JPS6047900A - Jet pump for nuclear reactor - Google Patents

Abstract

PURPOSE:To mix sufficiently driving water with driven water in an inlet mixer to obtain stable flow without separation by a method wherein a plurality of legs are provided between the circumference of inlet section of the inlet mixer and a nozzle as a driven water whirling means. CONSTITUTION:A plurality of legs 21, arranged obliquely into the same direction with respect to the central direction of the inlet mixer 13, are welded between the circumference of inlet section of the inlet mixer 15 and nozzles 13. According to this method, the flow of the driven water is induced into the inlet mixer 15 with a flow speed having a component whirling into the same direction in case it passes through the legs 21 in the jet pump, the whirling component remains slightly at the outlet port of the inlet mixer 15 after being mixed with the driving water flow and the flow in a diffuser becomes stable without causing separation. Accordingly, unstable element of the output of the nuclear reactor due to the fluctuation of the discharging flow amount of the jet pump 20 may be removed. Further, the inlet mixer 15 and the diffuser may be shortened in the lengths thereof and, therefore, the jet pump may be miniaturized and made compact.

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to improvements in jet pumps for boiling water nuclear reactors.

[Technical background of the invention]

The flow of coolant in a boiling water reactor with a built-in jet pump will be explained with reference to FIG. Here the first
The figure shows a cross-sectional view of a boiling water reactor with a built-in jet pump.

The reactor water in the reactor pressure vessel 1 flows downward through the annular flow path formed by the reactor pressure vessel 1 and the shroud 3 (2) together with the feed water supplied from the water supply sparger 2.
Jet pump 4) drives the reactor pressure vessel by water
Inner lower part (-guided. Also here, w of jet pump 4
The driving water is guided from the lower part of the annular flow path formed by the reactor pressure vessel 1 and the shroud 3 (=) to the outside of the reactor pressure vessel 1 and is pressurized by the recirculation pump 5 (= reactor water is used).

The reactor water sent to the lower part of the reactor pressure vessel 1 flows upward while being heated in the reactor core 6, becomes a two-phase flow of steam and water, and is sent to the steam-water separator 28 via the shroud head 7, where it becomes steam. and water (2).The steam separated in the steam-water separator 8 is further removed from moisture in the steam dryer 9,
The live steam nozzle 10 is sent to a generator turbine (not shown) via a main steam pipe 11.

Here, the configuration and operation of the jet pump will be explained using FIG. 2. FIG. 2 shows a structural diagram of the jet pump.

A jet pump 4, which performs forced circulation of reactor water, supplies the pressurized drive water from the recirculation pump 5 into the reactor (2 riser pipes 12,
The nozzle 13 connected concentrically with
At 4, the inlet mixer 15 is concentric with the nozzle 13 (=fixed), and the diffuser 16 is concentric with the inlet mixer 15 (two connected diffusers 16 and 16 are connected), which efficiently decelerates the high-speed flow and restores static pressure. It is well structured.

Configuration of the jet pump 4 (two-way jet pump 4)
The flow is shown below. The reactor water pressurized by the recirculation pump 5 is guided into the reactor pressure vessel 1 by the riser pipe 2, and is injected at high speed into the inlet mixer 15 by the nozzle 13 as driving water for the jet pump 4. The water around the suction port of the jet pump 4 is
1. Propellant water (2) is drawn and sucked into the inlet mixer 15 as 4+11 water. 15, the momentum of the driving water and the driven water is changed C2. Therefore, the downstream of the inlet mixer 15 (line 1 The water is guided to the diffuser 16 and decelerated (-thereby restoring the static pressure).

[Between background techniques; low point]

Here, in order for the diffuser 16 to work efficiently, the flow from the inlet mixer 15 outlet must have a sufficiently uniform velocity distribution.Also, the flow at the inlet mixer 15 outlet must be sufficiently mixed with carbon dioxide. If the velocity distribution is different from the turbulent velocity distribution (2), separation or deviation of the flow in the diffuser 16 will occur, and the expected performance will not be obtained. Because the flow is unstable, the core flow rate itself fluctuates, which could lead to instability such as fluctuations in the reactor output.Therefore, in order to improve the efficiency of the conventional jet pump 4 (second There was a proposal to increase the length of the inner body of the pump 4.However, the expansion angle of the diffuser 16 is approximately 5 degrees, which is efficient even when the diffuser 16 population has a turbulent velocity distribution. Since the outlet area of the diffuser 16 is limited by the required flow rate and the distance between the reactor pressure vessel 1 and the shroud 3, the length of the diffuser 16 is limited to 1h1. In order to provide a sufficiently uniform velocity distribution in the 16 population, increasing the mixing distance between the driving flow and the driven flow is limited by the space in which the jet pump 4 is installed in the reactor. Increasing the length by +*-2 increases the flow loss in the inlet (2,
There was a fear that the efficiency of the jet pump 4 as a whole would be reduced.

As mentioned above, there were various problems in order to improve the efficiency of conventional jet pumps.

[Purpose of the invention]

The purpose of the invention was based on the above situation, and to stabilize the flow inside the jet pump without changing the length of the jet pump itself installed inside the reactor (2).
An object of the present invention is to provide a jet pump for eliminating instability in nuclear reactor output caused by IL failure.

