JP2008170367A - Jet pump and nuclear reactor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a jet pump and a nuclear reactor capable of suppressing flow force vibration of a jet pump, and heightening an efficiency furthermore. <P>SOLUTION: This jet pump has a nozzle, a bell mouth, a throat 12 and a diffuser 13. The diffuser 13 is arranged under the throat 12 connected to the lower end of the bell mouth. A ring member 14 is fixed to the upper end of the diffuser 13. A projection part 29 is projected to the outside on the lower end of the throat 12. A hollow 28 formed on the inner surface on the lower end of the throat 12 is extended upward from the lower end of the throat 12. The upper end of the diffuser 13 is inserted into the hollow 28. A seal member 16 is arranged between the diffuser 13 upper end and the throat 12 lower end. A cap nut 15 supported by the projection part 29 is engaged with the ring member 14, and the upper end of the diffuser 13 is pressed onto the lower end of the throat 12. The inner diameter D1 of the throat 11 lower end is the same as the inner diameter D2 of the diffuser 12 upper end. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a jet pump and a nuclear reactor, and more particularly, to a jet pump and a nuclear reactor suitable for application to a boiling water reactor.

  A conventional boiling water reactor (BWR) has a jet pump installed in a reactor pressure vessel. The jet pump includes a nozzle, a bell mouth, a throat, and a diffuser. The recirculation piping is connected to the reactor pressure vessel. The cooling water whose pressure has been increased by driving a recirculation pump provided in the recirculation system pipe passes through the recirculation system pipe and is jetted from the nozzle into the jet pump as drive water. The nozzle increases the speed of the driving water. Driven water, which is cooling water existing around the nozzle, flows from the bell mouth into the throat by the jetted drive water. The cooling water discharged from the diffuser through the throat is supplied to the core through the lower plenum (see Patent Documents 1 to 3).

  Patent Document 2 describes a jet pump in which the lower end of a throat is inserted into the upper end portion of a diffuser (see FIG. 5 of Patent Document 2). Patent document 3 describes providing a slip joint part in the throat which becomes a negative pressure inside, in order to prevent the cooling water in a jet pump from leaking outside from the slip joint part. That is, the throat is divided into two at the axial center, and the upper end of the lower throat is inserted into the lower end of the upper throat (see FIG. 6 of Patent Document 3).

  Improvements have been made in the efficiency of jet pumps used in BWRs. Patent Document 4 describes that a plurality of thin vertical grooves extending in the axial direction are formed on the inner surface of a throat of a jet pump.

JP-A-2005-233152 JP 58-28695 A Japanese Patent Laid-Open No. 58-15798 JP-A-8-135600

  The performance of the jet pump is expressed by the M ratio, N ratio, and efficiency as shown below. The M ratio is a ratio of the flow rate Qb of the driven water (cooling water) to the flow rate Qa of the drive water (recirculation water), and is expressed by the equation (1).

M ratio = Qb / Qa (1)
The N ratio is the total head ratio of the driven water with respect to the driving water, and is expressed by equation (2).

N ratio = (Hc−Hb) / (Ha−Hc) (2)
Here, Ha is the total head at the driving water inlet of the nozzle, Hb is the total head at the driven water inlet of the jet pump, and Hc is the total head at the jet pump outlet. Efficiency is the ratio of driven water energy to driving water, and is expressed as the product of the M ratio and the N ratio.

Efficiency = M ratio x N ratio (3)
As a jet pump, it is desirable that the M ratio, the N ratio, and the efficiency be higher. If the flow rate of the cooling water discharged from the jet pump can be increased efficiently by using a small-capacity recirculation pump, the recirculation system can be made compact and the installation space of the recirculation system can be reduced.

