RU2480700C2 - Device for automatic analysis of heat carrier parameters, and method for its implementation - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: device for automatic analysis of heat carrier parameters, which contains a sampling device having the possibility of sampling, preparation and supply of analysed sample of liquid or gaseous heat carrier, a liquid analyser and an electronic control unit. The sample preparation device includes one heat exchanger consisting of a steam receiver and a refrigerator, and the liquid analyser includes one measuring cell, which can contain one or more sensors for measurement of heat carrier parameters. A heat carrier parameter control method is proposed as well.

EFFECT: reduction of dimensions and improvement of reliability.

7 cl, 1 dwg

Description

FIELD OF THE INVENTION

The present invention generally relates to systems for controlling the parameters of materials using electrochemical and magnetic means. In particular, the present invention relates to devices for automatically monitoring the parameters of the coolants of atomic and thermal power plants, heat supply stations, and can also be used in the metallurgical, chemical, food industries.

BACKGROUND OF THE PRIOR ART

The reliability and stability of the equipment of power units used in industry, largely depends on the parameters of the coolant entering the power units. To continuously monitor the parameters of the coolant and timely prevent various deviations that can lead to a decrease in the life of the product or to its accident, devices are used that constructively and functionally combine two subsystems - a sample preparation device and a sample analyzer.

Known sample preparation devices are based on the use of coil heat exchangers having a high hydrodynamic resistance and a low rate of condensation of a liquid from a vaporous coolant (for example, RF patent application 2005122473). Such systems use mechanical pressure reducers, throttles or overflow systems, which in turn reduces the overall system uptime and requires regular maintenance (for example, RF patent 2344290).

In addition, well-known sample analyzers are performed on a modular basis, which in turn leads to an increase in measurement error and requires constant manual control of the system parameters at control points (for example, application for the invention of the Russian Federation 94026994).

Some of these shortcomings were eliminated in the device for automatic control of the water coolant of power plants (certificate for utility model RF 38508), containing at least one sample preparation device and at least one analyzer with a sensor. However, in this device, the measuring cell (a separate container for measuring any environmental parameter) contains only one sensor. When analyzing several parameters of the coolant at the same time, the measuring cells turn out to be hydraulically connected in series, which increases the size and weight of the installation, as well as the processing time of one sample.

SUMMARY OF THE INVENTION

The objective of the present invention is to develop a device for controlling the parameters of a liquid or vaporous coolant, which is small in size and ensures the preparation of the analyzed sample with the necessary level of reliability and the specified preparation parameters, as well as quick and accurate analysis of the sample. The objective of the present invention is also to develop a method for automatically controlling the parameters of a liquid or vaporous coolant.

A device for automatic analysis of the parameters of the coolant and a method for its implementation, comprising a sample preparation device configured to take, prepare and supply an analyzed sample of a liquid or vapor coolant, a liquid analyzer containing at least one sensor, and an electronic control unit. The sample preparation device contains one heat exchanger, and the liquid analyzer contains a measuring cell, which may contain one or more sensors for measuring the parameters of the coolant.

The use of only one heat exchanger, including for high-pressure steam and a measuring cell with one or more sensors, ensures the small size of the device, as well as quick analysis of samples.

According to one embodiment, the heat exchanger is a steam receiver configured to condense steam, and a tangential inlet is provided in the steam receiver for the source coolant. The indicated design of the heat exchanger allows condensation and cooling of the sample in a short time and without the need for additional heat exchangers.

According to another embodiment, the steam receiver is configured to manually take a prepared sample.

According to another embodiment, the measuring cell is configured to rinse (clean). This is necessary to obtain reliable measurement results.

According to another embodiment, said measuring cell includes several sensors or combinations thereof: an EMF measurement sensor, an electrical conductivity measurement sensor, a dissolved molecular oxygen concentration measurement sensor, a temperature measurement sensor, a pressure measurement sensor, and other sensors.

A method for analyzing heat carrier parameters is also proposed, according to which an analyzed sample of a liquid or vapor coolant is fed to a heat exchanger, the specified sample is prepared in the heat exchanger by condensing steam in the presence of a vapor coolant, the temperature and pressure of the specified sample are regulated, the specified sample is fed to the measuring cell, the parameters of the specified sample are measured washing the measuring cell. Moreover, all the steps of the method are carried out automatically under the control of an electronic control unit or manually, or by a combination of the above methods, and the specified sample is fed to the heat exchanger by means of tangential input.

