CZ11093A3 - process of purifying primary section of a gas producer and apparatus for making the same - Google Patents

Abstract

The primary part comprises a bundle (18) of U-shaped tubes connected to a water box (22), the bundle (18) comprising healthy tubes with open ends and defective tubes with blocked ends. According to the process the bundle (18) is subdivided into a number of subassemblies (106), each comprising a substantially identical number of tubes. An acidic decontaminating solution containing cerium is circulated successively in each subassembly (106), simultaneously in all the healthy tubes of the subassembly. The ends of the decontaminated healthy tubes are then plugged, the plugs of the undecontaminated defective tubes are pierced and the decontaminating solution is circulated in the water box (22) and the defective tubes. The liquid effluents are neutralised, taken to dryness and confined in standard storage enclosures. <IMAGE>

Description

Technical field

The present invention relates to a process for cleaning a primary part of a steam generator used with a pressurized light water nuclear reactor, wherein the primary part comprises a plurality of heat exchange elements, wherein the contaminated surfaces of the primary part are contacted with an acidic cleaning solution containing cerium IV Ce ^ *. The invention further relates to an apparatus for carrying out the method defined above.

BACKGROUND OF THE INVENTION

The primary part of the steam generator comprises heat exchange elements, in particular a bundle of U-shaped tubes, the ends of which are connected to the water container and are fixed in the hollow plate. The outer surface of this tube bundle is in contact with the feed water of the secondary ring.

During operation of the steam generator, the tubes are subjected to considerable stresses. which may damage the pipes and cause leakage between the primary and secondary circuits ·

Defective or suspect pipes are taken out of service during maintenance and inspection by closing their ends with plugs ·

When the proportion of closed tubes in the bundle increases too much, namely when more than 10% of the tubes in the bundle are defective, the power of the heat steam generator decreases considerably and will be discarded and possibly replaced with another ·

A discarded steam generator emits radiation of considerable activity reaching several hundred curies. This radiation makes the transport of the generator very difficult and costly.

Thus, it is preferred to store the discarded steam generator at a site created directly at the site of the nuclear central office from which it originates.

· To eliminate the need to supervise a decommissioned steam generator and to solve various storage problems, it has been proposed to dismantle the generator to reduce the amount of waste stored and to recover or recycle some rare materials contained in the generator, especially Inconel used usually as

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material for the production of bundle tubes.

Before disassembling the steam generator it is necessary to reduce its radioactivity by cleaning.

The radioactive contamination of the steam generator is substantially spread on the inner surface of the bundle tubes and the water container. du. This contamination is mainly due to the presence of a layer of oxides containing radionuclides such as cobalt 60, cobalt 58 and manganese 54 ·

The contamination is concentrated in a layer of oxides of 3 to 5 µm thickness and surface in a metal wall of pipes of about 3 µm thickness.

A known prior art, namely WO 90/0 19741, discloses a method for cleaning a surface containing a deposit of radioactive oxides using cerium IV in the form of Ce ⁴ * ions in solution in an acidic medium.

Cerium solution. they form an aggressive and strongly oxidizing-chemical environment enabling the erosion of the oxide layer and the contaminated surface. During purification, the cerium is reduced to a thickness of HX and then regenerated to a thickness of IV by injecting ozone into the solution. The temperature of the solution should be below 60 ° C in order to avoid premature destruction of the injected ozone.

The object of the invention is to efficiently clean the primary part of the steam generator, in particular the tube bundle, by using a limited volume of the cleaning solution, without increasing the pressure inside the primary part, without increasing the temperature of the solution above 60 ° C.

SUMMARY OF THE INVENTION

SUMMARY OF THE INVENTION The present invention provides a method of purifying a primary portion of a steam generator used with a pressurized light water nuclear reactor, the primary portion comprising a plurality of heat exchange elements, wherein the contaminated surfaces of the primary portion are contacted with an acidic purifying solution containing IV. in the form of Ce * ⁴ * ions, the principle of which is that a plurality of heat exchange elements are divided into several subgroups and each subgroup is gradually subjected to the following stages of purification:

- a predetermined volume of the cleansing solution is circulated in a closed circuit in the polluted sub-group elements for a period of time T, the cleansing solution being continuously supplied with ozone,

- drain the cleaning solution,

3- rinse the rinse solution in the subset of elements and

- The rinse solution is drained.

