EP0955498A1 - Steam generator having an improved water feeding device - Google Patents

Abstract

The steam generator has a cylindrical outer shell (2), a coaxial inner shell (4) containing a core of heat exchange tubes, and an annular gap (9), containing a toroid collector (12), for the circulation of feed water. The collector has an upper wall pierced by a series of holes (18) and a guide (14) in the form of an envelope surrounding the collector. This forms a water flow space with radial partitions (19a) between the collector and guide.

Description

The invention relates to a steam generator and in particular a steam generator of a pressurized water nuclear reactor comprising an improved water supply device.

Steam generators such as steam generators of nuclear reactors cooled by pressurized water have an outer casing of generally cylindrical shape arranged vertically in the nuclear reactor building, i.e. with the axis of the vertical outer shell.

The steam generators of pressurized water nuclear reactors make it possible to heat and vaporize feed water, by heat exchange with the pressurized cooling water of the nuclear reactor which circulates inside tubes of an exchange bundle. The tube bundle is arranged inside a generally cylindrical bundle envelope which is arranged coaxially inside the external envelope.

The bundle tubes are fixed at their ends in a tubular plate, so that they open at a first end, in a first part of a steam generator water box and, at a second end, in a second part of the steam generator water box. The steam generator water box distributes the pressurized water from the nuclear reactor vessel in which the core made up of fuel assemblies is placed and collects the pressurized water that has circulated inside the exchange tubes, to return the pressurized water recovered in the nuclear reactor vessel.

Steam generator feed water is introduced into the external envelope and channeled, so as to reach, in an inlet part of the exchange bundle, the lower part of the bundle and of the bundle envelope . The feed water then flows from bottom to top inside the bundle envelope, in contact with the external surface of the tubes, so that it heats up then vaporizes and is found in the form of steam in the upper part of the outer casing of the steam generator. The vapor recovered in the upper part of the steam generator is sent to the reactor turbine.

The supply water is generally introduced into the upper part of an annular space formed between the envelope of the tube bundle and the external envelope or between the envelope of the bundle and a skirt delimiting a circulation space communicating with a end portion of the bundle formed by the ends of the cold branches of the tubes, that is to say of the branches of the tubes through which the cooling water comes out of the reactor used for heating and vaporizing the feed water.

By using a supply space delimited by a skirt, the supply water is preheated by circulation in contact with the bundle envelope and in contact with the cold branches of the tubes which are separated from the hot branches by a wall. vertical separation of diametral direction, over part of the beam height.

In all cases, the feed water introduced into the envelope of the steam generator circulates from top to bottom in an annular space of vertical axial direction, up to the lower part of the bundle envelope.

To obtain a good output from the steam generator and satisfactory operating conditions, it is necessary to distribute the feed water flow, in the circumferential direction of the annular supply space of the steam generator.

For this, it has been proposed to use a manifold of generally toroidal shape which is disposed inside the external envelope of the steam generator, perpendicular to the upper part of the annular water supply space. . The collector is connected to a water supply pipe passing through the external envelope of the steam generator and comprises means for distributing and guiding the supply water distributed in the circumferential direction of the annular supply space. in water. The means for distributing and guiding the supply water can be constituted by inverted J-shaped tubes whose vertical straight branch is fixed to the collector and whose loop is directed downwards, in the direction of the part upper annular supply space. The distribution in the circumferential direction and the flow through each of the J-shaped tubes provides a satisfactory distribution of the feed water in the circumferential direction of the annular space. However, this device has the drawback that the jets leaving the J-shaped tubes have high speeds, which disturbs the flow of water going towards the annular supply space.