Other aspects and features of the present invention will become apparent after reading the description and the accompanying drawings.

The sample preparation device and analyzer can be used both together and separately.

BRIEF DESCRIPTION OF THE DRAWINGS

In FIG. 1 shows a functional diagram of a device for monitoring the parameters of the coolant according to one embodiment of the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

According to a preferred embodiment, the device for monitoring the parameters of the coolant consists of a sample preparation device (SCP) containing a heat exchanger in the form of a steam receiver 1 with cooled walls and a refrigerator 2, and an analyzer containing a measuring cell 3, sensors 4-7, as well as an electronic control unit (see Figure 1). In addition, for washing the cell 3, a container 8 is provided for storing distilled water. To control the movement of the coolant and for the operation of the device, taps 19-16 are provided, which can be structurally combined, for example, taps 13 and 14 can be replaced by one tap.

The soft starter is designed to prepare and feed the sample to the analyzer by adjusting its pressure and temperature. The soft starter can be used to work with coolants in liquid and vapor form (water and aqueous solutions of substances) that do not cause corrosion of stainless steel and nickel-plated brass.

In a preferred embodiment, the SCP provides:

- selection, preparation and supply of an analyzed sample of water and steam coolants with a temperature from + 30 ° С to + 565 ° С and a pressure from 0.05 MPa to 32 MPa to automatic chemical control devices by reducing pressure and temperature;

- the ability to select, prepare and supply the analyzed sample for manual analysis by the device operator;

- adjustment of the temperature of the analyzed sample at the outlet from + 2 ° C to + 50 ° C;

- the required level of protection operation (overlapping the flow of the analyzed sample when the temperature and / or pressure of the sample goes beyond the set limits of the adjustments);

- indication of temperature, pressure and flow rate of the sample, as well as the transfer of information about the measured parameters of the sample and alarms to the control system of the upper level;

- connecting, if necessary, several sensors simultaneously, depending on the number of controlled parameters of the analyzed sample;

- mechanical cleaning of the sample.

The control valves of the soft starter according to the results of measuring the temperature of the sample and an alarm about the output of the sample pressure outside the permissible limits is carried out by the electronic control unit or manually.

In one embodiment, the soft starter forms a sample for the analyzer at least 6 times per hour. In addition, the preparation of each new sample can occur simultaneously with the control of the parameters of the previous sample in the analyzer.

It should be noted that the increase in the rate of formation of parameters is provided by the design of the steam receiver, built on the principle of "decantation". The coolant at the sampling point enters the steam receiver through a tangential inlet (32 kg / cm ² at t = 565 ° C), i.e. the steam receiver can be described as an expansion system with cooling, with further condensation and condensate accumulation in the lower part of the steam receiver.

The analyzer is a liquid analyzer designed to measure the EMF of electrode systems and convert the results into ion concentration / activity, conductivity, dissolved molecular oxygen concentration, liquid temperature, liquid pressure and / or other parameters, both individually and collectively, for preliminary processing of measurement results (mathematical and statistical), for control of control elements and protection of soft starters, for cottages in automatic process control system (PCS) of the array of current and / or stored data and outputting the unified output analog and digital signals in the automatic control and regulation system.

The analyzer provides an indication of the measurement results on the digital indicator of the controller unit, an alarm signal for exceeding the limits of the set values (settings) via potentiometric, amperometric and conductometric channels.

The analyzer has an analog output unified DC signal, as well as a digital interface of the RS-485 standard for transmission to automatic process control systems (ACS TP) (not shown) of an array of accumulated and current data. Measurements in the analyzer have increased accuracy due to the use of new data processing algorithms, namely, due to the inclusion of entropy processes in thermal circuits and in analytical chemical reactions.

The main controlled environment is water and aqueous solutions of the first and second circuits and auxiliary systems of nuclear power plants and thermal power plants. The composition of this medium may include condensate and demineralized condensate of the turbine, feed and boiler water or steam condensate, including their H-cation samples. The following impurities are allowed in feed water: iron and copper - up to 5 ÷ 10 μg / kg, ammonia up to 1000 μg / kg, hydrazine up to 100 μg / kg. The medium may be corrosive (pH 5.0 to 12.5). In this case, the presence of mechanical impurities with a particle size of not more than 0.3 mm is allowed.

