RU2653163C1 - Method of calibration counting channel of reactometer in pulse-current mode - Google Patents

Abstract

FIELD: measuring equipment; nuclear physics.

SUBSTANCE: invention relates to the field of reactor measurements and can be used in nuclear reactor control systems. Neutron detector is connected to the counting and current channels of the reactometer. As detector uranium fission chamber is used. Reactor is led to a power level corresponding to the neutron detector current, which higher by at least an order of magnitude the value of the current at which the reactometer goes into pulsed mode. After the reactor control element is moved, the time derivative calculated by the reactivity meter is monitored. In the case of a change in this derivative, the second and third levels of discrimination are regulated at the moment of transition of the reactometer from current to pulse mode. Then, the operations of moving the control element are repeated under the above conditions and corresponding adjustment of the discrimination levels until the time derivative of the reactivity calculated by the reactometer is obtained at the instant of transition of the reactometer from current to pulse mode.

EFFECT: increase the calibration accuracy of the counting channel of the reactometer and expansion of method functional capabilities.

1 cl, 3 dwg

Description

The claimed technical solution relates to the field of reactor measurements and can be used in monitoring systems of nuclear reactors.

One of the most important characteristics that determine the dynamics of a nuclear reactor is reactivity, the value of which carries information about the processes occurring in the reactor — acceleration of the reactor, operation at a constant power level, or shutdown of the reactor. Modern reactivity measuring instruments are digital reactimeters and the quality of their calibration determines the accuracy of measuring the neutron-physical characteristics of nuclear reactors.

A known method of calibrating the counting channel of a reactimeter, [patent RU No. 2379710, publ. 01/20/2010], including the placement of gamma detectors connected to the counting channel of the reactimeter in the radiation zone of gamma sources and adjusting the checked counting channel in accordance with the power of gamma sources. The disadvantage of this method is its low accuracy due to the fact that the amplitude spectrum of the current pulses of the spectrometric amplifier of the reactimeter, formed in this method under the influence of gamma radiation, differs from the similar amplitude spectrum formed under the influence of neutrons in a nuclear reactor.

Closest to the proposed solution is a method of calibrating the counting channel of a reactimeter [patent RU No. 2560531, publ. 07/22/2015], including monitoring the neutron flux of a nuclear reactor using a detector connected to the counting channel of the reactimeter, made on the basis of a uranium fission chamber, and adjusting the counting channel of the reactimeter depending on the reactivity calculated by the reactivity meter, stabilizing the power of the nuclear reactor at a fixed level and moving the power control reactor control from one position to another in the direction corresponding to a decrease in power. The prototype eliminated the disadvantage associated with a decrease in the accuracy of calibrating the reactimeter, determined by the difference in the amplitude spectra of the current pulses of the spectrometric amplifier, formed under the influence of gamma radiation - in the analogue and under the influence of neutrons in a nuclear reactor - in the prototype. However, there is another factor that reduces the accuracy of the calibration of the reactimeter during calibration, carried out in accordance with the prototype method. Namely, the calibration in the prototype method is carried out in a counting mode and does not take into account possible violations of the linearity of the calculated reactivity during the transition from pulse to current mode and vice versa. In addition, a significant drawback of the prototype method is the limitation of its functionality associated with the need to create special conditions for the implementation of the method under which the influence of the spatial effects of reactivity, reactivity feedbacks, and constant neutron sources should be eliminated on the meter readings.

The technical problem facing the author of the claimed technical solution is the creation of a method that allows to increase the accuracy of the calibration of the counting channel of the reactimeter due to the additional use of the current range when it is carried out, as well as to expand the functionality of the method, which consists in conducting the calibration without creating special conditions that eliminate spatial effects reactivity, reactivity feedback and the influence of constant neutron sources.

To solve the above problem in a known method for calibrating the counting channel of a reactimeter, including

control of the neutron flux of a nuclear reactor using a detector connected to the counting channel of a reactimeter, made on the basis of a uranium fission chamber,

adjustment of the counting channel of the reactimeter depending on the reactivity calculated by the reactimeter,

stabilization of reactor power at a fixed level,

moving the power regulating reactor power of the control from one position to another in the direction corresponding to a decrease in power

calibration is carried out as follows:

additionally connect a reactimeter to a neutron detector through a current channel,

the reactor is brought to a power level to which the neutron detector current corresponds, at least an order of magnitude higher than the current value at which the reactimeter goes into pulsed mode,

the control element controlling the reactor power is moved, after which the time derivative of the reactivity calculated by the reactivity meter is controlled and,

in the case of a change in this derivative at the time of the transition of the reactimeter from the current to pulsed mode, the second and third levels of discrimination are regulated,

then the operations of moving the control body under the above conditions and the corresponding adjustment of the discrimination levels are repeated until the reactivity constant calculated by the reactivity meter at the moment the reactimeter is switched from current to pulse mode is obtained.

Signs that distinguish the proposed method from the closest known method according to patent RU No. 2560531:

- additional connection of the reactimeter to the neutron detector through the current channel;

- output of the reactor to a power level to which the current of the neutron detector corresponds, exceeding at least an order of magnitude of the current at which the reactimeter switches to pulsed mode;

- moving the control element of the reactor power control and monitoring the time derivative of the reactivity calculated by the reactivity meter;

- in the case of a change in the specified derivative at the time of the transition of the reactimeter from current to pulsed mode - adjustment of the second and third levels of discrimination;

- repeating the operation of moving the control element at the initial reactor power level, which corresponds to the neutron detector current, which is at least an order of magnitude greater than the current value at which the reactimeter switches to pulsed mode and the operation of adjusting discrimination levels until a reactivity constant calculated by the reactivity meter is obtained in moment of transition of the reactimeter from current to pulsed mode.