It has also been proposed to adapt this supply device to the case of preheating steam generators comprising an economizer constituted by a skirt for guiding the supply water communicating with the end of the cold branches of the bundle tubes. In this case, the guide skirt which has the shape of a cylindrical sector delimits with the beam envelope, an annular space extending over an arc of a circle of less than 180 ° around the beam envelope of the generator. steam. The collector is then constituted by a portion of torus extending over less than 180 ° around the bundle envelope, directly above the upper part of the annular supply space. This device has the same drawbacks as the device, the collector of which consists of a complete toric envelope completely surrounding the bundle envelope, since the distribution of the feed water at the outlet of the collector is also ensured by tubes. J-shaped. It has been proposed to extend the J-shaped tubes in the vertical direction, in the annular water supply space. This arrangement does not, however, completely solve the turbulence problems and complicates the mechanical design of the steam generator, because of the length of the outlet branches of the J-shaped tubes.

It has been proposed, in French patent FR-2,700,383 (EP-0.607.071) to produce the water supply collector in the form of a weir constituted by a gutter having the general shape of a torus open to its upper part or a portion of open torus, with which guide walls of the feed water directed downward, in the upper part of the annular space. The supply water is brought inside the collector by a supply line passing through the external envelope of the steam generator and opening into the collector. The supply water fills the gutter-shaped collector, up to level of a discharge edge above which the supply water flows in a flow space delimited by the guide walls. The weir provides a certain distribution of the flow of feed water along the circumference of the annular space, but it is very difficult to determine precisely what this distribution will be, depending on the supply conditions of the weir.

Another drawback of the device comprising a weir is that it is not easy to ensure satisfactory mechanical strength of the weir, during high mechanical stresses, of the type water hammer, or in an accidental situation, in the event of a break in the drinking water piping. It is therefore necessary to design elements constituting the dispensing device which are extremely resistant and which are made from very thick sheets.

The object of the invention is therefore to propose a steam generator comprising an outer casing of generally cylindrical shape arranged with its vertical axis, a bundle of exchange tubes fixed inside a bundle casing of generally cylindrical shape arranged coaxially inside the external envelope, so as to delimit with the external envelope or with a guide skirt coaxial with the external envelope, an annular space for circulation of water supplying the steam generator in the axial direction and a device for supplying feed water to an upper axial end of the annular space comprising a generally toroidal manifold disposed along at least part of the circumference of the annular space, at least one pipe supplying the collector passing through the outer casing and means for guiding the supplying water downwards, in the direction of the annular space, the device tif supply of supply water ensuring a perfectly controlled regular supply of the annular space and with a well-defined circumferential distribution, while being of a mechanical structure allowing it to resist jolts of the supply in water.

For this purpose, the toroidal manifold has an upper wall crossed by a plurality of flow openings distributed along the circumferential direction of the collector and the means for guiding the supply water comprise an envelope disposed around at least part of the collector, so as to delimit with the collector a space for flow of water, at least one guide wall extending the casing downwards and a plurality of radial direction partition walls dividing the water flow space into a plurality of successive sections in the circumferential direction of the manifold.

In order to clearly understand the invention, there will now be described by way of example, with reference to the attached figures, an embodiment of a steam generator according to the invention.

Figure 1 is an elevational view in partial section through a vertical plane of a steam generator according to the invention.

FIG. 2 is a half-view in section through a horizontal plane of the steam generator, along 2-2 of FIG. 1.

Figure 3 is a sectional view along 3-3 of Figure 2.

Figure 4 is a sectional view along 4-4 of Figure 2.

Figure 5 is a sectional view along 5-5 of Figure 2.

Figure 6 is a sectional view along 6-6 of Figure 2.

FIG. 7 is a sectional view along 7-7 of FIG. 6.

In FIG. 1, we see a steam generator of a pressurized water nuclear reactor generally designated by the reference 1.

The steam generator 1 comprises an outer casing 2 of generally cylindrical shape comprising a lower part having a first diameter and an upper part having a second diameter greater than the first diameter, the two parts of the external casing being connected together by a ferrule frustoconical 2a.

When it is in service in the nuclear reactor building, the steam generator is arranged vertically, that is to say in such a way that the axis of the external envelope 2 is vertical.