According to a preferred embodiment of the present invention, when the primary part of the pam-Cho generator comprises a tube bundle of shape

For forming heat-walled elements and having their ends each connected to one, a water container compartment, the bundle comprising good tubes whose ends are open and defective tubes whose ends are closed by plugs,

the tube bundle is divided into several subgroups, each containing approximately the same number of tubes,

- successively run a cleaning solution simultaneously through each of the sub-groups of tubes through all good tubes of the same sub-group,

- After cleaning all good bundle tubes, plugs of uncleaned faulty tubes are pierced, the cleaning solution is circulated through both compartments of the water tank and faulty tubes.

According to another preferred embodiment of the present invention, the purification solution comprises nitric acid and has a pH of from 0 to 5, further comprising cerium nitrate in a proportion of 3 to 10 g / L and ozone in a concentration of 1: 2.5 · 1 :Ο.

According to another preferred embodiment of the present invention, the temperature of the cleaning solution is between 20 and 30 ° C.

According to another preferred embodiment of the present invention, each subset of tubes comprises about 400 tubes and the volume of the purification solution is about 3 ar.

According to another preferred embodiment of the present invention the time. The circulation of the scrubbing solution in each subset of bundle tubes is between 6 and 24 h.

According to a further preferred embodiment of the present invention, the sense of circulation of the cleaning solution in the bundle tubes changes every 1 hour.

According to a further preferred embodiment of the present invention, the speed of circulation of the cleaning solution in the bundle tubes is between 2.5 and 25 cxs ¹ .

According to another preferred embodiment of the present invention, the rinse solution comprises demineralized water and oxygen-enriched water.

According to another preferred embodiment of the present invention, the cleaning solution circulating in the contaminated elements of the primary portion is filtered through at least one filter retaining the particles drawn by the cleaning solution from the primary portion if the pressure loss across the filter is less than a predetermined value.

According to a further preferred embodiment of the present invention, the liquid waste containing the cleaning solution and the rinsing solution after their use in the primary part is treated by performing these steps?

- a reagent reducing Ce4 ⁺ ions to Ce4 ⁺ ions is injected into the liquid waste,

- the neutralizing agent is injected into the solution,

- the liquid waste is dried.

- the dried wastes are placed in. suitable storage area from weak and medium activity wastes ·

According to another preferred embodiment of the present invention, the reducing agent ions Ce ^ ⁺ ions Ce ^ ⁺ contains water enriched with oxygen ...

According to another preferred embodiment of the present invention, the waste neutralizing agent comprises a soda.

According to another preferred embodiment of the present invention, the liquid waste is dried by evaporation below. vacuum.

According to a further preferred embodiment of the present invention, the liquid waste is dried by first centrifuging the waste to obtain insoluble waste and then evaporating the waste under vacuum to collect the soluble waste.

The invention further provides an apparatus for carrying out the method as defined above, comprising a closed loop purge circuit comprising a purge solution tank and a circulator for circulating the purge solution between the purge solution tank and the end before the purge solution tank. contaminated elements of the primary part of the steam generator, and further comprising ozone means.

According to another preferred embodiment of the present invention, the closed loop purge circuit comprises filter means connected between the outlet end of the contaminated elements of the primary portion and the purge solution tank.

According to a further preferred embodiment of the present invention, the device comprises a return means for changing the sense of circulation of the cleansing solution of the contaminated elements of the primary part of the steam generator.

According to another preferred embodiment of the present invention

The filter means comprises at least two parallel-connected filters, valves for separating each filter from the purge circuit, and a derivative valve.

According to a further preferred embodiment of the present invention, the ozonator comprises an ozonizer connected to a mixer with a tube, the front end of which is fed with a cleaning solution from a pump connected to the circulation tank and the rear end of which is connected to the circulation tank.

According to a further preferred embodiment of the present invention, the device comprises an auxiliary tank connected by a transfer means to the circulation tank and intended in particular for preparing the cleaning solution and for temporarily storing the cleaning solution after emptying the circulation tank.

According to a further preferred embodiment of the present invention, the scrubbing circuit is connected to the front and rear ends of a subset of contaminated elements of the primary part of the steam generator by stationary connection means.

According to another preferred embodiment of the present invention, the stationary connection means comprises two stationary collectors each connected to a front end and a rear end of a bundle of tube bundles and to a purge circuit, the skirt flange being joined by a tight joint against the hollow plate to secure the ends of the bundle tubes. against the front ends and the other against the rear ends of the subgroup tubes.

