EP0261255B1 - Process for working up an aqueous phosphoric-acid solution - Google Patents

Description

The invention relates to a method for preparing a aqueous phosphoric acid solution which is used up in the course of chemical and / or electrochemical decontamination of parts of the system which are radioactively contaminated on its surface and is thereby substantially saturated with iron, with evaporation and the solids formed being conditioned for final storage. - Chemical decontamination means pickling in particular.

Phosphoric acid electrolyte baths have been used for electrochemical decontamination for several years. After prolonged use, the iron content and activity in the electrolyte solution increase. With iron concentrations of over 100 g Fe / I, the use of the electrolyte becomes uneconomical because the decontamination does not succeed or the time and personnel expenditure is extremely high. That is why these electrolytes are discarded. Since they are radioactively contaminated, they must be disposed of and conditioned. The following two variants can be considered:

First, the electrolyte containing approx. 30-40% phosphoric acid is diluted 50-fold with water. This is necessary in order to avoid precipitation of the NaεPO4 · 12 H20 during the subsequent neutralization with sodium hydroxide solution. In a second step, a pH of 7 is adjusted with vigorous stirring with NaOH. During the neutralization, the previously dissolved iron phosphate precipitates out as a precipitate that can be decanted off. The iron phosphate precipitation binds most of the radioactivity, so that the excess sodium phosphate solution is below the official exemption limit for radioactive waste water. The water can also be subjected to a precipitation / flocculation process. This method is advantageous because only about 1000 kg of iron phosphate remain for conditioning per 3000 l of electrolyte bath. It is disadvantageous that the radioactive waste water from a 3000 l electrolyte bath contains approx. 1800 kg NasP04, that is approx. 1500 kg PO ---. For reasons of environmental protection, this procedure is therefore only possible in special cases.

The usual technique today is evaporation of the electrolyte solution. The acid must be neutralized (pH 10) in order to protect the evaporator and to maintain a solid product that can be stored for final storage. NaεPO ₄ · 12 H ₂ 0 and iron phosphate form as a mixture. About 1000 kg of iron phosphate and 5200 kg of sodium orthophosphate with 12 H ₂ O are formed per 3000 I batch of electrolyte bath, which are conditioned. The high volume of waste is to be emphasized in this process, because both the sodium orthophosphate and the iron phosphate must be disposed of as radioactive waste.

The aim of the procedure described below is the decontamination of dismantled parts of the system that are radioactive contaminated, while at the same time minimizing the amount of radioactive waste. Electrochemical decontamination is the most economical method of decontamination of large-area parts, whereas pickling in an acid bath is preferred for smaller parts and those with complicated geometries. The suitability of a decontamination process depends on the fulfillment of several prerequisites: firstly, the radioactive contamination should be removed as completely as possible, but only as little inactive material as possible removed; Furthermore, a minimal amount of secondary wastes and a minimal release of radioactive substances via water and air are desirable, and finally the operating personnel dealing with the decontamination should be exposed to the lowest possible radiation exposure. Processing the contaminated workpieces by pickling or electrochemical decontamination not only leads to a constant increase in activity in the acid baths, but also, due to the increase in the concentration of iron, to a gradual exhaustion of the baths. The direct disposal of these iron-contaminated baths would contradict the requirement to minimize secondary waste; on the other hand, regeneration of the baths with the aim of reducing the iron content enables the operation to continue, which corresponds to the above requirement.

The invention has for its object to perform the method according to the preamble of claim 1 so that only relatively small amounts of radioactive waste have to be disposed of.

The solution to this problem according to the invention is that the spent phosphoric acid solution is combined with an aqueous oxalic acid solution, that the iron oxalate formed is separated off and conditioned after pyrolysis, and that the remaining phosphorus solution for reuse to a phosphoric acid content of 15 to 65% by weight. % is evaporated.

The invention is based on the consideration already indicated above that a minimization of the radioactive waste is only possible if the used phosphoric acid solution is processed in such a way that it is subsequently reusable and only the iron extracted from the solution is sent to the final storage.

There are several possibilities for the further configuration within the scope of the invention. This leads to a particularly high iron removal or purity of the phosphoric acid solution if the spent phosphoric acid solution is subjected to a reduction treatment before being combined with the oxalic acid solution until at least 80% of the iron is in divalent form. According to a preferred embodiment, the reduction treatment is carried out electrochemically in a stainless steel trough connected as a cathode with an immersed graphite anode surrounded by a diaphragm. The reduction can also be brought about by using spent phosphoric acid solution as a decontamination solution (pickling) for a few days without electricity; this procedure is preferably used when many small parts have to be treated. Optimal precipitation conditions for the iron oxalate result if the ver needed phosphoric acid solution is entered in a template of the cold oxalic acid solution. In addition, it is advisable to work in this connection with an oxalic acid solution which has an oxalic acid content of 5 to 15% by weight, in particular 10% by weight. The iron oxalate formed is expediently separated off by sedimentation and / or filtration. Furthermore, for reasons of energy saving, it is advisable to let the separated iron oxalate dry before pyrolysis. In any case, the remaining phosphoric acid solution is best evaporated to a phosphoric acid content of about 40% by weight, because this phosphoric acid content enables both purely chemical decontamination (pickling) and electrochemical decontamination. Finally, for cost reasons, it is also advisable to condense the evaporated water and use it to prepare fresh oxalic acid solution.

