CN213456303U - Air bag sampling intermittent type flue gas measuring system - Google Patents

Abstract

The utility model discloses an air bag sampling intermittent flue gas measuring system, wherein a gas storage device is positioned in a shell, the bottom of the gas storage device is fixedly connected with the inner wall of the shell, one end of a flue gas sampling tube is inserted into a flue, the other end of the flue gas sampling tube is communicated with the inlet of the gas storage device through a first check valve, the outlet of the gas storage device is communicated with the inlet of a flue gas analyzer through a second check valve, and the output end of the flue gas analyzer is connected with the input end of a computer; the blow vent of shell is linked together through the entry of first solenoid valve with the aspiration pump, and the air pipe is linked together with the entry of aspiration pump, is provided with the second solenoid valve on the air pipe, and the export of aspiration pump is divided into two the tunnel, and wherein is linked together through the blow vent on third solenoid valve and the shell all the way, and another way is connected with the fourth solenoid valve, and this system can realize the continuous measurement of flue gas, and is with low costs simultaneously, and the adaptability is stronger.

Description

Air bag sampling intermittent type flue gas measuring system

Technical Field

The utility model belongs to flue gas test field relates to an gasbag sample intermittent type formula flue gas measurement system.

Background

Concentration field measurement of flue gas components (mainly water-insoluble flue gas components such as nitric oxide, oxygen, carbon monoxide and the like) in the whole flue section is one of the most common measurement scenarios in flue gas measurement of a thermal power plant. The commonly used measurement method is point-by-point measurement, i.e. under a stable working condition, after one point is measured, switching to another point, and a time difference exists between the points, and the actually measured concentration field is not the result at the same time, but a measurement result which lasts for tens of minutes or even hours. Although the working condition is macroscopically relatively stable, the data of each measuring point fluctuates at all times, so that the representativeness of the switching measuring result is poor; the method solves the problem of multi-point synchronous measurement, but has higher realization cost, is more suitable for occasions with higher requirements on measurement, and is too complex for occasions with general measurement requirements.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome above-mentioned prior art's shortcoming, provide an gasbag sample intermittent type formula flue gas measurement system, this system can realize the continuous measurement of flue gas, and is with low costs simultaneously, and adaptability is stronger.

In order to achieve the above purpose, the intermittent flue gas measuring system for air bag sampling of the utility model comprises a gas storage device, a shell, a flue gas sampling tube, a first check valve, a second check valve, a flue gas analyzer, a computer, a first electromagnetic valve, an air pump and an air pipeline;

the gas storage device is positioned in the shell, the bottom of the gas storage device is fixedly connected with the inner wall of the shell, one end of the smoke sampling tube is inserted into the flue, the other end of the smoke sampling tube is communicated with the inlet of the gas storage device through a first check valve, the outlet of the gas storage device is communicated with the inlet of the smoke analyzer through a second check valve, and the output end of the smoke analyzer is connected with the input end of the computer;

the air vent of the shell is communicated with the inlet of the air extracting pump through a first electromagnetic valve, the air pipeline is communicated with the inlet of the air extracting pump, a second electromagnetic valve is arranged on the air pipeline, the outlet of the air extracting pump is divided into two paths, one path is communicated with the air vent on the shell through a third electromagnetic valve, and the other path is connected with a fourth electromagnetic valve.

The first check valve is communicated with the first check valve, the second check valve is communicated with the second check valve, and the first check valve is communicated with the second check valve.

A flue gas pretreatment device is arranged between the second check valve and the flue gas analyzer.

A filter is arranged between the first check valve and the flue gas sampling tube.

The gas storage device is an air bag.

The air pump further comprises a controller, wherein the controller is connected with the first electromagnetic valve, the second electromagnetic valve, the third electromagnetic valve, the fourth electromagnetic valve, the fifth electromagnetic valve, the air pump and the computer.

The utility model discloses following beneficial effect has:

when the air bag sampling intermittent flue gas measuring system is operated specifically, the air extracting pump extracts air to enable negative pressure to be generated in the shell, and the gas storage device extracts flue gas in a flue through the flue gas sampling tube, the filter and the first check valve to realize sampling of the flue gas in the flue; the air pump is used for inflating the shell, so that positive pressure is generated in the shell, the air storage device is compressed, the smoke enters the smoke analyzer for component analysis, continuous measurement of the smoke is achieved, meanwhile, the cost is low, the adaptability is strong, and the cost of a multipoint arrangement measuring system is greatly reduced.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Wherein, 1 is a filter, 2 is a first check valve, 3 is a second check valve, 4 is a gas storage device, 5 is a first electromagnetic valve, 6 is a second electromagnetic valve, 7 is a third electromagnetic valve, 8 is a fourth electromagnetic valve, 9 is an air pump, 10 is a controller, 11 is a flue gas pretreatment device, 12 is a flue gas analyzer, 13 is a computer, 14 is a flue gas sampling tube, 15 is a flue, 16 is a fifth electromagnetic valve, and 17 is a shell.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings:

