KR101445557B1 - Hybrid Incore Detector Assembly For Core Monitoring And Protection - Google Patents

Abstract

The present invention relates to a hybrid in-line instrument cluster aggregated for core monitoring and core protection, and more particularly, to a hybrid type in-line instrument cluster capable of simultaneously performing a core monitoring function and a core protection function. In order to perform a core monitoring function, And a platinum measuring instrument for performing a core protecting function, and a core core outlet thermocouple integrated into one. According to the present invention, a core monitoring function and a core protection function can be simultaneously performed as a hybrid type using a vanadium meter and a platinum meter.

Description

[0001] Hybrid Incore Detector Assembly for Core Monitoring and Protection [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cluster of in-furnace meters, and more particularly to a hybrid type in-furnace cluster aggregate capable of simultaneously performing a core monitoring function and a core protecting function.

The most important indicator for the safe operation of the reactor is the output peak factor. To monitor this value, the accurate three-dimensional power distribution of the core must be continuously measured. In-line instruments used for nuclear core monitoring of nuclear power plants are mobile (used in WH type nuclear power plants) and fixed type (used in OPR1000 nuclear power plants).

Although the mobile in-line instrument has the advantage of measuring the accurate three-dimensional core power distribution, there is a problem that on-line measurement can not be performed because the output distribution is measured only periodically. On the other hand, fixed-type in-line measuring instruments are capable of on-line measurement, but the number of axial measuring instruments of the core is limited, reaction time is slow, and it is burnt in the core.

On the other hand, the fixed rhodium in-silencer assemblies used in the OPR1000 monitor the neutron flux distribution of the reactor core in real time at a rated power of 20% or higher while being fixedly inserted in the guide tube at the center of the nuclear fuel assembly during normal operation. In the reactor core, there are 45 fixed in-line instrument cluster assemblies where it is deemed appropriate to monitor the power distribution within the core.

As shown in Figures 1 and 2, the conventional in-furnace instrument cluster 10 includes five rhodium meters 11, one background meter 12, two core outlet thermocouples capable of measuring the coolant outlet temperature of the core A central member assembly 13 and a filler wire 14 filling the space between the measuring instruments, an inner extension tube 15 and an outer sheath tube 16.

The rhodium meter 11 contained in each of the in-furnace meter assemblies 10 has a length of about 16 inches (40 cm), and the output distribution of the core at 10, 30, 50, 70, and 90% As shown in FIG.

On the other hand, conservative calculation is required in the conventional core protection system because it uses an extraneous measuring instrument for calculating the nuclear boiling bounce rate and the local power density, which are the main safety variables of the core. In the case of using an extrinsic instrument, it is impossible to accurately measure the three-dimensional power distribution of the core, which is the most important indicator for the safe operation of the nuclear reactor. Therefore, the nuclear boiling bounce rate and the local power density are calculated using a virtual conservative power distribution.

Therefore, the importance of the safety grade in-line instrument is emphasized because it is possible to directly obtain the 3-dimensional power distribution of the core using safety grade in-line measuring instruments and to use it in the core protection system to obtain a very large stop margin or safety margin . However, the conventional rhodium in-line measuring instrument has a problem in that the lifetime of the measuring instrument is about 2 ~ 3 cycles (3 ~ 4 years) as well as the uncertainty due to the time delay of the measurement signal, have.

The conventional in-line measuring instrument is responsible for the core monitoring function, while the external measuring instrument is responsible for the core protection function. Moreover, the lifetime of the conventional rhodium in-line measuring instrument is about two to three cycles, which is a burden on the operation of the nuclear power plant due to an increase in the replacement cost of the instrument and a problem of securing high-level waste storage space.

[0006] In the conventional art, a radiator electrode is formed at an inner center of a cladding constituting a collector electrode, and a coaxial cable for signal transmission is connected to one end of the radiator electrode, And a space between the radiator electrodes to which the coaxial cable is connected are formed of a platinum (Pt) solid meter filled with an insulator; A radiator electrode is formed at an inner center of the cladding constituting the collector electrode. A coaxial cable for signal transmission is connected to one end of the radiator electrode. The space between the cladding tube and the radiator electrode connected to the coaxial cable is filled with an insulator A formed Vanadium meter; Wherein a coaxial cable for signal transmission is formed in a cladding tube constituting a collector electrode and a background neutron measuring instrument formed by filling an insulator between the cladding tube and the coaxial cable is integrally formed in the space between the cladding tube and the coaxial cable, (Refer to Patent Document 1).