For example, in the case of improving the power output in an existing nuclear reactor (for example, BWR), the range of improvement in the reactor power can be expanded by increasing the core flow rate. Further, by increasing the control width of the core flow rate, the width of change in the void ratio in the core increases, and fuel economy can be improved. In order to increase the core flow rate in this way, the recirculation pump, feed water pump, and jet pump may be improved. The inventors have found that in the modification of an existing nuclear reactor for the purpose of improving the output, the improvement of the jet pump is more effective than the modification or replacement of large equipment such as a recirculation pump and a feed water pump. . In particular, the inventors have newly found that it is possible to improve the performance of the jet pump by improving the structure of the throat and the diffuser. A new problem found by the inventors will be described below.
(Problem 1)
In order to improve the output in a BWE having an existing jet pump, it is necessary to increase the efficiency of the jet pump. If the N ratio of the jet pump is the same without changing the recirculation pump, an increase in the efficiency of the jet pump can be achieved by increasing the M ratio. Increasing the M ratio will increase the pressure loss of the bellmouth, throat and diffuser resulting in a decrease in the N ratio. Therefore, in order to increase the efficiency of the jet pump with a high M ratio and N ratio, it is necessary to reduce the pressure loss of the bell mouth, throat, and diffuser.
(Problem 2)
Moreover, the jet pump installed in the existing BWR that improves output employs a slip joint that inserts the lower end of the throat into the upper end portion of the diffuser in order to facilitate maintenance (FIG. 5 of Patent Document 2). reference). In such a structure, the cooling water in the jet pump leaks outside through a gap formed in the slip joint. Hydrodynamic vibration is generated based on this leakage, which causes wear at the connection between the diffuser and the throat. Therefore, in order to ensure the soundness of the jet pump, it is necessary to suppress wear at the connecting portion between the diffuser and the throat due to the fluid vibration.

  An object of the present invention is to provide a jet pump and a nuclear reactor that can suppress the hydrodynamic vibration of the jet pump and further increase the efficiency.

  The feature of the present invention that achieves the above-described object is that the upper end of the diffuser is inserted into a recess formed inside the throat at the lower end of the throat, and the throat at the lower end of the inner surface of the throat is located above the recess. The first inner diameter is equal to or larger than the second inner diameter of the diffuser at the upper end of the diffuser, and the gap between the throat and the diffuser is sealed.

  Since the upper end portion of the diffuser is inserted into the recess formed inside at the lower end portion of the throat and the first inner diameter of the throat is equal to or larger than the second inner diameter of the diffuser, pressure loss at the throat can be reduced. In addition, the flow rate of the driven fluid sucked into the throat increases. Therefore, the efficiency of the jet pump increases. Since the gap between the throat and the diffuser is sealed, there is no leakage of the fluid flowing in the jet pump, and there is no fluid vibration generated due to the leakage fluid. For this reason, it is possible to avoid wear of the throat and the diffuser based on this fluid vibration.

  According to the present invention, the hydrodynamic vibration of the jet pump can be suppressed and the efficiency of the jet pump can be further increased.

The above problems 1 and 2 have been newly found by the inventors by examining the conventional jet pump shown in FIG. The examination result will be described. In order to facilitate maintenance of the conventional jet pump, as shown in FIG. 3 described above, the lower end portion of the throat is inserted into the upper end portion of the diffuser, and they are connected. This conventional jet pump cannot increase the inner diameter of the insertion portion at the lower end of the throat. If the inner diameter is increased, it is necessary to increase the outer diameter of the diffuser over the entire length, and a large-scale remodeling work is required. In the structure shown in FIG. 3 above, when the flow rate of the driven fluid is increased in order to increase the M ratio, the flow rate is limited by the throat, so that the pressure loss of the jet pump increases and the N ratio decreases. Become. As a result, improvement in jet pump efficiency cannot be expected.
In the embodiment of the present invention, the lower end portion of the throat is made larger than the upper end portion of the diffuser so as to enclose, thereby increasing the diameter of the throat and bell mouth, reducing the N ratio, and increasing the M ratio. It was set as the form which aims at improvement.

