KR102525035B1 - Apparatus for controlling control rod of reactor - Google Patents

Abstract

The present invention relates to a position detection apparatus of a control rod for a nuclear reactor, which can, since the configuration of the position detection apparatus is modularized, be easily assembled as well as increase productivity, and enables precise measurement of the position of a control rod. In addition, the position detection apparatus is formed in a structure of duplicating a train, so that even when a problem occurs in any one train, the position of the control rod can be detected.

Description

Control rod position detection device of nuclear reactor {APPARATUS FOR CONTROLLING CONTROL ROD OF REACTOR}

The present invention relates to a control rod position detection device for a nuclear reactor, and more particularly, since the configuration constituting the position detection device is modularized, assembly is simple, productivity is increased, control rod positions can be precisely measured, and trains are redundant. It relates to a control rod position detection device for a nuclear reactor, which is formed to enable detection of the position of control rods even if a problem occurs in any one of the trains.

As is well known in the field of nuclear power technology, conventional nuclear reactors burn (nuclear fission) a plurality of fuel rods made of enriched uranium to generate steam with the heat generated at this time, and rotate turbines and generators with the steam to produce electricity. is configured to Since nuclear fission has the property of gradually accelerating over time, in order to prevent an accident caused by excessive nuclear fission, for example, a meltdown of a nuclear reactor, the Departure from Nucleate Boiling Rate and local It is necessary to continuously measure the local power density and control the burning speed of the fuel rod based on this.

A control rod made of boron is used to control the combustion rate of the fuel rod. The control rods are arranged between the fuel rods in the form of an assembly, and are driven up and down in the vertical direction by the control rod driving device. The control rod absorbs neutrons generated during nuclear fission to suppress the combustion of the fuel rod. Therefore, as the control rod descends and penetrates deeper into the core, the combustion rate of the fuel rod decreases. burning rate increases. The control rod is held at a predetermined position by the latch of the control rod driving device in normal times, and at this time, the control rod driving device is in an energized state. In an emergency, the supply of current to the control rod driver is cut off, and accordingly, the latch is released and the control rod is dropped to the bottom of the core so that nuclear fission does not proceed any further and the operation of the nuclear reactor is stopped. This is called a trip of the reactor.

As described above, since the control rod increases or decreases the combustion rate of the fuel rod depending on its position and in some cases stops the operation of the nuclear reactor, accurately detecting the current position of the control rod is extremely important for proper control of the nuclear reactor and prevention of accidents. Conventionally, a permanent magnet is attached to the top of a drive shaft connected to a control rod, and a voltage driver network is installed along a moving path of the permanent magnet to detect the position of the control rod according to a voltage value applied to the voltage divider circuit.

One pair of such voltage divider circuits is installed per control rod, and each voltage divider circuit is a plurality of pairs arranged at equal intervals along the length of the drive shaft, for example, 100 pairs of reed switches and a plurality of reed switches connected in series corresponding to each pair. It consists of two resistors. Each pair of reed switches is normally kept open, and closed as the permanent magnet approaches due to the vertical movement of the control rod. Depending on which position the reed switch is closed, the output voltage varies, and this output voltage is converted into a digital signal by an analog/digital converter and then input to a microprocessor. The microprocessor calculates the position of the control rod according to the voltage signal and informs the reactor operator through a display device.

In general, it is necessary to detect the position of the control rod in subdivision as much as possible, and the fewer the number of reed switches and resistors, the better. To this end, the distance between each pair of reed switches is such that, as the permanent magnet moves in the vertical direction, first the first pair of reed switches is closed, then the adjacent first and second pairs of reed switches are simultaneously closed, and then the second pair is closed. Set only the reed switches of the pair to close. In this way, the position of the control rod can be subdivided into about twice the number of reed switches and detected. In other words, if different voltage signals are generated not only when the permanent magnet is precisely aligned on a specific reed switch but also when it is aligned in the middle of two adjacent reed switches, the number of reed switches and resistors can be reduced by half. will be. The reason why the reed switches are installed in pairs is to ensure that the voltage divider circuit is normally operated by the other reed switch even if one reed switch is continuously closed due to a failure.

