KR102488033B1 - In-Core Thimble Tube Guide Tool in Reactor Vessel - Google Patents

Abstract

Provided is a guide device for providing moving paths of in-core instrumentation tubes when moving the in-core instrumentation tubes into a reactor. According to an embodiment of the present invention, the in-core instrumentation tube guide device in a reactor comprises: an upper support plate; a lower support plate provided below the upper support plate; and guide tubes extending in a longitudinal direction from the upper support plate to the lower support plate to provide moving paths of in-core instrumentation tubes. Therefore, the in-core instrumentation tube guide device can be moved to the inside of the reactor or replaced while maintaining straightness without bending or damaging the in-core instrumentation tubes, thereby reducing exposure of workers to radiation and enabling efficient distribution of working hours.

Description

In-Core Thimble Tube Guide Tool in Reactor Vessel}

The present invention relates to an auxiliary device used during inspection and maintenance of a nuclear power plant, and more particularly, to a guide device providing a moving path for an in-furnace nuclear measurement tube when moving it into a nuclear reactor.

FIG. 1 is a view illustrating an in-reactor nuclear instrumentation tube connected to a lower head of a fuel assembly 10 of a primary system of a nuclear reactor, and FIG. 2 is a view illustrating a nuclear fuel assembly being pulled out.

The in-reactor nuclear measuring tube 20 shown in FIG. 1 is a tube that is elevated and inserted into the inside of the nuclear fuel assembly 10 to measure the output state inside the reactor when the reactor is in operation, and moves along the in-reactor nuclear measuring tube guide tube. In addition, the hole inside the fuel assembly serves as a guide when the tube ascends and prevents the tube from bending to maintain straightness and prevent damage.

Specifically, the in-reactor nuclear measurement tube 20 can maintain a state of being moved to the lower portion of the core support plate before nuclear fuel is withdrawn during the planned preventive maintenance period of the nuclear power plant, but inspection/maintenance of the reactor lower head and its surroundings or replacement of the in-reactor nuclear measurement tube is required. If necessary, re-elevation or insertion of the in-reactor nuclear measurement tube 20 is required, but when the nuclear fuel is removed, the in-reactor nuclear measurement tube 20 does not maintain its shape and rises in a bent state when it is raised inside the reactor, increasing the possibility of damage A problem exists.

In addition, inspection and maintenance around the lower head of the existing nuclear reactor must be performed with the nuclear measurement tube 20 installed in the reactor, resulting in frequent breakdowns of inspection and maintenance equipment due to high radiation dose and short work time per individual due to the risk of overexposure to workers. And there is a problem in power plant exposure management due to the input of large-scale manpower.

In addition, if the in-reactor nuclear measurement tube 20 is raised to the inside of the reactor after fuel withdrawal, the radiation dose around the lower head of the nuclear fuel assembly 10 is lowered, thereby reducing exposure and increasing working time. There is a problem that the tube rises in a bent state because there is no device to accurately fix the tube and there is a possibility of damage.

The present invention has been made to solve the above problems, and an object of the present invention is to raise and insert the nuclear measurement tube in the reactor along the tube guide tube without bending when ascending into the reactor, and to inspect and maintain the lower head and surroundings of the reactor When the nuclear measurement tube is lifted, the nuclear measurement tube inside the reactor is moved to the bottom of the reactor, so that the tube guide device for nuclear measurement inside the reactor can be moved or replaced inside the reactor while maintaining straightness without bending or damaging the tube. is in providing

According to one embodiment of the present invention for achieving the above object, a nuclear instrumentation tube guide device in a nuclear reactor inner furnace includes an upper support plate; a lower support plate provided below the upper support plate; and a guide tube extending along the longitudinal direction from the upper support plate to the lower support plate so as to provide a moving path of the nuclear measurement tube in the furnace.

In addition, according to an embodiment of the present invention, the nuclear measurement tube guide device in the reactor is formed on the upper support plate and the lower support plate, respectively, so that a separately provided underwater camera for monitoring is allowed to enter when the nuclear measurement tube in the reactor is moved. and a plurality of flow holes to reduce disturbance of the flow flow when entering or moving underwater in the reactor.

