FR2628254A1 - Limiting intensity of parasitic water jets through baffle of PWR - Google Patents

Abstract

A device that partially blocks the openings in those reinforcing plates below the upper reinforcement is introduced through the opening in the upper reinforcement during a reactor shut down. The obstructing device remains in place in the reactor after restart, allowing the pressure drop of the coolant circulating in the annular space between the baffle and the core barrel to be controlled. Pref. the device consists of a shaft engaged in a series of openings in the reinforcements aligned in a vertifical direction.

Description

 The invention relates to a method and a device for limiting the intensity of parasitic jets of cooling water in a pressurized water nuclear reactor in service.

 Pressurized water nuclear reactors generally comprise a core constituted by combustible assemblies of prismatic shape arranged vertically and juxtaposed. The core is placed inside the nuclear reactor vessel through which the reactor cooling water circulates. The heart is surrounded by a partition which closely follows the shape of its peripheral surface and ensures its maintenance inside a heart envelope of cylindrical shape with vertical axis. The partition comprises vertical plates placed at right angles to each other. compared to the others and reproducing the external shape of the heart as well as reinforcements constituted by horizontal plates arranged at regular intervals according to the height of the heart. in an annular space formed between the periphery of the heart and the interior surface of the heart envelope.

 In the most common type pressurized water nuclear reactors built until the early 1970s. Cooling water penetrates into the core shell through one or more orifices provided in its upper part and circulates from top to bottom in the annular space surrounding the core, the horizontal reinforcement plates of the partitioning being pierced with the exclusion of the plate located at the highest point and disposed above the orifice of the courtyard envelope, which constitutes the reinforcement superior. The cooling water circulates inside the heart in the vertical direction and from bottom to top. On either side of the partitioning, the cooling water therefore flows in opposite directions.

On the other hand, this circulating cooling water undergoes pressure drops. in particular inside the core assemblies, at the level of the spacer plates ensuring the maintenance of the fuel rods. There is therefore a difference of almost
ion 'n on either side of the vertical plates of the partitioning which cancels out in the lower part of the heart where the current of cooling water enters the heart and which is maximum at the upper part of the heart, the water circulating cooling having then undergone the maximum pressure drop.

 The vertical partitions plates are also reported at right angles to each other, without the junction area being sealed. I1 therefore generally remains a gap between two successive partitioning plates, this gap placing in communication the annular space at the periphery of the partitioning, with the core disposed inside the partitioning.

 Due to the pressure difference existing between the two sides of the vertical walls of the partitioning, parasitic cooling water jets appear when the nuclear reactor is in service. These parasitic water jets are directed in the direction going from the annular space around the partitioning towards the interior of the core and are likely to strike the fuel rods of the assemblies arranged near the connection zones of the partitions. These jets cause vibrations of the rods which are detrimental to their good performance in service.

 In more recent design nuclear reactors. attempts have been made to reduce or eliminate these parasitic jets, by reducing or canceling the differential pressure on either side of the partition or even making this difference in pressure negative.

 For this, we slightly modified the structure and the design of the core envelope and the partitioning to obtain a circulation of the cooling water of the reactor directed from bottom to top, both in the core and in the annular space. located at the periphery of the partitioning. The core envelope has no orifice at its upper part and the horizontal upper reinforcement of the partition is pierced to allow the passage of cooling water to the upper part of the annular space. The horizontal reinforcements of the partition are arranged in coincidence with the spacer plates of the core assemblies and these reinforcements are drilled so that the cooling water circulating in the annular space undergoes a pressure drop when the reinforcements pass equivalent to the pressure drop undergone by the water circulating in the core, in the passage of the spacer plates of the assemblies.

 In the case of nuclear reactors of older design which have been put into service and used according to the principle of the circulation of cooling water against the current on either side of the partitioning, provision has been made for intervention allowing circulate the cooling water in the same direction on both sides of the partitioning of the heart. This intervention consists of plugging the orifice (s) located at the upper part of the core envelope and piercing the upper reinforcement of the partitioning.

 Such an intervention brings a definite improvement in the operation of the reactor by reducing the intensity of the parasitic jets of cooling water through its partitioning. However, there are still areas in particular in the lower part of the heart where the pressure in the annular space at the periphery of the partition is greater than the pressure inside the heart. This is in particular due to the fact that the reinforcements do not are generally not arranged at the same level as the grids of the core assemblies.

