EP0122190A1 - Steam generator for a liquid metal-cooled reactor - Google Patents

Abstract

The invention relates to a steam generator for transferring heat conveyed by a liquid metal to a water-steam circuit. The generator includes a drain tank (126) suspended directly from the lower end of the casing (110). A drain pipe (130) connected to the bottom (110b) of the envelope is arranged inside the tank and carries a burst membrane (132) at its end. This membrane is placed behind a removable manhole (142, 142 ') fixed to the drain tank and authorizing its replacement. Application to nuclear reactors cooled by a liquid metal.

Description

The present invention relates to a steam generator intended in particular to ensure the heat exchange between the secondary circuit and the tertiary circuit of a nuclear reactor cooled by a liquid metal.

It is known that fast neutron nuclear reactors comprise at least two successive cooling circuits making it possible to convey as large a fraction as possible of the heat released by the fuel elements in the reactor core to the turbo-generators used to transform this heat into electrical energy. More precisely, the liquid metal, generally consisting of sodium, circulating in the primary circuit conveys the heat released in the core to heat exchangers in which part of this heat is transferred to a liquid metal, also consisting most often by sodium, circulating in the secondary circuit. This secondary circuit in turn allows this heat to be conveyed to steam generators in which it is used to vaporize water circulating in a tertiary circuit. The steam thus formed drives the turbo-alternators which are also arranged in the tertiary circuit.

The steam generators used to ensure the heat exchange between the primary fluid and the secondary fluid generally comprise a cylindrical envelope, of vertical axis, in which the sodium of the secondary circuit circulates between inlet and outlet pipes. The sodium is thus in contact with the tubes of a bundle of tubes arranged inside the envelope and in which the water of the tertiary circuit circulates.

Such a steam generator is shown schematically by way of example in FIG. 1, in which we can see in particular the cylindrical casing 10, the inlet tubes 12 of the secondary sodium preferably situated near the upper end of the 'casing 10 and the outlet pipe 14 of the secondary sodium which opens here in the bottom of the casing of the generator. The secondary sodium thus circulates from top to bottom inside the envelope 10, which constitutes the most favorable direction of flow since the formation of vapor in the tubes 16 of the bundle of tubes also shown in FIG. 1 requires practically a circulation of water from the bottom to the top inside these tubes. The tubes 16 pass through the envelope 10 of the steam generator to open, on the one hand, into one or more upstream collectors 18 arranged near the bottom of the envelope 10, and, on the other hand, into one or more collectors downstream 20 disposed slightly below the inlet tubes 12 of the secondary sodium. Inside the envelope 10, the tubes 16 are helically wound around a central core 22, so that they occupy the annular space defined between this core and the envelope 10. As illustrated also in FIG. 1, the core 22 extends to the outlet tube 14 for the secondary sodium, so that passages 24 must be formed in the lower part of the core 22 to allow the flow of the secondary sodium from the annular space formed between this core and the casing 10 up to the outlet pipe 14.

It is easy to understand that in a fast neutron nuclear reactor, steam generators are particularly sensitive components since it circulates both liquid sodium and water and the multiplicity of tubes This water necessary for the efficiency of the heat exchange increases all the more the risks of a sodium / water reaction inside the envelope of the generator.

To take this risk into account, it is customary to associate a steam generator with an installation allowing it to be drained quickly when an overpressure due to a sodium / water reaction appears in the generator. Currently, and as very diagrammatically illustrated in FIG. 1, such an installation comprises an auxiliary drain tank 26 resting on the ground 28 and a large diameter pipe 30 connecting the bottom of the envelope of the steam generator to the tank 26. This pipe 30 is normally closed by at least one burst membrane 32 sensitive to the pressure prevailing in the generator, to rupture when this pressure exceeds a determined threshold corresponding to the appearance of a sodium / water reaction in the generator. More specifically, it can be seen in FIG. 1 that the burst membrane 32 is disposed in the piping 30 near the bottom of the envelope 10. In these existing installations, the drain tank is of large capacity and is used to store all the sodium contained in the secondary circuit.

This structure of current installations is unsatisfactory for various reasons.

Firstly, differential expansions can appear in the piping 30. Given the large cross-section of these pipelines which is essential for rapid emptying of the steam generator in the event of a sodium / water reaction, it is uneconomical to compensate for these expansions by providing the expansion lyres pipes. Indeed, these lyres increase the length of the tubes and therefore increase the cost of installation. As a result, as illustrated in Figure 1 the pipes 30 are advantageously equipped with expansion bellows 34. However, we know that after a certain period of use, the mechanical strength of these bellows tends to deteriorate. The presence of these bellows therefore has the effect of introducing an additional risk from the point of view of safety.