[Summary of the invention]

The present invention relates to a nuclear reactor pressure vessel and 15 parts of this reactor pressure vessel.
side (with two installed diffusers) and this diffuser (with one concentric (
An inlet mixer arranged in two rows, a nozzle provided concentrically on the upper part of the inlet mixer, a leg that connects and supports the nozzle and the inlet mixer, and a leg arranged concentrically with the nozzle. This is a jet pump for a nuclear reactor, which is characterized by having a jet pump for a nuclear reactor (2) and a driven water suction section (1) a driven water swirling means.

[Embodiments of the invention]

An embodiment of the present invention will be described using FIG. 3.

FIG. 3 is an enlarged sectional view showing only the essential parts of the present invention, and FIG. 4 is a sectional view taken along the line A--A in FIG. 3.

Note that the same parts as in the conventional example are given the same reference numerals.

Nozzle 13 of jet pump 20 and inlet mixer 1
51 Yu is Nozu A/13 and Inlent Miki? A plurality of legs 21 are welded between the periphery of the inlet of the inlet mixer gill and the nozzle 13 in order to fix the distance between the inlet mixer 15 and suspend the inlet mixer 15. The legs 21 are arranged diagonally in the same direction with respect to the center direction of the inlet mixer 13 as shown in FIG. 4 (-).

Therefore, in the jet pump application of the present invention, the driven flow is sucked into the inlet mixer 15 in the same direction (with a flow velocity of a swirling component) when passing through the leg 21.The driven flow has a swirling component. In this case, the axial direction of the inlet mixer 15 (
For the same mixing length, compared to flowing along two
The contact area between driven water and driving water is large, and momentum exchange efficiency is high. Therefore, in order for the movable water and the driven water to be sufficiently mixed and made homogeneous (-required inlet mixer), the length of 5 is shorter than when the excitation flow has a swirling component (1). If the driven water has a swirling component in the inlet mixer 15 population, some swirling component will remain at the inlet mixer 15 outlet even after mixing with the driving flow, and the swirling component will remain at the inlet mixer 15 inlet. It flows into the diffuser 16 with a swirling component.

When the flow velocity distribution of the Din User 16 has a swirling component, the flow within the diffuser 16 can flow without separation even if the spread is greater than in the case where it does not have a swirling component by 9 angles, and a stable flow can be obtained.

Therefore, the driven water (
When two swirling components are given, if the inlet mixer 15 and diffuser 16 are configured as before, the driving flow and the driven flow will be sufficiently mixed. recovery? It depends on what you do. ? Both the inlet mixer 15 and the diffuser 16 can be shortened without compromising the performance of conventional jet pumps, and the combined length can be shortened to provide a compact jet pump.

Next, another implementation sequence of the misfired 1st son will be explained with reference to Figure 5 of the 1st younger brother.The same parts as the implementation and U of Figure 5 A and 3 are given the same reference numerals.The nozzle of the jet pump 30 )! /13
F, the inlet mixer 31 is connected to the leg 14 (2 concentrically (= fixed), and the inlet mixer 3
A plurality of blades 32 are provided around the inner wall of the inlet 1 to swirl the suction flow of the permeated water.

Therefore, this embodiment provides the same effects as the embodiment shown in FIG. In addition, the swirling component of the present invention is obtained by dividing the nozzle that injects the driving flow at high speed into compound expressions, &dynamic flow (
- In order to give a swirling component (- It is also possible to use a fan arrangement in which the nozzles are spaced apart, or in the nozzle (2) In the case where vanes are provided to swirl the driving flow (1) to swirl the driving flow (
- also provides the same effect as the embodiment shown in FIG.

〔Effect of the invention〕

The jet pump according to the present invention can sufficiently mix driving water and driven water in the inlet mixer, and achieves a stable flow without separation of the flow in the diffuser. Fluctuations in discharge flow rate (
It is possible to eliminate the two factors that cause unstable reactor output. Also, since the length of the inlet mixer and diffuser can be shortened, it is possible to provide a jet pump for a narrow space between two walls in a nuclear reactor.

[Brief explanation of drawings]

Fig. 1 is a sectional view of a boiling water reactor incorporating a jet pump, Fig. 2 is a side view partially showing a conventional jet pump, and Fig. 3 is an embodiment of the jet pump according to the present invention. 4 is a sectional view showing only the main parts of the
FIG. 5 is a sectional view showing another embodiment of the present invention. 1... Reactor pressure vessel, 3... Shroud 4.2
0.30... Jet pump, 12... Riser pipe'' 3... Nozzle, 1.4.21... Leg 15.31
...Inlet mixer, 16...Diffuser: 3
2... Hane agent Patent attorney Nori Chika Keisuke (and 1 other person) Figure 1

Claims (3)

[Claims] (1) Reactor pressure vessel and the inside of this reactor pressure vessel (
= Between the installed shroud (2 installed diffusers, this diffuser (2 concentric (2 connected inlet mixers), and the upper part of this inlet mixer (2 concentric (2 installed nozzles), In a jet pump for a nuclear reactor, which includes legs that connect and support this nozzle and the inlet mixer, and a riser pipe that is concentrically connected to the nozzle, A jet pump for a nuclear reactor, which is characterized by the following: (2) The atom according to claim 1, wherein the driven water swirling means is a leg arranged obliquely toward the center of the inlet mixer and connecting and supporting the nozzle and the inlet mixer. Furnace jet pump. (3) The jet pot soap for a nuclear reactor according to claim 1, wherein the driven water swirling means is a plurality of guide vanes provided around the inner wall of the inlet mixer inlet.