According to a further preferred embodiment of the present invention, each collector comprises one double skirt defining a channel for collecting a possible leak of the solution circulating in the collector, which channel is connected to the leak collector.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention is illustrated in the drawings, wherein FIG. 1 is a schematic of a device for cleaning a primary portion of a steam generator connected to the front end and the rear end of a bundle of tube bundles for carrying out the method of the invention; Fig. 1 is a diagram similar to Fig. 1 in which the cleaning device is connected to two compartments of the steam generator water vessel.

FIG. 1 is a diagram of a device 10 for cleaning a primary portion of a steam generator. The apparatus 10 is connected to two elements of the primary part of the decommissioned steam generator 12 which has been connected to a pressurized light water nuclear reactor. This steam generator 12 is mounted horizontally on two supports 14 and 16 in a room not shown in the drawings. which is, however, built directly at the location of the nuclear headquarters from which the decommissioned steam generator originates.

The primary part of the steam generator 12 comprises a bundle 18 of U-shaped tubes of Inconel material. The imaginary envelope surface of the tube bundle 18 is marked with dashed lines. The ends of the bundle tubes 18 are mounted in the hollow plate 20 and are connected to a water container 22 comprising two compartments 22A.22B.

Defective or suspected bundle tubes 18 have ends closed by plugs (not shown). Good bundle tubes 18 have open ends.

Each compartment 22A.22B of the water container 22 includes a connection sleeve 23A.23B to the primary water lines. These lines were disconnected from the steam generator 12 when it was shut down. The connection sleeves 23A.23B define openings for introducing tools or fixtures into the water container 22.

The device 10 comprises a purging circuit 24 in which a predetermined volume of the cleansing solution and the ozone means 25 of the cleansing solution circulate in a closed circuit.

The purge circuit 24 includes a circulation tank 26 for receiving a portion of the cleaning solution volume and connected via a line 28 to the suction side of the circulation pump 30. The circulation pump 30 is connected to a discharge line 32 connected by the first stationary connection means 34A.34B to the first end of the subset of This subset of contaminated elements will be described in more detail below.

The purge circuit 24 also includes filter means 36 fed on the front side via line 38 connected by a second stationary attachment means 34A.34B to the other end of a subset of contaminated elements of the primary section of the steam generator 12.

The filter means 36 comprises two filters 42.44 connected in parallel to lines 38 and 40. Each filter 42.44 may be separated from the purge circuit 24 by two valves 46.48 located upstream and downstream of the filter 42.44. 42 ;; 44>

The cleaning means return means 52

-7 in the primary part, the connection means 34A.34B connects both to the discharge line 32 of the circulation pump 30 and to the supply line 38 of the filters 42.44 »

Between the discharge line 32 of the circulation pump 30 and the inlet line 38 of the filters 42.44, «a derivative valve 54 of the elements of the primary part of the steam generator 12» is connected »

Ozone means 25 comprises an ozonizer 58 connected via line 60 to injector 62 with tube 64.

The ozonator 58 is. connected via a pipe 68 provided with a safety valve 69 to a feed tank, for oxygen 66.

The injector 62- comprises an injection pump 70 whose suction side is connected via a line 72 to the circulation tank 26 and whose discharge side is connected to the front end of the tube 64 via the line 74. The rear end of the tube. 64 is connected to the circulation tank 26 via line 76,

Pipes T2.76 are provided with valves 72A and 76A, respectively, to separate the ozone 25 from the purge circuit 24,

The apparatus 1G further comprises an auxiliary tank 78 connected to the circulation tank 26 by the overflow means 80. The auxiliary tank 78, the internal volume of which is between 4 and 8 m,, is intended in particular for preparing the cleaning solution and temporarily storing this solution after emptying the circulation tank 26.

The transfer means 80 comprises a conduit 80 connecting the circulation tank 26 and the auxiliary tank 78 and provided with a return pump 80.

In particular, the mixing means 86 located in the auxiliary tank 78 makes it possible to mix various components of the solution during its preparation.

The upper part of the auxiliary tank 78 is connected via a conduit 88 to a means 90 for processing and evacuating the gaseous medium in the auxiliary tank 78 above the liquid level. The device 90 comprises a high efficiency filter 92 of a known type connected in series with the ozone depleter 94 discharged into the atmosphere.

