RU2722475C1 - Method and an automatic system for calibrating gas analyzers using micro stream sources - Google Patents

Abstract

FIELD: measuring equipment.SUBSTANCE: invention relates to measurement equipment, in particular to gas-analytical measurements, and can be used for monitoring condition and composition of atmosphere. Method for automatic calibration of gas analyzers includes feeding a mixture with zero content of SOand NO, a calibration mixture of known concentration obtained using micro stream sources, on gas analyzer in turn with atmospheric air samples in automatic mode using program-controlled valves, note here that zero and calibration mixture as well as atmospheric air samples are supplied from two altitude levels by means of discharge pumps. Note here that volume of air mix supplied to gas analyzer inlet exceeds that of gas analyzers.EFFECT: technical effect is to provide an automatic system and method for calibrating gas analyzers, allowing high precision to carry out the concentration measurement in the air, such gases as sulfur dioxide (SO) and nitrogen oxide (NO).7 cl, 3 dwg, 1 tbl

Description

The invention relates to measuring technique, in particular to gas-analytical measurements, and can be used in solving problems of monitoring the state and composition of the atmosphere.

Known [RU 49288 U1, 2005], in which the post of environmental air control is disclosed and a method for providing metrological parameters of a gas analyzer, which are provided by an integrated calibrator, is described. Calibration performed using calibration gas mixtures (CGS) is carried out to verify the reliability of the results obtained from gas analyzers. The frequency of calibration is determined by the operator. The calibration is carried out as follows. When calibrating gas analyzers according to the operator’s signal, the gas flow switching device switches the gas analyzers from the Atmosphere sampling probe to cylinders with standard calibration gas mixtures (ASG). In this case, the mixture from the cylinders, for example, СО, enters the diluent generator of gas mixtures, which dilutes it with air (clean air comes from the cylinder) to a certain concentration. Next, the mixture of a given concentration goes to the gas analyzers. Then, the known concentration of the mixture from the diluent generator of gas mixtures is compared with the readings of the gas analyzer. Calibration is performed using the microflow source available in the gas analyzer.

The disadvantages of the above analogue are:

- the presence in the calibration path of the diluent generator, which introduces an additional error;

- constant use for calibration of an expensive reference gas mixture.

As the nearest technical solution, an automatic system was selected for calibrating gas analyzers using microflow sources, which was disclosed in the article [Arshinov M.Yu., Belan B.D., Davydov D.K., Ivlev G.A., Kozlov A.V., Pestunov D.A., Pokrovsky E.V., Tolmachev G.N., Fofonov A.V. Posts for monitoring greenhouse and oxidizing gases. Optics of the atmosphere and ocean, 20, No. 1, 2007, 53-61]. Calibration is carried out using both a mixture with a zero content of SO ₂ and NO ₂ , and a calibration mixture of a known concentration obtained using microflow sources. To implement the calibration process, the known system contains a nitrogen cylinder, which is used as a mixture with zero SO ₂ and NO ₂ content, thermostats with microflow sources, providing a calibration mixture of known concentration, air lines with installed program-controlled on-off valves for switching air flows, pumps that supply one of the sources of the air mixture to the air lines: samples of atmospheric air or air mixture with zero content of SO ₂ and NO ₂ , and a calibration mixture of known concentration.

The disadvantages of the technical solution described in the above document include:

- in the system, pumps that stimulate the flow and deliver air for analysis are located after the devices, which, firstly, is not sufficient to ensure a stable pressure at the inlet of the gas analyzers since the lines through which the gas mixtures are supplied have different lengths and, therefore, resistance and secondly, it makes it impossible to change the speed of pumping the air mixture through a thermostat with a microflow source, since with this arrangement the flow of the air mixture through the thermostat is determined by the flow rate through the gas analyzer.

- in the system, for each source of microflow, a separate thermostat is used, which leads to an increase in the cost and complexity of the system.

The objective of the invention is to develop an automatic system and method for calibrating gas analyzers, allowing high accuracy to measure the concentration in the atmospheric air of such gases as sulfur dioxide (SO ₂ ), and nitrogen oxides (NO _x ), mainly included in the monitoring system of the state and composition of the atmosphere .