According to the conventional control rod position detection device as described above, since only two voltage divider circuits are used per control rod, if an erroneous signal is generated due to a failure of one voltage divider circuit, a control rod position calculator that emergency monitors the positions of four control rods may cause position deviation. It is determined that there is an abnormality in the nuclear reactor, and a variable that unnecessarily trips the reactor is generated, and power generation is stopped until the voltage divider circuit is repaired and the reactor is restarted, resulting in enormous economic loss. In addition, since the voltage divider circuit is configured using a plurality of pairs of reed switches and a plurality of resistors, the structure of the control rod position detecting device becomes complicated and the price is high.

Republic of Korea Utility Model Publication No. 20-1999-0038053 (published on October 15, 1999)

The present invention has been made to solve the above problems, and an object of the present invention is to modularize the configuration of the position detection device, so that assembly is easy, productivity is increased, and the control rod position of the nuclear reactor is capable of precisely measuring the position of the control rod. It is to provide a detection device.

Another object of the present invention is to provide an apparatus for detecting the position of control rods in a nuclear reactor, which is capable of detecting the position of control rods even when a problem occurs in one of the trains by redundant trains.

The object of the present invention is not limited to the tasks mentioned above, and other tasks not mentioned will be clearly understood by those skilled in the art from the following description.

An apparatus for detecting the position of a control rod of a nuclear reactor of the present invention for solving the above problems includes: a housing formed in a circular shape with an open central portion and continuously installed vertically; At least one connector coupling hole formed through the housing; a connection nut coupled to the housing to connect the housing to the housing and having a double train composed of a cover fixed to the top of the housing and fixed with a bolt member; an O-ring mounted on an outer circumferential surface of the upper end of the housing to maintain airtightness; a first connector coupled to the connector coupling hole and to which an MI cable is connected; And it characterized in that it comprises a second connector three are coupled to the connector coupling hole.

The first connector may include an insulating member coupled to the connector coupling hole; Connector pins continuously coupled upward and downward into the insulating member; a protruding portion protruding from an upper portion of the connector pin; fastening holes formed in the connector pins; an insertion hole through which the MI cable is inserted through the insulating member and the connector pin; A fixing means for fixing the MI cable is provided, and the fixing means is fixed by any one of a bare bolt, welding, and soldering.

The second connector may include an insulating member coupled to the connector coupling hole; Connector pins continuously coupled upward and downward into the insulating member; A protrusion protruding from an upper portion of the connector pin is provided.

a coupling protrusion protruding from an outer circumferential surface of the connector pin and bound to an insulating member; A protrusion protruding from the outer circumferential surface of the insulating member to prevent the first and second connectors from being disconnected is further provided.

An anti-loosening bolt is further provided to prevent the loosening of the connecting nut by being coupled to the housing through a through hole passing through the connecting nut.

According to the present invention, since the configuration constituting the position detection device is modularized, assembly is simple, productivity is increased, and the position of the control rod can be accurately measured.

In addition, according to the present invention, there is an effect of enabling the detection of the position of the control rod even if a problem occurs in any one of the trains by duplicating the trains.

1 is a cross-sectional configuration diagram of a control rod position detection device for a nuclear reactor according to an embodiment of the present invention.
2 is an exploded perspective view of a control rod position detection device for a nuclear reactor according to an embodiment of the present invention.
3 (a) and (b) are cross-sectional views of first and second connectors according to an embodiment of the present invention.
4 is a state diagram in which first and second connectors are coupled to a housing according to an embodiment of the present invention.
5 is a structure in which an MI cable is fastened to a first connector according to an embodiment of the present invention.
6 and 7 are state diagrams of a control rod position detection device of a nuclear reactor according to an embodiment of the present invention installed in a stacked manner.
8 is a state diagram in which cables are connected by jumpers to first and second connectors according to an embodiment of the present invention.
9 is an exploded perspective view of an apparatus for detecting a control rod position of a nuclear reactor according to another embodiment of the present invention.
10 (a) and (b) are cross-sectional views of first and second connectors according to another embodiment of the present invention.
11 is a state diagram illustrating a state in which a device for detecting a control rod position of a nuclear reactor according to another embodiment of the present invention is installed in a stacked manner.
12 is a cross-sectional configuration diagram of a control rod position detection device for a nuclear reactor according to another embodiment of the present invention.

1 is a cross-sectional view of a control rod position detection device for a nuclear reactor according to an embodiment of the present invention, and FIG. 2 is an exploded perspective view of a control rod position detection device for a nuclear reactor according to an embodiment of the present invention.

