KR20130079247A - Recovery system for cooling water reakage of coolant pump - Google Patents

Abstract

PURPOSE: A coolant recovery system of a reactor coolant pump is provided to collect coolant discharged through a draining channel in a reactor drain tank, thereby preventing the coolant from coming out to the outside. CONSTITUTION: A drain channel (211) is formed at least one of a pump casing (12) and a seal housing (21) for collecting coolant leaked between the pump casing and the seal housing in a reactor drain tank such that the coolant can be collected in the reactor drain tank even when caskets (26,27) that are installed between the pump casing and the seal housing are damaged.

Description

TECHNICAL FIELD [0001] The present invention relates to a coolant recovery apparatus for a nuclear reactor coolant pump,

The present invention relates to a coolant recovery apparatus for a reactor coolant pump that prevents coolant from leaking out of a pump in a reactor coolant pump that supplies a coolant to a reactor.

Generally, nuclear power is the principle of heating the water with the energy generated from the reactor and using the generated steam to start the turbine generator. To this end, a nuclear power generator is composed of a large energy generating reactor, a pump for circulating water, a steam generator for converting water into steam, and a pressurizer for pressure and volume control of the reactor coolant system. The reactor coolant system is equipped with a reactor coolant pump for circulating the coolant.

The reactor coolant pump is a heavy weight of about 150 tons or more. In the reactor coolant pump, a motor unit serving as a driving source is installed on the upper side, and a pumping unit is installed on the lower side to pump and circulate the coolant while operating by the motor unit. And the shaft of the motor unit (hereinafter referred to as the motor shaft) and the shaft of the pumping unit (hereinafter referred to as the pump shaft) is connected to the coupling is made to rotate simultaneously.

Here, the pumping unit consists of a vertical centrifugal pump having an impeller at its lower end, usually at high temperatures and pressures, e.g., 290.6 DEG C (555 DEG F) and 15.306 MPa (2200 psi) have.

The pumping unit of the reactor coolant pump as described above is supplied with sealing water to each stage of the three-stage seal from the charge pump of the chemical and volume control system during normal operation, and some of the sealing water injected into the first stage is lowered. The bearing is cooled and lubricated and the sealant is withdrawn into the pump casing of the pumping unit through a gap between the impeller and the diffuser facing the impeller and the service seal.

At this time, when the function of supplying the sealed water is lost, the recirculation seal injection line is opened to allow the reactor coolant in the pump casing to be recycled and supplied to the sealed water.

However, in the pumping unit of the conventional coolant pump as described above, although a gasket is provided on the contact surface between the pump casing and the seal housing that is in sealing contact with the upper surface of the pump casing, the gasket is damaged or the contact surface is damaged. The coolant pumped into the inner space of the pump casing may leak through the contact surface between the pump casing and the seal housing and be exposed to the outside.

It is an object of the present invention to provide a coolant recovery apparatus for a reactor coolant pump that can prevent coolant from leaking between contact surfaces between a pump casing and an actual housing.

In order to achieve the object of the present invention, a pump shaft coupled to the motor shaft, the pumping unit is provided with an impeller coupled to the pump shaft to pump the coolant while rotating; And a sealing unit for supplying a sealing water between the pump shaft and a bearing water holding part for supporting the pump shaft, wherein the pump casing forming the pumping unit and the seal housing constituting the sealing unit are axially opposed to each other And a drain path for communicating with a contact surface between the pump casing and the seal housing so as to drain the coolant at the contact surface is formed on at least one of the seal housing and the pump casing. A coolant recovery apparatus may be provided.

At least one gasket may be provided on a contact surface between the pump casing and the seal housing, and at least one gasket may be disposed outside the drain passage.

Two gaskets may be provided on a plane at predetermined intervals, and the drainage passage may be formed to communicate with a space formed between the two gaskets.

A drainage groove may be formed on the surface corresponding to the end of the drainage passage so as to contain the coolant.

And the drainage passage may be connected to the inlet side of the sealing unit through a drainage line.

