EP0470893A1 - Process for sealing a tube of a heat exchanger with straight tubes and use of this process - Google Patents

Abstract

The cutting of the tube (4) at its ends adjacent to the first and the second connection piece (14, 15) is carried out, and the metal of the zones (16, 16') joining the tube (4) to each of the connection pieces (14, 15) is eliminated. The cutting and elimination of at least one portion of the tube (4) adjacent to at least one of the connection pieces (14, 15) are carried out. A plug (24, 30) of tubular shape, the diameter of which is smaller than the inside diameter of the tube (4), is introduced into each of the ends of the tube (4) in place inside the heat exchanger, in such a way that the plug has a closed end (24a, 30a) on the inside of the tube (4) and an opposite end arranged on the inside of the corresponding connection piece (14, 15). The plugs (24, 30) are fixed in place in the connection pieces (14, 15), and a continuous sealing weld is made between each of the plugs (24, 30) and the corresponding connection piece (14, 15), the tube (4) having some freedom of movement in the longitudinal direction in relation to the plugs (24, 30). …<IMAGE>…

Description

The invention relates to a method of plugging a tube of a straight tube heat exchanger comprising two tubular plates which are substantially parallel and spaced apart from one another through openings at the level of which the tubes are fixed at their ends. .

The invention applies in particular in the case of a steam generator with straight tubes of a fast neutron nuclear reactor cooled by a liquid metal such as sodium.

Steam generators of fast neutron nuclear reactor cooled by a liquid metal are known, which comprise a bundle constituted by a set of parallel straight tubes fixed at their ends in tubular plates parallel to each other and integral with the external envelope of the generator. steam. The tubular plates delimit inside the envelope of the steam generator three successive zones which constitute for the first a water box, for the second a zone of circulation of the coolant liquid metal in contact with the external surface of the tubes of the bundle and, for the third, a vapor collector.

The tubular plates are pierced over their entire thickness by holes at the level of each of which is fixed the end of a tube, by welding on a connection nozzle of tubular shape and arranged in projection relative to the internal face of the plate. tubular, this connection connection being generally designated by the term "teat" in the technique considered.

Each of the tubes of the heat exchanger bundle is fixed at one of its ends to a first connection of a first tubular plate and, at its other end, to a second connection of a second tubular plate, the inside diameter of the second nozzle and the corresponding opening of the second tube plate being substantially greater than the outside diameter of the tube which is connected to the second nozzle by a junction zone of frustoconical shape.

Each of the tubes therefore provides the junction between the water box and the steam collector, the water supplying the steam generator distributed in all of the tubes of the bundle at the outlet of the water box then being heated and vaporized. inside the tubes, by thermal contact with the heat transfer liquid metal. The vapor formed in the tubes is then recovered in the vapor collector.

The hot liquid sodium is generally brought to the upper part of the steam generator, in the vicinity of the tubular plate delimiting the steam collector; the liquid sodium then circulates vertically outside the bundle tubes.

In the event that one of the tubes has a crack generating a leak, this leak must be detected very quickly, so that the operation of the steam generator can be stopped and its emptying can be carried out, before the reaction between the liquid sodium and the water flowing through the leak reaches such an extent that the steam generator can be deteriorated and this reaction can no longer be controlled by the safety devices provided on the steam generator and ensuring damping pressure waves in sodium.

A leak at one of the tubes of the steam generator can be highlighted, either by the detection of the hydrogen which is formed by the reaction of water on the sodium, or by the acoustic detection of the noise of the reaction.

After complete emptying of the steam generator, it is necessary to carry out a repair on the defective tube presenting a leak, either by plugging, or by replacement of this defective tube, in order to allow the steam generator to operate again.

In order to plug a defective tube of a steam generator, various techniques have been proposed, as described for example in patents FR-A-2,524,609 and FR-A-2,560,962.

In patent FR-A-2,524,609, it is proposed to plug the tube by automatic displacement of a valve placed inside the tube, so as to close off this tube, under the effect of the pressure difference accompanying the appearance of the leak and the subsequent reaction between sodium and water. This plugging of the tube makes it possible to prevent the leak from having harmful consequences, by separating, in a safe and immediate manner, the water or the steam under pressure from the sodium.

In patent FR-A-2,560,962, a plugging is recommended by fitting a flexible sleeve, in an axial arrangement inside the tube, this sleeve being fixed by mechanical keying or by explosion welding.