Further, in the structure shown in FIG. 3, the cooling water in the jet pump leaks to the outside from between the throat and the diffuser. Hydrodynamic vibration is generated based on the leaked water, and wear occurs at the connecting portion between the diffuser and the throat. In the configuration shown in FIGS. 6 and 7 of Patent Document 3, it is necessary to replace the existing throat and diffuser of the jet pump, and a large-scale remodeling work is required. Since the inner diameter is the same as the conventional one, when the leak amount is set to 0, the pressure loss at the throat portion is not changed, and the increase of the M ratio cannot be expected. In contrast to the conventional method, the place where the downcomer water is sucked is improved although the M ratio is slight. However, fluid vibration is generated by the sucked inflow water, and wear occurs at the connection portion between the diffuser and the throat.
In the embodiment of the present invention, the structure in which the gap between the lower end of the throat and the upper end of the diffuser is eliminated is used to avoid wear due to hydrodynamic vibration. By taking these forms, it is possible to avoid wear caused by hydrodynamic vibration and to achieve a significant improvement in efficiency.
Details of the embodiment of the jet pump according to the present invention will be described below.

  A jet pump according to embodiment 1, which is a preferred embodiment of the present invention, will be described below. A schematic structure of a boiling water reactor (BWR) equipped with the jet pump of this embodiment will be described below with reference to FIGS. 1 and 2.

  The BWR has a reactor pressure vessel (reactor vessel) 1 and a reactor core shroud 3 is installed in the reactor pressure vessel 1. A core 2 loaded with a plurality of fuel assemblies (not shown) is disposed in a core shroud 3. A steam separator 5 and a steam dryer 6 are disposed in the reactor pressure vessel 1 above the core 2. A jet pump 9 is disposed in an annular downcomer 7 formed between the reactor pressure vessel 1 and the core shroud 3. The reactor pressure vessel 1 is provided with a recirculation system. This recirculation system has a recirculation system pipe 18 and a recirculation pump 19. The recirculation pump 19 is provided in the recirculation piping 18. One end of the recirculation system pipe 18 is connected to the reactor pressure vessel 1 and communicated with the downcomer 7. The other end of the recirculation pipe 18 is connected to the nozzle 10 of the jet pump 9 via a riser pipe 21 and a branch pipe 22 disposed in the downcomer 7. A main steam pipe 25 and a water supply pipe 26 are connected to the reactor pressure vessel 1.

  Cooling water (driven fluid, coolant) 8 existing in the upper part of the reactor pressure vessel 1 is mixed with the feed water 27 supplied to the reactor pressure vessel 1 from the feed water pipe 26 and descends in the downcomer 7. The cooling water 8 flows into the recirculation system pipe 18 by driving the recirculation pump 19 and is boosted by the recirculation pump 19. The raised cooling water 8 is referred to as driving water (driving fluid) for convenience. The drive water 23 is ejected from the nozzle 10 of the jet pump 9 through the recirculation system pipe 18, the riser pipe 21 and the branch pipe 22. The cooling water 8 present around the nozzle 10 is sucked into the throat 12 from the bell mouth 11 by the ejection of the driving water 23. The cooling water 8 descends in the throat 12 together with the driving water 23 and is discharged from the diffuser 13. Cooling water (including cooling water 8 and driving water 23) discharged from the diffuser 13 is referred to as cooling water 24. The cooling water 24 is supplied to the core 2 through the lower plenum 4. The cooling water 24 is heated when passing through the core 2 and becomes a two-phase flow containing water and steam. The steam separator 5 separates steam and water. The separated steam is further dehumidified by the steam dryer 6 and discharged to the main steam pipe 25. This steam is guided to a steam turbine (not shown) to rotate the steam turbine. The steam discharged from the steam turbine is condensed into water by a condenser (not shown). This water is supplied into the reactor pressure vessel 1 from the water supply pipe 26 as water supply 27. The cooling water separated by the steam separator 5 and the steam dryer 6 falls to become the cooling water 8.

