KR101257619B1 - Flange type nozzle with concentric inner cylinder - Google Patents

Abstract

The reactor vessel of the integral reactor is provided with a water supply nozzle and a steam nozzle for coupling the steam generator feed header and the steam header. The concentric, double-pipe flanged nozzle connecting the steam generator is coupled to a water supply header or a steam header, one end of which is coupled to the reactor vessel, the other end of which is flanged, inserted into the outer nozzle and inserted into the outer nozzle. And an inner cylinder disposed on a concentric circle, a blinder coupled to close the flange of the outer nozzle, and a plurality of fastening members fastening the blinder to the flange.

Description

FLANGE TYPE NOZZLE WITH CONCENTRIC INNER CYLINDER}

The present invention is to provide a connection structure of the water supply and steam nozzles that can be inspected during the maintenance and operation of the steam generator installed inside the integrated reactor in the pressurized water reactor system of the nuclear power plant.

Nuclear power uses the enormous energy of the nucleus of materials such as uranium. Various types of nuclear reactors, such as pressurized light water reactors, pressurized heavy water reactors, boiling water reactors, and liquid metal furnaces, have been used to slowly dissipate and convert nuclear energy generated when nuclear atoms are split or fused into electrical energy.

The PWR system consists of a reactor, a steam generator, a reactor cooling pump (RCP), and a pressurizer.The coolant is connected by cold and hot leg pipes connecting the components. The circulation circuit is made.

The nuclear power plant steam generator uses the heat of the reactor coolant heated at the core to heat the secondary cooling water to produce steam during reactor output operation to generate electricity by rotating the turbine.In case of reactor cooling and accidents, the residual heat of the primary system is generated. It is a device to remove.

The steam generator of the commercial nuclear power plant is a recirculation U-tube steam generator in which the reactor tube and the pipe are separated and the heat pipes are U-shaped and the high-temperature reactor coolant of the primary system flows inside the heat pipe.

Unlike the commercial nuclear power plant, the steam generator has a form of a once-through spiral steam generator in which a steam generator is built into the reactor vessel. The steam generator circulates the secondary coolant inside the heat transfer pipe to directly produce superheated steam by heat exchange with the primary reactor coolant flowing outside the heat transfer pipe and removes residual heat from the primary system in case of reactor cooling operation and accident. do.

In the integrated reactor, the nozzle structure in which the steam generator located in the reactor vessel and the secondary cooling water system is connected generally has a method of directly connecting a pipe to the nozzle or a flanged pipe directly to the nozzle by bolts. These existing methods require extra work to fix the steam generator to the reactor vessel inner wall and seal the nozzle connections. In addition, when the steam generator is to be withdrawn or an in-service inspection is performed, the pipe connected to the nozzle is first removed. There was a difficulty in performing a series of tasks that require disassembly of the connecting pipes after cutting or removing the flanges.
For the nozzle structure connecting the steam generator and the secondary cooling water system in such an integrated reactor, ME Ricotti's "Preliminary safety analysis of the IRIS reactor" ((2002) 10th International conference on nuclear engineering, ICONE10-22398) and CV Lombardi "Pressure vessel and internals of the international reactor innovative and secure" ((2002) 10th International conference on nuclear engineering, ICONE10-22523).

According to embodiments of the present invention to provide a nozzle for a steam generator having a structure capable of inspecting during maintenance and operation of the steam generator without cutting or disassembling the pipe connected to the water supply nozzle and the steam nozzle formed in the reactor vessel.

In the water supply nozzle and the steam nozzle of the integrated reactor steam generator according to the embodiments of the present invention described above, the concentric, double-pipe flanged nozzle is coupled to the water supply nozzle or the steam nozzle, one end of which is coupled to the reactor vessel, and the other end thereof. A flange formed outer nozzle, an inner cylinder inserted into the outer nozzle and disposed concentrically with the outer nozzle, a blinder coupled to close the flange of the outer nozzle, and a plurality of fastening members fastening the blinder to the flange. It is configured to include.

According to one side, the inner cylinder is formed on one side of the inner cylinder, the secondary cooling water flow nozzle for providing a flow path for supplying water or discharging steam from the secondary system, the inner cylinder is formed inside the inner cylinder Blocking plate for blocking and is formed at the end of the inner cylinder is coupled to the blind and comprises a rotation preventing groove for preventing the rotation of the inner cylinder. Here, the blinder is formed with an inner cylinder support protrusion inserted into the rotation prevention groove at a position corresponding to the rotation prevention groove. A protruding outer jaw is formed at a portion of the inner cylinder coupled to the steam generator fixing jaw and the steam generator header. The outer nozzle and the inner cylinder are provided to be spaced apart from each other.