In reality, the sealing techniques using expansive sleeves, valves, or the fixing of a shutter member by swaging, welding by explosion or keying, are no longer used in the context of maintenance operations or repair of steam generators using liquid sodium as primary fluid. It is indeed necessary to guarantee, in operation, an absolute seal between water and liquid sodium. None of techniques mentioned above does not guarantee such an absolute seal.

Indeed, the operation of a steam generator of a fast neutron nuclear reactor results in very high temperatures of the heat transfer fluid ensuring the heating and vaporization of water, by extremely rapid temperature transients and by thermal shocks due to temperature variations which can be very significant of the liquid metal constituting the heat transfer fluid.

In addition, the proportion of tubes closed during successive repair operations of a steam generator must not exceed a certain percentage of all the tubes.

It is generally considered that this percentage should be between 10 and 15% of the tubes.

The technique of plugging the tubes has the disadvantage of causing a loss of power of the steam generator and of introducing a temperature asymmetry in the tube bundle, so that the other tubes of the bundle undergo increased thermomechanical stresses.

In addition, for safety reasons, it is not possible to place plugs on the outer walls of the tubular plates of a steam generator, i.e. on the side of the water box or on the side of the vapor collector. Indeed, in this case, the detection of hydrogen or the acoustic detection making it possible to detect the appearance of a leak of water or of vapor in the sodium cannot be carried out in a safe and rapid manner. Late detection of a water leak in sodium has very serious drawbacks which have been mentioned above.

Welds are avoided on the tubular plates which are liable to induce weld stresses in these plates and make it necessary to relax the tubular plates after welding and the implementation of control procedures which are difficult to carry out.

The plugs for closing the tubes must therefore be placed on the internal walls of the tube plates, that is to say the walls directed towards the area of the steam generator containing the bundle of tubes. The tubular plates have thicknesses which can be relatively large, for example of the order of 400 mm, so that the plugs must be placed on walls located at considerable distances from the external access faces of the tubular plates.

In the case where the defective tube is cut and extracted before the corresponding orifices of the tube plates are plugged, the thermohydraulic behavior of the steam generator is modified, insofar as the extraction of the defective tube modifies the circulation of the coolant in the hydraulic channel located between the tubes adjacent to the defective tube.

In the case where the plugging is carried out without extracting the defective tube from the steam generator, this tube is liable to expand and deform by buckling during the operation of the nuclear reactor. The defective tube can come into contact with the adjacent tubes and cause deterioration of these tubes, by friction under the effect of the vibrations generated by the flow of the heat transfer fluid.

The object of the invention is therefore to propose a method of plugging a tube of a heat exchanger with straight tubes comprising two plates which are substantially parallel and spaced apart from each other through openings at the level of which the tubes are fixed at their ends by welding on connection nozzles, each of the tubes of the heat exchanger bundle being fixed, at one of its ends, on a first connection of a first tubular plate and, at its other end, on a second tapping of a second tubular plate, this process making it possible to produce an efficient and reliable plugging, from the outside of the steam generator and to remedy the drawbacks of the processes according to the prior art.

• on réalise le découpage du tube à ses extrémités voisines du premier et du second piquages et on élimine le métal des zones de jonction du tube à chacun des piquages, par l'intérieur du tube et à travers l'une ou l'autre des plaques tubulaires,
• on réalise le découpage et l'élimination d'au moins un tronçon du tube voisin de l'un au moins des piquages,
• on introduit, dans chacune des extrémités du tube en place à l'intérieur de l'échangeur de chaleur, un bouchon de forme tubulaire dont le diamètre est inférieur au diamètre intérieur du tube, de manière que le bouchon présente une extrémité fermée à l'intérieur du tube et une extrémité opposée disposée à l'intérieur du piquage correspondant,
• on fixe les bouchons en place dans les piquages et on réalise une soudure continue d'étanchéité entre chacun des bouchons et le piquage correspondant, à l'intérieur de chacun des piquages, les tubes présentant une certaine latitude de déplacement dans la direction longitudinale, par rapport aux bouchons.