 In the case where the clearance between the partitions is relatively strong, the parasitic jets of cooling water locally exhibit an intensity greater than the generally accepted limits. In that case.

it is necessary to reduce the clearance between the partitions either by hammering the joint or by screwing the parts of the partitions in coincidence.

 Such operations must be carried out under water during a period of reactor shutdown and require the use of specially designed means.

 The object of the invention is therefore to propose a method for limiting the intensity of parasitic jets of cooling water in a nuclear pressurized water reactor in service, the reactor comprising a core constituted by juxtaposed fuel assemblies and surrounded at its periphery. by a partition comprising vertical plates between which there remain interstices constituting passages for the parasitic jets of water through the partitioning, towards the interior of the core and horizontal reinforcing plates disposed at different levels between the vertical plates and a cylindrical core envelope with vertical axis surrounding the partitioning and providing an annular space around the vertical plates. in which are placed the reinforcements which are pierced so that the cooling water circulates from bottom to top, both in the heart and inside the annular space of the partitioning. this process making it possible to reduce or even cancel the parasitic jets. whatever the clearance between the partitions and whatever the arrangement of the reinforcements of the partitioning. in an existing nuclear reactor.

 For this reason. is introduced and put in place, during a reactor shutdown, by Jes openings of the reinforcement located higher, or upper reinforcement, partial sealing devices of at least part of the openings of the reinforcements located below the reinforcement superior. the closure devices remaining in place after the restart of the reactor to increase and adjust the pressure drops of the cooling water circulating in the annular space.

 The invention also relates to devices for partially closing the openings in the reinforcements of the partitioning. to limit the intensity of parasitic jets of cooling water.

 In order to clearly understand the invention, we will now describe, by way of non-limiting examples, with reference to the appended figures, several embodiments of the process according to the invention compared to the processes according to the prior art used to reduce parasitic emissions in a pressurized water nuclear reactor.

 Figure 1 is a half-sectional view through a vertical plane of the partitioning of the core of a nuclear reactor according to a design causing a counter-current circulation of the cooling water on either side of the partitioning.

 FIG. 2 is a curve representing the variation of the pressure difference on either side of the partitioning shown in FIG. 1, according to the height of the core.

 Figures 3 and 4 are large-scale views, in section through a horizontal plane, of two areas of junction between vertical plates of a partition, in the case of a reactor core constituted by assemblies of a first type and of a second type.

 Figure 5 is a half-sectional view through a vertical plane of a partitioning of a pressurized water nuclear reactor core of a design causing circulation of the cooling water in the same direction, from and on the other side of the compartmentalization.

 FIGS. 6 and 7 are exploded perspective views of the partitioning of a pressurized water nuclear reactor, before and after a conversion operation making it possible to modify the operation of the reactor, as regards the direction of circulation of the water cooling.

 FIG. 8 represents the curves of variation of the pressure difference on either side of the partitioning, before and after 3 8 conversion shown in FIGS. 6 and 7 respectively.

 Figure 9 is a sectional view through a vertical plane, of a partial closure device of the openings of the reinforcement of a partition for implementing the method according to the invention.

 FIG. 10 represents curves of variation of the pressure along the height of the core of a nuclear reactor, on either side of the partitioning. after a conversion operation as shown in FIGS. 8 and 9.

 Figure-11 is a vertical sectional view of a prel.i; re alternative embodiment of a partial sealing device according to the invention.

 Figure 12 is a view along 12-12 of Figure 11.

 Figure 13 is a vertical sectional view of a second alternative embodiment of a partial closure device according to the invention.

 Figure 14 is a + 'vertical sectional view of a tr) isieme alternative embodiment of a partial closure device according to the invention.

 Figure 15 is a view along 15-15 of Figure 14.

 FIG. 16 is a view in vertical section of an alternative embodiment of the support means of a closure device as shown in FIG. 9.

 Figure 17 is a vertical sectional view of a fourth alternative embodiment of a partial closure device according to the invention.

 Figure 18 is a vertical sectional view of the device shown in Figure 17 3ors of its establishment using an appropriate tool.