The steam generator 1 comprises a bundle of heat exchange tubes 3 disposed inside a bundle casing 4 of generally cylindrical shape placed coaxially inside the outer casing 2 of the steam generator.

The bundle of tubes 3 consists of curved tubes having the shape of an inverted U, the straight branches of which are fixed at their ends in a tubular plate 5 integral with the external envelope 2.

Below the tubular plate 5 traversed by the tubes of the bundle 3, is arranged a water box 6 of hemispherical shape comprising two compartments 6a and 6b separated from one another by a partition.

Pressurized water for cooling the reactor coming from the vessel containing the nuclear reactor core is introduced into compartment 6a and distributed in the branches of the tubes of bundle 3 opening into compartment 6a, these branches constituting the hot branches of the bundle 3.

The pressurized water for cooling the reactor circulates inside the tubes of the bundle to reach compartment 6b of the water box into which the cold branches of the tubes of the bundle 3 open. The cooling water having circulated in the bundle 3 tubes is returned to the nuclear reactor vessel.

A separation plate 7 between the lower parts of the hot branches and cold branches of the tubes of the bundle 3 is arranged vertically between the branches of the bundle and fixed at its lower part to the tubular plate 5, in a diametrical direction of the tubular plate.

Between the bundle envelope 4 and the external envelope 2 of the steam generator arranged coaxially with respect to one another, a supply water guide skirt 8 having the shape of a cylindrical sector is placed. with an amplitude of about 180 ° in the circumferential direction. The upper part 8a of the skirt 8 is flared upwards and has the shape of a frustoconical sector.

The lower end of the skirt 8 is in contact with the upper face of the tube plate 5.

Between the bundle casing 4 and the guide skirt 8 of the steam generator feed water is provided an annular space 9 for circulation of the steam generator feed water. The annular space 9 for circulating feed water in an axial direction is closed at its lower part by the tubular plate 5.

The lower end of the bundle envelope 4 is arranged at a certain height above the upper face of the tube plate 5, so that the space for circulation of feed water 9 communicates with the part of the bundle casing 4 enclosing the lower ends of the cold branches of the bundle tubes 3, delimited by the vertical separation plate 7.

In the upper part of the annular space 9 for circulating feed water, between the frustoconical part 8a of the skirt 8 and the bundle casing 4, is placed a device 10 for supplying and distributing water d 'supply ensuring the introduction of a stream of feed water to the steam generator which is distributed in the circumferential direction of the annular space 9 surrounding part of the bundle envelope 4.

The device 10 for introducing and distributing feed water, which is produced in accordance with the invention, will be described below.

The feed water introduced into the upper part of the annular space 9 flows from top to bottom, in the vertical direction, that is to say in the axial direction of the steam generator, up to the upper face. of the tubular plate 5 constituting the lower end of the annular space 9. The feed water then enters the bundle envelope 4, to come into contact with the lower end part of the cold branches of the tubes of the bundle 3. The feed water is preheated during its circulation in the annular space and in contact with the end parts of the cold branches in which circulates the cooling water of the reactor which is collected in compartment 6b of the box water.

The steam generator feed water arriving at the upper edge of the separation plate 7 comes into contact with the hot branches of the tubes of the bundle 3 in which the water under cooling pressure circulates coming from the reactor vessel . Contact with the hot branches and the upper part of the cold branches of the bundle produces additional heating of the feed water which rises inside the bundle, while heating and vaporizing.

The vapor formed from the heated feed water in contact with the bundle leaves the bundle envelope through its upper part and enters in the upper large-diameter part of the outer casing 2 of the steam generator in which steam separators and dryers are arranged.

The dried steam is sent to the turbine associated with the nuclear reactor via a pipe connected to the pipe 11 constituting the upper part of the external envelope 2 of the steam generator.

The feed water introduction and distribution device 10 must ensure satisfactory distribution of the feed water in the circumferential direction of the annular space 9.