The upper part of the circulation tank 26 is connected to the upper part of the auxiliary tank 78 by a line 96 provided with a safety valve 98 to enable the gaseous environments of the circulation tank 26 and the auxiliary tank 78 to be connected.

The lower part of the auxiliary tank 78 is connected to a solution drain 100 comprising a pipe 102 provided with a drain valve 104. The first end of the pipe 102 is connected to the bottom of the auxiliary tank 78 and the other end of the pipe 102 is connected to a negative-changed liquid waste collector.

Various subgroups of contaminated elements of the primary part of the steam generator 12 and the purification process stages of the present invention will now be described. apply to these subgroups.

The bundle 18 is divided into several subgroups, each containing approximately the same number of tubes. 7 of the present example, each subset of about 400 tubes and the entire bundle 18 comprises eight to nine tube subgroups.

In FIG. 1, an imaginary wrapping area delimiting one subset of 106 adjacent tubes is shown in solid line.

The good tubes of sub-assembly 106 are connected by connection means 34A.34B to the purge circuit 24. These connection means. 34 &apos; 34 &apos; include flexible conduits 108, the first end of which is connected to the purge circuit 24 and the expensive end of which is connected to the stationary header. 110 shown in detail in FIG. Flexible ducts-108 pass through openings delimited by connection and sleeves 23 A? 23 B of the water container 22.

The stationary pantographs 110 are generally bell-shaped and are connected by a tight joint against the hollow plate 20. The first pantograph 110 is located opposite the front ends, the second pantograph 110 is opposite the rear ends of the tubes of the sub-assembly 106.

FIG. 2 shows one of the collectors 110 connected to the beam subgroup 106. 18.

This header 110 is positioned against the open ends of the good tubes 18A and optionally against the closed ends of the faulty tubes 18B. The header 110 has a double skirt 112 provided with a tight seal 114 and defining a channel 116 for collecting any leaks of solution circulating across the header 110.

The channel 116 is an opening 118 extending across the wall of the header 110 to the leakage conduit 120. The line 120 is connected to a liquid waste collector (not shown).

The collectors 110 are located in the compartments of the water container 22 and are connected to the hollow plate 20 by known means, in particular by means of an articulated support arm of the type known as ROflEO housed in the water container 22.

The contour of the manifold flange 112 has a variable shape depending on the spacing of the pipe ends in the hollow plate 20. Depending on whether the ends of the pipes of the same subset are spaced from the walls of the water container 22 or are adjacent to any of the walls of the water container 22, 110 approximately rectangular or approximately complementary

-9 shape to contour the water container wall.

The process of cleaning the good bundle tubes 18 which are not closed by plugs will now be described.

The tube subgroups 106 are cleaned sequentially by attaching one subgroup after another to the purge circuit 24 as described above.

First, a volume of about 3 m ^{3 of the} cleaning solution is prepared in the auxiliary tank 78. This volume makes it possible to fill all the good pipes of the subgroup to be cleaned.

The purification solution contains nitric acid and the pH of the solution is between 0.5 to 1, further containing cerium nitrate in a proportion equal to 8 to 10 g / l. Alternatively, the cerium nitrate may be replaced with cerium sulphate.

When the cleaning solution has been prepared, it is pumped from the auxiliary tank 78 to the circulation tank 26 by a return pump 84. thereafter the following cleaning stages are carried out with each sub-tube.

In the purge circuit 24, the purge solution is circulated in a closed loop by the circulation pump 30. The purge solution is circulated through all good tubes of the same subgroup simultaneously for a period of T equal to 6 to 24 h.

When the purge solution is circulated, it is supplied with ozone from the ozone composition 25 while maintaining an ozone concentration in the purge solution of about 1: 2.5 * 10.

The scrubbing solution reacts with a layer of oxides covering the inner surface of the tubes and a metal surface coating of the tubes.

In particular, the iron of thickness II of the oxide layer is oxidized to the thickness of m.

Ce ⁴ * + Cr ₂ O ₃ + 11 B ^ O-> 2 HgCrO + 6 Ce ³ * + 6 H ^ O *

The iron of strength HI and chromium of strength VI are dissolved in the purification solution. The ceramics III (Cq ^j ions) are regenerated by the ozone IV (Ce ⁴ * ions) according to the following chemical reaction:

HjO * * Qj + 6 Ce ³ * -> 6 Ce ⁴ * + 9 HgO.