 In FIG. 1, - the core envelope 1 of a pressurized water nuclear reactor is seen, inside which the partition 2 is arranged, intended to laterally delimit the core of the reactor, the assemblies of which rest on the lower plate 3.

 An upper core plate 4 rests on the upper part of the assemblies. The plates 3 and 4 are drilled so as to allow the passage of the coolant from the core.

 The partition 2 is constituted by flat vertical plates 5 arranged at right angles to one another and delimiting a polygonal contour corresponding to the contour of the heart.

The partitioning 2 also comprises reinforcing plates 6 arranged along the height of the core, at variable intervals. The plates 6 have a circular outer edge corresponding to the internal section of the envelope 1 and an inner edge cut out in the shape of a polygon corresponding to the shape of the section of the core. The horizontal reinforcements 6 are arranged along the width of the annular space 7 formed between the external surface of the partitions 5 and the internal surface of the core envelope 1.

 The core envelope 1 has in its upper part, below the upper reinforcement 6a, an orifice 8-through which the cooling water enters, when the reactor is in operation.

 The cooling water circulates from top to bottom in the annular space 7 then from bottom to top inside the heart (arrows 9). During its upward circulation in the core, the cooling water passes through the spacer plates of the fuel assemblies of the core whose position has been shown in FIG. 1 (marks 10).

 FIG. 2 shows the variations, depending on the height of the core, of the pressure difference P P of the cooling fluid, on either side of the vertical plates 5 of the partitioning.

There is shown in the left part of Figure 2, the position of the successive reinforcements 6 of the partitioning as well as the position of the upper reinforcement 6a, in the direction Y corresponding to the height of the heart.

 The pressure difference a P on either side of the vertical plates 5 of the partition increases irregularly but nevertheless continuously.

from the bottom of the heart to the top. At the bottom of the core, the downward flow of cooling water meets the upward flow and the pressure difference P is zero.

This pressure difference t P is maximum at the upper part of the core, in the vicinity of the reinforcement 6a.

 In Figures 3 and 4 we see two vertical plates 5a. 5b of the partitioning of the core shown in FIG. 1. These plates are represented in section by a horizontal plane and in the vicinity of their junction zone. A gap 12 remains between the plates 5a and 5b so that a parasitic jet of cooling fluid 13 (Figure 3) or 13 (Figure 4) is directed from the outside of the partitioning towards the inside of the heart, when 'There is a positive pressure difference P on either side of the two faces of the plates 5a and 5b.

 As can be seen in Figure 2, this effect is particularly marked in the upper part of the heart.

 In the case of Figure 3, the fuel rods of the assemblies are arranged so that the jet 13 does not directly strike any fuel rod 14. On the contrary. in the case of FIG. 4, the fuel assemblies are arranged in such a way that the jet 13 comes directly to strike a fuel rod 14 on an external row of an assembly.

 In both cases, however, the jet 13 or 13 is likely to generate a vibration of the rods which causes an increase in their wear in service.

 FIG. 5 shows a partitioning of the core of a pressurized water nuclear reactor produced according to a new design making it possible to reduce or even eliminate the parasitic jets passing through the partitioning, to wait for the fuel rods.

 In this new design. the core casing 20 does not have an orifice in the upper part and the horizontal reinforcements 16 of the vertical partitions 15 are all drilled including the upper reinforcement plate 16a, so that the cooling water of the reactor circulates from below above, both in the annular space 17 between the partition 15 and the internal surface of the core envelope 20. as in the reactor core, inside the partition 15.

 The reinforcements 16 are arranged at the level of the spacer plates of the core assemblies and are drilled so that the pressure drop is substantially equal for the cooling water circulating in the annular space 17 and for the cooling water circulating in the core, when crossing the reinforcements 16 and the spacers of the fuel assemblies, respectively.

 In this way, the cooling water is under pressure on either side of the partition 15.

 Thanks to this new concept of pressurized water nuclear reactors, we therefore avoid the appearance of parasitic jets directed towards the interior of the heart, through the partitioning.

 However for nuclear reactors according to the old design and which have been put into service, the undesirable effect of the parasitic jets passing through the partitioning remains.