In addition, according to an embodiment of the present invention, a plurality of in-furnace nuclear measurement tube guide devices are installed at the lower end of the lower support plate so that the in-furnace nuclear measurement tube moves along the guide tube, and the lower end of the lower support plate is fixed. A lower support plate fixing pin to do; may further include.

And the lower support plate fixing pin, the first fixing pin; and a plurality of second fixing pins having a length shorter than that of the first fixing pin and disposed adjacent to the first fixing pin.

In addition, the lower part of the guide tube extends to the lower side of the lower support plate through the flow hole of the lower support plate, and the lower end of the guide tube extending to the lower side of the lower support plate has a fallopian tube whose diameter increases toward the lower side. A guide cone may be provided that is formed into a shape and guides the in-furnace nuclear measurement tube to more easily enter the guide tube.

And, according to an embodiment of the present invention, the nuclear instrumentation tube guide device in the reactor inner furnace is disposed adjacent to the guide tube, and extends along the longitudinal direction of the guide tube from the upper support plate to the lower support plate, and the upper support plate and the lower support plate A support plate fixing structure for supporting so that the coupling between the support plate and the guide tube is maintained; may further include.

In addition, according to an embodiment of the present invention, a nuclear instrumentation tube guide device in a reactor interior furnace includes a plurality of lifting lugs installed on the upper side of an upper support plate so that the upper support plate is raised or lowered using a separately provided lifting means; may further include.

On the other hand, according to another embodiment of the present invention, a nuclear measurement tube guide system in a furnace inside a nuclear reactor includes an in-furnace nuclear measurement tube provided for nuclear measurement in a furnace inside a nuclear reactor; and an upper support plate, a lower support plate provided below the upper support plate, and a guide pipe extending from the upper support plate to the lower support plate in the longitudinal direction so as to provide a moving path of the nuclear measurement tube in the furnace. A nuclear measuring tube guide device; includes

As described above, according to the embodiments of the present invention, the in-reactor nuclear measurement tube can be moved or replaced inside the reactor while maintaining its straightness without being bent or damaged, thereby reducing the radiation exposure of workers and enabling efficient distribution of working hours. can make it possible.

1 is a view illustrating an in-reactor nuclear instrumentation tube connected to a lower head (nuclear fuel assembly) of a nuclear fuel assembly 10 of a primary system of a nuclear reactor;
2 is a view illustrating a state of withdrawing a nuclear fuel assembly;
3 is a view illustrating a state in which a nuclear instrumentation tube guide device in a reactor internal furnace according to an embodiment of the present invention is installed in a nuclear fuel assembly;
4 is a view provided for explaining the configuration of a nuclear instrumentation tube guide device in a reactor internal furnace according to an embodiment of the present invention;
5 is a view provided in a more detailed description of a guide pipe according to an embodiment of the present invention;
6 is a view provided for explanation of a lower support plate fixing pin according to an embodiment of the present invention;
7 is a view provided in a more detailed description of a lower support plate fixing pin according to an embodiment of the present invention, and
8 to 9 are views provided for explanation of a lower support plate according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

3 is a view illustrating a state in which the nuclear instrumentation tube guide device 100 in a nuclear reactor internal furnace according to an embodiment of the present invention is installed in a nuclear fuel assembly, and FIG. It is a drawing provided in the configuration description of the nuclear measurement tube guide device 100.

The nuclear measurement tube guide device 100 in the nuclear reactor according to the present embodiment is provided so that the nuclear measurement tube 20 in the reactor is not bent or damaged, maintains straightness, and can be moved or replaced inside the reactor.

Specifically, when the nuclear measurement tube guide device 100 inside the reactor is moved into the reactor, the nuclear measurement tube 20 is inserted along the guide tube without bending, and when the inspection and maintenance of the lower head and surroundings of the reactor are completed, By moving the in-reactor nuclear measurement tube 20 back to the bottom of the reactor, it is possible to move or replace the in-reactor nuclear measurement tube 20 into the reactor.

To this end, the nuclear instrumentation tube guide device 100 in the reactor internal furnace includes an upper support plate 110, a lifting lug 120, a flow hole 130, a guide pipe 140, a support plate fixing structure 150, and a lower support plate ( 160) and a lower support plate fixing pin 170.

The upper support plate 110 is provided on the upper side, so that the nuclear measurement tube 20 and the guide tube 140 in the furnace can be installed.