According to one side, the one side of the outer nozzle is provided with a pipe connection nozzle for connection with the pipe.

According to one side, the fastening member is a stud bolt is used.

As described above, according to the embodiments of the present invention, it is possible to perform maintenance work and in-service inspection of the steam generator without cutting or dismantling the pipe of the secondary system connected to the pipe connection nozzle.

In addition, it is possible to mitigate the thermal shock of the reactor vessel in the case of a sudden temperature change of the secondary cooling water.

1 is a perspective view of main parts of a concentric, double-pipe flanged nozzle portion according to one embodiment of the present invention;
FIG. 2 is an exploded perspective view of the flanged nozzle of FIG. 1. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings, but the present invention is not limited to or limited by the embodiments. In describing the present invention, a detailed description of known functions or configurations may be omitted to clarify the gist of the present invention.

Hereinafter, the structure of the steam generator 20 and the flanged nozzle 23 according to an embodiment of the present invention will be described in detail with reference to FIGS. 1 and 2.

Referring to the drawings, a steam generator 20 is provided inside the reactor vessel 21. The steam generator 20 has a plurality of heat transfer tube (not shown) bundle is wound in the form of a helical coil, the reactor coolant heated in the core flows to the outside of the heat pipe and the secondary coolant flows inside the heat pipe. Steam is generated by heat exchange between the reactor coolant and the secondary coolant.

For reference, a detailed technical configuration of the integrated reactor steam generator 20 can be understood from the known art, and since it is not the gist of the present invention, a detailed description will be omitted and only the main components will be briefly described.

A water supply nozzle for supplying water to the heat transfer pipe is connected to the water supply header at the bottom of the steam generator 20, and a steam nozzle for discharging steam generated through the heat transfer pipe is connected to the steam header at the top of the steam generator.

Hereinafter, the water supply nozzle will be described as an example, but the flange-type nozzle 23 structure according to the present invention can be similarly applied to a steam nozzle.

The flanged nozzle 23 is composed of an inner cylinder 25 and an outer nozzle 231 disposed on concentric circles, and the inner cylinder 25 is inserted into and coupled to the outer nozzle 231. It is configured.

The steam generator 20 is provided with a steam generator header 211 coupled with the water supply / steam nozzle of the reactor vessel 21 to inject cooling water and discharge steam, and includes a plurality of stud bolts for the steam generator. A stud bolts for steam generator 215 is provided to fix the steam generator header 211 to the reactor vessel 21. Here, reference numeral 213 denotes a steam generator header support 213 in which the inner cylinder 25 is inserted and supported and installs a stud bolt 211 for the steam generator.

One side of the outer nozzle 231 is joined to the reactor vessel 21 by welding, and the other side is a flange for steam generator nozzle 233 to which the blinder 29 is attached. One side of the external nozzle 231 is provided with a feed water & steam nozzle to piping 26 for connection with a pipe line 27.

The inner cylinder 25 is inserted into and fixed to the steam generator holding jaw 213 and the blinder 29 installed inside the reactor vessel 21. Here, the inner cylinder 25 and the outer nozzle 231 are spaced apart at predetermined intervals so that an empty space is formed therebetween, and the secondary space is filled with secondary cooling water and steam.

The inner cylinder 25 has a secondary coolant flow nozzle 251 that provides a flow path for supplying water or discharging steam from the secondary system. And the middle portion of the inner cylinder 25 is attached to the blocking plate 253 for the smooth flow of water and steam. Here, the blocking plate 253 is formed at a position where the secondary coolant flow nozzle 251 is formed, and the internal space defined by the blocking plate 253 becomes a flow space so that the coolant and the secondary cooling water flow nozzle 251 are formed. Flow the steam.

The blinder 29 is formed to close the end of the flange 233. For example, the blinder 29 has a disk shape having a size corresponding to the flange 233. A plurality of blind stud bolts 31 provided along the circumference of the blinder 29 fasten the blinder 29 to the flange 233. In the drawings, reference numeral 291 denotes a fastening part 291 to which the stud bolt 31 for the blinder is fastened.

