SU1746291A1 - Gas analyzer for hydrocarbons other than methane - Google Patents

Abstract

Usage: measurement of the content of non-methane hydrocarbons in ambient air, industrial air and other environments. SUMMARY OF THE INVENTION: The gas analyzer comprises a pump, a gas pressure stabilizer, two adsorbers connected in parallel, solenoid valves connected to the adsorber inlets, pneumatic resistance for reverse blowing them, two flame ionization detectors with pneumatic resistance tees, two electrometric amplifiers and a recording device . A detector measuring the total hydrocarbon content is connected to the output of the pressure stabilizer. A second detector measuring the methane concentration is connected to the outlet of the adsorbers. A second tee is inserted in the device between the discharge outlets of the solenoid valves and the pneumatic resistance for the back blow of the adsorbers. In this case, the first tee connects the outlets of the adsorbers to the metering pneumatic resistance of the flame ionization methane detector. operation of adsorbers, since in both half cycles the sample is dosed with one pneumatic resistance, 1 sludge. (Ls

Description

2

Och

ND Yu

The invention relates to the field of gas analysis and can be used to measure the content of non-methane hydrocarbons in atmospheric air, industrial air and other environments.

A device for measuring non-methane hydrocarbons in gases, operating on the adsorption method of separating hydrocarbons, is known. Solenoid valves are used in the device to switch gas flows through the adsorbers.

The disadvantage of the device is that the solenoid valve, which commutes gas flows at the outlet of the adsorbers, introduces a significant error in the measurement result, especially when measuring microconcentrations of hydrocarbons. This is due to the fact that the design of modern electromagnetic valves includes rubber or plastic membranes, rubber gaskets, and lubrication of the metallic core. These elements are the source of the emission of organic matter that enters the sample stream and changes the gas analyzer readings.

The closest in technical essence to the proposed invention is a device that contains two adsorbers connected in parallel, solenoid valves, heaters and a fan installed on the adsorbers, pneumatic resistance for the back blow of the adsorbers, two flame ionization detectors with sample metering of the pneumatic resistors. MI, a tee electrometric amplifiers at the output of the detectors, a microprocessor device and a recording device.

However, the pneumatic resistance metering the sample flow rate for a flame ionization detector measuring the methane concentration is not the same for both adsorber cycles.

After each of the adsorbers, its own dosing pneumatic resistance is established, the sample gas from which is fed to the analysis to the detector when the corresponding adsorber is switched on in the adsorption mode. This means that every half hour the sample flow rate in the detector measuring the concentration of methane changes, since it is technologically very difficult to create two identical pneumatic resistances. The instability of the sample flow significantly increases the systematic error of the gas analyzer, reduces its accuracy.

In the known device, the pneumatic resistors are made on the basis of watch stones with calibrated holes. The selective control showed that even in one batch of stones, the spread of flow values is a value. Therefore, when assembling a gas analyzer, a preliminary selection of pneumatic resistances is necessary. It is even more difficult to ensure equal sample costs after adsorbers, if the pneumatic resistances are made of capillary tubes,

The aim of the invention is to improve the accuracy of the gas analyzer.

The goal is achieved by the fact that the gas analyzer containing a pump, a gas pressure stabilizer, two adsorbers connected in parallel, electromagnetic valves connected to the adsorber inlets, heaters and a fan mounted on the adsorbors are pneumatic resistance for reverse blown adsorbers, two flame ionization detectors with metering sample flow rate, tee, two electrometric

an amplifier, a microprocessor device and a registering device; a second tee is introduced, two inputs of which are connected to the electromagnetic output

valves, and the third inlet is connected to the atmosphere with pneumatic resistance to blow back the adsorbers, the first tee with two of its inlets is connected directly to the outlets of the adsorbers, and its third inlet is connected to the second flame-ionization detector.

The drawing shows a schematic diagram of the gas analyzer.

The gas analyzer contains a pump 1, a gas pressure stabilizer 2 with a discharge, located after it, two adsorbers

3 and 4 with solenoid valves 5 and 6 at the inlet, heaters 7 and 8 and the fan

9 installed on adsorbers tee

10 connecting the outlets of the solenoid valves 5 and 6 s

pneumatic resistance 11 for reverse flushing of adsorbers, a tee 12 connecting the outputs of adsorbers with dosing pneumatic resistance 13, dosing pneumatic resistance 14, two flame ionization detectors 15 and 16, electrometric amplifiers 17 at the output of the detectors, a microprocessor device 18 and a recording device 19.

