RU2609140C1 - Method for humidity control of leaks of pipelines and equipment cooling circuit of nuclear or thermal power plant - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to leak control based on air humidity. Measured values of relative humidity and temperature are transmitted to a computing unit, where they are transformed in values of absolute humidity. Then values of absolute moisture content are corrected using the values of absolute moisture of the reference sensor by formula: ρ(t_n)=aρ(t_n-τ)+b, where p(t_n), kg/m³ – absolute humidity from the reference sensor at the moment of time, t_n; ρ(t_n-τ), kg/m³ – absolute humidity from the reference sensor at the moment of time, (t_n-τ); τ, min is the delay time; a is scaling factor, calculated using a criterion of minimum square deviations; b, kg/m³ – correcting correction, calculated using a criterion of minimum square deviations. Corrected absolute moisture content is compared with threshold value of moisture content and the presence of leaks is detected if the threshold value is exceeded.

EFFECT: invention allows to reduce the probability of false alarm on presence of leak and reduce the possibility of failure to detect the leak.

1 cl, 1 dwg, 1 tbl

Description

The invention relates to the field of monitoring leaks in air humidity and can be used to detect a leak in the piping and equipment of the cooling circuits of a nuclear or thermal power plant.

The closest set of essential features to the claimed invention is a method for monitoring leaks in pipelines and equipment of a cooling circuit of a nuclear or thermal power plant, including measuring relative humidity and air temperature in control rooms with technological sensors and pipelines and equipment, measuring a relative humidity and air temperature with a reference sensor outside the mentioned premises, transfer of measured values to the computing unit values of humidity and temperature, comparison with a threshold humidity value and fixing the presence of a leak when the threshold value is exceeded (RF patent No. 2268509, IPC G21C 1/17, publ. 01.20.2006).

In the known method, the control sensors are located in the sampling lines emerging from the technological premises and located in the serviced room, well ventilated and without moisture sources. The reference sensor is located in the sampling line, also located in this room, but not connected to the process room. To increase the sensitivity of the control sensors before measuring the humidity in the technological premises, air is cooled (for example, water) in the sampling lines until the temperature of the room in which the control and reference sensors are installed is reached. Relative humidity and air temperature of technological rooms are measured by control sensors in the sampling lines, and relative humidity and air temperature of the served room are measured with a reference sensor. Then, after making sure that the values of the air temperature at the output of the sampling lines are approximately equal, the relative humidity and temperature data are transmitted from the control and reference sensors to the computing unit, where the relative humidity values from the control sensors are compared with the threshold value of relative humidity. When the threshold value is exceeded, an alarm is triggered and the operator, by means of a graphic or other analysis, compares the received data from the computing unit with the current values of relative humidity from the reference sensor. The operator makes a final conclusion about the presence of a leak with an asynchronous increase in relative humidity or the absence of a leak with a synchronous increase in relative humidity. Thus, in the known method, an alarm signal is generated regardless of the actual presence of a leak, a signal can be generated with an increase in atmospheric humidity (outdoor humidity). In the known method, the presence of leaks is controlled by the operator, i.e. The control result is subjective and depends on the professional qualities of the operator, which does not guarantee high reliability of the control. In addition, to take into account the influence of atmospheric humidity fluctuations depending on weather conditions, the threshold value of relative humidity is adjusted 5-6 times a year and with the help of an operator, i.e. manually.

The disadvantage of this method is the high probability of false alarms about the presence of a leak, which is associated with the subjectivity of the control due to the participation of the operator in this process, and the increased possibility of skipping the fact of a leak, due to the need to use multiple manual adjustments to the threshold humidity value. In addition, the disadvantage of this method is the difficulty of its implementation due to the large number of hydraulic and mechanical equipment necessary for cooling the air in the sampling lines and equalizing the temperature in them. Aligning the temperature of air samples in all sampling lines is a prerequisite for further measurement and analysis of changes in relative humidity.