The temperature of the scrubbing solution is maintained between 20 and 30 ° C to ensure a sufficient ozone life in the scrubbing solution, allowing the recovery of the potency III.

The velocity of the scrubbing solution in the tubes of the bundle 18 is between 2.5 cm.sup.2 and 25 cm.sup.2 in order to prevent settling of contaminated particles drawn from the surface of the tubes in the same tubes.

The screen of the Inccnel 18 bundle tubes is eroded on the surface with a cleaning solution, which mainly produces Cr, Fe ³ * and Ni ²⁺ ions.

The erosion of the inner surface of the tubes of the bundle 18 is homogenized by reversing the direction of circulation of the purge flow in the tubes by the return means 52 in about one hour.

The filter means 36 allows to retain a portion of the particles withdrawn from the primary portion of the steam generator 12. Preferably, one filter 42.44 is used. When the pressure drop across the operating filter increases too much, the process is transferred to another filter by the 46.48 filter separation valves. It is also possible to stop filtration after a period of circulation of the cleaning solution by separating the filters from the purge circuit 24 and opening the derivative valve 50.

At the end of the cycle of the cleaning solution in the good tubes of the subgroup, the injection of ozone into the cleaning solution is stopped and the entire volume of the cleaning solution contained in the tubes of the bundle 18 and in the cleaning circuit 24 is removed. The cleaning solution is pumped to the auxiliary tank 78 by a return pump 84 and is not excessively stored therein.

When the purge solution is exchanged, particularly when the cerium concentration is too low and the contaminated particle concentration has risen too much, the drain valve 104 is opened and the purge solution is discharged into the liquid waste collector for treatment by subsequent stages, which will be described.

Typically, one and the same scrubbing solution can be used to clean three sub-groups each containing about 400 tubes. All good bundle tubes are cleaned in eight to nine passes using about 9 m ^{3 of} cleaning solution.

After the purge solution has been pumped off, the tubes of the bundle 18 are rinsed with a solution containing demineralized water and oxygen-rich water. The rinse solution is introduced into the circulation tank 26 by known means (not shown) and circulated by the circulation pump 30 through the good tubes of the bundle 18.

Oxygen-enriched H 2 Og reacts with the residual cerium IV and reduces it to the IH cerium according to the following chemical reaction:

HgOg ♦ 2 Ce ⁴⁺ -> 2 Oe ³ * + 0 ₂ + 2 H *.

After the rinsing of the tubes with the known means is removed

-11 · rinse solution · The rinsed solution collected is collected in the liquid waste collector to be processed in the next stages described below ·

After cleaning and rinsing of good tubes, one subgroup of bundle 18, the scrubber circuit 24 is switched to another subset of tubes, which is subjected to the cleaning and rinsing stages described above.

Depending on the state of change of the scrubbing solution, the same scrubbing solution is used or a new batch of scrubbing solution of the same volume is prepared after the previous tube subset has been cleaned.

The steps of cleaning the water container 22 and the faulty bundle tubes closed by plugs will now be described.

After cleaning all the good tubes of the bundle 18, both ends of the good tubes are plugged and the plugs of any defective uncleaned tubes are pierced. Thus, the two compartments 22A.22B of the water container 22 are connected by defective stoppers.

Fig. 3 shows a device 10 similar to the device 10 shown in Fig. 1. 7 is a view similar to FIG. and having similar functions marked with the same reference numbers *

The purge circuit 24 is connected to a sub-assembly 121 of the primary part of the steam generator having two compartments 22A.22B of the water container 22 and the defective bundle tube 18 of the plugs. For clarity, only one defective tube 18B is shown in FIG.

Clamps 23A.23B of vessel 22. The water is closed by plates 122A2122B provided with openings for connection to the conduits 108 that connect the water container 22 to the purge circuit 24.

The cleaning of the water container 22 and the defective tubes 18B is accomplished by:. they allow a certain volume of the purification solution of the type described above to be circulated therein following stages similar to those used in the cleaning of good pipes.

Defective pipes present a risk of leakage at pressures close to 15 MPa. On the contrary, this danger is eliminated by allowing the cleaning solution to circulate in the defective tubes at a pressure approximately equal to the atmospheric pressure.

The volume of scrubbing solution used is dependent on the total volume defined by the compartments 22A and 22B of the water container 22 and the defective tubes to be filled with the scrubbing solution.