In Figure 2, there is shown a device 10 for introducing and distributing water according to the invention which mainly comprises a collector 12 having the shape of a torus portion extending over an arc of a circle slightly less than 180 °, a conduit 13 for introducing feed water into the manifold 12 and an assembly 14 in two parts for guiding the feed water downwards, in the direction of the annular space 9 delimited between the skirt 8 and the bundle envelope 4 of the steam generator.

The conduit 13 for introducing feed water is connected on the one hand to a pipe 15 for crossing the external envelope of the steam generator and on the other hand to a central section 16 of the manifold 12 in the form of a portion torus. The manifold 12 is constituted by a portion of large diameter toroidal pipe fixed by means of supports 17 on the internal surface of the external envelope 2 of the steam generator, above the part 8a of the shaped skirt 8 of frustoconical sector.

The manifold 12, in the form of a torus portion, comprises, in the upper part of its wall, openings 18, the centers of which are aligned on a circle centered on the axis of the steam generator common to the external envelope 2, at the bundle envelope 4 and at the manifold 12. Most generally, the successive openings 18 whose sections can be differentiated are spaced from each other by a substantially constant distance, so as to allow a homogeneous distribution of feed water in the circumferential direction of the collector 12 in the form of a torus portion.

Of course, depending on the desired distribution of water in the circumferential direction of the manifold and the annular space 9, it is possible to provide openings 18 whose dimensions and distributions are adapted to the particular distribution of feed water to be obtained. . This is true even when one wishes to obtain a homogeneous distribution.

As can be seen in FIGS. 3 and 4, each of the two parts of the guide device 14 for the feed water has an external wall 14a comprising a part in the form of a torus portion, the cross section of which corresponds substantially to a quarter of circular section and a frusto-conical part extending downwards the toric part, substantially parallel to the frusto-conical part 8a of the skirt 8. The guide device 14 further comprises an internal part 14b of cylindrical shape located opposite the frustoconical lower part of the external wall 14a of the guide device. The two parts 14a and 14b of the guide device are fixed to the manifold 12. The openings 18 passing through the upper wall of the toric manifold 12 open into a space 20 for water flow delimited between the surface of the manifold 12 and the toric part 14a of the guide device arranged around the wall of the manifold 12.

The guide assembly 14 is placed in a coaxial arrangement with respect to the manifold 12 and the steam generator. The flow space 20, delimited between two parallel toric surface portions, has a tubular and annular shape. The space 20 opens into a space for the outlet of the supply water delimited between the external frustoconical part 14a and the internal cylindrical part 14b of the guide device 14. The fluid outlet space itself emerges vertically of the annular space 9 for supplying the steam generator.

As can be seen in Figures 2 and 4, the two portions of the guide device 14 are each separated into several successive sections (three sections 26a, 26b and 26c in the case shown in Figures 2 and 4) by radial walls such as 19a, 19b, 19c and 19d.

The walls 19b and 19c are walls separating two successive sectors of the guide device and the walls 19a and 19d are walls for closing the ends of the portion of the guide device 14. The two portions of guide device 14 disposed symmetrically with respect to the supply conduit 13 of the manifold 12 are produced in the same way.

It can be seen in FIG. 4 that the partition wall 19c has the shape of the section of the flow and outlet spaces of the feed water of the guide device. The walls such as 19c are welded to the walls of the guide device.

As can be seen in FIG. 5, the conduit 13 for supplying the collector 12 connected to the central section 16 of the collector opens into the collector, below the upper part of the collector comprising the openings 18, so as to ensure the supply of supply water to the collector 12. As can be seen in FIG. 2, two filtration devices 21a and 21b are placed on the central section of the collector on either side of the connection zone of the supply conduit 13. The two filtration devices 21a and 21b are produced in an identical manner, so that only the filtration device 21b described in FIGS. 5, 6 and 7 will be described.