The analyzer’s sensors can include an EMF measurement sensor with conversion of the results into values of ion concentration and / or activity, electrical conductivity measurement sensor, dissolved molecular oxygen concentration measurement sensor, temperature measurement sensor, pressure measurement sensor and / or other parameters both individually and together.

A potentiometric method is used to measure the activity of pH ions (pX) in solutions. The electrode system used in conjunction with the measuring transducer consists of an ion-selective measuring electrode, a reference electrode and a temperature sensor.

A potentiometric method is used to measure the concentration of sodium ions in solutions. The electrode system used in conjunction with the measuring transducer consists of a Na-selective measuring electrode, a reference electrode, a temperature sensor and a pH electrode to control the level of alkalization of the sample.

To measure the concentration of molecular dissolved oxygen, a membrane amperometric cell is used, which is an electrode system separated from the analyzed medium by a gas-permeable membrane. The electrode system includes indicator, auxiliary and protective electrodes.

The measurement of electrical conductivity is based on measuring the active component of an alternating current passing between the electrodes of the conductivity cell through which the analyzed medium flows.

The parameter control device as a whole has increased reliability due to the lack of a mechanical pressure reducer, throttle and overflow system, and thanks to the electronic control unit, the measurement process is fully automated and does not require preliminary configuration and subsequent adjustment of the device.

The method for analyzing the parameters of the heat carrier according to the preferred embodiment includes supplying cooling water to the cooling circuit of the steam receiver 1 and the refrigerator 2, supplying an analyzed sample (for example, superheated steam) to the tangential input of the steam receiver 1. The superheated steam entering the steam receiver 1 is cooled to a saturation temperature and condenses . In this case, the condensate having the desired temperature, after opening the valve 14 enters the measuring cell 3.

The sample is prepared by adjusting its temperature and pressure, and by the signal of the LE sensor (19), the valve 14 is closed and the condensate received is analyzed sequentially by the sensors 4, 6, 7 of the parameters (QE-4, QE-6, QE-7) and the temperature measurement sensor 5 ( THOSE). The measurement result is sent to the electronic control unit.

The condensate remaining in the steam receptacle 1 is drained after closing the valve 14 by opening the valve 13. After determining the characteristics of the water, the valve 16 is opened and the condensate is drained from the cell 3. Next, the valve 16 is closed and the valve 15 is opened, through which the cell 3 is supplied from the tank 8 water (distillate) to flush this cell. Then the water is drained from cell 3. Upon completion of this operation, the whole process can be resumed.

The system provides the possibility of manual sampling when opening the valve 13. The crane 10 serves to supply the coolant to the installation.

The present invention is not limited to the specific embodiments disclosed herein for illustrative purposes only, and encompasses all modifications and variations without departing from the scope and spirit of the invention as defined by the claims.

Claims (7)

1. A device for automatic analysis of the parameters of the coolant, containing
a sample preparation device configured to carry out the selection, preparation and supply of an analyzed sample of a liquid or gaseous coolant, a liquid analyzer and an electronic control unit,
characterized in that the sample preparation device contains one heat exchanger, consisting of a steam receiver and a refrigerator, and the liquid analyzer contains one measuring cell, which may contain one or more sensors for measuring the parameters of the coolant. 2. The device according to claim 1, in which the heat exchanger is a steam receiver configured to condense steam, and a tangential inlet is provided for the initial heat carrier in the steam receiver. 3. The device according to claim 2, in which the steam receiver is configured to manually select the cooked coolant. 4. The device according to claim 1, in which the measuring cell is made with the possibility of washing. 5. The device according to claim 1, in which at least one measuring sensor is indicated. 6. The device according to claim 1, in which an EMF measurement sensor, a specific electric conductivity measurement sensor, a dissolved molecular oxygen concentration measurement sensor, a temperature measurement sensor or a pressure measurement sensor are connected to the analyzer. 7. The method of analysis of the parameters of the coolant, according to which serves the analyzed sample of liquid or gaseous coolant in the heat exchanger,
preparing said sample in a heat exchanger by lowering the temperature and pressure of said sample to the required values,
the specified sample is supplied to the measuring cell, the parameters of the specified sample are measured,
washing the measuring cell,
characterized in that all the steps are carried out both under the control of the electronic control unit, and in manual mode, or a combination of these, and this sample is fed into the heat exchanger by means of tangential input.

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