SU1603218A1 - Apparatus for calibrating flame-ionizing gas analyzer - Google Patents

Abstract

The invention relates to the field of gas sample preparation before being supplied to a gas analyzer and can be used in determining the hydrocarbon compounds in the composition of industrial gases and transport off-gases. The aim of the invention is to increase the reliability of the device. The inlet gas line of the analyzed sample with a dust filter installed on it is connected to the heated chamber to induce consumption. The output of the heated chamber is connected to the output gas line of the sample being analyzed through the first choke with a flame ionization detector, and the input gas line of the air with a dust filter installed on it is connected to the second chamber to induce consumption. The output of the second chamber through the air filtration unit, the pressure regulator of the "after itself" type and through the second choke is connected to the normally open input of the first solenoid valve, and through the third choke to the flame ionization detector. The normally closed inlet of the first solenoid valve is connected to the inlet gas pipeline of the calibration gas mixture, and the outlet of the first solenoid valve is connected to the normally closed inlet of the second solenoid valve, whose normally open inlet is connected to the atmosphere, the outlet of the second solenoid valve is connected to the inlet of the gas flow distributor. The cavity of the first valve of the distributor is connected to the heated chamber of the flow rate booster, and the submembrane cavity of the second valve is connected to the inlet gas pipeline of the analyzed sample. The output of the gas flow distributor is connected to the outlet of the flow rate booster chamber and through the first choke with a flame ionization detector. 1 il.

Description

The invention relates to the preparation of a gas sample before being fed to a gas analyzer and can be used in the determination of hydrocarbon compounds in the composition of the waste gases of industrial enterprises and transport.

The purpose of the invention is to increase the reliability of the device.

The drawing shows a block diagram of the proposed device (in the supply mode of the CGS).

The device contains an inlet gas pipeline 1 of the analyzed sample, a filter 2 dust (samples), a heated chamber 3 flow rate booster, a gas distribution valve 4, an output gas pipeline 5 of the analyzed sample, the first choke 6, the flame ionization detector 7, the filter 9 dust (air), the second chamber 10 of the flow rate pump, air filtration unit 11, pressure regulator 12

“After themselves, the second and third chokes 13 and 14, the gas pipeline 15 of hydrogen, the gas pipeline 16 of zero gas, the first solenoid valve 17, the second solenoid valve 18, the inlet gas pipeline 19 of the calibration gas mixture (CBC).

The inlet gas line 1 of the analyzed sample with a dust filter 2 installed on it is connected to the heated chamber 3 of the flow rate booster, the output of the heated chamber 3 is connected to the output gas pipeline 5 of the analyzed sample through the first choke 6 with the flame ionization detector 7 with the dust gas line 8 installed on it the filter 9 is connected to the second chamber 10 of the flow rate pump, the output of which is through the air filtration unit 11, a pressure regulator 12 of the type "after itself, and a second choke 14 with a normally open inlet of the first el electromagnetic valve 17, and through the third choke 13 with a flame ionization detector 7, the normally-open inlet of the first solenoid valve 17 is connected to the inlet gas pipeline 19 of the calibration gas mixture, and the outlet of the solenoid valve 17 is connected to the normally closed inlet of the second solenoid valve 18, the normally open second inlet the electromagnetic valve 18 is connected to the atmosphere (reset), the output of the second electromagnetic valve 18 is connected to the inlet of the distributor 4 gas flows, the cavity of the first shut-off valve The distributor 4 is connected to the chamber 3 of the flow rate driver, and the submembrane cavity of the second shut-off valve is connected to the inlet gas pipeline of the sample being analyzed, the outlet of the gas flow valve 4 is connected to the outlet of the chamber 3 of the flow rate actuator 6 and through the first throttle 6 with a flame ionization detector 7. By the gas pipeline 15 hydrogen enters detector 7.

The device works as follows.

The device ensures the operation of a flame ionization gas analyzer in three modes of operation: the supply mode of the analyzed gas sample, the supply mode of the test gas mixture and the supply mode of zero gas (air). In the feed mode of the analyzed gas sample, the device operates as follows. When electrical voltage is applied to the engine, the flow rate driver from the object under investigation is taken through the inlet gas line 1 of the sample through the dust filter 2 using a heated chamber 3 and the flow rate driver and the output gas line 5 passes through a first pressure reactor 6 to a flame ionization detector 7, at the same time under the action of the springs the first and second shut-off valves of the distributor 4 gas

Flows overlap the gas channels of the entrance gas calibration mixture.