In addition, when the burst membrane ruptured following a sodium / water reaction in the steam generator, it is necessary to replace this membrane before restarting the reactor. This membrane is also replaced during periodic maintenance visits. This operation is difficult in existing installations, due to the arrangement of the membrane in the piping.

In addition, although the diameter of the piping allows a relatively large sodium flow, the length of this piping is generally such that the time required to completely drain the generator is not as short as might be desired in overpressure conditions generated by a sodium / water reaction.

The present invention specifically relates to a steam generator comprising an integrated drain tank fulfilling the same function as the drain tank 26 of the installations of the prior art as shown in FIG. 1, while being of a particularly simple design and eliminating the aforementioned drawbacks of existing installations.

To this end and in accordance with the invention, a steam generator is proposed for a reactor cooled by a liquid metal, this generator comprising a cylindrical casing with a vertical axis, inlet and outlet pipes for a liquid metal in said envelope, a bundle of tubes arranged at the interior of the envelope and in which water circulates, and a drainage tube opening at the lower end of said envelope and comprising at least one bursting membrane capable of breaking when the pressure prevailing in said envelope exceeds a given threshold, to make the envelope communicate with a drain tank, characterized in that the drain tank is fixed directly to the lower end of said shell, the drain pipe being disposed inside the tank and carrying the bursting membrane at its end, behind a removable manhole fixed to the tank.

In a preferred embodiment of the invention, the emptying tank comprises a cylindrical neck extending downwards a cylindrical part of said casing and a container of larger section connected to the lower end of the cylindrical neck, the removable view being attached to the tank neck.

Preferably, the drainage tube then ends in a substantially horizontal part whose end carrying the bursting membrane is located in an opening formed in the neck of the tank and on which the removable manhole is fixed. The drain pipe can also include a substantially vertical part arranged along the axis of the envelope and connected by an elbow to the substantially horizontal part.

In accordance with a first embodiment of the invention, the removable manhole closes said opening, so that a rupture of the bursting membrane has the effect of emptying into the tank neck the liquid metal contained in the envelope .

According to a second alternative embodiment of the invention, the removable manhole has the form of a pipe fixed, on the one hand, to the opening formed in the tank neck and, on the other hand, to a second opening formed in the container, so that a rupture of the burst membrane has the effect of emptying the liquid metal contained in the envelope into the container. The second opening can in particular be formed in an upper wall of the container, the axes of said openings being arranged in the same plane passing through the axis of the envelope and substantially at right angles to one another, such so that the pipe formed by the gaze has the shape of an elbow.

In accordance with a secondary characteristic of the invention, the volume of the drain tank is substantially equal to the volume of the liquid metal contained in the envelope of the generator. In addition, means can be provided for emptying the emptying tank into a larger capacity tank.

• - la figure 1, déjà décrite, représente de façon schématique un générateur de vapeur équipé d'une installation de vidange séparée, conformément à la technique antérieure, et
• - la figure 2 représente à plus grande échelle et de façon également schématique l'extrémité inférieure d'un générateur de vapeur comprenant, conformément à l'invention, un réservoir de vidange intégré.

Two alternative embodiments of the invention will now be described, by way of non-limiting example, with reference to the appended drawings, in which:

• FIG. 1, already described, schematically represents a steam generator equipped with a separate emptying installation, in accordance with the prior art, and
• - Figure 2 shows on a larger scale and also schematically the lower end of a steam generator comprising, according to the invention, an integrated drain tank.

In FIG. 2, only the lower part of the steam generator according to the invention has been shown, since only this part differs from the steam generators currently known. In particular, the rest of the steam generator according to the invention can be made in the same way as the corresponding part of the steam generator described above with reference to Figure 1 to illustrate the state of the art.

However, it will be readily understood that many types of known steam generators could be modified in accordance with the invention, so that the latter should not be limited to the generator described above with reference to FIG. 1. In particular, the secondary sodium inlet and outlet pipes and the circulation thereof inside the envelope of the generator can be carried out in any manner known elsewhere, without departing from the scope of the invention. The same is true of the location occupied by the bundle of tubes in the generator and the shape given to the bundle tubes.

We recognize in Figure 2 the cylindrical envelope 110, of vertical axis, of the steam generator. This envelope comprises in known manner a dome (not shown, a cylindrical part 110a and a bottom 110b. We also recognize the upstream collectors 118 and the bundle of tubes 116 arranged inside the steam generator, in the annular space defined between the cylindrical part 110a of the envelope and the central core 122.

