a precipitate of elements other than Cs and Sr precipitated and removed in the denitration step. High-level high compaction solidification method for treating a radioactive liquid waste, comprising the steps of. 2. The addition of formic acid to a high-level radioactive waste liquid, which is an aqueous solution of nitric acid, to adjust the pH to a neutral range of 6 to 8, thereby substantially precipitating and removing elements other than Cs and Sr in the high-level radioactive waste liquid. A denitration step of obtaining a denitration waste liquid containing a high concentration of Cs and Sr by passing the denitration waste liquid obtained in the denitration step through a first column filled with an adsorbent for selectively adsorbing Sr, A step of adsorbing and separating Sr in the denitrification waste liquid, and a step of passing the denitrification waste liquid from which the Sr flowing out of the first column is removed through a second column filled with an adsorbent for selectively adsorbing Cs. A step of adsorbing and separating Cs from the inside, and the denitration waste liquid from which the Sr and Cs flowing out of the second column have been removed is solidified together with the precipitates of elements other than Cs and Sr that have been precipitated and removed in the denitration step High-level high compaction solidification method for treating a radioactive liquid waste, comprising the steps of sense. 3. A step of eluting and recovering Cs by passing an eluent of Cs through the column containing an adsorbent adsorbing Cs, and eluting Sr into the column containing an adsorbent adsorbing Sr. 3. The method according to claim 1, further comprising a step of eluting and recovering Sr by passing the solution. 4. The method according to claim 3, further comprising the step of solidifying the eluted and recovered Cs and Sr. 5. An element other than Cs and Sr in the high-level radioactive waste liquid is substantially precipitated and removed by adding formic acid to the high-level radioactive waste liquid as an aqueous nitric acid solution to adjust the pH to a neutral range of 6 to 8. A denitration step of obtaining a denitration waste liquid containing a high concentration of Cs and Sr by mixing the denitration waste liquid obtained in the denitration step with an adsorbent for selectively adsorbing Cs and an adsorbent for selectively adsorbing Sr Through a column packed with Cs.
And Sr collectively adsorbing and separating, and a step of solidifying the denitration waste liquid from which Cs and Sr flowing out from the column have been removed together with the precipitates of elements other than Cs and Sr precipitated and removed in the denitration step. A high-volume solidification treatment method for high-level radioactive liquid waste. 6. The method further comprises the step of passing a mixture of an eluent of Cs and an eluent of Sr through the column containing an adsorbent adsorbing Cs and Sr to collectively elute and recover Cs and Sr. The method of claim 5. 7. The method according to claim 6, further comprising a step of solidifying the eluted and recovered Cs and Sr.