KR20160025640A - Incore instrument assembly with multi type thermo-coupler - Google Patents

Abstract

The present invention relates to in-core nuclear instrumentation with multiple thermocouples to more accurately diagnose the internal state of a reactor and maximize the utilization of a device by including multiple thermocouples having measuring points at different heights and providing temperature information at different heights inside the reactor. In the in-core nuclear instrumentation, a detector for signal compensation, thermocouples, multiple neutron detectors are installed in a space between a center pipe with a circular cross section and an outer protective pipe. The multiple thermocouples have measuring points at different heights. Each thermocouple is bonded while the wires of different materials are adjacent to each other. There are one detector for signal compensation and five neutron detectors. The thermocouples are 2 or more and less than 5. If fewer than five thermocouples are installed, the space without thermocouples is filled with a filler cable. The thermocouple or the filler cable and the neutron detector are disposed alternately. In the above-described configuration, if the thermocouples are five, two or three thermocouples have the measuring points at the same height. When there is an empty space on the upper part of the thermocouple, the space is filled with the filler cable.

Description

{Incore instrument assembly with multi-type thermo-coupler}

In particular, the present invention relates to a multi-thermocouple furnace inner core measuring instrument, and more particularly, to a thermocouple having a plurality of thermocouples having different sidewall points at different heights to provide temperature information at different heights inside the reactor, The present invention relates to a multi-thermocouple furnace inner-core measuring instrument capable of assisting a plurality of thermocouples.

The furnace inner nuclear instrument installed in a stationary form has a plurality of, for example, 61, neutron flux neutrons in the reactor to measure the neutron flux three-dimensionally accurately and to monitor its output distribution. A key component of this inner core instrument is a self-powered neutron detector with an emitter that absorbs neutrons and emits signal current.

Conventionally, a self-emitting neutron detector using rhodium (Rh) is operated by the neutron capture reaction principle of a rhodium emitter material. When the neutrons incident on rhodium are captured, they emit high energy electrons with enough energy to escape from the emitter through beta decay. The emitted electrons are collected in a collector via an aluminum oxide (Al ₂ O ₃ ) insulator and a positive charge is generated in an electric conductor attached to the emitter. The generated positive charge generates current proportional to the neutron absorption rate of the emitter. Depending on the emitter material, it can be divided into a rhodium detector, a V-detector, a cobalt detector or a Pt-detector.

1 is a front view of a conventional furnace nuclear instrument. As shown in FIG. 1, the conventional furnace inner nuclear measuring instrument 10 is composed of a measuring unit 20, a seal plug 30, a flexible hose 40, and a connector. The measuring unit 20 is enclosed by an outer protective pipe 25 and a bullet-nose 26 is connected to one end of the measuring unit 20. The metering section 20 is inserted into the reactor through a guide tube (not shown), which is about 36 m in length.

Fig. 2 is a longitudinal sectional view taken along the line A-A in Fig. 1. Fig. 2, the measuring unit 20 of the conventional furnace inner nuclear measuring instrument 10 includes a central tube 21, a thermocouple 22, a signal compensating detector 24, an outer protecting tube 25, and a neutron detector 27 ).

In the above-described configuration, the center tube 21 passes through the inside of the measuring unit 20 in the longitudinal direction, and has a hollow tube shape for matching the diameter with the guide tube, and its length is also roughly standardized. The thermocouple 22 is composed of a pair of cables having a circular cross section, that is, a chromel wire 22a and an alumel wire 22b, and is used to measure the temperature of the cooling water inside the reactor. A K type thermocouple is mainly used. The neutron detector 27 is also implemented as a cable having a circular cross section, and a total of five (strands) are provided to measure neutron flux in the reactor. The detector 24 for signal compensation of one (strand) is also implemented as a cable having a circular cross section to measure a background signal (noise).

The length and diameter of each neutron detector 27, the thermocouple 22 and the signal-compensating detector 24 (hereinafter collectively referred to as a detector) are substantially the same. When the length and diameter of the neutron detector 27, the thermocouple 22, (22) and the detector (27) when the neutron detector (27) is arranged to surround the central tube (21) in a space between the central tube (21) A total of eight (stranded) filler cables 23 are provided for filling an empty space for disposition.