 We therefore imagined an intervention to modify the direction of circulation of the cooling water in the annular space between the partitioning and the core envelope. Figures 6 and 7 show the principle of this intervention, Figure 6 showing the structure of the partitioning and the direction of circulation of the cooling water for a reactor according to the old design and before its conversion and Figure 7 showing the structure partitioning and the direction of circulation of the cooling water in the same reactor, after an intervention making it possible to carry out the conversion of the reactor to obtain a circulation of the cooling water from bottom to top. in the annular space at the periphery of the partitioning.

 The corresponding elements in FIG. 1 on the one hand and in FIGS. 6 and 7 on the other hand bear the same references.

 The configuration shown in Figure 6 corresponds substantially to the configuration of Figure 1. the core envelope 1 having an orifice 8 in its upper part and the upper reinforcement 6a of the partition having no water passage holes.

 In addition, a heat shield 19 is placed around the core casing 1 and constitutes therewith an annular space into which part of the flow of cooling water circulating in the bifurcated tank 21 penetrates. This flow of cooling water 21 enters the annular space 7 comprised between the vertical partitioning plates 5 and the inner surface of the core envelope 1, through the orifice 8. The flow of cooling water 21 circulates then in the vertical direction and from top to bottom, inside the annular space 7, crossing the reinforcements 6 through the orifices provided in these reinforcements. Finally, the flow of cooling water 21 comes to mix with the flow main 22 of cooling water at the base of the partition. to then flow in the vertical direction and from bottom to top inside the heart.

 This type of cooling water circulation from top to bottom at the periphery of the partitioning is generally designated by the English term "down flow". The down flow circulation, as explained previously with reference to FIG. 2. causes a pressure difference on either side of the partitioning and the appearance of particularly intense partitioning jets 23 in the upper part of the heart.

 An intervention has therefore been planned on the nuclear reactor which makes it possible to pass from a down flow circulation to an up flow circulation, that is to say a circulation in the vertical direction and directed upwards, around the partitioning. . as shown in figure 7.

 To do this, the opening 8 of the core envelope 1 is closed by a plug 24 and a bore in the upper reinforcement 6a in alignment with the holes passing through the other reinforcements 6.

 To install the plug 24, a hole 24 is made through the thermal screen 19.

 In the type of up flow circulation of cooling water, this type of circulation also being that which is implemented in the case of the new design shown in FIG. 5, the main flow 22 of cooling water passing to the outside the core envelope crosses the bottom core plate 3. is distributed inside the core and in the annular space 7 and circulates in parallel from bottom to top, in the core and in the annular space 7 .

 In FIG. 8, the pressure difference ss P of the cooling fluid is represented on either side of the partitioning, in the case of the down flow circulation as represented in FIG. 6 (curve in solid lines) and in the the case of up flow circulation as shown in Figure 7 (dotted curve). The curve in solid lines in FIG. 8 which corresponds substantially to the curve in FIG. 2 shows that the pressure difference ss P on either side of the partitioning increases from a zero value at the base of the partitioning up to at a maximum value at the top of the partition.

In the case of an up flow circulation of cooling water, the pressure losses of the fluid circulating in the annular space at the periphery of the partitioning, when passing through the openings provided in the reinforcements, are of the same order as the pressure losses undergone by the fluid circulating in the core, during the crossing of the spacer plates of the assemblies. However, unlike the structure according to the new design shown in FIG. 5, the reinforcements 6 are not systematically placed at the level of the plates between
tuises of the assemblages of the heart.
it can be seen in figure 8, that it certainly remains
n areas where the pressure of the cooling water is higher in the annular space outside the partitioning than inside the partitioning
the same altitude. These areas are located mainly in the lower part of the heart.

When the clearance between the partitions is low, the parasitic jets entrained by this difference in pressure and directed towards the interior of the heart have a low intensity and much lower than the criteria.
admissible.

However, when the clearance between the partitions has a higher value, the parasitic jets directed towards the interior of the heart may have an intensity
such that the pencils are vibrated.

 In Figure 9. there is shown a device for implementing the method according to the invention, so as to limit the intensity of the parasitic jets to a very low value, along the entire height of the heart.

 The process according to the invention is implemented on the partitioning of the core of a nuclear reactor which has undergone an intervention as shown in FIG. 7 in order to pass from a down flow circulation to an up flow circulation of the re rubbing.

 The corresponding elements in Figures 7 and 9 have the same references.