The control rod position detection device (A) of the present invention includes a housing 110 formed in a circular shape with an open central portion and continuously installed vertically and horizontally; At least one connector coupling hole 120 formed through the housing 110; The trains 100 and 100' composed of a cover 130 that is in close contact with the upper part of the housing 110 and fixed with bolt members 131 are redundant, and are coupled to the housing 110 to form a housing 110 and a connection nut 200 connecting the housing 110; an O-ring 300 installed between the housing 110 and the connection nut 200 to maintain airtightness; a first connector 400 coupled to the connector coupling hole 120 and to which an MI cable is connected; and second connectors 500 three of which are coupled to the connector coupling hole 120 .

The trains 100 and 100' are manufactured in a circular shape and are continuously redundant, so that even if a problem occurs in any one train 100, 100', there is no problem in detecting the position of the control rod. .

The trains 100 and 100' are characterized by maintaining airtightness to prevent leakage of materials inside the pressure boundary while maintaining electrical independence, and separation of each train 100 and 100' is possible. Partial replacement is very easy.

Since the trains 100 and 100' are configured to be manufactured through the same mold, productivity is improved as well as manufacturing cost is reduced.

The trains 100 and 100' are composed of a housing 110, a connector coupling hole 120, and a cover 130, and the housing 110 has a circular shape and has an open central portion.

The connector coupling hole 120 is formed through the housing 110, and a total of four connector coupling holes 120 are formed so that the first and second connectors 400 and 500 are selectively coupled to each other.

The cover 130 is a plate body formed with the same outer diameter and inner diameter as the housing 110, and is fixed to the upper portion of the housing 110 through a bolt member 131.

A connector coupling hole 120 ′ corresponding to the connector coupling hole 120 formed in the housing 110 is formed in the cover 130 .

In addition, the connection nut 200 is configured to connect the housing 110 to each other, and a screw thread is formed on the inner circumferential surface and a screw thread is formed on the outer circumferential surface of the housing 110 to correspond to the connection nut 200, The housing 110 and the housing 110 are connected to each other by the engagement of the screw thread.

In addition, as shown in FIG. 7, the O-ring 300 is an airtight member made of rubber, and is mounted in a mounting groove formed on the outer circumferential surface of the upper end of the housing 110, and another Before the housing 110 is coupled, the O-ring 300 partially protrudes outward from the mounting groove.

When another housing 110 is coupled to the upper end of the housing 110, the O-ring 300 is partially compressed and tightly fixed between the housings 110 and the housing 110.

In addition, the first connector 400 includes an insulating member 410, a connector pin 420, a protrusion 430, a fastening hole 440, an insertion hole 450, and a fixing means 460.

The first connector 400 is coupled to any one of the connector coupling holes 120 .

The insulating member 410 has a circular shape to be coupled to the connector coupling hole 120 and is made of special rubber, FFKM. The FFKM has chemical resistance, heat resistance and corrosion resistance.

The connector pin 420 is mounted on the inside of the insulating member 410 and continuously coupled upward and downward, and is formed of a highly conductive metal material.

A protruding portion 430 protrudes from an upper portion of the connector pin 420 so that the connector pin 420 can be continuously coupled.

The fastening hole 440 is formed on the upper or lower surface of the connector pin 420, and the insertion hole 450 penetrates the insulating member 410 and the connector pin 420 to communicate with the fastening hole 440. do.

The MI cable 10 is inserted into the insertion hole 450 and extended into the fastening hole 440 , and the MI cable 10 is connected and fixed to the connector pin 420 by the fixing means 460 .

Here, the fixing means 460 may be composed of a bolt fastened to the fastening hole 440 to connect and fix the MI cable, and the MI cable 10 extended to the fastening hole 440 may be welded or soldered. can also be fixed.

In addition, the second connector 500 includes an insulating member 510 , a connector pin 520 , and a protrusion 530 .

The second connector 500 is coupled to the remaining three connector coupling holes 120 except for the connector coupling hole 120 to which the first connector 400 is coupled.

The insulating member 510 has a circular shape to be coupled to the connector coupling hole 120 and is made of special rubber, FFKM. The FFKM has chemical resistance, heat resistance and corrosion resistance.

The connector pin 520 is mounted on the inside of the insulating member 510 and continuously coupled upward and downward, and is formed of a highly conductive metal material.