Gas analyzer works as follows

in a way.

The analyzed gas is sucked by the pump 1 into the gas analyzer, then at a constant pressure provided by the pressure stabilizer 2 to itself, part

the analyzed gas enters through the dosing pneumatic resistance 14 to the flame ionization detector 16 analyzing the total hydrocarbon content in the sample, and the rest of the analyzed gas through the electromagnetic valves 5 and 6 alternately (in accordance with the commands of the microprocessor device 18) enters one of the adsorber 3 or 4 where all hydrocarbons are absorbed,

except methane. Next, the sample stream containing only methane through the tee 12 and the dosing pneumatic resistance 13 enters the flame ionization detector 15, analyzing the methane content

in the sample. The current signal from the detectors 15 and 16 is amplified by electrometric amplifiers 17 and is fed to the input of the microprocessor device 18, which forms three information channels: the concentration of methane, the concentration of total hydrocarbons minus methane and the concentration of total hydrocarbons. This information is displayed and recorded by the recording device 19. The methane emission device operates cyclically. In the first half-cycle, the solenoid valves 5 and 6 operate so that the sample of the analyzed gas under constant pressure enters the adsorber 3 and then through the tee 12 and pneumatic resistance 13 to the flame -ionization detector 15 methane. A part of the sample containing only methane also goes through tee 12 to purge adsorber 4 and through solenoid valve 6 and tee 10 to the pneumatic resistance 11, metering the flow rate of the purge and associated with the atmosphere. For half a hour, for half an hour, the regenerated adsorber 4 is heated by the heater 8 for the first 10 minutes, then cooled by the fan 9 to room temperature for 20 minutes.

In the second half-cycle of operation of the adsorbers, the solenoid valves 5 and 6 are switched so that the adsorber 4 becomes working, and the adsorber 3 is blown through with a portion of the analyzed sample containing methane, and is regenerated with the help of heater 7 and fan 9. Purge gas through solenoid valve 5, tee 10 and the pneumatic resistance 11 is discharged into the atmosphere at a constant flow rate.

The operation of the solenoid valves, the heaters and the fan is controlled by a microprocessor in the same way as in the known device.

The pneumatic resistance 11 is removed from the output of the adsorbers 3 and 4 and is located at the discharge outlet of the solenoid valves 5 and b, connected by a tee 10. This made it possible to dose the methane sample flow with one pneumatic resistance 13 in both half cycles of the adsorbers.

The use of the invention will significantly reduce the systematic

gas analyzer error, increase its accuracy. It will reduce the cost and laboriousness of manufacturing a gas analyzer due to the absence of the need to manufacture, select and adjust the exact pneumatic resistance.

The use of a gas analyzer will make it possible to improve the control of the sanitary and hygienic state of the atmospheric air and will ensure the obtaining of a social effect from a decrease in the content of toxic gases in the atmosphere.

Claims (1)

The claims of the gas analyzer of non-methane hydrocarbons in gases, containing a pump, a gas pressure stabilizer, two adsorbers connected in parallel, solenoid valves connected to the adsorber inlets, heaters and a fan installed on the adsorbers, pneumatic resistance for back-blowing adsorbers, two flame ionization detectors with dosing flow rate of the pneumatic resistance, tee, while one of the detectors measuring the total hydrocarbon content is connected to the output of the pressure stabilizer and another detector, measuring the concentration of methane, is connected to the output of adsorbers, two electrometric amplifiers, a microprocessor device and a recording device, which is characterized by the fact that, in order to improve the accuracy of the gas analyzer, a second tee is introduced, two of which are connected to the discharge outputs solenoid valves, and the third input is connected to the pneumatic resistance input for the back blow of adsorbers, the output of which communicates with the atmosphere, while the first tee is connected with its two inputs directly It is connected to the outputs of the adsorbers, and its third input is connected to the second flame-ionization detector through a dosing pneumatic resistance. wo J7