A plurality of lifting lugs 120 are installed on the upper side of the upper support plate 110, and the upper support plate 110 can be moved (raised or lowered) using a separately provided lifting means (ex. wire sling). .

For example, the lifting lugs 120 are installed on the upper edge of the upper support plate 110 at four points on the upper, lower, left and right sides, and are lifted by a separately provided lifting means so that the upper support plate 110 is raised or lowered. can

A plurality of flow holes 130 are formed in the upper support plate 110 and the lower support plate 160, respectively, so that a separate underwater camera (not shown) for monitoring the movement of the nuclear measurement tube 20 in the furnace can be entered. It is possible to reduce the disturbance of the fluid flow when entering or moving underwater in a nuclear reactor.

The guide tube 140 may extend along the longitudinal direction from the upper support plate 110 to the lower support plate 160 .

Specifically, a plurality of guide tubes 140 may be provided between the upper support plate 110 and the lower support plate 160 to provide a movement path for the nuclear measurement tube 20 in the furnace.

At this time, the guide tube 140 may extend to the lower side of the lower support plate 160 through the flow hole 130 of the lower support plate 160 .

That is, when the in-furnace nuclear measurement tube 20 moves into the reactor, it can be inserted along the guide tube 140 without bending.

The support plate fixing structure 150 is disposed adjacent to the guide tube 140, and extends along the longitudinal direction of the guide tube 140 from the upper support plate 110 to the lower support plate 160, and the upper support plate 110 ) And the coupling between the lower support plate 160 and the guide tube 140 can be maintained.

The lower support plate 160 is provided on the lower side of the upper support plate 110, and after the reactor upper internals and fuel are removed, the lower support plate fixing pins ( 170) can be settled.

A plurality of lower support plate fixing pins 170 are installed at the lower end of the lower support plate 160 so that the in-furnace nuclear measurement tube 20 moves along the guide tube 140 so that the lower end of the lower support plate 160 is fixed. can do.

5 is a view provided for a more detailed description of the guide pipe 140 according to an embodiment of the present invention.

Referring to FIG. 5 , the guide tube 140 is provided in plurality between the upper support plate 110 and the lower support plate 160 as described above, and extends from the upper support plate 110 to the lower support plate 160 in the longitudinal direction. It is formed to extend along the furnace, so that a moving path of the nuclear measurement tube 20 in the furnace can be provided.

Further, the guide pipe 140 may extend to a lower side of the lower support plate 160 through a lower portion passing through the flow hole 130 of the lower support plate 160 .

At this time, the lower end of the guide tube 140 extending to the lower side of the lower support plate 160 may be provided with a guide cone 141 formed in the shape of a fallopian tube whose diameter increases toward the lower side.

The guide cone 141 is formed in the shape of a fallopian tube whose diameter increases toward the lower side, so that the nuclear measurement tube 20 in the furnace can be guided into the guide tube 140 more easily.

6 is a view provided for explanation of the lower support plate fixing pin 170 according to an embodiment of the present invention, and FIG. 7 is a more detailed description of the lower support plate fixing pin 170 according to an embodiment of the present invention. 8 and 9 are views provided for explanation of the lower support plate 160 according to an embodiment of the present invention.

As described above, a plurality of lower support plate fixing pins 170 according to an embodiment of the present invention are installed at the lower end of the lower support plate 160 so that the lower end of the lower support plate 160 is fixed, so that the in-furnace nuclear instrumentation tube (20) can be moved along the guide tube (140).

To this end, the lower support plate fixing pin 170 has a length shorter than that of the first fixing pin 171 and a plurality of first fixing pins 171 disposed adjacent to the first fixing pin 171. 2 fixing pins 172 may be included.

For example, when the first fixing pin 171 is installed in the area A-1 in FIG. 9, A-2, A-3 and A- in FIG. 9 corresponding to positions adjacent to the first fixing pin 171. The second fixing pins 172 may be individually installed in each of the four areas, and the guide tube 140 may be installed at the upper end of the midpoint of the area where the first fixing pin 171 and the plurality of second fixing pins 172 are installed. This installation allows the in-furnace nuclear measurement tube 20 to move along the guide tube 140 .