 The intervention on the partitioning consisted in piercing the upper reinforcement 6a in order to produce through orifices 25 for this reinforcement, each located in alignment with a line of orifices 26 passing through the reinforcements 6 situated below the reinforcement 6a and at place a closure cap 24 in the hole 8 located at the top of the core envelope 1.

 The method according to the invention consists in increasing the pressure drop of the cooling fluid during the crossing of the orifices 26 of the reinforcements 6. by partial obturation of these orifices 26. This obturation is carried out from above the partitioning by introducing the devices d 'closing by the orifices 25 of the upper reinforcement 6a.

 In the case of the embodiment shown in FIG. 9, partial obturation devices are used which consist of the main part of a rod 27 having an upper support part 27a on the upper support 6a and an enlarged lower part 27b ensuring the guidance and ballasting of the rod during its introduction into the partitioning.

 The upper support part 27a of the rod comprises two wings 90 whose length is greater than the diameter of the orifice 25.

 The method according to the invention is implemented during a shutdown of the nuclear reactor. the vessel of this reactor being open and filled with water. The rods 27 are supplied and placed in position in the lines of orifices of the partitioning, from the edge of the reactor pool.

 When the reactor is put back into operation, the rods 27 remain in place in the partition where they are held in position under the effect of their own weight or of a holding device.

 FIG. 10 shows the evolution of the pressure drop of the reactor cooling water. according to the height of the heart, inside the partitioning, that is to say in the heart itself (curve 29 in solid lines) and in the annular space at the periphery of the partitioning. in the case of an up flow conversion without using the method according to the invention (dotted curve 30) and in the case of an up flow conversion with the use of the method according to the invention of partial obturation of the orifices of the reinforcements (curve 31 in phantom).

In addition, along the ordinate axis, the zones occupied by the reinforcements (zones
R) and the zones occupied by the grids (zones G).

 It can be seen that the zones occupied by the reinforcements and the zones occupied by the grids are not superimposed and that the curve 30 passes over the curve 29 in certain zones 32 situated mainly at the bottom of the core. In these areas. the pressure of the cooling water is higher in the annular space than in the heart, so that parasitic jets directed towards the interior of the heart are likely to form.

 In revaricli. ', The curve 31 is located below the curve 29, the partial sealing of the orifices 26 of the reinforcements 6 causing an increase in the pressure drop in the cooling fluid circulating in the annular space, mainly at the level orifices 26 of the lower reinforcement 6b in which the enlarged parts 27b of the rods 27 are engaged.

 It is visible that the process according to the invention makes it possible to avoid the formation of parasitic jets. mainly in the lower part of the heart, by otherwise distributing the pressure drop of the cooling fluid circulating in the annular space at the periphery of the partitioning.

 It is obvious that one can introduce into the orifices 26 reinforcements 6 arranged in a vertical row a rod of variable section making it possible to reduce more or less the passage section of the orifices 26, depending on the position of the reinforcement 6 corresponding to the height of the heart. It is also possible to achieve a reduction in section only on some of the orifices of the reinforcements 6.

 The method according to the invention is therefore very flexible and makes it possible to best adapt the passage sections of the orifices of the reinforcements and therefore the pressure losses in the annular space at the periphery of the partitioning, to the passage section. and at the position of the spacer grids in the core determining the pressure drops of the cooling water circulating inside the partitioning.

 FIGS. 11 and 12 show an alternative embodiment of a device for partially obstructing an orifice 26 of a reinforcement 6 of the partitioning of a nuclear reactor having undergone an up flow conversion.

 The section reduction device consists of a hollow rod 35 provided with centering fins 36 placed 90 ′ from one another and constituting several successive sets along the length of the rod.

 The successive sets of fins 36 are arranged so as to be placed at the level of the reinforcements 6. inside the orifices 26, when the rod 35 is placed in position in the partitioning. in the same way as the rod 27 shown in FIG. 9. The fins 36 have a radial dimension such that there remains a very small clearance between their end and the edges of the orifice 26. after the rod 35 has been put in place .

 An operating rod 37 is disposed inside the hollow rod 35 and has diametrically widened parts 38 intended to cooperate with profiled and constricted parts 35a of the internal bore of the rod 35 located at the level of the sets of fins. 36 to achieve the diametrical expansion of the rod 35 and the fins 36 inside the orifice 26. An irreversible fixing of the rod 35 is thus obtained inside the orifices 26 of the reinforcements 6.