[Patent Document 1] Published Japanese Patent Application No. 10-2008-0011782

Accordingly, it is an object of the present invention to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and a method for measuring a neutron-emitting emitter material in a non-depleting or low- depleting material to increase the life of the measuring instrument.

In order to achieve the above object, the present invention provides a hybrid type in-line measuring instrument cluster capable of simultaneously performing a core monitoring function and a core protection function, And a background meter, a platinum meter for performing a core protection function, and a core outlet thermocouple integrated into one, and a signal generated from the vanadium meter is input to a core monitoring system, Dimensional core output distribution to perform a core monitoring function, and the vanadium measuring instrument is arranged at 10, 30, 50, 70, 90% height of the height of the nuclear fuel assembly, , The signal generated from the platinum meter is input to the core protection system, And the platinum meter is configured to be three in number, and is disposed so as to cover one third of the core.

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According to the present invention, a core monitoring function and a core protection function can be simultaneously performed by using a vanadium meter and a platinum meter.

In addition, by using in-furnace meter-based core protection system, which can not be solved by the prior art, by using platinum as an emitter material capable of quick response, it is possible to directly measure the state of the core, . Therefore, it is possible to improve the output of the nuclear power plant by increasing the margins of the nuclear boiling rejection ratio and the local power density by eliminating the water conservancy when using an external measuring instrument.

In addition, the life of the instrument can be extended by applying non-compact or low-smoke materials such as vanadium or platinum as the emitter material to react with neutrons. This makes it possible to reduce the amount of waste in the in-furnace instrument after use, which is a high-level radioactive material, to three times or more than the conventional one. This will not only ensure a space for high-level waste, but also contribute to the reduction of the coating of nuclear power users.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a cross-sectional view of a conventional rhodium in-situ aggregate structure.
2 is a conceptual diagram showing the structure of a conventional rhodium-in-nano meter aggregate.
3 is a conceptual diagram showing the structure of a hybrid in-line instrument cluster for core monitoring and core protection according to the present invention.
4 is a cross-sectional view illustrating the structure of a hybrid in-line measurement instrument cluster for core monitoring and core protection according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. In addition, the preferred embodiments of the present invention will be described below, but it is needless to say that the technical idea of the present invention is not limited thereto and can be variously modified by those skilled in the art.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a conceptual view showing a structure of a hybrid in-line measurement instrument cluster for core monitoring and core protection according to the present invention, and FIG. 4 is a sectional view showing the structure of a hybrid in-furnace instrument cluster for core monitoring and core protection according to the present invention.

The hybrid in-line measurement instrument cluster for core monitoring and core protection according to the present invention can simultaneously perform the core monitoring function and the core protection function, as well as the instrument emitter material reacting with the neutron (3) in the core (1) -depleting) or low-depleting material, thereby extending the life of the measuring instrument.

As shown in the drawing, the hybrid in-line measurement instrument cluster 100 for core monitoring and core protection according to the present invention is a hybrid type in-line measurement instrument cluster capable of simultaneously performing a core monitoring function and a core protection function, Which has five vanadium meters 110 and one background meter 120 to perform core protection functions and three platinum meters 130 to perform the core protection function and a single integrated core outlet thermocouple 140 . Reference numeral 150 denotes an outer sheath tube.

That is, in order to perform the core monitoring function, five vanadium meters 110 and one background meter 120 are provided in the same manner as the rhodium meter used by the conventional core operating limit monitoring system (COLSS). At this time, the signals generated from the five vanadium meters 110 are input to the core monitoring system to calculate the output distribution of the three-dimensional core 1, thereby performing the core monitoring function. That is, it is used to closely monitor the output distribution of the core 1 and provide information about the local neutron (3) distribution. The five vanadium meters 110 can each be disposed at 10, 30, 50, 70, 90% height of the nuclear fuel assembly height, each having a length of 30 inches (76 cm) in the core 1.