The objective of the present invention is to provide an easy-to-implement and reliable method for monitoring leakage of pipelines and equipment of a cooling circuit of a nuclear or thermal power plant.

The technical result of the present invention is to reduce the likelihood of false alarms about the presence of a leak and reduce the possibility of skipping the occurrence of a leak by eliminating the direct involvement of the operator in the monitoring process, including repeatedly manually adjusting the threshold humidity value. In addition, the technical result is to simplify the method by eliminating the actions associated with cooling the air in the sampling lines, and a large number of hydraulic and mechanical equipment necessary for carrying out the cooling process.

The specified technical result is achieved by the fact that in the known method for controlling the leakage of pipelines and equipment of the cooling circuit of a nuclear or thermal power plant, which includes measuring with control sensors the relative humidity and air temperature in technological rooms with controlled pipelines and equipment, measuring with a reference sensor the relative humidity and air temperature outside the mentioned premises, transfer to the computing unit the measured values of humidity and temperature tours, comparison with the threshold humidity value and fixing the presence of a leak when the threshold value is exceeded, according to the claimed invention, the relative humidity and temperature of the outside air are measured with the reference sensor, and the relative humidity and temperature values measured by the control and reference sensors are converted into absolute humidity values in the computing unit at the absolute humidity values from the control sensors are adjusted using the absolute humidity values from the reference d tchika by the formula:

ρ (t _n ) = aρ (t _n-τ ) + b,

Where

p (t _n ), kg / m ³ - absolute humidity from the control sensor at time t _n ;

ρ (t _n-τ ), kg / m ³ - absolute humidity from the reference sensor at time (t _n-τ );

τ, min - delay time;

a is a scaling factor calculated according to the criterion of the minimum of squares of deviations and taking into account the statistical characteristics of these local climatic conditions that affect the change in humidity;

b, kg / m ³ - correction correction calculated according to the criterion of the minimum of squares of deviations and taking into account the statistical characteristics of these local climatic conditions that affect the change in humidity,

and with the threshold humidity value, the corrected absolute humidity values are compared.

The invention is illustrated in the drawing, which shows a schematic diagram of a system for monitoring leakage of pipelines and equipment of the cooling circuit of a nuclear power plant.

The system for monitoring the leakage of pipelines and equipment of the cooling circuit is located in the reactor building 1 of the NPP unit, which has technological rooms 2 and 3, in which the controlled pipelines and equipment of the cooling circuit are located, and the serviced room 4. The system contains a reference humidity / temperature sensor 5 located on the outside of the reactor building 1 and directly in contact with the outside air in the area of the industrial site of the nuclear power unit. The humidity / temperature control sensors 6 are installed in the sampling lines 7, which are located in the serviced room 4 and connected to the high-temperature technological room 2, the air temperature in which reaches 280 ° C, as a result of which the location of the humidity / temperature control sensors 5 directly in this room is impossible. When measuring relative humidity in a low-temperature technological room 3 (the temperature in these rooms is 60-70 ° C), control humidity / temperature sensors 6 are installed directly in this room, and direct sensors were used. The reference humidity / temperature sensor 5 and control humidity / temperature sensors 6 are connected by electrical communication lines 8 to secondary equipment - thermo-hygrometers 9. Thermo-hygrometers 9 are connected by electrical communication lines 10 to a correction and comparison computing unit, which is used as a computer 11.

The method is as follows.

Humidity / temperature control sensors 6 continuously measure relative humidity and air temperature in technological controlled rooms 2 and 3, for example, a power unit of a nuclear power plant. A reference humidity / temperature sensor 5, mounted on the external wall of the building of the power unit, continuously measures the relative humidity and temperature of the outside air. Humidity / temperature sensors 6 and a humidity / temperature sensor 5 via electrical communication lines 8 transmit the measured values to thermohygrometers 9, from which signals are transmitted via electrical communication lines 10 to computer 11, in which the relative humidity and temperature are converted into absolute humidity values into a fixed point in time t _n using the formula proposed by the international association for the study of the properties of water and steam IAPWS-95:

Where:

ρ (ϕ _r , T) is the absolute humidity of the air, kg / m ³ ;

ϕ _r is the relative humidity of the air;

T - air temperature, K.