The method according to the invention is described in more detail below: one begins with the selection of dismantled components for the subsequent decontamination process; it may be necessary to disassemble larger parts into workable pieces beforehand. The chemical decontamination takes place either by pickling in an acid bath (approx. 40% phosphoric acid, approx. 60 _° C) or by electrochemical decontamination, because the workpiece connected as anode is also immersed in approx. 40% phosphoric acid; under the influence of a voltage of approximately 15 V, a current of approximately 1000 to several 1000 A flows between a stainless steel trough connected as a cathode and the workpiece, the strength of which increases with increasing temperature and decreases with increasing iron content. Since the electrolyte heats up due to the current flow, the temperature must be stabilized to approx. 70 _° C with the help of the cooling water. When pickling and electrochemical decontamination, the attack of the acid dissolves the accessible metallic surface of the workpiece. This, as well as the effect of the resulting gaseous hydrogen (during pickling) or oxygen (during electrochemical decontamination) mechanically removes corrosion layers adhering to the surface. After the layers containing the activity have been removed, the workpiece is removed from the bath and sprayed with deionized water. The cleaned workpiece is checked for any remaining activity and, if the measurements confirm that it falls below the exemption limit, is subjected to what is known as harmless recycling based on official approval.

The cycle of phosphoric acid begins with the previously described processes of pickling and electrochemical decontamination. The electrolyte used for this absorbs considerable amounts of dissolved iron (up to over 100 g / l), which leads to a reduction in effectiveness. After saturation with iron, the electrolyte is stored in a designated container and, if the proportion of divalent iron in the total iron is less than about 80%, filled into the stainless steel trough for reduction. A graphite anode surrounded by a diaphragm dips into this. Under the influence of a DC voltage, the trivalent iron coming into contact with the tub connected as a cathode is reduced, while 0 ₂ , C0 ₂ and CO are formed at the graphite anode; this also leads to the gradual consumption of the anode.

After the reduction has ended, if the iron (II) content is at least 80%, the electrolyte is poured into the reaction vessel, in which the same volume of cold oxalic acid solution has already been placed, and mixed intimately with the same while stirring. The precipitation of iron oxalate, FeC ₂ 0 ₄ .2 H ₂ 0, begins within one minute; this precipitation is prevented by vigorous stirring. After total mixing, the resulting suspension is pumped into a cylindrical plastic container, on the bottom of which there is a filter basket. The sedimentation of the precipitation that collects in the filter basket takes place in this container over the course of a few hours. The supernatant clear solution is either added immediately to the phosphoric acid evaporator or, to remove remaining suspended solid particles, through a further filter basket into the filtrate collecting container, from where the pumping into the evaporator takes place.

The now low-iron electrolyte is heated in the evaporator until a sufficient amount of water has been distilled off at a boiling temperature of approximately 102 _° C. that the phosphoric acid content is approximately 40 to 65% by weight. The electrolyte is then ready for use again and can be used again for pickling or for electrochemical decontamination, which closes the cycle.

The water also circulates in a closed cycle. All water supplied to the storage tank comes from the condenser of the evaporator system; It is used to spray the workpieces, to add oxalic acid solution and to wash the iron oxalate. The spray water (contaminated by phosphoric acid and iron phosphate) is also used to produce oxalic acid solution.

The solid oxalic acid (oxalic acid dihydrate; H ₂ C ₂ 0 ₄ .2 H ₂ 0) is mixed with such an amount of water at room temperature and stirred that an approximately 10% oxalic acid solution is formed. This is stored in a storage container and reacted with the reduced electrolyte if necessary.

The iron oxalate, which is almost free of phosphoric acid after repeated washing, is first dried. Thermal decomposition of the iron oxalate at about 250 _° C. gives a mixture of iron oxides (FeO, Fe ₂ 0 ₃ and others), which are either filled as such in cast drums or, after mixing with cement and water, are filled into roller barrel drums and, after setting, are finally stored.