At the same time, air from the atmosphere through the air inlet duct 8 through the dust filter 9 is removed by means of the second chamber 10 and the flow rate through the duct through the air filtration unit 11, the pressure regulator 12 of the type "after itself and the second choke 14 enters

a normally open inlet of the solenoid valve J7 and a third choke 13 to the flame ionization detector 7. The air filtration unit 11 cleans the extracted atmospheric air from hydrocarbon compounds, which is then used as a zero gas and a gas that supports the combustion of a hydrogen flame in flame ionization detector. The hydrogen entering through the pipeline 15 is displaced with the sample breakdown of the analyzed gas, ensures the combustion of hydrocarbon compounds in the flame of the detector, resulting in an ion current between the two electrodes, the value of which is proportional to the concentration of hydrocarbons in the sample.

In the calibration gas supply mode, the voltage of the electric current flows to the first 17 and second 18 solenoid valves are switched and the test gas mixture under the excess

pressure is applied to the inlet of the distributor 4 gas streams. Under the pressure of the ASG, the membrane of the gas flow distributor 4 bends, the second shut-off valve opens and the transverse gas mixture flows into the output gas pipeline 5

of the analyzed sample, while the pressure of the ASG acts on the output valve of the heated chamber 3, the flow rate is outside the compartment of the chamber 3 cavity from the output gas pipeline 5. At the same time, the stem of the second valve of the distributor 4

displaces the first shut-off valve of the distributor 4, connects the cavity of the heated chamber 3 by the flow drainage gas pipeline to the inlet gas pipeline 1, as a result, there is no effect of compressing the gas in the heated chamber 3 and the chamber 3 itself works.

Thus, the gas flow distributor 4 provides the calibration gas mixture to the flame ionization detector 7 without disconnecting the two-chamber

prompting expense. In the mode of supplying zero gas, the voltage of the electric current is supplied to the second solenoid valve 18, the solenoid valve 18 switches and the zero gas from the pressure regulator 12 of the type "after itself through the second

the throttle 14, the normally open inlet of the first solenoid valve 17 under excessive pressure enters the inlet of the distributor 4 gas streams and further.

similar to a transverse gas mixture, on a flame ionization detector 7.

When relieving the voltage of the electric current from the solenoid valves 17 and 18, the solenoid valves cut off the flow of the test gas mixture, the pressure in the supra-membrane cavity of the second valve of the gas flow distributor 4 drops to the atmospheric value and under the action of the springs the first and second shut-off valves block the drainage gas pipeline and the supply channel of the calibration gas mixture and the device is switched to the mode of supplying the sample of the analyzed gas. In order to increase the reliability of actuation of the distributor 4 of gas streams and eliminate leakage of the test gas mixture into the supermembrane cavity of the second shut-off valve, the above-membrane cavity through the normally open inlet of the second valve 18 is connected to the atmosphere.

The heating chamber 6 is structurally removed from the electric motor of the flow rate booster and placed in the thermostat together with the detector 7, and the gas flow distributor 4 is mounted in the chamber lid. Such placement of elements allows to reduce the volume and length of gas channels, which reduces the transport time lag.

The use of the proposed device improves the reliability of the gas analyzer by eliminating the contact of the high-temperature aggressive gas mixture with the structural elements of the gas flow distributor.

Claims (1)

Invention Formula D.L device for calibrating a flame ionization gas analyzer containing a two-chamber flow booster, a sample gas pipeline connected to one of the flow rate booster chambers, a pneumatic distributor of gas flows and a gas-ionization detector located in a thermostat, as well as air gas pipelines and calibration gas mixture (CBC), and the first solenoid valve is installed on the CGS gas pipeline, the normally closed inlet of which is connected to the CGS gas pipeline, and the normally open inlet is connected to the gas by an air wire, characterized in that it additionally A second solenoid valve was installed, installed on the gas mains pipeline and connected by a normally closed inlet to the outlet of the first electromagnetic valve, and a normally open inlet to the atmosphere, and a gas flow distributor in the form of two shut-off valves kinematically connected to each other, with the cavity of the first shut-off valve J connected to the heated chamber of the flow rate, the submembrane cavity of the second shut-off valve connected to the sample inlet gas pipeline, the inlet of the gas distribution valve located in the supra-membrane cavity of the second shut-off valve the valve is connected to the outlet of the second solenoid valve, and the outlet of the gas flow distributor is connected to the outlet of the heated chamber to induce flow. five ASG reset Pro-l Air.