For this reason :

• the tube is cut at its ends close to the first and second nozzles and the metal is removed from the areas where the tube joins each of the nozzles, from inside the tube and through one or other of the plates tubular,
• cutting and elimination of at least one section of the tube adjacent to at least one of the taps,
• is introduced into each end of the tube in place inside the heat exchanger, a tubular plug whose diameter is less than the inner diameter of the tube, so that the plug has one end closed at the inside the tube and an opposite end disposed inside the corresponding tap,
• the plugs are fixed in place in the nozzles and a continuous sealing weld is made between each of the plugs and the corresponding nozzle, inside each of the nozzles, the tubes having a certain latitude of movement in the longitudinal direction, by compared to traffic jams.

In order to clearly understand the invention, a description will now be given, by way of nonlimiting examples, with reference to the attached figures, of several embodiments of the plugging process according to the invention applied to a generator tube. vapor from a fast neutron nuclear reactor cooled by liquid sodium.

Figure 1 is an elevational view in partial section of a steam generator with straight tubes of a fast neutron nuclear reactor.

Figure 2 is a sectional view of a steam generator tube showing in particular the ends of the tube connected to the first tube plate on the side of the steam collector and to the second tube plate on the side of the generator water box of steam, respectively.

Figures 3A, 3B, 3C and 3D are sectional views showing different successive stages of implementation of the method according to the invention and according to a first embodiment.

Figures 4A, 4B, 4C and 4D are sectional views showing different successive phases of the implementation of the method according to the invention and according to a second embodiment.

Figure 5 is a sectional view on a large scale of a plug placed by the method according to the invention at the upper end of a tube, on the side of the vapor collector.

Figure 6 is an enlarged sectional view of a plug placed at the lower end of a steam generator tube, on the side of the water box.

FIG. 7 is a cross-sectional view of various tubes of the bundle of a steam generator, during an operation for checking the plug welds placed inside a defective tube.

In Figure 1, we see a steam generator with straight tubes comprising an outer casing 1 and two tubular plates 2 and 3 fixed on the casing at its upper and lower ends respectively. The tubular plates 2 and 3 are pierced with holes over their entire thickness and straight and parallel tubes 4 are arranged between the two plates 2 and 3 in the extension of the holes passing through these plates. The lower plate 3 delimits with a hemispherical envelope 5 a water box 6 communicating with the inlet ends of the tubes 4. The plate 2 delimits with a hemispherical envelope 7 a vapor collector 8 in communication with the outlet ends of the tubes 4 Between the water box 6 and the vapor collector 8, the external casing 1 of the steam generator defines an area in which circulates liquid heat-carrying metal such as liquid sodium entering the casing 1 via a pipe 10 and leaving of this envelope by a pipe 11.

Water is introduced into the water box 6 which distributes it in the tubes 4 of the bundle. This water circulates in the tubes from bottom to top, heats up and vaporizes under the effect of the heat given up by the heat-transfer liquid metal. The vapor formed is recovered in the collector 8.

In Figure 2, we see the ends of a tube 4 of the bundle, at the junction areas with the upper tube plate 2 and with the lower tube plate 3, respectively. The junction is ensured by means of nozzles 14 and 15 of the plates 2 and 3 respectively, projecting relative to the internal faces 2a and 3a of these tubular plates. The taps 14 and 15 of the tubular plates 2 and 3 of tubular shape, called "teats", are arranged so as to surround the outlet end of an opening 12 or 13 of the corresponding tubular plate 2 or 3 on the faces 2a and 3a.

The diameter of the hole 13 passing through the plate 3 and the inside diameter of the bore of the teat 15 are slightly greater than the outside diameter of the tube 4, the placement in the beam can be carried out through the tube plate 3, before the establishment of the envelope 5 of the water box 6. The upper end 4a of the tube 4 is fixed to the end of the nipple 14, by butt welding, the junction being provided by a form weld ring finger 16.

The lower part of the tube 4 is connected to the nipple 15, by means of a junction zone by welding 16 ′ of substantially frustoconical shape produced by fusion of the end of the tube 4 engaged over a short length inside. of the nipple 15 and of the end of the nipple 15.

In FIGS. 3A, 3B, 3C and 3D, a tube 4 is shown having a leakage-generating crack which is plugged by the process according to the invention.

The corresponding elements in FIGS. 2 on the one hand and 3A, 3B, 3C and 3D on the other hand bear the same references.