The coolant recovery apparatus for a reactor coolant pump according to the present invention is characterized in that at least either of the pump casing and the seal housing is provided with a drainage passage for collecting cooling water leaked between the pump casing and the seal housing into the drainage tank, Even if the gasket provided between the housings is damaged, the coolant can be collected into the reactor drainage tank through the drainage passage, and thus the coolant can be prevented from leaking to the outside of the coolant pump.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram showing a configuration in which a sealing water is circulated and supplied in a reactor coolant pump according to the present invention;
FIG. 2 is a longitudinal sectional view showing a part of the reactor coolant pump according to FIG.
FIGS. 3 and 4 are enlarged vertical sectional views of the 'A' portion of FIG. 2, wherein FIG. 3 shows a case where there are a plurality of gaskets, and FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a coolant recovery apparatus for a nuclear reactor coolant pump according to the present invention will be described in detail with reference to an embodiment shown in the accompanying drawings.

FIG. 1 is a schematic diagram showing a configuration in which a sealing water is circulated and supplied to a reactor coolant pump according to the present invention, and FIG. 2 is a longitudinal sectional view showing a part of a reactor coolant pump according to FIG.

As shown therein, the reactor coolant pump 1 according to the present embodiment includes a pump shaft 11 coupled to a motor shaft (not shown) to pump a coolant, and a pump shaft 11. ) And a sealing unit 20 for supplying sealing water between the bearing part (not shown) for supporting the pump shaft 11.

2 and 3, the pumping unit 10, the impeller 13 is rotatably installed inside the pump casing 12, the discharge side of the impeller 13 is pumped through the impeller 13 The diffuser 14 may be installed to increase the pressure of the coolant.

The impeller 13 is integrally coupled to the pump shaft 11 by the impeller stud bolt 15, and a lower bearing 16 constituting the water bearing part is installed at the lower end of the pump shaft 11, and the lower bearing 16 is connected to the pump shaft 11. A service seal 17 may be fixedly installed between the impellers 13 to prevent the reactor coolant contained in the inner space of the pump casing 12 from flowing backward in the lower bearing direction. The service chamber 17 may be installed such that its bottom surface is spaced apart from the upper surface of the impeller 13 by a predetermined gap.

The pump casing 12 has an internal space 121 having a predetermined volume, a suction port 122 is formed at the lower end of the pump casing 12, and the side of the pump casing 12 communicates with the coolant inlet of the reactor. The discharge port 123 may be formed. In addition, the inner space 121 of the pump casing 12 may be connected to the recycling chamber injection line 257 of the sealing unit 20 to be described later.

The sealing unit 20 is installed to contact the pump casing 12 of the pumping unit 10, as shown in Figs. 1 and 2 and seal housing (seal housing 21) surrounding the lower end of the pump shaft (11), It may be made of a sealing water supply portion 25 through the coupling to the seal housing 21 to supply the sealing water to the outer peripheral surface of the pump shaft (11). The sealing water supply unit 25 may be formed in a plurality of stages along the axial direction of the pump shaft 11 (examples of the three stages are shown in the drawing).

The sealing water supply unit 25 includes an injection line 251 connected to a charging pump (not shown), a cooler 252 installed between the injection line 251 and cooling the sealing water, 251, 252, 253, 254, 252, 254, 252, 254, 252, 253, 254, 255).

The recovery type sealing lines 253 and 254 include a first stage sealing line 253 and a second stage sealing line 254 close to the pumping unit 10 based on the pumping unit 10, and a circular sealing line Reference numeral 255 may include a three-stage sealing line 255 farthest from the pumping unit 10 and closest to the motor. The two-stage sealing line 254 may be combined with the three-stage sealing line 255 to form a drainage line 256.

1, the pump casing 12 and the injection line 251 of the pumping unit 10 are connected to the recycle chamber injection line 257, and in the middle of the recycle chamber injection line 257, A recirculation valve 258 may be provided to selectively open and close the line.

Reactor coolant pump according to the present embodiment as described above has the following effects.

That is, the sealing water supplied through the injection line 251 supports the pump shaft 11 and the pump shaft 11 through the first-stage sealing line 253 and the two-stage sealing line 254, which are reclaimable sealing lines. It is supplied between the bearing portion to prevent the leakage of the coolant of the pump casing 12 between the outer circumferential surface of the pump shaft 11 and the inner circumferential surface of the pump shaft 11, and at the same time lubricating action so that the pump shaft 11 can rotate smoothly Done.