The above signs can improve the accuracy of the calibration of the counting channel of the reactimeter due to the additional use of the current range when calibrating it, as well as expand the functionality of the proposed method, which consists in calibrating without creating special conditions that eliminate the spatial effects of reactivity, feedback on reactivity and the influence of constant neutron sources .

These advantages, as well as features of the present invention are illustrated by the best option for its implementation with reference to the accompanying figures. The figures depict:

FIG. 1 is a graphical illustration showing the change in reactivity when moving the controls in the direction of decreasing power from a position corresponding to the current mode, in the case of a violation of the linearity of the calculated reactivity due to the lack of pulses;

FIG. 2 is a graphical illustration showing the change in reactivity when moving the controls in the direction of power reduction from the position corresponding to the current mode, in case of violation of the linearity of the calculated reactivity due to pulse conversion;

FIG. 3 is a graphical illustration showing the change in reactivity when moving the controls in the direction of power reduction from the position corresponding to the current mode, in the absence of a violation of the linearity of the calculated reactivity, where the left Y axis represents the change in the power signal (current in amperes and count rate in pulses per second ) on a logarithmic scale, the right Y axis represents the reactivity of the nuclear reactor in units of ρ / β, the time in seconds is plotted along the X axis.

In FIG. 1-3 graphs A and B represent the power signal and reactivity, respectively; the time stamp t1 corresponds to the moment of the beginning of the movement of the controls, the time stamp t2 corresponds to the moment of transition of the reactimeter from the current to the pulse mode.

Calibration of the counting channels of the reactimeter is as follows.

For the practical implementation of the proposed method, a KNM uranium fission chamber with a PIK-24-1 suspension and a PVR-7 reactimeter manufactured by FSUE “NITI named after A.P. Alexandrova. " The uranium fission chamber controlling the neutron flux in a nuclear reactor is connected to the counting and current channels of the reactimeter. Set the magnitude of the discrimination levels of the reactimeter, for example, in accordance with the values specified in the prototype: d ₁ = (0.3 ÷ 0.5) U _n , d ₂ = l, 6U _n , d ₃ = 2.56 U _n , where U _n is the nominal amplitude of the voltage pulse coming from the spectrometric amplifier to the input of the discriminator. The reactor is brought to the power level, which corresponds to the current of the neutron detector, one to two orders of magnitude higher than the current value at which the reactimeter goes into pulsed mode. When using these cameras and a reagent meter, the power level to which the reactor is brought out during calibration of the counting channel provides a neutron detector current of the order of 10 ^-6 -10 ^-5 A, which is one or two orders of magnitude higher, respectively, than the current of the reagentmeter switching to pulsed mode. The controls governing the power of the reactor are moved from one position to another in the direction corresponding to a decrease in power, while the time derivative of the reactivity calculated by the reactivity meter is monitored. In the case of a change in the value of this derivative at the time of the transition of the reactimeter from current to pulse mode, the second and third levels of discrimination are regulated.

The direction of adjustment of the indicated levels depends on the nature of the change in the time derivative of the reactivity calculated by the reactimeter at the moment the reactimeter changes from current to pulse mode. If the reactivity at a specified point in time changes as shown in FIG. 1, the levels of discrimination are reduced, and if so, as in FIG. 2, then increase. After such adjustment, the reactor is again brought back to the power level, which corresponds to the neutron detector current of 10 ^-6 -10 ^-5 A, and the movement of the controls governing the reactor power from one position to another in the direction corresponding to the power reduction is repeated. The operation of moving the control at the initial reactor power level, which corresponds to a neutron detector current of 10 ^-6 -10 ^-5 A, and adjusting the discrimination levels are repeated until the change in the time derivative of the reactivity calculated by the reactivity meter at the moment the reactimeter transitions from the current to pulse mode, as shown in FIG. 3.

Claims (1)

A method for calibrating the counting channel of a reactimeter in a pulsed-current mode, including monitoring the neutron flux of a nuclear reactor using a detector connected to the counting channel of a reactimeter, made on the basis of a uranium fission chamber, and adjusting the counting channel of the reactimeter depending on the reactivity calculated by the reactivity meter, stabilizing the reactor power on a fixed level and movement of the control element regulating the reactor power from one position to another in the direction corresponding to the decrease in power springs, characterized in that the reactimeter is additionally connected to the neutron detector through the current channel, the reactor is brought to a power level that corresponds to the neutron detector current, which exceeds, at least by an order of magnitude, the current value at which the reactimeter goes into pulsed mode, and the control power is moved the control element of the reactor, after which the time derivative of the reactivity calculated by the reactimeter is controlled and, if this derivative changes at the moment the reactimeter changes from current to pulse the mode, regulate the second and third levels of discrimination, then repeat the operations of moving the control body under the above conditions and correspondingly adjust the levels of discrimination until the reactivity constant calculated by the reactimeter at the moment the reactimeter is switched from current to pulse mode is received.

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