The tube 4 is plugged on the steam generator, after emptying the liquid sodium, steam and water, cooling the steam generator and dismantling the external walls 5 and 7 of the water box 6 and the collector of steam 8, respectively.

In this way, the outer face of the tubular plates 2 and 3 is accessible, which makes it possible to introduce into the tube to be dismantled, through the through openings of the plates 2 and 3, the tools necessary for making the cut and / or the machining of tube 4 which is capped as well as the introduction, installation and welding of the plugs.

As a first step, as can be seen in FIG. 3A, a section 20 of the tube 4 situated at its lower part is cut, in the vicinity of the teat 15 projecting from the inner face 3a of the plate. tubular 3.

The section 20 is cut from inside the tube 4, using a device of known type, as described in patent application FR-A-2,613,961 filed on April 17, 1987. The cutting device comprises a milling cutter attached to the end of an axis allowing it to rotate and be inserted inside the tube, from the outside face of the plate 3, for its positioning at the areas to be cut from inside the tube. The axis of the cutter makes it possible to move the latter in the radial direction, so as to ensure the penetration of the cutter into the metal, during machining.

The section of the tube 20 is cut by making two transverse cuts 21 and 22. The cut 21 is made in the zone 16 ′ of the junction of the tube 4 with the nipple 15 projecting from the face 3a of the tube plate 3 The cut 21 made by milling makes it possible to eliminate the metal from the junction part 16 ′, of frustoconical shape, from the tube 4 with the teat 15 from the tube plate 3. The metal from the junction zone 16 ′ is eliminated under in the form of filings, chips or cut particles which are extracted from the steam generator through the opening 13 of the tube plate 3.

The cut 22 is made in an area of the tube 4 located in its lower part and above the first spacer plate 23 for holding the tubes of the bundle.

When the cuts 21 and 22 are made, the tube section 20 is extracted through the opening 13 of the tube plate 3.

As can be seen in FIG. 3B, there is introduced through the opening 13 of the tubular plate 3, a lower plug 24 of tubular shape having one end 24a closed by a sealed bottom, so that the end 24a of the plug 24 is introduced into the lower end of the tube 4, the section of which was made previously.

As can be seen in FIGS. 3B, 3C and 3D and in FIG. 6, the plug 24 comprises a tubular body whose diameter which is substantially identical to the diameter of the tube 4 is less than the dimension of the bore of the nozzle 15 and of the opening 13 of the plate 3.

The end portion 24a of the plug 24 has a diameter very slightly less than the diameter of the tube 4, so that the end 24a of the plug can be freely engaged inside the tube.

The end of the plug 24 opposite its end 24a engaged in the tube is located at the end of the nipple 15 on which one carries out, through the interior of the opening 13 of the tubular plate, the fixing of the plug 24 by welding points.

The tube 4 is thus held in place at its lower part by the plug 24.

Is carried out from the outside of the tube plate 2, by engaging a cutting tool comprising a cutter as described above, in the opening 12, a cut of the end of the tube 4, at the level of the junction 16 of this tube with the nipple 14 of the tube plate 2. The machining of the tube and the end of the nipple 14 is carried out so as to eliminate under in the form of filings or chips, all of the metal in the junction zone 16. The filings, chips or particles of metal formed during machining are recovered, so as to avoid polluting the interior of the steam generator.

The machining of the tube 4 is continued, by moving the cutter in the direction of the arrow 26, so as to eliminate a section of tube 25, in the form of filings or milling chips which are recovered outside the generator. steam.

The tube 4 which is held in the steam generator by its lower part, thanks to the plug 24, has, after machining, a free upper end 27.

As can be seen in FIG. 3C, a plug 30 of tubular shape having an outside diameter slightly smaller than the inside diameter of the tube 4 is then engaged, and an end portion 30a closed by a sealed bottom, inside the opening 12 of the tubular plate 2, so as to introduce the closed end 30a of the tube 30 into the upper end 27 of the tube 4.

The end of the plug 30 opposite the closed end 30a is placed at the end portion of the teat 14 of the tubular plate 2. The plug 30 is fixed in place, inside the teat 14, by solder points.

A continuous and sealed weld 28 is then produced between the end of the plug 24 and the end of the nipple 15, the weld zone 28 having a substantially frustoconical shape.

As can be seen in FIG. 3D, the fixing of the upper plug 30 is then completed by a continuous and sealed annular weld 29 ensuring the junction between the plug 30 and the end of the teat 15.