  The jet pump 9 including the nozzle 10 and the throat 12 as main components effectively transmits the power of the recirculation pump 19 from the driving water 23 to the cooling water 8, and the flow rate of the cooling water 24 discharged from the jet pump 9. Is increased more than the flow rate (Qa) of the driving water 23. Specifically, the drive water 23 is used to increase the flow rate of the cooling water 24 supplied to the core 2. The kinetic energy of the driving water 23 provided by the recirculation pump 19 effectively acts on the cooling water 8, the flow rate (Qb) of the cooling water 8 sucked into the bell mouth 11 is increased, and the flow rate of the cooling water 24 is increased. Further increase. For this reason, the flow rate of the drive water 23 at the outlet of the nozzle 10 is increased so that the kinetic energy of the drive water 23 increases, and the flow path area is made smaller than that of the bell mouth 11 at the inlet portion of the throat 12. The speed of water 8 is increased to reduce the static pressure. Thereby, the cooling water 8 can be sucked into the throat 12, and a necessary core flow rate can be secured with a small amount of power. In FIG. 2, the parts representing the symbols of the expressions (1) and (2) necessary for evaluating the performance of the jet pump 22 are also shown.

  As shown in FIG. 2, the jet pump 9 includes a nozzle 10, a bell mouth 11, a throat 12, and a diffuser 13. The bell mouth 11, the throat 12, and the diffuser 13 are referred to as a jet pump body. The bell mouth 11 has a channel cross-sectional area that decreases downward, and the upper end of the throat 12 is connected to the lower end. A diffuser 13 is disposed below the throat 12. The channel cross-sectional area of the throat 12 is the narrowest in the jet pump body. The diffuser 13 has a narrow channel cross-sectional area at the upper end, and the channel cross-sectional area gradually increases toward the bottom. The nozzle 10 is disposed to face the upper opening of the bell mouth 11. Between the nozzle 10 and the bell mouth 11, a cooling water suction channel is formed for guiding the cooling water 8 existing around the nozzle 10 into the bell mouth 11. A fixing plate 17 fixes the nozzle 10 to the bell mouth 11.

  A coupling structure of the throat 12 and the diffuser 13 in this embodiment will be described with reference to FIG. A ring member (first protrusion) 14 is fixed to the upper end of the diffuser 13 by welding (or shrink fitting or cold fitting). The upper end of the ring member 14 is positioned below the lower end of the throat 12. The ring member 14 is threaded on the outer surface. A protrusion 29 is provided at the lower end of the throat 12 and protrudes outward in the radial direction. The cap nut 15 surrounds the protrusion 29 and is supported by the protrusion (second protrusion) 29. The cap nut 15 is hooked on the protrusion 29. A recess 28 is formed in the inner surface at the lower end of the throat 12. The recess 28 extends upward from the lower end of the throat 12 and is formed over the entire circumference in the circumferential direction of the throat 12. It can be said that such a depression 28 is an annular depression. The throat 12 has a step at the upper end of the recess 28. The upper end portion of the diffuser 13 is inserted into the recess 28 of the throat 12. A seal member (for example, a metal O-ring) 16 is disposed between the upper end of the diffuser 13 and the lower end of the throat 12. The screw formed on the inner surface of the cap nut 15 is engaged with the screw of the ring member 14. The cap nut 15 is fastened to the ring member 14, and the upper end of the diffuser 13 is pressed toward the lower end of the throat 12. In this way, the throat 12 and the diffuser 13 are coupled so that they can be disassembled during maintenance. The seal member 16 prevents the coolant flowing in the throat 12 from leaking outside through the lower end of the throat 12 and the upper end of the diffuser 13.

  In the present embodiment, the inner diameters of the connecting portions of the throat 12 and the diffuser 13 described above, that is, the inner diameter D1 of the throat 11 at the position of the lower end of the inner surface of the throat 11 above the recess 28 and the inner diameter of the diffuser 12 at the upper end position. D2 can be the same. The inner diameter D1 is larger than the inner diameter D1 '(see FIG. 5B in Example 2 described later) at the lower end of the throat of a conventional jet pump (see FIG. 3 of Patent Document 3). In this embodiment, the inner diameter D1 of the lower end of the throat 12 can be made approximately 5% larger than the inner diameter of the lower end of the throat in the jet pump currently installed in the BWR. For this reason, the flow path cross-sectional area at the lower end of the throat 12 in this embodiment increases by about 10%. Further, the inner diameter of the throat 11 and the inner diameter of the bell mouth 21 can be increased with the same dimensional ratio. Therefore, the pressure loss at the throat 11 can be reduced, and the N ratio of the jet pump 9 of this embodiment increases. Further, the reduction of the pressure loss at the throat 11 increases the flow rate of the driven water sucked into the bell mouth 11 and increases the M ratio. By increasing the M ratio and the N ratio, the efficiency of the jet pump 9 is improved. The BWR of the present embodiment using the jet pump 9 can achieve an output improvement without increasing the capacity of the recirculation pump 19. The inner diameter D1 may be larger than the inner diameter D2.