At the end of the cleaning, the water container 22 and the defective tubes 18B are rinsed with a rinse solution of the type described above while monitoring

-12 stages similar to those used in rinsing good 18 &quot; tubes.

Liquid wastes containing cleansing solutions and rinsing solutions of poor quality are collected in a collector (not shown) for subsequent processing.

The treatment of cleaning and rinsing solutions of inferior quality after their use in the elements of the primary part of the steam generator 12 will now be described. These solutions collected in the liquid waste collectors are subjected to the following processing stages.

An agent containing oxygen-enriched water is injected into the liquid waste to reduce the ions to Ce4 ⁺ ions and then store cerium III.

The liquid wastes are then neutralized by injecting a soda-containing reagent, then pumped into a drying apparatus not shown, where it is subjected to evaporation under vacuum.

Alternatively, the liquid waste can be dried by first centrifuging the waste to collect the insoluble waste and then evaporating the waste in a vacuum to collect the soluble waste.

The dried wastes are stored in rooms of a known type adapted for the storage of nuclear waste of low and medium activity. These rooms can be concrete or metal. In the example described, the total weight of the dried waste after cleaning the entire bundle 18 and the water container 22 is about 1500 kg.

Filled filters used in the cleaning circuit are compacted. These filters make it possible to collect about 50% of the solid particles drawn by the cleaning solution from the propyne portion of the steam generator 12.

In the example described, the total waste volume in the compacted filters, the dried waste and the surrounding concrete is about 5

This volume of waste is stored, for example, in containers known as MOSAIK.

The cleaning method according to the invention makes it possible to obtain a cleaning factor defined by the ratio of the radiation field before the treatment and the radiation field after the cleaning is greater than 1000, but may be greater than 15000.

In addition to the ingredients already mentioned, the cleansing solution may also contain sulfuric acid · Also, nitric acid in the cleansing solution may be replaced by sulfuric acid ·

The primary circuit elements are cleaned without restriction

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below 60 ° C.

The cleaning method according to the invention makes it possible to simultaneously clean the bundle of bundle tubes 18 and to limit the volume of waste generated during the cleaning to several cubic meters.

Waste generated can be stored in standard rooms ·

The cleaning solution described has a composition suitable for cleaning the Inconel primary water tube bundle 18 in an optimal manner, but this solution can also be used to clean the inoxel elements.

The purification method of the invention can also be used for a steam generator comprising a bundle of straight primary water tubes. These tubes are connected at each end to the hollow plate and to the water container. In this case, the subset of tubes is connected to the purge circuit by collectors mounted on the hollow plates of the bundle ends.

ϋΤΙβ-93

-14ΡΑΤΕΜΓΟνΰ HÍEOKI

Claims (21)