The leaktight sealing of the defective tube 4 was thus carried out, the internal space of the tube 4 and the internal volume of the steam generator being insulated in a completely sealed manner with respect to the water box and with respect to the steam collector, thanks to the plugs 24 and 30 attached to the internal part of the tubular plates 3 and 2 respectively.

In addition, the defective tube 4 is held in place, which makes it possible to avoid modifying the thermohydraulic regime of the steam generator in the vicinity of the defective tube 4.

In addition, the plugs 24 and 30 are engaged by their end portion 24b and 30a, completely freely, inside the ends of the tube 4.

Because the plugs 24 and 30 are not connected to the ends of the tube 4, these ends are capable of sliding on the end portions 30a and 24a of these plugs, in the longitudinal direction, for example when the tube 4 is subjected to thermal expansion or retraction in the generator in operation.

This avoids any buckling of the defective tube 4 maintained after plugging in the steam generator.

We will now describe, with reference to FIGS. 4A, 4B, 4C and 4D, a second mode of implementation of the plugging method according to the invention.

The corresponding elements on elements 3A, 3B, 3C, 3D on the one hand and 4A, 4B, 4C, 4D on the other hand bear the same references.

The first phase of the implementation of the method according to the second embodiment allows performing the cutting of a section 20 ′ of the tube 4, in its lower part, in a manner identical to the cutting of the section 20, during the first phase of the first embodiment of the capping method according to the invention.

The section 20 ′ is cut by milling the junction zone 16 ′ and the wall of the tube 4, along cutting zones 21 ′ and 22 ′ respectively.

The metal from the junction zone 16 'is removed as described in the case of the first embodiment and an additional cut of the tube is made in the cutting zone 22'.

The cutting area 22 'is located at a greater distance from the inner surface 3a of the tube plate 3 than the cutting area 22 implemented in the first embodiment of the method, that is to say in a arrangement located towards the inside of the steam generator, in relation to zone 22.

As can be seen in FIG. 4B, in a second phase, the interior and the cutting are carried out by machining of the zone 16 where the tube 4 joins the teat 14 of the tube plate 2 , the lower part of the tube which has been cut previously being held by a tool engaged and clamped inside the tube 4.

After having cut the tube by machining the junction zone 16, the tube 4 is moved downwards, as shown by the arrow 31, using the tool engaged in the lower part of the tube 4.

As shown in FIG. 4C, the tube 4 is moved downwards, so that its upper end 27 is at a distance from the end of the teat 14 corresponding substantially to the length of the tube section 25 removed by machining, in the case of the first embodiment.

A tubular plug 30, closed at one of its ends 30a, is engaged inside the opening 12, so that the end 30a of the plug 30 is freely engaged in the upper end part of the tube 4 and that the end of the plug 30 opposite its end 30a is coincident with the end part of the teat 14.

The plug 30 is fixed by welding points inside the nipple 14.

The tube 4 is then held in place inside the steam generator by the upper plug 30 and by the tool engaged in its lower part which may be constituted by a centering and guiding assembly for the cutting device.

A cut is made to length from the lower part of the tube, along the cut line designated by the arrow 30 in FIG. 4C.

As can be seen in FIG. 4D, a plug 24 similar to the bottom plug described in the first embodiment and shown in FIG. 6 is introduced into the lower part of the tube 4.

The plug 24 has an end portion 24a which is freely engaged in the end of the tube 4 which has previously been cut to the desired length. The plug 24 is fixed in place by welding points, then a continuous and sealed annular weld 28 is produced at the end of the plug 24 opposite its end 24a engaged in the tube 4.

The weld 28 is produced on the end part of the plug 24 placed in coincidence with the end of the teat 15.

In the final phase, the plugs 24 and 30 are fixed to the teats 15 and 14 and engaged in the ends of the tube 4, which makes it possible to obtain the same advantages, as regards the efficiency of the plugging and the possibilities of longitudinal expansion of the tube, as in the case of the first embodiment.

In Figures 5 and 6, there is shown on a larger scale the plugs 30 and 24 for closing the openings 12 and 13 of the tubular plates 2 and 3 respectively, the plugs 30 and 24 having respective ends 30a and 24a freely engaged at inside the ends of the defective tube 4.