The problem is achieved in that, like the well-known proposed method for automatic calibration of gas analyzers includes:

- supply of a mixture with a zero content of SO₂ and NO₂ and a calibration mixture of known concentration obtained using sources of microflow to the gas analyzer in turn with atmospheric air samples in automatic mode using program-controlled valves.

New is the fact that the supply of zero and calibration mixtures, as well as samples of atmospheric air, from two altitude levels, is carried out using pressure pumps.

In this case, the volume of the supplied air mixture to the inlet of the gas analyzers exceeds the flow rate of the gas analyzers themselves.

In addition, the discharge of excess air is organized at the inlet of each device, controlled by an electronic flow meter.

At the same time, scrubbers were used to obtain a mixture with a zero content of SO ₂ and NO ₂ .

In addition, during the calibration process, it is possible to change the concentration of the calibration mixture obtained using microflow sources.

Moreover, the system uses one thermostat for two different sources of microflow.

The task is achieved in that, like the well-known proposed automatic calibration system for gas analyzers, contains program-controlled on-off valves installed in the air lines for switching air flows, pumps that supply one of the air mixture sources to the system: atmospheric air samples or test gas mixtures .

What is new is that in the system, the supply of zero and calibration mixtures, as well as samples of atmospheric air, from two altitude levels, is carried out using pressure pumps.

In addition, the system organizes the discharge of excess air, controlled by an electronic flow meter.

The system also contains scrubbers to obtain a zero mixture and purify the spent calibration mixtures from the toxic impurities SO ₂ and NO ₂ contained in them.

The proposed method and automatic calibration system is based on the use of software-controlled on-off valves that supply one of the gas mixture sources to gas analyzers: atmospheric air samples from two altitude levels, a gas mixture with zero content of SO ₂ and NO ₂ , a calibration mixture of known concentration, obtained using microflow sources. Pumps delivering the sample from the upper and lower altitude levels operate continuously, forcing air into the so-called receivers, from which the sample is supplied to the gas analyzers through a valve system. A zero mixture is obtained when air is taken directly from the room through the scrubber, calibration when passing through the scrubber and cuvettes in which there are sources of microflow. Structurally, cuvettes with microflow sources are located in one thermostat, which provides a given temperature. The gas analyzers used to measure NO _x and SO ₂ have their own flow drivers. Therefore, the gas mixture is supplied to the inlet of the device in excess quantity, in connection with this, at the inlet of each device, a discharge of excess air is organized, controlled by an electronic flow meter.

The air mixture is supplied to the gas analyzers by creating excess pressure in the supply air ducts . Gas analyzers used to measure NO_x and SO₂have their own expense drivers; therefore, there is a need ensuring the same conditions at the inlet of the gas analyzers in the presence of various sources of the air mixture.

In the proposed system, to solve this problem, injection pumps are used and a controlled discharge of excess air sample is organized directly at the inlet of the gas analyzers. Moreover, since gas analyzers have their own flow drivers, there is no need for precise control of the inlet pressure of each gas analyzer.

The invention is illustrated in graphic materials.

In FIG. 1 is a functional diagram of an automatic calibration system for gas analyzers SO ₂ and NO _x using a gas mixture with zero content of SO ₂ and NO ₂ and a calibration mixture of known concentration.

In FIG. 2 is a timing chart of the concentration of SO ₂ during calibration.

In FIG. Figure 3 shows a timing diagram of the concentration of NO _x during calibration.

The proposed automatic gas analyzer calibration system shown in FIG. 1 contains a thermostat 1, inside which there are sources of microflow (SO ₂ ) 2 and (NO ₂ ) 3. The air mixture is supplied to the thermostat by pump 4 using flow regulators 5 and 6, valves 7, 8, 9, 10 and scrubbers 11, 12, designed to create zero gas. Valves 13, 14, 15 and 16 are used to supply the calibration gas mixture to the gas analyzers of sulfur dioxide 17 and nitrogen oxides (NO _x ) 18. To clean the air mixture from the toxic impurities SO ₂ and NO ₂ contained in it, the system uses a scrubber 19. Electronic flow meters 20 and 21 are designed to control the discharge of excess ASG at the inlets of gas analyzers 17 and 18. An air line containing pumps 22 and 23, receivers 24 and 25, and valves 26 and 27 is used to supply atmospheric air samples.

The proposed device operates as follows.

