RU111709U1 - HEATING LEAK DETECTION SYSTEM IN NPP ROOMS - Google Patents

Abstract

1. A system for detecting a coolant leak in NPP premises, containing an air sampling line and a cooler installed in series in it, a moisture separator with a condensate drain line, a gas flow heater, a flow meter and a flow booster, characterized in that it is equipped with a cooler installed in the sampling line in front of the cooler a two-way flow direction device, one outlet of which is connected to the gas flow inlet to the cooler, a humidity and temperature measuring device included in the sampling line downstream of the heater, and a bypass line connected at one end to the second outlet of the two-way flow direction device, and the other connected to the line sampling behind the heater. ! 2. The system according to claim 1, characterized in that it is equipped with a device for measuring the volumetric activity of aerosols, included in the sampling line after the flow meter. ! 3. The system according to claim 1 or 2, characterized in that it is equipped with a device for measuring the amount of condensate connected to the condensate drain line. ! 4. The system according to claim 3, characterized in that the device for measuring the amount of condensate is made in the form of a container and contains a drain valve and a condensate level indicator. ! 5. The system according to claim 1 or 2, characterized in that it is provided with a temperature sensor installed in the sampling line upstream of the two-way flow direction device. ! 6. The system according to claim 2, characterized in that it is equipped with a second temperature sensor installed on the sampling line in front of the device for measuring the volumetric activity of aerosols. ! 7. System according to claim 1 or 2, characterized in that it is equipped with a pressure sensor mounted on the l

Description

The utility model relates to the nuclear industry, namely to a system designed to detect coolant leakage by monitoring the humidity or aerosol activity of the air in the premises of a nuclear power plant.

A known system for detecting a coolant leak by controlling aerosol activity in the premises of a nuclear power plant, containing a dehumidifier that separates the air of the controlled room into condensate and air, a device for measuring the volumetric activity of aerosols in the air, and a module for measuring the volumetric activity of gamma-emitting radionuclides in liquids (RU 82915 U1, 05/10/2009). However, this system is difficult to operate, has bulky equipment, low accuracy and a long measurement time, since measurements are carried out both in the gaseous and in the liquid phase.

Also known is a system for detecting a coolant leak by monitoring aerosol activity (prototype), comprising a device for separating the air of a controlled room into condensate and an air medium connected by an air medium pipe to a device for measuring volumetric activity of aerosols, and a pipe for condensate drainage with a volumetric measurement module the activity of gamma-emitting radionuclides in a liquid, while the device for measuring the volumetric activity of aerosols is connected to the pipeline p zryazheniya and measurement unit volume activity of gamma-emitting radionuclides in the fluid conduit is connected to the condensate discharge into the special sewage (RU 100 817 U1, 27.12.2010).

The disadvantages of the system known from patent RU 100817 are that the desired value of the initial volumetric activity of aerosols in the air in controlled rooms is achieved by summing two components - the measured volumetric activity of aerosols in a gas (in dried samples) and the measured volumetric activity of gamma-emitting radionuclides in liquids (in condensate from samples) - taking into account the parameters of the rate of formation of condensate and the flow rate of samples through the sampling pipe. Instruments for measuring the volumetric activity of radionuclides in liquids are quite expensive, cumbersome, and difficult to operate, require additional circuits of demineralized water and compressed air to periodically flush and dry the measuring volumes of the system, which naturally creates significant difficulties in the implementation and operation of such systems. In addition, the means of measuring the volumetric activity of aerosols in a gas and the volumetric activity of gamma-emitting radionuclides in liquids traditionally measure various types of radionuclides, which can introduce a significant error in calculating the desired value of the initial aerosol activity of the air in controlled rooms due to the variable radionuclide composition of the coolant during the micro-campaign of the power unit. In connection with the foregoing, the known system has low technical and operational performance.

The objective of the utility model was to develop a coolant leak detection system in NPP premises with high technical and operational characteristics, the main indicators of which in this case are a wide measurement range with high accuracy and reliability of control, measurements of the required set of parameters for use in the developed algorithms, reduction of time and simplified measurements, reduced mass and volume of the system (since the proposed system does not have a module for measuring the volumetric act the properties of gamma-emitting radionuclides in a liquid).

Thus, the technical result is to improve the technical and operational characteristics of the proposed system.

The specified technical result is achieved by the fact that the system for detecting coolant leaks in the premises of a nuclear power plant, containing a line for sampling air and a cooler, a moisture separator with a condensate drain line, a gas flow heater, a flow meter and a flow inducer in accordance with the utility model, is installed in sampling lines in front of the cooler with a two-way flow direction device, one output of which is connected to the gas flow inlet to the cooler, zhnosti and temperature included in a sampling line for a heater and a bypass line, with one end connected to the second output of the two-way flow direction device, and other - is connected to sampling line for the heater.

In addition, the system can be equipped with a device for measuring the volumetric activity of aerosols included in the sampling line behind the flow meter.

It is envisioned that the system may be provided with a condensate measuring device connected to a condensate drain line.

In addition, the device for measuring the amount of condensate can be made in the form of a container and contain a drain valve and a condensate level indicator.

It is also envisaged that the system can be equipped with a temperature sensor mounted on a sampling line in front of a two-way flow direction device.

At the same time, the system can be equipped with a second temperature sensor installed on the sampling line in front of the device for measuring the volumetric activity of aerosols.

It is envisaged that the system can be equipped with a pressure sensor installed on the sampling line in front of the device for measuring humidity and temperature.

It is also recommended that the system be equipped with a second pressure sensor mounted on the sampling line in front of the aerosol volumetric activity measuring device.