ΡΑΤΕΜΓΟνΰ HÍEOKI A process for cleaning a primary part of a steam generator in use and a pressurized light water nuclear reactor, the primary part comprising a plurality of heat exchange elements, wherein the contaminated surfaces of the primary part are contacted with an acidic purification solution containing cerium IV ⁺ , characterized in that the plurality of heat exchange elements are divided into several subgroups and each subgroup is subjected to the following stages of purification successively: - a predetermined volume of the cleansing solution is circulated in the contaminated sub-group elements for a period of I in a closed circuit, continuously feeding the cleansing solution with ozone, - drain the cleaning solution, - rinse solution is circulated in the subset of elements and - rinse solution is drained · The method of claim 1, wherein the primary portion of the steam generator comprises a bundle of tvaru shaped tubes forming heat exchange elements and having their ends connected to each compartment of the water container, the bundle comprising good tubes whose ends are open and faulty tubes whose ends are closed by plugs, characterized in that: - the tube bundle is subdivided into several subgroups, each containing approximately the same number of tubes, - successively run the scrubbing solution through each good sub-group of tubes simultaneously through all good tubes of the same sub-group, and - After cleaning all good bundle tubes, the faulty tube plugs are pierced, 'the cleaning solution is circulated through both compartments of the water container and the faulty tubes. 5. The process of claim 2 wherein the scrubbing solution comprises nitric acid and has a pE of 0.5 to 1, further comprising cerium nitrate in a proportion of 8 to 10 g / l and ozone at a concentration of 1: 2.5 * 10 &lt; -1 &gt; 4. The method of vDPvwKX 2 or 3, characterized in that the temperature of the cleaning solution is between 20 and 50 ° C. A method according to any one of 2 to 4, wherein each tube bundle subset comprises about 400 tubes and that the volume of the scrubbing solution is? 3?. 6. A method according to any one of claims 2 to 5, wherein the cycle time T of the scrubbing solution in each subset of tubes is selected. -15beam is between 6 and 24 h. ... 7. The method according to any one of claims 2 to 6, characterized in that the sense of circulation of the cleaning solution in the bundle tubes changes every 1 hour. A method according to any one of 2 to 7, characterized by falls with weak and st M · ' 12. A method according to claim 1, wherein the speed of circulation of the cleaning solution in the bundle tubes is between 2.5 and 25 cm @ ^-1 . The method according to any one of claims 1 to 8, wherein the rinse solution comprises demineralized water and oxygen-enriched water. . _t 10. A method according to any one of claims 1 to 9, wherein the purge solution circulating in the contaminated elements of the primary portion is filtered through at least one filter retaining the particles drawn by the purge solution from the primary portion when the pressure loss across the filter is less than a predetermined amount. A process according to any one of Claims 1 to 10, characterized in that the liquid waste comprising the cleaning solution and the desiccant rinsing solution in the primary part is treated by performing the following stages: - a reagent reducing the Ce ^ ⁺ ions to Ce ^ ⁺ ions is injected into the liquid waste, - the neutralizing agent is injected into the solution, the liquid waste is dried, and - dried wastes are stored in a suitable storage area by decontamination activity · 11, characterized in that the reducing agent of Ce4 ^{+ to} Ce4 ⁺ ions comprises water enriched with kenic ^acid . The method according to claim 11 or 12, wherein the waste neutralizing agent comprises soda. Process according to any one of claims 11 to 13, characterized in that the liquid waste is dried by evaporation under vacuum. Process according to any one of Claims 11 to 13, characterized in that the liquid waste is dried by first centrifuging the waste to obtain insoluble waste and then evaporating the waste under vacuum to collect the soluble waste. Apparatus for carrying out the method according to any one of claims 1 to 15, characterized in that it comprises a purge circuit (24) in a closed loop comprising a tank (26) for circulating the purge 16s. a solution and a circulating pump (30) for circulating the scrubbing solution between the scrubbing solution tank (26) and the end upstream of the contaminated elements (106, 121) of the primary part of the steam generator (12), and further comprising ozonizing means (23); 17. The apparatus of claim 6, wherein the purge circuit (24) in the closed loop comprises filter means (36) connected between the outlet end of the contaminated elements (106, 121) of the primary portion and the circulation tank (26). Apparatus according to claim 16 or 17, characterized in that it comprises a return means for changing the sense of circulation of the cleaning solution of the contaminated elements (106, 121) of the primary part of the steam generator (12). r Apparatus according to any one of items 16 to 18, characterized in that the filter means (36) comprises at least two filters (42-44) connected in parallel ^; valves (46.48); to separate each filter (42, 44) from the purge circuit (24) and the derivative valve (50). Apparatus according to any one of Claims 16 to 19, characterized in that the ozonating means comprises an ozonizer (58) connected to the mixer with a tube (64), the front end of which is fed with a purge. a solution from a pump connected to the circulation tank (26) and the rear end of which is connected to the working tank (26). Apparatus according to any one of Claims 16 to 20, characterized in that it comprises an auxiliary tank (78) connected by a transfer means (80) to the circulation tank (26) and intended especially for. * preparing a cleaning solution and temporarily storing the cleaning solution after the circulation tank (26) has been emptied _o Apparatus according to any one of Claims 16 to 21, characterized in that the purge circuit (24) is connected by immovable attachment means (34A, 34B) to the front and rear ends of the contaminated element subset (106, 121) of the primary part of the steam generator (12). 23. The apparatus of item 22, wherein the stationary attachment means (34A, 34B) comprises two stationary collectors (110) each connected to the front and rear ends of the beam subgroup (106) and to the purge circuit (24). , the skirt (112) of the collectors (110) is connected by a tight joint against the hollow plate (20) for fastening the ends of the bundle tubes, one collector (110) facing the front ends and the other collector (110) against the rear ends of the tubes of the subset (106). -1724. Apparatus according to Claim 23, characterized in that each header (10) comprises one double bead (112) defining a channel (116) for collecting a possible leak of solution circulating in the header (110), which channel (116) is connected to the leak collector.