However, according to the conventional furnace inner nuclear instrument as described above, since the total of eight filler cables are provided only for flow prevention and interval maintenance of each detector, there is a problem that the utilization of the furnace inner nuclear measuring instrument, which is relatively expensive, there was.

Prior Art: 10-2014-0010501 Disclosure of the Invention (Title of Invention: In-line instrument with improved neutron flux detection sensitivity)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a thermoelectric power generation system having a plurality of thermocouples having internal temperature- And to provide a multi-thermocouple furnace inner-core measuring instrument capable of helping diagnosis.

It is another object of the present invention to provide a thermocouple having a plurality of thermocouples, each having a sidewall point at a different height, instead of a filler cable, to provide temperature information at different heights inside the reactor, And to provide a furnace inner nuclear measuring instrument.

According to an aspect of the present invention, there is provided a furnace inner nuclear measurement instrument including a detector for signal compensation, a thermocouple, and a plurality of neutron detectors in a space between a center tube having a circular section and an outer protective tube, And a plurality of thermocouples formed with an on-point.

In the above-described configuration, the number of the signal compensating detectors is one, the number of the neutron detectors is five, the number of the thermocouples is two or more and five or less, and when less than five thermocouples are installed, Is characterized in that the filler cable is filled.

The thermocouple or the filler cable and the neutron detector are alternately arranged.

And the filler cable is filled in the empty space when the hollow space above the thermocouple is formed.

And each of the thermocouples is formed by joining wires of mutually different materials adjacent to each other.

And the strands of the different materials are chromel strands and alumel strands.

According to the multi-thermocouple furnace inner nuclear measurement instrument of the present invention, a plurality of thermocouples having different sidewall temperature points at different heights are provided to provide temperature information at different heights inside the reactor, thereby helping to more accurately diagnose the internal state of the reactor And can maximize the utilization of the device.

1 is a front view of a conventional furnace nuclear instrument;
Fig. 2 is a longitudinal sectional view taken along line AA in Fig. 1; Fig.
3 is a front view of a multi-thermocouple furnace inner nuclear instrument according to an embodiment of the present invention.
Fig. 4 is a longitudinal sectional view taken along line AA in Fig. 3; Fig.
FIG. 5 is a structural view of a multi-thermocouple furnace inner core analyzer of the present invention in a state in which the inside of the apparatus is expanded on a plane. FIG.

Hereinafter, preferred embodiments of the multi-thermocouple furnace inner nuclear measurement instrument of the present invention will be described in detail with reference to the accompanying drawings.

3 is a front view of a multi-thermocouple furnace inner nuclear instrument according to an embodiment of the present invention. 3, the multi-thermocouple furnace inner nuclear measurement apparatus 10 'of the present invention includes a measuring unit 100, a seal plug 30, a flexible hose 40, and a connector ). The measuring unit 100 is surrounded by an outer protective pipe 25 and a bullet-nose 26 is connected to one end of the measuring unit 100. The measuring unit 100 is inserted into the reactor through a guide tube (not shown), and is about 36 m in length.

Fig. 4 is a longitudinal sectional view taken along the line A-A in Fig. 3, and is a longitudinal sectional view of the lower portion of the measuring portion 100 in a state adjacent to the seal plug 30, that is, inside the reactor. 4, the measuring unit 100 includes a central tube 110, thermocouples 121 to 125, a signal compensating detector 140, an external protective tube 150 And a neutron detector 170. [0031]

In the above-described construction, the center pipe 110 penetrates the inside of the measuring unit 100 in the longitudinal direction. Since the center pipe 110 is inserted into the reactor through the guide tube (not shown), the degree of the flow And the length of the hollow tube is also standardized. The neutron detector 170 is also implemented as a cable having a circular cross section, and a total of five (strands) are provided to measure neutron flux in the reactor. The detector 140 for signal compensation of one (strand) is also implemented as a cable having a circular cross section to measure a background signal (noise).

In the meantime, the multi-thermocouple furnace inner core measurement apparatus of the present invention may further include additional thermocouples 122 to 125 in addition to the thermocouple 121 used for measuring the temperature of the cooling water in the reactor, 125 may be replaced with a total of eight filler cables provided in the conventional furnace inner nuclear measurement device, so that a maximum of four thermocouples may be additionally provided. In this case, in order to detect the temperature at different points (height) inside the reactor, it is preferable that the thermocouples 121 to 125 have mutually different sideways points.