The drawing shows a schematic diagram of a system for detecting a coolant leak in the premises of a nuclear power plant.

The coolant leak detection system in the premises of a nuclear power plant contains a sampling line (1) of the air environment and a cooler (2), a water separator (3) with a condensate drain line (4), a gas flow heater (5), a flow meter (6), and a sequentially installed one flow stimulator (7) mounted at the end of the sampling line. The system is also equipped with a two-way flow direction device (8) installed in the sampling line in front of the cooler (2), a humidity and temperature measuring device (9), included in the sampling line behind the heater, and a bypass line (10). One output of the two-way flow direction device (8) is connected to the gas flow inlet to the cooler (2). The bypass line (bypass line) is connected at one end to the second output of the two-way flow direction device, and at the other end is connected to the sampling line (1) behind the heater (5). In addition, to obtain a high accuracy of the measured parameters, the system can be equipped with a device for measuring the volumetric activity of aerosols (11), included in the sampling line behind the flow meter (6). It is envisaged that the system can be equipped with a condensate amount measuring device (12) connected to a condensate drain line (4) from a moisture separator (3). The device for measuring the amount of condensate (12) can be made in the form of a container and contain a drain valve and a condensate level indicator. To create an air flow and rarefaction in the sampling line (1), a vacuum pump, a fan or an exhauster installed at the end of the mentioned line can be used as a flow inducer (7). In the cooler (2), a compression refrigeration machine or an absorption refrigeration unit, or a thermoelectric refrigeration unit can be used as a source of cold. The system can be equipped with a temperature sensor installed on the sampling line (1) in front of the two-way flow direction device (8). In addition, the system can be equipped with a second temperature sensor installed on the sampling line in front of the device for measuring the volumetric activity of aerosols (11). It is envisaged that the system can be equipped with a pressure sensor installed on the sampling line in front of the device for measuring humidity and temperature (9), as well as a second pressure sensor installed on the sampling line in front of the device for measuring volumetric activity of aerosols (11).

The system operates as follows. Air from the controlled room enters the sampling line (1) and through a two-way flow direction device (8), enters the cooler (2), where it is cooled to form condensate, which is separated from the gas stream in the moisture separator (3). Condensate flows through a condensate drain line (4) into a special sewer to collect radioactive waste. After leaving the dehumidifier, the drained gas stream is sent to the heater (5). The gas flow is heated to a predetermined value in order to prevent the formation of condensate in the installation area of the measuring equipment and thus increase the accuracy of measurements. From the heater (5), the gas stream enters the device for measuring humidity and temperature (9), and then through the flow meter (6) to the device for measuring the volumetric activity of aerosols (11). Using a two-way flow direction device (8), the flow of air samples can be directed along the bypass line (11), bypassing the cooler (3) and heater (6), through a gas flow meter (9) to a moisture measuring device (10). The direction of sample flow is selected based on the temperature and humidity conditions formed in the installation zone of the measuring elements of the system and determines two main modes of operation of the system - respectively, the mode with cooling the samples and the mode without cooling the samples. The flow of air (gas) through the working elements of the system is created by the flow driver (7) installed at the end of the sampling line (1). If it is necessary to use a device for measuring the amount of condensate (12) connected to the condensate drain line (4) from the moisture separator (3), when the condensate reaches the maximum set level in the tank, the drain valve (or valve) opens for a certain time and allows condensate to drain through drainage line to a special sewer for radioactive waste.

In this technical solution, the desired value of the initial volumetric aerosol activity of the air in the controlled rooms is determined based on the measured activity of the residual aerosols in the dried samples and the calculated ratio between the amount of aerosols deposited in the condensate and the residual amount of aerosols contained in the dried samples. Moreover, this ratio is found by the parameters of the residual moisture content in the dried samples and the rate of condensate formation, taking into account the flow rate of samples through the sampling line (1) of the air medium, as well as the coefficient of deposition of aerosols with condensate.

High technical and operational characteristics of the proposed system are due to the composition of the equipment and the relationships of the equipment elements, i.e. the set of essential features given in the independent claim of the utility model formula.

Claims (8)

1. A system for detecting a coolant leak in the premises of a nuclear power plant, comprising a line for sampling the air and a cooler, a moisture separator with a condensate drain line, a gas flow heater, a flow meter and a flow inducer sequentially installed in it, characterized in that it is equipped with a sampling line in front of the cooler a two-way flow direction device, one output of which is connected to the gas flow inlet to the cooler, a humidity and temperature measuring device included in the sampling line for odogrevatelem and bypass line attached at one end to the second output of the two-way flow direction device and the other connected to a sampling line for the heater. 2. The system according to claim 1, characterized in that it is equipped with a device for measuring the volumetric activity of aerosols, included in the sampling line for the flow meter. 3. The system according to claim 1 or 2, characterized in that it is equipped with a device for measuring the amount of condensate connected to the condensate drain line. 4. The system according to claim 3, characterized in that the device for measuring the amount of condensate is made in the form of a container and contains a drain valve and a condensate level indicator. 5. The system according to claim 1 or 2, characterized in that it is equipped with a temperature sensor mounted on the sampling line in front of a two-way flow direction device. 6. The system according to claim 2, characterized in that it is equipped with a second temperature sensor mounted on the sampling line in front of the device for measuring volumetric activity of aerosols. 7. The system according to claim 1 or 2, characterized in that it is equipped with a pressure sensor installed on the sampling line in front of the device for measuring humidity and temperature. 8. The system according to claim 2, characterized in that it is equipped with a second pressure sensor installed on the sampling line in front of the device for measuring volumetric activity of aerosols.