SU873058A1 - Photocalorimetric gas analyzer - Google Patents

Description

The invention relates to analytical instrument skim ^1, based on measuring the optical properties of the indicator means, caused by the chemical action of the tracer substance with a defined component of a gas mixture ^{of 5,} and can be used in various branches of industry and scientific research in the determination of the concentration of impurities or separate komponentdv in a gaseous environment . ¹⁰ A known gas analyzer containing an indicator line through which the analyzed gas-oil mixture is blown ['] ·

A gas analyzer is also known, ® where the analyzed gas mixture is brought to the surface of the indicator tablet m

The disadvantage of these photocolorimetric gas analyzers is the presence of indicator preparation units in the design of mechanical assemblies.

Closest to the invention is a photocolorimetric gas analyzer containing a reaction chamber with an indicator tablet, a · ⁴ mandrel apparatus, a flow inducer, a pneumatic pulse generator, a light source, a photodetector, a level meter, and detecting boron [s}.

The disadvantage of this gas analyzer is the low measurement accuracy due to the dependence of the sensitivity change of the indicator tablet on the overall color level, which is especially sharp in the initial period after replacing the tablet.

The purpose of the invention is to increase the accuracy of measurements by increasing the rate of rise of the overall color to a given level after replacing the indicator tablet.

This goal is achieved by the fact that in the photocolorimetric gas analyzer containing a reaction chamber with a sensitive element, a command device, a flow inducer, a pneumatic pulse generator, a light source, a photodetector, a color level meter and a recording device, a threshold element, a logic circuit, and an acceleration generator are additionally introduced , while the input of the threshold element is connected to the output of the color level meter, the output to the first input of the logic circuit, the output of which is connected to the second input command apparatus, the output of the acceleration generator is connected to the third input of the logic circuit, and the input of the pneumatic pulse generator is connected to the output of the logic circuit.

The drawing shows a diagram of a gas analyzer.

The gas analyzer contains a reaction chamber I with an indicator tablet 2, a light source 3, a photodetector 4, a color level meter, comprising a relative color increment meter 5 and a general color level meter 6 with a function block 7 and a sensitivity control unit ^ 8 threshold element 9, recording device 10 , buffer tank 11, test gas supply pipe 12, flow inducer 13, chambers 14 and 15 with membrane walls, pneumatic pulse generator 16, capillaries 17 and 18, logic circuit 19, commands o- apparatus 20 and generator 21 accelerations.

The gas analyzer operates as follows.

In the interval between measurement cycles, the flow inducer 13 provides the flow of the analyzed gas mixture in the direction indicated by arrows in the figure, i.e. through the capillary 17, the buffer tank 11 and the capillary 18. As a result, the buffer tank 11 is filled with the analyzed gas.

. . If the signal of the meter 6 of the General level of coloring does not reach the specified. of this value, the threshold element 9 is triggered. The logic circuit 9, in accordance with the signal from the acceleration generator 21, turns on the pneumatic pulse generator 16. Due to the presence of chambers 14 and 15 in the reaction chamber <1 and the buffer tank 11, oscillations of the gas mixture occur, which lead to the rapid mixing of the contents of the buffer tank and the reaction chamber. As a result of the oscillations of the gas mixture, the determined component contained in it is absorbed by the surface of the tablet 2. There is an accelerated increase in the level of general coloring to a predetermined value, upon reaching which the threshold element is turned off and the logic circuit 19 turns on and off the pneumatic pulse generator 6 only by signals from the comandand device 20.

The measurement cycle starts at time. At the same time, the command device 20 turns off the flow driver 13 and switches on the pneumatic pulse generator 16 through the logic 19. As a result of the oscillations of the gas mixture in the chambers 14, 15 and 1 and the tank 11 after a certain time, Ts + Tr _{eaK |} the entire component contained in the buffer tank 1I is absorbed by the surface of the tablet 2. At the end of the measurement cycle, the surface of the tablet 2 is photometric by the light source 3 and the photodetector 4. The signal converted from the photodetector 5 from the photodetector 4 is fed to a recording device. 10. The presence of an acceleration device, consisting of a threshold element 9, a logic circuit 19 and an acceleration generator 21, leads to a faster increase in the overall color to a predetermined level after replacing the indicator tablet. This occurs in the periods between measurement cycles without changing their duration. At the same time, the number of measurements is reduced by 5-10 times with an additional error on the indicator that has not reached the required sensitivity level.

The present invention improves the accuracy of the measurements in the initial period after replacing the indicator. .