Further, the chromel wire and the alluminium wire of each of the thermocouples 121 to 125 must be adjacent to each other so as to form a contact point at the ends of the chromel wire and the alumel wire constituting each of the thermocouples 121 to 125, It is preferable to arrange the neutron detector 170 between the thermocouples 121 to 125 so that the influence of the electric field generated in the thermocouples 121 to 125 is minimized and that the neutron detector 170 can be arranged at equal intervals as much as possible Do.

Each of the thermocouples 121 to 125 is formed of a pair of cables having a circular cross section, that is, a chromel wire 121a and an alumel 121b wire (the reference numeral is assigned only to the wire 121) K type thermocouple.

FIG. 5 is a structural view of a multi-thermocouple furnace inner core analyzer of the present invention in a state in which it is developed on a plane, and FIG. As shown in FIG. 5, the multi-thermocouple furnace inner core measurement apparatus of the present invention may include, for example, a total of five thermocouples in which a side temperature point is formed in each section of the reactor in which the inside of the reactor is divided into upper and lower halves.

In this case, for example, the thermocouple 121 having the side temperature point near the uppermost end of the measuring unit 100 has a problem of flow because the lengths of the adjacent neutron detector 170 and the signal compensating detector 140 are almost the same However, in the case of the thermocouples 122 to 125 having the sidewall point at the lower position, void spaces are formed on the thermocouples 122 to 125, so that the neutron detector 170 or the signal-compensating detector 140 flows or bends And the like. In order to prevent this, it is preferable to fill the empty spaces formed in the upper portions of the thermocouples 122 to 125 having low side-temperature points with the filler cables 131 to 134. As a result, the lengths of the filler cables 131 to 134 may be different from each other. The total length of the thermocouples 122 to 125 combined with the filler cables 131 to 134 is determined by the neutron detector 170 or the signal- Lt; / RTI >

Although the preferred embodiments of the multi-thermocouple furnace inner nuclear measurement instrument of the present invention have been described in detail, the present invention is not limited to these embodiments, and various modifications and changes may be made within the technical scope of the present invention. Accordingly, the scope of the present invention should be determined by the following claims.

For example, the number of thermocouples 121 to 125 may be two to four, not five. In this case, the thermocouple-free space may be filled with a conventional filler cable. The interval or the length between the side temperature points of the respective thermocouples 121 to 125 may be appropriately modified.

In the case where five thermocouples are provided in total, two or three thermocouples may have a sideways point of the same height so as to ensure the reliability of the measurement result. Also, the top space of all thermocouples may be empty, in which case filler cables will fill all of the voids. Thermocouples may also use other types of thermocouples than K-type.

10, 10 ': no inner nuclear measuring instrument, 20, 100: measuring part,
21, 110: central tube, 22, 121 to 125: thermocouple,
23, 131 to 134: filler cable, 24, 140: detector for signal compensation,
25, 150: an outer protective tube, 26: a blister nose,
27, 170: Neutron detector, 30: Seal plug,
40: Flexible hose

Claims (6)

In a furnace inner nuclear instrument equipped with a detector for signal compensation, a thermocouple and a plurality of neutron detectors in a space between a center tube having a circular section and an outer protective tube,
Wherein the thermocouple is made up of a plurality of thermocouples having side temperature points at different heights. The method according to claim 1,
The thermocouple is composed of two or more but not more than five thermocouples, and when less than five thermocouples are installed, the filler cable is filled in the space in which the thermocouple is not installed. Wherein the inner thermocouple is a thermocouple. 3. The method of claim 2,
Wherein the thermocouple or the filler cable and the neutron detector are arranged alternately. 4. The method according to any one of claims 1 to 3,
And the filler cable is filled in the hollow space when the hollow space above the thermocouple is formed. 5. The method of claim 4,
Wherein each of the thermocouples is formed by joining wires of different materials adjacent to each other. 6. The method of claim 5,
Wherein the strands of the different materials are chromel wire and alumel wire.

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