A protruding portion 530 protrudes from an upper portion of the connector pin 520 so that the connector pin 520 can be continuously coupled.

Meanwhile, as shown in FIG. 3 , coupling protrusions 600 are protruded from outer circumferential surfaces of the connector pins 420 and 520 of the first and second connectors 400 and 500, and the first and second connectors 400 and 500 ) 500 and the insulating member 410 (510) can increase the binding force.

In addition, protrusions 700 protrude from upper outer circumferential surfaces of the insulating members 410 and 510, and the first and second connectors 400 and 500 are coupled to the connector coupling holes 120 and 120'. At this time, since the protrusion 700 is coupled to and fixed to the cover 130, it is possible to prevent the first and second connectors 400 and 500 from falling downward.

In addition, as shown in FIG. 7 , an anti-loosening bolt 800 fixed to the housing 110 through the connection nut 200 to prevent the connection nut 200 from loosening may be further provided.

A through hole 210 is formed through the connection nut 200, and an anti-loosening bolt 800 is coupled and fastened to the through hole 210, and an end of the anti-loosening bolt 800 is connected to the housing 110. It is coupled to a certain depth so that the connection nut 200 does not rotate.

9 to 12 show another embodiment of the present invention, the height of the train 100 (100'), which is another embodiment of the present invention, is formed higher than the height of the train 100 (100'), which is one embodiment can do.

The basic structure of the train 100 (100'), which is another embodiment, is the same as the structure of the train 100 (100'), which is another embodiment, and the difference is that of the train 100 (100'). There is a difference in height.

As described above, by forming the heights of the trains 100 and 100' high, the lengths of the first and second connectors 400 and 500 coupled to the connector coupling holes 120 of the train 100 are increased. It will be.

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 with knowledge of, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

A: detection device
100,100': Train
110: housing
120: connector coupling hole
130: cover
200: connection nut
300: O-ring
400: first connector
410: insulation member
420: connector pin
430: protrusion
440: fastening hole
450: insertion hole
460: fixing means
500: second connector
510: insulation member
520: connector pin
530: protrusion
600: binding protrusion
700: protrusion
800: anti-loosening bolt

Claims (5)

A housing 110 formed in a circular shape with an open central portion and continuously installed up and down;
At least one connector coupling hole 120 formed through the housing 110;
The trains 100 and 100' composed of a cover 130 that is in close contact with the upper part of the housing 110 and fixed with a bolt member 131 are redundant,
A connection nut 200 coupled to the housing 110 and connecting the housing 110 to the housing 110;
an O-ring 300 mounted on an outer circumferential surface of the upper end of the housing 110 to maintain airtightness;
a first connector 400 coupled to the connector coupling hole 120 and to which the MI cable 10 is connected; and
A control rod position detection device for a nuclear reactor, comprising a second connector (500) coupled to the connector coupling hole (120).
The method of claim 1,
The first connector 400,
an insulating member 410 coupled to the connector coupling hole 120;
Connector pins 420 continuously coupled upward and downward to the inside of the insulating member 410;
a protruding portion 430 protruding from an upper portion of the connector pin 420;
fastening holes 440 formed in the connector pins 420;
an insertion hole 450 through which the MI cable 10 is inserted through the insulating member 410 and the connector pin 420;
A fixing means 460 for fixing the MI cable is provided,
The control rod position detection device for a nuclear reactor, characterized in that the fixing means 460 is fixed by any one of a no-bolt, welding, and soldering.
The method of claim 1,
The second connector 500,
an insulating member 510 coupled to the connector coupling hole 120;
Connector pins 520 continuously coupled upward and downward to the inside of the insulating member 510;
A control rod position detection device for a nuclear reactor, characterized in that a protruding portion 530 protruding from an upper portion of the connector pin 520 is provided.
According to claim 2 or claim 3,
Coupling protrusions 600 protruding from outer circumferential surfaces of the connector pins 420 and 520 and bound to the insulating members 410 and 510;
A control rod position detection device for a nuclear reactor, characterized in that a protrusion 700 protrudes from the outer circumferential surface of the insulating member 410, 510 to prevent the first and second connectors 400, 500 from coming off. .
The method of claim 1,
A nuclear reactor characterized in that an anti-loosening bolt 800 is further provided to prevent the loosening of the connection nut 200 by being coupled to the through-hole 210 passing through the connection nut 200 and fixed to the housing 110 Control rod position detection device.

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