 In the case of the alternative embodiment shown in FIG. 13, the hollow rod 35 ′ carries centering and fixing fingers 36 ′ articulated on the rod 35 ′ at the level of windows passing through its side wall, the centering finger assemblies of the rod 35 'being arranged so as to come inside the orifices 26 of the reinforcements 6, when the rod 35' is placed in the partitioning.

The rod 35 'has along its axis, a rod de.ma maneuver 37' having an enlargement 38 'capable of actuating the fingers 36'. The operating rod 37 ′ is movable axially inside the hollow rod 35 ′ to make the spacing of the centering and fixing fingers 36 ′ after the rod 35 ′ has been placed in the partitioning.

 The devices shown in Figures 11, 12 and 13 have the advantage of ensuring effective centering and holding of the partial obstruction devices of the orifices, inside the partitioning.

 In Figures 14 and 1-5, there is shown a third alternative embodiment of a device.

partial obstruction of the orifices 26 of the reinforcements 6 of a partitioning. The device comprises a centering element with fins 40 and a rod 41 similar to the rod 27 shown in FIG. 9.

 The fin centering elements 40 have a lower part engaged in the orifice 26 practically without play and an upper part with a larger diameter coming to rest on the reinforcement 6.

 The centering elements 40 make it possible to provide transverse support for the rod 41.

 In Figure 16. we see the lower part of a rod 43 similar to the rod 27 shown in Figure 9. The rod 43 has a lower support portion 44 diametrically enlarged and having a conical part capable of coming to engage in a cavity 45 machined in the lower core plate 3. in alignment with the orifices 26 in the reinforcements 6 of the partitioning 5.

 The enlarged part 44 of the rod 43 is placed inside the orifice 26 of the lower reinforcement 6b of the partitioning. The rod 43 may or may not include at least one other diametrically enlarged part 47 which engages in the orifice 26 of a reinforcement situated above the lower reinforcement 6b.

 In FIG. 17, there is seen a device for partially closing an orifice 26 passing through a reinforcement 6 constituted by a socket 48, the end parts 48a and 48b of which can be folded outwards in order to crimp the socket 48 in the orifice 26 of the reinforcement 6.

 In Figure 18, we see a tool 50 for carrying out the crimping of the sleeve 48 in the orifice 26 of the reinforcement 6. The tool 50 has a central rod 51 at the end of which is fixed a lower crimping ring 52 and a sliding sleeve 53, the end of which constitutes an upper crimping ring. The crimping of the sleeve 48 inside the orifice 26 is obtained by pulling the rod 51 upwards and by pushing the sliding sleeve 53 downwards.

 In any case, the process according to the invention can be carried out at any time after the down flow-up flow conversion of the key bare reactor. This process can be implemented. during a refueling of the reactor with fuel, after a certain time of operation of this reactor in up-flow circulation without using the process of the invention.

 The process and the devices according to the invention make it possible to greatly limit the intensity of the parasitic jets which may persist after an up-flow conversion without this process or possibly to eliminate these parasitic jets over the entire height of the heart.

 The invention is not limited to the embodiments which have been described.

 It is thus possible to imagine using partial sealing devices for the reinforcements openings of a different type from those which have been described.

 One can consider partially closing the passage openings of certain reinforcements only and in particular reinforcements located towards the lower part of the core. Advantageously. only the through holes of the lower reinforcement can be closed.

 In the case where the openings of the reinforcements are not aligned in vertical directions or even in the case where the openings of the lower reinforcements are not in alignment with the openings of the upper reinforcement, it is possible to use bent tools for the installation of partial sealing devices.

 The process and the devices according to 3. invention apply in the 3rd case of any nuclear reactor whose partitioning has been modified to pass from a down flow circulation to an up flow circulation of the cooling water.