To supply the calibration mixture, air lines are used, containing a pump 4, flow regulators 5 and 6, valves 7 and 8, scrubbers 11 and 12, valves 9, 10, thermostat 1 with microflow sources 2 and 3, valves 13, 14, 15, 16 The supply of the zero mixture is carried out along the same path as the calibration mixture, bypassing the thermostat and valves 13 and 14.

The measurement and calibration process is carried out as follows: hhh 00min pump 4 through the flow regulators 5 and 6, valves K7, 8, 9, 10, 13 and 14 provides a purge of the cell with the sources of microflow 2 and 3. To save the resource of the scrubbers 11 and 12, the purge is carried out untreated air bypassing scrubbers. The sample is supplied through valves 26, 27, 15, 16 from XXh 00min to Hhh 20min - a sample from the first altitude level, from Hhch 20min to Hhh 40min - a sample from the second altitude level At XXh 40min, valves 7 and 8 direct flows through scrubbers 11, 12 and then the purified air (zero mixture) enters through the valves 9, 15 and 10, 16 at the inlet of the gas analyzers. At XXh 50min through valves 7, 8, scrubbers 11, 12, valves 9, 10, 13, 14 the cell with capsules is purged with a zero mixture, at XXh 51min valves 13 and 14 are switched, and the calibration mixture is fed to the instrument inputs through 15, 16 . At XXh 00min the cycle repeats.

To confirm the technical result, comparative measurements of the concentrations of SO ₂ and NO ₂ were carried out. An example of the results of restoring the concentrations of SO ₂ and NO ₂ during one calibration cycle is presented in Table 1 and in graphical form FIG. 2 and FIG. 3.

Table 1 Example of calibration results for Thermo Environmental Instruments Model 42 i TL and Model 43 i- TLE gas analyzers during one measurement cycle

Gas C _PS , billion ^-1 C _{Model 43i} , billion ^-1 * σ, billion ^-1 * C _{Model 43i} , billion ^-1 ** σ, billion ^-1 ** SO ₂ 0 3,1 ± 0.02 0.1 ± 0.02 34,287 34.7 ± 0.02 34.3 ± 0.02 Gas C _PS , billion ^-1 C _{Model 42i} , billion ^-1 * σ, billion ^-1 * C _{Model 42i} , billion ^-1 ** σ, billion ^-1 ** NO ₂ 0 6.2 ± 0.03 -0.1 ± 0.05 101,338 82.7 ± 0.04 101.3 ± 0.05

With _PS - the concentration of the calibration mixture.

* average readings of Model 43 i- TLE and Model 42 i TL gas analyzers for 10 minutes during calibration to determine correction factors; σ is the standard deviation;

** average readings of Model 43 i- TLE and Model 42 i TL gas analyzers for 10 minutes after making correction factors; σ is the standard deviation.

Claims (7)

1. A method for automatically calibrating gas analyzers, comprising the following steps: supplying a mixture with zero SO₂ and NO₂, calibration mixture of known concentration obtained using microflow sources to the gas analyzer in turn with atmospheric air samples in automatic mode using program-controlled valves, characterized in that the supply of zero and calibration mixtures, as well as atmospheric air samples, from two altitude levels, is carried out using injection pumps, while the volume of the supplied air mixture to the inlet of the gas analyzers exceeds the flow rate of the gas analyzers themselves. 2. The method according to claim 1, characterized in that at the inlet of each device a discharge of excess air is organized, controlled by an electronic flow meter. 3. The method according to claim 1, characterized in that scrubbers are used to obtain a mixture with a zero content of SO ₂ and NO ₂ . 4. The method according to claim 1, characterized in that during the calibration process it is possible to change the concentration of the calibration mixture obtained using microflow sources, using one thermostat for two different microflow sources. 5. An automatic calibration system for gas analyzers, containing program-controlled on-off valves installed in the air lines for switching air flows, pumps supplying one of the gas mixture sources to the system, characterized in that the system supplies zero and calibration mixtures, as well as samples atmospheric air, from two altitude levels, is carried out using pressure pumps. 6. The system according to p. 5, characterized in that the system is organized discharge of excess air. 7. The system according to p. 5, characterized in that it contains scrubbers for cleaning the spent calibration mixtures and to obtain a zero mixture.

Images