In order to perform the core protection function, three platinum meters 130 may be disposed so as to cover one-third of the core 1, respectively, so that three out-of-range meter input algorithms can be used. At this time, the signal generated from the platinum meter 130 is input to the core protection system to perform the core protection function.

The conventional rhodium in-situ measuring instrument includes a core outlet thermocouple separated into two, but in the present invention, it has a core outlet thermocouple 140 integrated into one. At this time, the core exit exit thermocouple 140 may be disposed in a central member assembly space of a conventional in-furnace instrument.

As described above, the hybrid in-line measurement instrument cluster 100 for core monitoring and core protection according to the present invention is a hybrid type using the vanadium measuring instrument 110 and the platinum measuring instrument 130 and can simultaneously perform the core monitoring function and the core protecting function have.

In addition, by using the in-reactor core-based protection system, which can not be solved by the prior art, by using platinum as an emitter material capable of prompt response, it is possible to directly measure the state of the core (1) . Therefore, it is possible to improve the output of the nuclear power plant by increasing the margins of the nuclear boiling rejection ratio and the local power density by eliminating the water conservancy when using an external measuring instrument.

In addition, the life of the instrument can be extended by applying non-small or low-lean material such as vanadium or platinum as the emitter material to react with the neutron (3). This makes it possible to reduce the amount of waste in the in-furnace instrument after use, which is a high-level radioactive material, to three times or more than the conventional one. This will not only ensure a space for high-level waste, but also contribute to the reduction of the coating of nuclear power users.

Table 1 below compares the specifications and effects of the conventional rhodium meter and the hybrid in-line instrument cluster according to the present invention.

division
Rhodium meter Hybrid in-line instrument
effect vanadium platinum Emitter material Rh-45 V-51 Pt-105 Emitter diameter 0.0457 cm 0.113 cm 0.113 cm A comparable signal Use response time / filter 175sec / 27sec ~ 500 sec / a few seconds prompt Fast response time Instrument lifetime <3 years > 10 years > 10 years Extend life

In addition, in the case of the hybrid in-line measurement instrument cluster 100 for core monitoring and core protection according to the present invention, a signal-to-noise ratio (hereinafter referred to as &quot; ) And the emitter diameter of the vanadium and platinum meters 110 and 130 is determined in consideration of the preparation of the in-line measuring instrument.

Since vanadium and platinum have a relatively small neutron absorption cross-sectional area compared to rhodium, vanadium and platinum of the same specifications show smaller meter signals than rhodium. Therefore, the outer diameter of the hybrid in-line measurement instrument cluster 100 for core monitoring and core protection according to the present invention is kept equal to the outer diameter of the rhodium measuring instrument cluster, and the emitter diameter of the vanadium and platinum measuring instruments 110 and 130 is about 2.5 times So as to maintain the signal level of the conventional rhodium meter.

Although the present invention has been described with respect to a limited number of embodiments of a hybrid in-line measurement instrument cluster for core monitoring and core protection, the scope of the present invention is not limited to the specific embodiments, And various alternatives, modifications, and changes may be made within the scope of the invention.

Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . The scope of protection of the present invention should be construed according to the following claims, and all technical ideas falling within the scope of the same shall be construed as falling within the scope of the present invention.

1: core
2: Signal line
3: Neutron
100: In-furnace instrument cluster
110: Vanadium meter
120: background meter
130: Platinum meter
140: core outlet thermocouple
150: Sheath tube

Claims (5)

A hybrid type in-furnace instrument cluster (100) capable of simultaneously performing a core monitoring function and a core protection function,
A vanadium meter 110 and a background meter 120 are provided to perform a core monitoring function,
A platinum meter 130 is provided to perform the core protection function,
And an integrated core outlet thermocouple 140,
The signal generated by the vanadium meter 110 is input to a core monitoring system to calculate a three-dimensional core power distribution to perform a core monitoring function,
Each of the vanadium meters 110 has a predetermined length in the core 1 and is disposed at 10, 30, 50, 70, and 90% of the height of the nuclear fuel assembly,
The signal generated by the platinum meter 130 is input to a core protection system to perform a core protection function,
Wherein the platinum meter (130) is configured to be three in number and is arranged to cover one third of the core (1). delete delete delete delete

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