  Furthermore, by adopting the coupling portion of the throat 12 and the diffuser 13 that can ensure the sealing performance between the throat 12 and the diffuser 13 as described above, the leakage of the cooling water from the jet pump 9 to the downcomer 7 is eliminated. For this reason, it is possible to avoid wear caused by fluid vibration generated in the leaked water.

  The effect of the jet pump 9 used in the present embodiment will be described with reference to FIG. The horizontal axis represents the M ratio, and the vertical axis represents the efficiency of the jet pump. FIG. 4 shows the characteristics of the conventional jet pump installed in the BWR and the characteristics of the jet pump 9 in which the flow passage cross-sectional area of the throat 12 is increased by 10%. When compared with an M ratio of 2.64, the efficiency of the jet pump 9 is about 5% higher than that of the conventional jet pump.

  In this embodiment, the throat 12 can be removed from the diffuser 13 by removing the cap nut 15 from the ring member 14. For this reason, maintenance of the throat 12 can be easily performed.

  In the present embodiment, without removing the diffuser 13 from the reactor pressure vessel 1, the throat 12 can be removed from the diffuser 13 and the ring member 14 can be easily attached to the upper end of the diffuser 13. Moreover, the throat 12 which attached | attached the cap nut 15 can be easily prepared by forming the hollow 28 in the inner side of a lower end part, forming the protrusion part 29 in the outer side, thickening a lower end part. In this manner, the existing jet pump installed in the BWR can be easily improved in the configuration shown in FIG. 3 in a short time.

  A jet pump according to embodiment 2, which is another embodiment of the present invention, will be described with reference to FIG. This jet pump 9A is used for the BWR described above. The jet pump 9A includes a nozzle 10, a bell mouth 11, a throat 12A, and a diffuser 13A (see FIG. 5A).

  A coupling structure of the throat 12A and the diffuser 13A in this embodiment will be described with reference to FIG. Instead of the ring member 14, a protrusion (first protrusion) 30 is formed at the upper end of the diffuser 13 </ b> A so as to protrude outward. The protrusion 32 is a part of the diffuser 13A. A protrusion 29 is provided at the lower end of the throat 12A. The cap nut 15 is supported by the protrusion 29. A recess 28 is formed on the inner surface at the lower end of the throat 12, and the upper end surface of the recess 28 is a horizontal plane. At the upper end portion of the diffuser 13, a seal portion 31 having a triangular longitudinal section that also serves as a seal member is formed.

  The upper end portion of the diffuser 13 is inserted into the recess 28 of the throat 12, and the top portion of the seal portion 31 faces the upper end surface of the recess 28. The cap nut 15 is engaged with the ring member 14, and the upper end of the diffuser 13 is pressed toward the lower end of the throat 12. Thereby, the top part of the seal part 31 is pressed against the upper end surface of the recess 28, and the lower end of the throat 12 and the upper end of the diffuser 13 are sealed. Also in this embodiment, the throat 12 and the diffuser 13 are coupled so that they can be disassembled during maintenance. The seal portion 31 prevents the coolant flowing in the throat 12 from leaking outside through the lower end of the throat 12 and the upper end of the diffuser 13.