The values of the constants T _s , ρ _s , C ₁ , C ₂ , C ₃ , C ₄ , C ₅ and C ₆ are shown in the table:

Then, the absolute humidity values from the control sensors are corrected using the absolute humidity values from the reference sensor according to the formula:

ρ (t _n ) = aρ (t _n-τ ) + b,

Where

p (t _n ), kg / m ³ - absolute humidity from the control sensor at time t _n ;

ρ (t _n-τ ), kg / m ³ - absolute humidity from the reference sensor at time (t _n-τ );

τ, min - delay time;

a is a scaling factor calculated according to the criterion of the minimum of squares of deviations and taking into account the statistical characteristics of these local climatic conditions that affect the change in humidity;

b, kg / m ³ - correction correction calculated according to the criterion of the minimum of squares of deviations and taking into account the statistical characteristics of these local climatic conditions that affect the change in humidity.

In the above calculation formula, corrections: a - scaling factor and b - correction correction are entered for each room 2 and 3 separately. Further, the adjusted absolute humidity values are compared with the threshold humidity value, which remains constant throughout the campaign. If the threshold value is exceeded, a leak alarm is triggered automatically.

The claimed method monitors the correction of the time trend of the values of the absolute humidity in controlled technological rooms and the absolute humidity of the outside air (outside the building of the power unit), i.e. An analysis is made of the correlation of indoor air humidity and outdoor air. If such a relationship is manifested and synchronous changes in the absolute humidity inside and outside the air are observed, then the computer control algorithm decides that these changes are caused by climatic changes in the atmosphere (daily, weekly, monthly, seasonal) in the area of the power unit building. As a result, the adjusted humidity trend has no growth; there is no excess of the threshold value for humidity, i.e. there is no leak and there is no false response of the system. If there are asynchronous changes in the humidity of the air in the controlled technological rooms and the humidity of the outdoor air, and the humidity trend in the room is growing steadily, then the computer control algorithm decides that these changes are caused not by climatic changes in the atmosphere, but by the appearance of leaks in pipelines or equipment. As a result, the humidity trend has an increase, exceeds the threshold value for humidity, the system works normally and gives an alarm signal about a leak.

Claims (9)

A method for monitoring the leakage of pipelines and equipment of the cooling circuit of a nuclear or thermal power plant, including measuring the relative humidity and temperature of the air in control rooms with technological pipelines and equipment with control sensors, measuring the relative humidity and temperature of the air outside the premises by the reference sensor, transferring the measured humidity and temperature values, comparison with a threshold humidity value and fixing the presence leaks when the threshold value is exceeded, characterized in that the relative humidity and temperature of the outside air are measured with a reference sensor, and the relative humidity and temperature values measured by the control and reference sensors are converted into absolute humidity values in the computing unit, while the absolute humidity values from the control sensors are adjusted with using absolute humidity values from the reference sensor according to the formula: ρ (t_n) = aρ (t_n-τ) + b, Where: ρ (t _n ), kg / m ³ - absolute humidity from the control sensor at time t _n ; ρ (t _n-τ ), kg / m ³ - absolute humidity from the reference sensor at time (t _n-τ ); τ, min - delay time; a - scaling factor calculated according to the criterion of the minimum of squares of deviations and taking into account the statistical characteristics of these local climatic conditions that affect the change in humidity; b, kg / m ³ - correction correction calculated according to the criterion of the minimum of squares of deviations and taking into account the statistical characteristics of these local climatic conditions that affect the change in humidity, and with the threshold humidity value, the corrected absolute humidity values are compared.

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