According to the invention, the drain tank 126 is fixed directly to the lower end of the casing 110 of the steam generator. More specifically, the reservoir 126 comprises a neck 138 in the form of a ferrule and a container 140 constituting the reservoir itself. The neck 138 is cylindrical, of the same diameter as the part 110a of the envelope and of axis coincident with the vertical axis of the latter. Its upper edge is fixed to the casing 110 by a weld 136, so that it extends downwards the cylindrical part 110a and supports at its lower end the container 140. As illustrated in FIG. 2, the latter is of larger section than the neck 138. It defines an upper wall 140a by which it is connected to the neck 138, a side wall 140b which can be at will cylindrical or of any other shape and a bottom 140c.

The connection between the interior of the envelope 110 and the reservoir 126 is carried out by means of a drainage tube 130 disposed in the neck 138 of the reservoir. The upper end of the tube 130 opens into the bottom 110b of the envelope of the steam generator, the lower end carrying a burst membrane 132.

More specifically, it can be seen in FIG. 2 that the tubing 130 is connected to the bottom 110b of the generator casing by a substantially vertical part 130a arranged coaxially with the cylindrical part 110a and at the neck 138 of the reservoir. The burst membrane 132 is mounted at the end of a substantially horizontal part 130b of the drain pipe. The parts 130a and 130b are connected by an elbow 130c. The length of the substantially vertical part 130a is less than the height of the neck 138 and the length of the substantially horizontal part 130b is close to the radius of the neck 138, so that the membrane 132 is housed in an opening 141 formed in the lower part of tank neck 126.

According to a first alternative embodiment of the invention shown in solid lines in FIG. 2, a removable manhole 142 in the form of a pipe is fixed, on the one hand, to a flange 144 surrounding the opening 141 and, on the other hand hand, on a bridle 146 surrounding an opening 148 formed in the upper wall 140a of the container 140. This fixing is carried out in leaktight manner by any known means such as screws or bolts.

More precisely, the axes of the openings 141 and 148 being respectively horizontal and vertical and arranged in the same plane passing through the vertical axis common to the envelope 110 of the steam generator and to the neck 138, the manhole 142 in the form of pipe has the shape of an elbow which extends the drain pipe 130.

The pipe formed by the sight glass 142 thus makes it possible, after rupture of the burst membrane 132, to cause the liquid sodium contained in the envelope 110 of the steam generator to flow directly into the container 140 of the drain tank.

In the second variant embodiment of the invention shown in broken lines in FIG. 2, the manhole 142 ′ behind which the burst membrane 132 is placed consists of a plug closing the opening 141. This plug can in particular be fixed on the flange 144 by screws or by bolts like the sight 142 in the previous variant. In this case, the liquid sodium which flows from the steam generator after bursting of the membrane 132 is discharged through the plug 142 'into the neck 138 of the tank, before going down into the container 140. Of course, so that this circulation is possible, the plug 142 ′ is placed at a certain distance from the membrane 132 and the diameter of the opening 141 is substantially greater than the diameter of the tube 130.

Given the location of the tubing 130 in place of the secondary sodium outlet tubing in the steam generator shown in Figure 1, the location of this tubing must be changed. Thus, the outlet pipe 114 can in particular be disposed laterally at the lower end of the cylindrical part 110a of the generator casing, as shown in FIG. 2. The core 122 is then closed at its lower end , arranged at a certain distance from the bottom 110b.

As already mentioned above, this provision is given for information only. Thus the tubing 130 opening into the bottom 110b of the envelope could be eccentric, so as to allow the implantation of the outlet tubing 114 in the bottom of the generator. The outlet pipe 114 would then pass through the neck 138 of the drain tank. Conversely, one could also install the outlet tube 114 for the secondary sodium at the upper end of the steam generator, the sodium then rising inside a chimney replacing the core 122.

In accordance with a secondary characteristic of the invention, it will be noted that the volume of the storage tank 126 is just sufficient to collect the secondary sodium contained in the steam generator after rupture of the burst membrane 132. This characteristic also distinguishes the invention of the prior art according to which the storage tank used to drain the entire secondary circuit of the reactor is used as the drainage tank and whose volume is substantially greater than the volume of the tank 126.

Preferably, the bottom of the drain tank 126 communicates with a larger volume storage tank (not shown) common to several steam generators. This communication can in particular be carried out by means of a pipe 150 equipped with a valve 152 and pumping means (not shown). The pipe 150 plunges at one end into the bottom of the tank 126, as shown in FIG. 2. Since the transfer of the liquid sodium between the drain tank 126 and the storage tank does not need to be carried out quickly , the pipe 150 is of small diameter, so that the differential expansions can be easily compensated for by providing it with expansion lyres.