Here, when a failure occurs in the injection supply channel including the injection line 251, the supply of the sealing water through the injection line 251 is stopped, and the recirculation valve 258 is opened to open the internal space 121 of the pump casing 12. The reactor coolant contained in the NF is supplied to each of the sealing lines 253, 254, and 255 through the recirculation chamber injection line 257.

At this time, a gasket is installed between the pump casing 12 of the pumping unit 10 and the seal housing 21 of the sealing unit 20. However, when the gasket is damaged, the pump casing 12 and the seal housing 21 are damaged. The coolant may leak and be exposed to the outside.

3, a drain path 211 is formed through the seal housing 21 so as to communicate with a space between both the gaskets 26 and 27, Even if the gasket provided between the pump casing 12 and the seal housing 21 is aged or damaged by recovering the coolant to be leaked between the casing 12 and the seal housing 21 by the charge pump, It is possible to prevent the coolant from leaking into the gap between the first and second openings 21.

The drainage passage 211 has a first drainage hole 211a penetrating in a radial direction of the threaded housing 21 and the other end connected to a reactor drainage tank (not marked) through a drainage line 212, And a second drain hole 211b penetrating from the other end of the first housing 211a to the bottom surface of the threaded housing 21. Thereby, a coolant to be leaked between the pump casing and the seal housing is recovered to the drain line 212 through the second drain hole and the first drain hole, and the coolant can be recovered through the injection line 251 to the charge pump.

The gasket insertion grooves 121 may be formed in the contact surfaces of the seal housing 21 and the corresponding pump casing 12 so that the gaskets 26 and 27 are inserted and fixed, respectively. The gasket insertion grooves 121 may be formed at predetermined intervals in the radial direction on the plane of the pump casing 12. [ A drainage groove 122 having a predetermined depth may be formed in the space between the gasket insertion grooves on the contact surface of the pump casing 12 so as to fill the coolant to be leaked to the outside. The drainage groove 122 may be formed such that the end of the second drainage hole 211b is correspondingly formed.

The end of the second drain hole 211b is formed to communicate with a space between the gaskets 26 and 27 when there are a plurality of the gaskets 26 and 27, It may be preferable that the gasket 27 is formed so as to communicate with the space between the pump casing 12 and the seal housing 21 inward.

Meanwhile, it is preferable that a drainage pump 213 is installed in the middle of the drainage line 212 to allow the coolant to be sucked through the drainage passage 211.

 In this way, even if the gasket provided between the pump casing and the seal housing is damaged, the coolant is discharged to the outside of the coolant pump by discharging the coolant to the charge pump by the drain passage communicating with the contact surface between the pump casing and the seal housing. So that it can be prevented from being exposed.

12: Pump casing 121: Gasket insertion groove
122: drainage groove 13: impeller
21: Actual housing 211:
211a: first drain hole 211b: second drain hole
26,27: Gasket

Claims (5)

A pumping unit coupled to the motor shaft, and a pumping unit having an impeller coupled to the pump shaft to pump the coolant while rotating; And
And a sealing unit for supplying sealing water between the pump shaft and the bearing portion supporting the pump shaft.
Wherein a pump casing constituting the pumping unit and an actual housing constituting the sealing unit are installed so as to face each other in the axial direction,
Wherein a drain path for communicating with the contact surface between the pump casing and the seal housing and discharging the coolant on the contact surface is formed on at least one of the seal housing and the pump casing. Recovery device. The method of claim 1,
At least one gasket is provided on a contact surface between the pump casing and the seal housing,
And at least one gasket is disposed on the outer side of the drainage flow path. The method of claim 2,
Wherein the two gaskets are installed on a plane at a predetermined interval, and the drainage passage is formed to communicate with a space formed between the two gaskets. The method of claim 3,
And a drain groove is formed on a surface of the drainage passage corresponding to the end of the drainage passage so that the coolant can be contained therein. 5. The method according to any one of claims 1 to 4,
Wherein the drainage passage is connected to an inlet side of the sealing unit through a drainage line.

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