The filtration devices are mounted on the upper part of the manifold 12, at the level of openings cut in the wall of the toroidal manifold whose shape corresponds to the section of a cylinder with the toric surface of the manifold. The filtration device 21b comprises a support structure consisting of a cylindrical wall 23 comprising a peripheral flange 22 which comes to rest on the O-ring manifold 12, in a coaxial arrangement relative to an opening passing through the wall of the O-ring manifold.

The filtration element of the filtration device consists of a flat lattice plate 24 held in the envelope of the O-ring manifold 12, at the level of the opening through which the cylindrical wall 23 of the support structure is placed. The means for holding the flat plate 24 of the filtration element comprise a guide rail of substantially semi-circular shape fixed on the internal surface of the O-ring wall and a closure pad 25 having a circular outline and having a diametrical slot in which is engaged the upper edge of the plate 24. The closure pad 25 has a peripheral flange allowing its fixing by screws on the peripheral flange 22 of the support assembly. In addition, the pad 25 has a shape such that it fills the interior volume of the cylindrical wall 23 of the support assembly, in order to avoid the presence of a dead volume in the upper part of the support assembly. The filtration plate 24 has a semi-circular end portion whose shape and size correspond to the half-section of the torus 12.

When the filtration device 21b is placed on the upper part of the torus, at a through opening, the filtration plate 24 penetrates inside the torus, so as to completely close the meridian section of the torus, as shown in Figures 5 and 6.

In this way, the feed water introduced through the feed pipe 13, which enters the central section 16 of the manifold 12, must pass through the filtration walls 24 of the filtration devices 21a and 21b before filling the two parts. distribution manifold located on either side of the central section 16. In this way, the feed water is filtered, so that the migrant bodies possibly contained in the feed water are stopped in the central space for introduction of the collector and cannot be entrained in the two distribution parts of the collector and in the annular space 9 for supplying the steam generator.

The feed water filling the two distribution parts of the torus on either side of the central section 16 flows through the upper openings 18 of the manifold 12, into the flow space 20 and then into the space of outlet located in the extension of the flow space 20. The supply water is thus guided downward, towards the annular space 9 supplying the steam generator.

The device according to the invention makes it possible to obtain both an optimal distribution of the feed water in the circumferential direction of the annular feed space of the steam generator and a flow whose turbulence is very limited to the outlet of the supply device due to the distribution of water through openings passing through the toroidal casing of the manifold at its upper part and the presence of the segmented guide device.

In addition, the mechanical strength of the collector consisting of a closed O-ring is better than the mechanical strength of a gutter-shaped weir.

It also avoids any risk of vortex formation at the outlet of the supply device, in the annular space of the steam generator.

The water passage openings of the O-ring manifold are made so as to avoid any risk of flooding of the O-ring manifold, in the event of a drop in level in the steam generator which would result in an accumulation of steam in the upper part of the O-ring manifold . Such an accumulation of steam would be detrimental, when the food water supply installation is put back into operation, after a shutdown period.

The design of the guide device in the form of successive sectors separated by radial separation plates makes it easier to produce this guide device. The presence of radial separation plates makes it possible to create successive feed water streams in the circumferential direction and contributes to better stability of the flow. The presence of separate sectors also makes it possible to maintain at the outlet of each of the elementary sectors the same flow distribution as that existing at the outlet of the openings of the collector.

The dimension of the mesh of the trellis or of the grid constituting the filtration element 24 is chosen so as to retain the migrant bodies having a dimension greater than a predetermined dimension. Preferably, the predetermined dimension is less than the distance between the tubes of the bundle of the steam generator, in order to avoid that migrant bodies coming from the secondary circuit do not get caught between the tubes of the bundle and do not risk damaging them. .

To improve the filtration power of the lattice or grate, it is possible to place a wire mesh on the upstream face of the grate or lattice, that is to say on the face of the grate or lattice facing towards supply water supply.