When the reservoir 126 has been drained by the line 150, it becomes possible to replace the membrane 132 by removing the sight glass 142 or 142 '. Indeed, for obvious safety reasons, this intervention must be carried out without a direct view of sodium. It can also be seen in FIG. 2 that a pipe 154 fitted with a normally closed valve 156 makes it possible to communicate the interior of the envelope 110 of the steam generator with the reservoir 126. This pipe 154 allows, when necessary and apart from any rupture of the burst membrane 132, to drain the sodium contained in the envelope of the steam generator inside the drain tank 126, after opening the valve 156.

Finally, FIG. 2 shows the pipes 158 opening into the drain tank 126. These pipes are used, when a sodium / water reaction occurs inside the casing. eg from the generator, to evacuate the gaseous products formed by this reaction, such as hydrogen or sodium aerosols. These pipes are connected by their opposite end to separators (not shown).

Thanks to the characteristics of the invention which have just been described with reference to FIG. 2, it is understood that the problems posed by the installations of the prior art are resolved. In particular, safety is improved since the expansion bellows are eliminated. In addition, we see that the particular arrangement of the burst membrane 132 allows a particularly easy replacement thereof. In addition, the tubing 130 ensuring the flow of liquid sodium from the steam generator to the drain tank is substantially shorter than the connection piping according to the prior art, so that the speed of the drain is thereby finds significantly increased. Finally, mounting the tank on the steam generator is particularly simple and even allows the installation of this tank on existing generators.

Claims (10)

1. Steam generator for a reactor cooled by a liquid metal, this generator comprising a cylindrical envelope (110) with a vertical axis, inlet and outlet pipes (114) of a liquid metal in said envelope, a bundle of tubes (116) disposed inside the envelope and in which water circulates, and a drain pipe (130) opening at the lower end of said envelope and comprising at least one burst membrane ( 132) able to rupture when the pressure prevailing in said envelope exceeds a given threshold, to make the envelope communicate with a drain tank (126), characterized in that the drain tank (126) is fixed directly to the lower end of said casing, the drain pipe (130) being disposed inside the tank and carrying the burst membrane (132) at its end, behind a removable manhole (142, 142 ') fixed to the tank. 2. Steam generator according to claim 1, characterized in that the drain tank (130) comprises a cylindrical neck (138) extending downwards a cylindrical part (110a) of said envelope, and a container (140) more large section connected to the lower end of the cylindrical neck, the removable manhole (142, 142 ') being fixed to the neck of the tank. 3. Steam generator according to claim 2, characterized in that the drain pipe (130) ends in a substantially horizontal part (130b) whose end carrying the burst membrane (132) is located in an opening ( 141) formed in the neck (138) of the tank and on which is fixed the removable manhole (142, 142 '). 4. Steam generator according to claim 3, characterized in that the drain pipe (130) comprises a substantially vertical part (130a) disposed along the axis of the envelope (110) and connected by an elbow (130c) to the substantially horizontal part (130b). 5. Steam generator according to any one of claims 3 and 4, characterized in that the removable manhole (142 ') closes said opening (141), so that a rupture of the burst membrane (132) has the effect of emptying into the neck (138) of the tank the liquid metal contained in the envelope (110). 6. Steam generator according to any one _- that of claims 3 and 4, characterized in that the removable manhole (142) has the shape of a pipe fixed, on the one hand, on the opening (141) formed in the neck (138) of the reservoir and, on the other hand, on a second opening (148) formed in the container (140), so that a rupture of the burst membrane (132) has the effect of drain the liquid metal contained in the envelope into the container (140), through said pipe. 7. Steam generator according to claim 6, characterized in that the second opening (148) is formed in an upper wall of the container (140), the axes of said openings (141, 148) being arranged in the same plane passing through the 'axis of the envelope (110) and substantially at right angles to each other, so that the pipe formed by the manhole (142) has the shape of a bend. 8. Steam generator according to any one that of the preceding claims, characterized in that the volume of the drain tank (126) is substantially equal to the volume of the liquid metal contained in the casing (110) of the generator. 9. Steam generator according to any one of the preceding claims, characterized in that means (150) are provided for emptying the drain tank (126) in a larger capacity tank. 10. Drain generator according to any one of the preceding claims, characterized in that a drain pipe (154) normally closed by at least one valve (156) directly communicates the drain tank (126) with the interior of the envelope (110).

Images