That is, the lower support plate 160 in the lower internals of the nuclear reactor capable of supporting the fuel after the fuel is removed includes the first fixing pin 171 and the plurality of first fixing pins 171 so that the nuclear measurement tube 20 in the reactor is set and fixed in an accurate position. 2 fixing pins 172 are installed, through which the in-furnace nuclear measuring tube 20 whose position is set by the first fixing pin 171 and the plurality of second fixing pins 172 is located on the lower support plate 160. When seated on the top, it can be automatically moved along the guide tube (140).

Here, when the in-furnace nuclear measurement tube 20 reaches the lower end of the lower support plate 160, when the first fixing pin 171 is first set to match the position of the in-furnace nuclear measurement tube 20, a plurality of first fixing pins 171 are set. The position of the nuclear measurement tube 20 in the furnace can be finely set and fixed through the two fixing pins 172 .

Through this, the nuclear measurement tube 20 in the furnace can be moved or replaced inside the reactor while maintaining straightness without being bent or damaged, thereby reducing exposure of workers and enabling efficient distribution of working hours.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and is common in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible by those who have knowledge of, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

10: nuclear fuel assembly
20: In-furnace nuclear measurement tube
30: actuator
40: Conventional guide pipe
100: Nuclear measurement tube guide device
110: upper support plate
120: lifting rug
130: Flow Hole
140: guide pipe
141: guide cone
150: support plate fixed structure
160: lower support plate
170: lower support plate fixing pin
171: first fixing pin
172: second fixing pin

Claims (8)

upper support plate;
a lower support plate provided below the upper support plate; and
A guide tube extending along the longitudinal direction from the upper support plate to the lower support plate to provide a moving path of the nuclear measurement tube in the furnace;
It is formed on the upper support plate and the lower support plate, respectively, to enable entry of a separately provided underwater camera for monitoring when the nuclear instrumentation tube is moved in the reactor, and to reduce disturbance of the flow flow when entering or moving underwater in the reactor. A plurality of flow holes (Flow Hole); nuclear instrumentation tube guide device inside the nuclear reactor, characterized in that it further comprises.
delete The method of claim 1,
and a plurality of lower support plate fixing pins installed at the lower end of the lower support plate to allow the in-furnace nuclear measurement tube to move along the guide tube so that the lower end of the lower support plate is fixed. Device.
The method of claim 3,
The lower support plate fixing pin,
a first fixing pin; and
A nuclear instrumentation tube guide device in a reactor internal furnace, comprising: a plurality of second fixing pins having a length shorter than that of the first fixing pin and disposed adjacent to the first fixing pin.
The method of claim 1,
the guide,
The lower portion passes through the flow hole of the lower support plate and extends to the lower side of the lower support plate,
The lower end of the guide tube extending to the lower side of the lower support plate,
An in-reactor nuclear measurement tube guide device, characterized in that it is formed in the shape of a fallopian tube whose diameter increases toward the lower side, and a guide cone is provided to guide the in-furnace nuclear measurement tube to more easily enter the guide tube.
The method of claim 1,
Doedoe disposed adjacent to the guide tube, extending along the longitudinal direction of the guide tube from the upper support plate to the lower support plate, support plate fixing structure to maintain the coupling between the upper support plate and the lower support plate and the guide tube; further comprising a Nuclear instrumentation tube guide device in the reactor inner furnace, characterized in that.
The method of claim 1,
A nuclear instrumentation tube guide device in a reactor internal furnace further comprising: a plurality of lifting lugs installed above the upper support plate to allow the upper support plate to be raised or lowered using a separately provided lifting means.
An in-furnace nuclear measurement tube provided for nuclear measurement in a furnace inside a nuclear reactor; and
A nuclear measurement tube guide device provided with an upper support plate, a lower support plate provided below the upper support plate, and a guide tube extending in the longitudinal direction from the upper support plate to the lower support plate to provide a moving path of the nuclear measurement tube in the furnace. include,
Nuclear measurement tube guide device,
It is formed on the upper support plate and the lower support plate, respectively, to enable entry of a separately provided underwater camera for monitoring when the nuclear instrumentation tube is moved in the reactor, and to reduce disturbance of the flow flow when entering or moving underwater in the reactor. A plurality of flow holes (Flow Hole); nuclear instrumentation tube guide system inside the nuclear reactor, characterized in that it further comprises.

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