The blind 29 and the inner cylinder 25 are coupled to each other to prevent the inner cylinder 25 from rotating. An inner cylinder support ledge 293 protruding a predetermined height is formed in a central portion of the inner surface where the blind 29 is coupled to the inner cylinder 25, and the inner cylinder 25 is rotated to a predetermined depth. An anti-rotating groove 255 is formed. In addition, when the inner cylinder support protrusion 293 is inserted into and coupled to the rotation preventing groove 255, the inner cylinder 25 may be prevented from rotating. In addition, an outer ledge 257 protruding outward a predetermined height is formed at one side of the inner cylinder 25. The outer jaw 257 serves to limit the depth at which the inner cylinder 25 is inserted into and coupled to the outer nozzle 231 and the steam generator header 211.

Hereinafter, an operation of the flanged nozzle 23 according to embodiments of the present invention will be described with reference to the drawings.

When the blind 29 is fastened to the outer nozzle 231 with the stud bolt 31 for the blind, the inner cylinder 25 is pulled to open the flanged nozzle 23. In this way, the open passage can be inspected during the operation of the inner wall of the steam generator 20, and the dismantling of the steam generator stud bolt 215 for detaching / attaching the steam generator 20 to the reactor vessel 21. And a fastening operation. The annular space between the inner cylinder 25 and the outer nozzle 231 is filled with secondary coolant and steam to mitigate thermal shock generated in the reactor vessel 21 even when a sudden temperature change of the secondary coolant and steam occurs.

According to the present embodiments, the concentric flanged nozzle 23 of the double pipe flange type can be applied to both the water supply nozzle and the steam nozzle of the SMART integrated reactor. In addition, the flanged nozzle 23 separates the blinder 29 from the flange 233 to perform maintenance work and in-service inspection of the steam generator 20 without cutting or dismantling the piping 27 of the secondary system. Can be done. In addition, the reactor vessel 21 may be used in a situation where the temperature of the secondary coolant and steam in the inner cylinder 25 changes rapidly due to the coolant and steam filled between the flange-shaped nozzle 23 and the inner cylinder 25. It can alleviate the thermal shock acting on.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. In addition, the present invention is not limited to the above-described embodiments, and various modifications and variations are possible to those skilled in the art to which the present invention pertains. Therefore, the spirit of the present invention should not be construed as being limited to the above-described embodiments, and all of the equivalents or equivalents of the claims, as well as the following claims, are included in the scope of the present invention.

20: steam generator
21: reactor vessel
23: flanged nozzle
25: inner cylinder
26: feed water & steam nozzle to piping
27: pipe line
29: blind
31: blind stud bolt
211: steam generator header
213: steam generator header support
215: stud bolts for steam generator
231: outer nozzle
233: flange for steam generator nozzle
251: secondary coolant flow nozzle
253: blocking plate
255: anti-rotating groove
257: outer ledge
291: fastening
293: inner cylinder support ledge

Claims (7)

In a flanged nozzle in which the steam generator located in the reactor vessel and the secondary cooling water system in the integrated reactor,
A water supply nozzle or steam nozzle for coupling the steam generator to the reactor vessel, the outer nozzle having one end coupled to the reactor vessel and having a flange formed at the other end thereof;
An inner cylinder inserted into the outer nozzle and disposed on a concentric circle with the outer nozzle;
A blinder coupled to close the flange of the outer nozzle; And
A plurality of fastening members fastening the blinder to the flange;
Concentric flanged nozzle of the conduit type.
The method of claim 1,
The inner cylinder,
A secondary coolant flow nozzle formed on one side of the inner cylinder and providing a flow path for supplying water and discharging steam from the secondary system;
A blocking plate formed inside the inner cylinder to block the inner cylinder; And
A rotation preventing groove formed at an end of the inner cylinder to be coupled to the blinder to prevent rotation of the inner cylinder;
Concentric flanged nozzle of the conduit type.
The method of claim 2,
The blinder is a concentric, double-pipe-type flange-type nozzle having an inner cylinder support protrusion is inserted into the rotation prevention groove in a position corresponding to the rotation prevention groove.
The method of claim 2,
A portion of the inner cylinder coupled to the steam generator fixing jaw is a concentric double tube type flange-type nozzle having a protruding outer jaw is formed.
The method of claim 2,
The outer nozzle and the inner cylinder are flanged nozzle of the concentric double tube type provided spaced apart from each other.
The method of claim 1,
One side of the outer nozzle is a flange type nozzle of the concentric double pipe type provided with a pipe connection nozzle for connecting to the pipe.
The method of claim 1,
The fastening member is a stud bolt concentric flange type nozzle.

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