The use of two filtration grids placed on either side of the central supply zone of the collector has the advantage that the two grids each ensure only the filtration of half of the supply water flow supplied to the steam generator, which reduces the pressure drop compared to a single grid. On the other hand, the arrangement of the filtration element inside the steam generator allows the support assembly 22, 23 and the buffer 25 for closing the filtration element to work under low pressure, a small leak which can appear at the level of the flange presenting no harmful consequence, owing to the fact that the water supplying the leak then falls directly into the annular space supplying the steam generator.

The invention is not limited to the embodiment which has been described.

It is thus possible to imagine devices for supplying feed water to the steam generator having a shape different from that which has been described.

In particular, the collector may have a shape and a structure different from those which have been described.

In the case of a steam generator with preheating of the type described, the collector has the shape of a portion of torus whereas in the case of a steam generator not using preheating, the collector can have the shape a complete torus placed above the steam generator supply space, around its entire circumference.

The arrangement and size of the manifold feed water outlet openings may be different from those which have been described.

The guide device can also have a shape different from the shape described and can be made in one piece or in the form of several successive sections. Likewise, the distribution of the radial partition walls in the circumferential direction of the guide device can be arbitrary.

The invention applies to any steam generator comprising an annular space for circulation of feed water and a device for supplying feed water to an upper axial end of the annular space for circulation of water d 'food.

Claims (6)

Steam generator comprising an outer casing (2) of generally cylindrical shape arranged with its vertical axis, a bundle of exchange tubes (3) fixed inside a bundle casing (4) of generally cylindrical shape arranged coaxially inside the external envelope (2) so as to delimit with the external envelope (2) or a guide skirt (8) coaxial with the external envelope (2), an annular space (9) for circulation steam generator feed water (1), in the axial direction and a feed water supply device (10) to an upper axial end of the annular space (9) comprising a manifold (12 ) of generally toroidal shape disposed along at least part of the circumference of the annular space (9), at least one supply line (13) of the collector (12) passing through the external envelope (2) and means of guide (14) of the feed water downwards towards space annular (9), characterized in that the toroidal manifold (12) has an upper wall crossed by a plurality of flow openings (18) distributed in the circumferential direction of the manifold (12), and that the means for guiding (14) the supply water comprise an envelope (14a) disposed around at least part of the collector (12) so as to delimit with the collector a space (20) for water flow, at least one guide wall extending the casing (14a) downwards and a plurality of partition walls (19a, 19b, 19c, 19d) in radial direction, separating the space (20) for water flow in a plurality of successive sections (14a, 14b, 14c, 14d) in the circumferential direction of the manifold (12). Steam generator according to claim 1, characterized in that the guide means (14) of the feed water further comprises a cylindrical wall (14b) disposed opposite the guide wall, towards inside the steam generator, extending the casing (14a) downwards. Preheating steam generator according to any one of claims 1 and 2, comprising a skirt (8) for guiding supply water coaxial with the external envelope (2) and with the bundle envelope (4) of the steam generator, disposed between the external envelope (2) and the bundle envelope (4), delimiting with the bundle envelope (4) the annular space (9) for circulation of feed water, on part of the periphery of the bundle envelope (4), characterized in that the collector (12) is constituted by a portion of torus disposed above the annular space for circulation of feed water. Steam generator according to claim 3, characterized in that the annular supply space (9), the collector (12) and the means (14) for guiding the supply water extend over an arc of circle slightly less than 180 °. Steam generator according to either of Claims 3 and 4, characterized in that the supply line (13) of the collector (12) is fixed to a median section (16) of the collector, so as to introduce l feed water in the central section (16) of the manifold (12), the feed water then being distributed in two parts of the water distribution of the manifold (12) located on either side of the central section (16). Steam generator according to claim 5, characterized in that two filtration devices (21a, 21b) are arranged in the central section (16) of the manifold (12) on either side of the pipe connection zone supply (13) with the central section (16) of the manifold (12).

Images