Claims (3)

The invention relates to analytical devices based on the measurement of the optical properties of the indicator means, due to the chemical effect of the indicator substance with a determined gas mixture component, and can be used in various industries and scientific studies to determine the concentration of impurities or individual components. in gaseous media A gas analyzer is known, containing | a measuring line, through which a gas9va mixture fl 1 is analyzed is blown. Also known is a gas analyzer Where the analyzed gas mixture is supplied to the display surface tabletkif2 disadvantage ztih photocolorimetric analyzers - the presence in the design of mechanical assemblies preparation indicator. The closest to the invention is a photocolorimetric gas analyzer containing a reaction chamber with an indicator tablet, a commander, a flow booster, a generator of pneumatic pulses, a light source, a photodetector, a level meter and recordings at. The disadvantage of this gas analyzer is the high accuracy of the measurements due to the dependence of the change in the sensitivity of the indicator tablet on the overall color level, which is especially sharp in the initial period after replacing the tablet. The purpose of the invention is to increase the measurement of the three-dimensional Hoctk by increasing the rate of increase of the total color to a predetermined level after replacing the indicator tablet. The goal is achieved by the fact that a photocolorimetric gas analyzer containing a reaction chamber with a sensitive element, a commander unit, a flow booster, a generator of pneumatic pulses, a light source, a photodetector, a color level meter and a registering device, additionally includes a threshold element, a logic circuit and an acceleration generator. while the input of the threshold element is connected to the output of the color level meter, the output is connected to the first input of the logic circuit, to the second input of which the output one of the control unit, the output of the accelerator generator is connected to the third input of the logic circuit, and the input of the generator of pneumatic pulses is connected to the output of the logic circuit. The drawing shows a diagram of a gas analyzer. The gas analyzer contains a reaction chamber 1 with an indicator tablet 2, a light source 3, a photodetector 4, a color level meter containing a measure 5 relative color increment and a total color meter 6 with a functional unit 7 and a frequency control unit 8 threshold element 9, a recording device 10 , buffer tank 11, test gas supply pipeline 12, flow rate booster 13, chambers 14 and 15 with diaphragm walls, pneumatic pulse generator 16, capillaries 17 and 18, logic circuit 19, command the device 20 and the generator 21 accelerations The gas analyzer operates as follows. In the interim, the mezkdu measurement cycles booster 13 flow provides the flow of the analyzed gas mixture in the direction indicated by arrows, i.e. through the capillary 17, the buffer tank 1 and the capillary 18. As a result, the buffer tank 11 is filled with the gas to be analyzed. .. . If the signal of the common-color meter 6 does not reach the specified value, threshold element 9 is triggered. Logic circuit 9, in accordance with the signal from the accelerator generator 21, includes a generator of 16 pneumatic and} 1 pulses. Due to the presence of chambers 14 and 15 in the reaction chamber and the buffer tank 11, oscillations of the gas mixture occur, which result in the rapid mixing of the contents of the buffer tank and the reaction chamber. As a result of the gas mixture oscillations, the component to be detected in it is absorbed by the surface of the tablet 2. There is an accelerated increase in the total color level to a predetermined value, when this threshold element is turned off and the logic circuit 19 turns on and off the generator 6 pneumatic pulses only by signals from the commander 20 The measurement cycle starts at time tj. At the same time, the control device 20 turns off the flow rate booster 13 and, via logic circuit 19, generates 16 pneumatic pulses B. As a result of oscillations of the gas mixture in chambers 14, 15 and 1 and tank 11, after a certain time, the component contained in buffer tank 1I is absorbed by the surface of tablet 2. At the end of the measurement cycle, the surface of the tablet 2 is photometric by the source 3 of the light and the photodetector 4. The signal converted by the sensor 5 from the photodetector 4 is fed to a recording instrument. 10. The presence of an acceleration device consisting of a threshold element 9, a logic circuit 19 and an acceleration generator 21 leads to a more rapid increase in the total color to a predetermined level after replacing the indicator tablet. This occurs in the periods between measurement cycles without changing their duration. -And this reduces the number of measurements by a factor of 5-10 with an additional error on the indicator that has not reached the required level of sensitivity. The present invention improves the measurement accuracy in the initial period after replacing the indicator. . The invention includes a photocolorimetric gas analyzer comprising a reaction chamber with a sensitive element, a commander, a flow booster, a generator of pneumatic pulses, a light source, a color level meter, and a recording device, which is characterized by the fact that, in order to improve measurement accuracy, it additionally contains a threshold element, logic circuit and acceleration generator, while the input of the threshold element is connected to the output of the color level meter, the output of the threshold element is connected to the first input One logic circuit, to the second input of which the output of the control unit is connected, the output of the acceleration generator is connected to the third input of the logic circuit, and the input of the generator of pneumatic pulses is connected to the output of the logic circuit. Sources of information taken into account in the examination. USSR Author's Certificate 333416, cl. G 01 N 21/00, 1970. 2. USSR author's certificate number 492200, cl. G 01 N 21/26, 1975. 3. Author's certificate of the USSR on application No. 2552065, cl. G 01 N21/77, 1977 (prototype).