Claims (13)

 1.- Method for limiting the intensity of parasitic jets of cooling water in a pressurized water nuclear reactor in service, the reactor comprising a core constituted by juxtaposed fuel assemblies and surrounded at its periphery by a partition comprising vertical plates (5) between which there are interstices constituting passages for the parasitic jets of water through the partitioning (5) towards the interior of the core, and horizontal reinforcing plates (6) arranged at different levels between the plates vertical (5) and a cylindrical core envelope (1) with a vertical axis surrounding the partitioning and providing an annular space (7) around the vertical plates (5) in which are placed the reinforcements (6) which are drilled so that the cooling water circulates from bottom to top, both in the heart and inside the annular space (7) of the partitioning, ca characterized by the fact that we introduce and put in p lace during a shutdown of the reactor, through the openings (25) of the reinforcement (6a) located at the highest, or upper reinforcement of the partial closure devices (27, 35, 35 ', 41, 48) of at least part openings (26) of the reinforcements (6) located below the upper reinforcement (6a), the closure devices (27, 35.  35 41 48) remaining in place after restarting the reactor, to increase and adjust the pressure drop of the cooling water circulating in the annular space (7).  2.- Method according to claim 1, ca acterized by the fact that performs the partial sealing of the openings (26) of the reinforcements located in the lower part of the partition only.  3.- Method according to claim 2, ca characterized in that one realizes the partial sealing of the openings (26) of the reinforcement (6b) located lowest on the cloiSoneinent only.  4.- Method according to any one of claims 1 2 and 3, characterized in that the devices for partially closing the openings (26) of the reinforcements (6) of the partitioning are such that the pressure in the annular space ( 7) the partitioning is less than the pressure in the heart, along the entire height of the heart. during reactor operation.  5.- Device for limiting the intensity of parasitic jets of cooling water in a pressurized water nuclear reactor, the reactor comprising a core constituted by juxtaposed fuel assemblies and surrounded at its periphery by a partition comprising vertical plates (5) between which there remain interstices constituting passages for parasitic jets of water through the partitioning, towards the interior of the core, and horizontal reinforcing plates (6) disposed between the vertical plates (5) and an envelope of cylindrical core (1) with vertical axis surrounding the partitioning and providing an annular space (7) around the vertical plates in which are placed the reinforcements (6) which are drilled so that the cooling water circulates from bottom to top as well in the heart, inside the partitioning than in the annular space (7), characterized by the fact that it is constituted by at least one partial obturation device (27, 35, 35 ', 41, 48> of at least one opening (26) of a reinforcement. {6) of the partitioning.  6.- obturation device according to claim 5, characterized in that it is constituted by a rod (27) having a diameter less than the diameter of the openings (26) of the reinforcements (6t capable of being engaged in a pZuraZity of openings (26) of the reinforcements (6) aligned in a vertical direction.  7.- obturation device according to claim 6, characterized in that the rod (27) has a diametrically widened end (27b, 44) capable of being engaged in the opening (26) of the reinforcement (6b) located the lowest on the partitioning.  8.- Device according to claim 7, characterized in that it comprises at its end opposite to the enlarged part (27b) a bearing part (27a) on the upper reinforcement (6a).  9.- obturation device according to the re vendicatiful @, characterized by the fact that the enlarged part (44) comprises a bearing part on a lower core plate (3) disposed below the partitioning (5).  10.- obturation device according to claim 6, characterized in that the rod (35, 35 ') is hollow and comprises centering devices (36. 36') placed on the rod (35. 35 ') in positions corresponding to the parts of the rod engaging inside all or part of the openings (26) of the reinforcements (6) and an operating rod (37 ') movable axially in the hollow rod (35, 35' ) to ensure the diametrical expansion of the centering devices (36, 36 ') by axial displacement.  11.- obturation device according to claim 10. characterized in that the positive centering devices (36) are constituted by fins arranged in radial directions around a part of the rod (35) in which the bore (35a) of the rod has a reduced diameter, the operating rod (37) comprising an enlarged part (38) capable of cooperating with the part (35a) of reduced diameter of the bore of the rod (35) to produce a radial expansion of the fins (38> inside the opening (26).  12.- obturation device according to claim 10, characterized in that the centering devices (36 ') are constituted by fingers (36') pivotally mounted on the rod (35 '), the operating rod (37 ') .mportant a portion (38') for actuating the fingers (36 '), for their movement outward in radial directions, inside the opening (26).  13.- obturation device according to claim 5. characterized in that it is constituted by a tubular sleeve (48) whose outside diameter is less than the diameter of the openings (26) of the reinforcements (6) comprising parts deformable (48a) for its crimping inside an opening (26) and its attachment to the corresponding reinforcement (6).