The sealing of the welded junction zones 29 and 28 which makes it possible to avoid any leakage of steam or water inside the steam generator in which the liquid sodium constituting the heat transfer fluid of the steam generator is ensured, in the extent that the welded areas do not show any defect.

When the plugs 24 and 30 have been fixed by welding to the nipples 15 and 14 of the steam generator, it is necessary to carry out a check on each of the welds 28 and 29. This check can be carried out either by ultrasound or by x-ray.

In Figure 7, there is shown a tubular plug 35 which can be constituted either by a lower plug such as the plug 24 shown in Figure 6, or by an upper plug such as the plug 30 shown in Figure 5, the plug 35 being associated with the lower part or the upper part of a defective tube 4 which has been plugged. FIG. 7 also shows the eight tubes 36 of the bundle of the steam generator surrounding the defective tube which has been plugged. The cross sections of the tubes 36 of the bundle of the steam generator are arranged in a square mesh network where each of the tubes is surrounded by eight tubes in neighboring arrangements. In the case where the control of the junction weld of the plug 35 must be carried out by radiography, a film 37 sensitive to X-rays is introduced inside the plug 35 at the weld connecting this plug to the corresponding nipple of the steam generator.

There is in each of the eight tubes 36 a source of radiation 38, so as to perform the radiography of the weld and of the zones of the plug and of the nipple adjacent to the welded zone, by transmission of the radiation produced by the sources 38 through the welding or the wall of the plug 35 or of the corresponding teat and by printing the sensitive film 37.

The film 37 is then extracted from the plug 35, developed and analyzed to determine the quality of the weld produced. We can thus guarantee the quality of the sealing welds of the plugs closing the defective tube.

The method according to the invention makes it possible to carry out, in a simple manner, an extremely efficient and extremely reliable plugging of a defective tube, while keeping the tube in place inside the steam generator.

This avoids modifying the thermohydraulic operation of the steam generator, in the vicinity of the defective tube.

In addition, the tube held in place in the steam generator can expand and retract freely by displacement in the axial direction relative to the plug.

The process according to the invention is not limited to the modes of implementation which have been described.

We can consider sequences of realization different operations for cutting and fixing the plugs different from those which have been described.

It is possible to carry out the cutting and the machining making it possible to eliminate the weld zones and part of the tube, in a different manner from that which has been described and by using a tool different from a milling cutter.

During the tube replacement operations, the interior space of the heat exchanger arranged around the bundle tubes can be filled with a protective gas of any kind, such as an inert gas or a neutral gas, making it possible in particular to protect the welding areas on their external side.

In the case of a steam generator whose primary fluid consists of a reactive liquid metal such as liquid sodium, filling the central part of the steam generator containing the liquid sodium during normal reactor operation, with a gas inert after draining the liquid sodium, avoids any risk of contacting an oxidizing gas with the sodium deposits which may remain in the central part of the steam generator.

Finally, the method according to the invention can be used to replace one or more tubes of a heat exchanger with straight or almost straight tubes different from a steam generator of a fast neutron nuclear reactor cooled by liquid sodium.

The process according to the invention applies to any heat exchanger with straight or almost straight tubes comprising two substantially parallel tubular plates spaced from one another and traversed by openings at the level of which the tubes are fixed at their ends.

Claims (7)