The gases produced during pyrolysis (CO, C0 ₂ , water vapor) are passed over a catalyst, whereby CO is converted into C0 ₂ . Together with the Ga. Generated during electrochemical decontamination, pickling and reduction sen (H ₂ , water vapor, 0 ₂ ; CO and C0 ₂ from the graphite anode) they are led into the exhaust air chimney under constant control for freedom from activity.

example

Among the decontamination processes, electrochemical decontamination plays the most important role, while pickling accounts for less than 10% of the total throughput of the iron. With a bath filling (3000 l regenerated electrolyte; 40% phosphoric acid with an iron concentration of 20 g / l) 24 t of material can be decontaminated in the course of about 6 to 7 weeks. Pickling accounts for around 2 t (corresponding to a total consumption of 250 l phosphoric acid) and electrochemical decontamination approx. 22 t (corresponding to 2750 l phosphoric acid); for the latter process (assuming a current efficiency of 50%) a current consumption of 422000 Ah is required, which corresponds to a work of 6330 kWh at a voltage of 15 V on average.

To clean the electrochemically decontaminated and the pickled parts, almost 500 l of phosphoric acid are used per bath and week, ie 3 m ³ in 6 to 7 weeks; the mass of the cleaned parts amounts to almost 24 t. One percent of the iron, i.e. 240 kg, gets into the phosphoric acid used for pickling and electrochemical decontamination, and to a lesser extent into the spray water.

To reduce the iron (assumptions; total iron content, possibly produced by entering the iron phosphate precipitated in the spray water into the acid bath, 100 g / l; proportion of divalent iron in the total iron at the beginning 30, at the end of the reduction 100%, current efficiency 50% ) 201500 Ah required.

The precipitation of the iron oxalate requires (assumptions: reduction in the amount of iron by 80%; complete conversion of the oxalic acid) 542 kg oxalic acid dihydrate (price per kg currently DM 2.92, totaling approximately DM 1600, -), which is dissolved in at least 4500 1 water ( Deionate or spray water) must be dissolved.

The sum of the volumes of 3000 I electrolyte and 4500 I oxalic acid solution, i.e. 7.5 m ³ , corresponds to 3 3/4 fillings of the 2 m3 reaction vessel.

Iron oxalate (FeC ₂ 0 ₄ .2 H ₂ 0) produces 773 kg; the sedimentation vessels, which also hold 2 m3 and have to be filled 3 3/4 times, have to hold 206 kg of iron oxalate per fill, which collects in the filter basket.

How much water is needed to wash the iron oxalate depends on the desired degree of removal of the adhering phosphoric acid; one can assume a total of about 1000 liters.

The volumes of decantate / filtrate (7.5 m ³ ) and wash water (1 m ³ ), totaling 8.5 m3, are sufficient to fill the phosphoric acid evaporator eight times. Since the 8.5 m ^{3 have} to be reduced to about 3 m ³ , i.e. 5.5 m3 have to be distilled off, a time requirement of at least 35 hours for the distillation can be assumed (the distillate decrease is approx. 158 I / h at maximum heating output). .

From the dried iron oxalate (773 kg, approx. 0.6 m ³ ), a mixture of iron oxides can be produced by thermal treatment, which is about 56% lighter than the oxalate (343 kg, approx. 0.3 m ³ ).

Claims (10)

1. A process for the preparation of an aqueous solution of phosphoric acid used up in chemical and/or electrochemical decontamination of components of equipment with radioactive surface contamination and thereby heavily loaded with iron, in which the spent phosphoric acid solution is combined with an aqueous solution and the solid materials thereby formed are separated and after draining are conditioned for final storage, and by which phosphoric acid solution is regenerated and used to decontaminate further components of the equipment, characterised in that the spent phosphoric acid solution is combined with an aqueous oxalic acid solution, that the iron oxalate thereby formed is separated and conditioned by heat treatment, and that the phosphoric acid solution remaining is concentrated for re-use by evaporation to a phosphoric acid content of from 15% to 65% by weight.

2. A process according to Claim 1, characterised in that before combination with the oxalic acid solution the spent phosphoric acid solution is subjected to a reduction treatment until at least 80% of the iron present is in the bivalent state.

3. A process according to Claim 2, characterised in that the reduction treatment is performed electrochemically in an alloy steel vat connected as cathode, with an immersed graphite anode surrounded by a diaphragm.

4. A process according to one of Claims 1 to 3, characterised in that the spent phosphoric acid solution is poured into the cold oxalic acid solution in a reaction vessel.

5. A process according to one of Claims 1 to 4, characterised in that the oxalic acid solution employed has an oxalic acid content of from 5% to 15% by weight.

6. A process according to Claim 5, characterised in that the oxalic acid solution employed has an oxalic acid content of 10% by weight.

7. A process according to one of Claims 1 to 6, characterised in that the iron oxalate formed is separated by sedimentation and/or filtration.

8. A process according to one of Claims 1 to 7, characterised in that the separated iron oxalate is dried before heat treatment.

9. A process according to one of Claims 1 to 8, characterised in that the remaining phosphoric acid solution is concentrated by evaporation to a phosphoric acid content of about 40% by weight.

10. A proceess according to one of Claims 1 to 9, characterised in that the evaporated water is condensed and used in the preparation of the oxalic acid solution.