  Also in the present embodiment, the inner diameter D1 at the lower end of the throat 11 can be the same as the inner diameter D2 at the upper end of the diffuser 12. Regarding the inner diameter D1, the inner surface of the throat of the conventional jet pump (see FIG. 3 of Patent Document 3) is indicated by a broken line in FIG. The inner diameter of this conventional throat lower end is D1 '. Its inner diameter D1 is larger than D1 '.

  This embodiment can obtain the effects obtained in the first embodiment. In this embodiment, the metallic O-ring that is the seal member 16 used in Embodiment 1 is not necessary.

  A jet pump according to embodiment 3, which is another embodiment of the present invention, will be described with reference to FIG. This jet pump 9B is used for the BWR described above. The jet pump 9B includes a nozzle 10, a bell mouth 11, a throat 12B, and a diffuser 13B (see FIG. 6A).

  A coupling structure of the throat 12B and the diffuser 13B in the present embodiment will be described with reference to FIG. The upper end portion of the diffuser 13B is inserted into a recess 28 formed on the inner surface of the lower end portion of the throat 12B. The diffuser 13B is coupled to the throat 12B by shrink fitting (or cold fitting) of the throat 12B. By this shrink fitting (or cold fitting), a seal is formed between the diffuser 13B and the throat 12B, so that the cooling water in the throat 12B does not leak to the outside.

  In the present embodiment, the effects produced in the second embodiment can be obtained. In this embodiment, since it is not necessary to follow the cap nut, the coupling structure of the throat and the diffuser can be simplified.

It is a block diagram of the boiling water reactor which is one suitable Example of this invention. It is a block diagram of the jet pump shown in FIG. It is a detailed longitudinal cross-sectional view of the A section of FIG. It is explanatory drawing which shows the characteristic of the jet pump which has the structure shown in FIG. 3, and the conventional jet pump. The structure of the jet pump in Example 2 of this invention is shown, (A) is a side view of a jet pump, (B) is a detailed longitudinal cross-sectional view of B section. The structure of the jet pump in Example 3 of this invention is shown, (A) is a side view of a jet pump, (B) is a detailed longitudinal cross-sectional view of B section.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Reactor pressure vessel, 2 ... Core, 6 ... Core shroud, 7 ... Downcomer, 9, 9A, 9B ... Jet pump, 10 ... Nozzle, 11 ... Bell mouth, 12, 12A, 12B ... Throat, 13, 13A, 13B ... Diffuser, 14 ... Ring member, 15 ... Cap nut, 16 ... Seal member, 18 ... Recirculation piping, 19 ... Recirculation pump, 28 ... Depression, 29 ... Projection, 31 ... Sealing part.

Claims (6)

A nozzle for ejecting a driving fluid; a throat into which the driven fluid and the driven fluid sucked in; and a diffuser connected to the throat through which the driving fluid and the driven fluid flow;
The upper end portion of the diffuser is inserted into a recess formed inside at the lower end portion of the throat, and the first inner diameter of the throat at the first position at the lower end of the inner surface of the throat above the recess. Is equal to or greater than the second inner diameter of the diffuser at the second position at the upper end of the diffuser, and the gap between the throat and the diffuser is sealed.   2. The jet pump according to claim 1, wherein the throat and the diffuser are joined by either shrink fitting or cold fitting at the position of the recess.   A first protrusion is provided on the upper end of the diffuser below the lower end of the throat, and a second protrusion is provided on the lower end of the throat. A second protrusion is provided on the second protrusion. The jet pump according to claim 1, wherein the throat and the diffuser are coupled by engaging a coupling member to be hooked with the first protrusion.   4. The jet pump according to claim 3, wherein a seal portion that seals between the throat and the diffuser is formed at an upper end portion of the diffuser in contact with an upper end surface of the recess.   The jet pump according to claim 3, wherein the first protrusion is attached to the diffuser by any one of welding, shrink fitting, and cold fitting, and a seal member is disposed between an upper end of the diffuser and an upper end surface of the recess. A reactor vessel and a plurality of jet pumps installed in the reactor vessel and supplying coolant to a core formed in the reactor vessel;
The nuclear reactor according to claim 1, wherein the jet pump is the jet pump according to claim 1.

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