1.- Method for blocking a tube (4) of a heat exchanger with straight tubes comprising two tubular plates (2, 3) substantially parallel and spaced from each other, crossed by openings (12, 13) at the level of which the tubes (4) are fixed at their ends by welding on connection nozzles (14, 15), each of the tubes of the heat exchanger bundle being fixed at one of its ends on a first tap (14) of a first tubular plate (2) and at its other end, on a second tap (15) of a second tubular plate (13), characterized by the fact: - that the tube (4) is cut at its ends close to the first and second nozzles (14, 15) and that the metal is removed from the junction zones (16, 16 ') of the tube (4) at each of the taps (14, 15), from the inside of the tube (4) and through one or the other of the tubular plates (2, 3), - that the cutting and elimination of at least one section (20, 25) of the tube (4) adjacent to at least one of the taps (14, 15) is carried out, - Introducing, into each end of the tube (4) in place inside the heat exchanger, a plug (24, 30) of tubular shape whose diameter is less than the inside diameter of the tube (4 ), so that the plug has a closed end (24a, 30a) inside the tube (4) and an opposite end disposed inside the corresponding tap (14, 15), - that the plugs (24, 30) are fixed in place in the nozzles (14, 15) and that a continuous sealing weld is made between each of the plugs (24, 30) and the nozzle (14, 15) corresponding, inside each of the taps (14, 15), the tubes (4) having a certain latitude of movement in the longitudinal direction, with respect to the plugs (24, 30). 2.- Method according to claim 1, in the case where the inside diameter of at least one of the taps or second tap (15) and of the corresponding opening of the second tubular plate (3) is substantially greater than the outside diameter the tube (4) which is connected to the second tap (15), by a junction zone (16 ') of substantially frustoconical shape, characterized by the fact: - cutting and extracting a section (20) of the tube adjacent to the second tap (15) is carried out, - which is introduced through the opening (13) of the second tubular plate (3) opening into the second tap (15) a plug (24), so as to introduce the closed end (24a) of the plug (24) in the end of the cut-off tube adjacent to the second tap (15) and the plug (24) is fixed by welding points in the second tap (15), - that the tube (4) is cut in its junction zone (16) at the first connection (14) and that the material of the tube is removed in the junction zone (16) and along a section (25) the tube arranged in the extension of the junction zone (16), - that a plug (30) of tubular shape is introduced through the opening (12) of the first tubular plate (2), so that a closed end (30a) of the plug (30) is engaged inside of the free end (27) of the tube (4) remaining in place in the steam generator after the elimination of the section (25) and which is fixed by welding points, the plug (30) inside the first tap (14), - and that continuous and sealed annular welds are made, inside the taps (14, 15) ensuring the junction of the plug (24, 30) with the corresponding tap (15, 14). 3.- Method according to claim 1, in the case where the internal diameter of at least one of the taps, or second tap (15) and the corresponding opening (13) of the second tubular plate (3) is substantially greater than the outside diameter of the tube (4) which is connected to the second nozzle (15), by a junction zone (16 ') of substantially frustoconical shape, characterized by the fact: - that a section (20 ') of the tube (4) adjacent to the second tap (15) is cut and extracted, from inside the tube (4) and through the second tubular plate (3 ), - that the tube (4) is cut in the vicinity of the first tap (14) of the first tubular plate (2) and the elimination of the junction zone (16) between the first tap (14) and the end of the tube (4), - the tube (4) is moved in the axial direction inside the steam generator, in the direction of the second connection (15) of the second tube plate (3), - that a plug (30) of tubular shape is introduced through the opening (12) of the first tubular plate (2), so that a closed end (30a) of the plug (30) is introduced into the end (27) of the tube (4) adjacent to the first tap (14) which has previously been cut and moved and that the plug (30) is fixed inside the tap (14) by welding points, - a cut is made to length of the end of the tube (4) close to the second tap (15), - Introducing, through the opening (13) of the second tubular plate (3), a plug of tubular shape, so that a closed end (24a) of the plug (24) is freely introduced into the second end of tube which has been cut to length and that the plug (24) is fixed inside the second tap (15) by welding points, - And that continuous and sealed annular welds are made inside the first and second nozzles (14, 15), ensuring the junction of the plugs (24, 30) with the corresponding nozzles (15, 14). 4.- Method according to any one of claims 1, 2 and 3, characterized in that it establishes, around the tube (4), an atmosphere of neutral gas, during all operations of plugging the tube (4) , by plugs (24, 30). 5.- Method according to claim (4), in the case of a heat exchanger comprising a bundle of tubes (4) surrounded by an envelope (1) fixed to the tubular plates (2, 3), characterized in that the envelope (1) of the heat exchanger is filled with neutral gas during the operations of replacing a tube (4) of the bundle. 6.- Method according to any one of claims 1 to 5, characterized in that after having made the continuous welds (28, 29) between the plugs (24, 30) and the corresponding tappings (15, 14) , the radiographic control of the welds (28, 29) of each of the plugs (24, 30) is carried out, by introducing a film (37) inside the plug (24, 30), at the level of the weld (28, 29) and X-ray sources (36) in tubes (4) of the bundle of the steam generator arranged adjacent to the tubes (4) which have been plugged. 7.- Use of a method according to any one of claims 1 to 6, for plugging a tube (4) of a steam generator of a fast neutron nuclear reactor cooled by liquid sodium.

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