referring to fig. 1, the intermittent gas-bag sampling system of the present invention includes a gas storage device 4, a housing 17, a gas sampling tube 14, a first check valve 2, a second check valve 3, a gas analyzer 12, a computer 13, a first solenoid valve 5, a gas pump 9 and an air pipeline; the gas storage device 4 is positioned in the shell 17, the bottom of the gas storage device 4 is fixedly connected with the inner wall of the shell 17, one end of the flue gas sampling tube 14 is inserted into the flue 15, the other end of the flue gas sampling tube 14 is communicated with the inlet of the gas storage device 4 through the first check valve 2, the outlet of the gas storage device 4 is communicated with the inlet of the flue gas analyzer 12 through the second check valve 3, and the output end of the flue gas analyzer 12 is connected with the input end of the computer 13; the vent hole of shell 17 is linked together through first solenoid valve 5 and the entry of aspiration pump 9, and the air conduit is linked together with the entry of aspiration pump 9, is provided with second solenoid valve 6 on the air conduit, and the export of aspiration pump 9 is divided into two routes, and wherein link is linked together through the vent hole on third solenoid valve 7 and the shell 17, and another link is connected with fourth solenoid valve 8.

The utility model discloses still include the evacuation pipe, wherein, the evacuation pipe is linked together with second check valve 3's export, is provided with fifth solenoid valve 16 on the evacuation pipe.

A flue gas pretreatment device 11 is arranged between the second check valve 3 and the flue gas analyzer 12.

A filter 1 is arranged between the first check valve 2 and the flue gas sampling pipe 14.

The gas storage device 4 is an airbag.

The utility model discloses still include controller 10, wherein, controller 10 is connected with first solenoid valve 5, second solenoid valve 6, third solenoid valve 7, fourth solenoid valve 8, fifth solenoid valve 16, aspiration pump 9 and computer 13.

The utility model discloses a concrete working process does:

when the smoke sampling is to be carried out, the control system opens the air extracting pump 9, the first electromagnetic valve 55 and the fourth electromagnetic valve 8, closes the second electromagnetic valve 6 and the third electromagnetic valve 7, the air extracting pump 9 extracts air, so that the shell 17 generates negative pressure, the gas storage device 4 extracts the flue gas in the flue 15 through the flue gas sampling pipe 14, the filter 1 and the first check valve 2, when the sampling of the gas storage device 4 reaches the set volume, the controller 10 closes the first solenoid valve 5 and the fourth solenoid valve 8, opens the second solenoid valve 6 and the third solenoid valve 7, meanwhile, the air pump 9 is used for inflating the shell 17, so that positive pressure is generated in the shell 17, the air storage device 4 is compressed, the flue gas is metered into the flue gas analyzer 12 through the second check valve 3 and the flue gas pretreatment device 11 for component analysis, and the analysis result is inputted to the computer 13, and when the measurement is finished, the fifth electromagnetic valve 16 is opened to discharge the remaining gas in the gas storage 4.

Claims (6)

1. An air bag sampling intermittent flue gas measuring system is characterized by comprising an air storage device (4), a shell (17), a flue gas sampling tube (14), a first check valve (2), a second check valve (3), a flue gas analyzer (12), a computer (13), a first electromagnetic valve (5), an air suction pump (9) and an air pipeline;

the gas storage device (4) is positioned in the shell (17), the bottom of the gas storage device (4) is fixedly connected with the inner wall of the shell (17), one end of the flue gas sampling tube (14) is inserted into the flue (15), the other end of the flue gas sampling tube (14) is communicated with the inlet of the gas storage device (4) through the first check valve (2), the outlet of the gas storage device (4) is communicated with the inlet of the flue gas analyzer (12) through the second check valve (3), and the output end of the flue gas analyzer (12) is connected with the input end of the computer (13);

the vent hole of shell (17) is linked together through first solenoid valve (5) and the entry of aspiration pump (9), and the air line is linked together with the entry of aspiration pump (9), is provided with second solenoid valve (6) on the air line, and the export of aspiration pump (9) is divided into two routes, and wherein is linked together through the vent hole on third solenoid valve (7) and shell (17) all the way, and another way is connected with fourth solenoid valve (8).

2. The air bag sampling intermittent smoke measuring system according to claim 1, further comprising an evacuation pipe, wherein the evacuation pipe is communicated with an outlet of the second check valve (3), and a fifth electromagnetic valve (16) is arranged on the evacuation pipe.

3. An air bag sampling intermittent flue gas measuring system according to claim 1, characterized in that a flue gas pre-treatment device (11) is arranged between the second check valve (3) and the flue gas analyzer (12).

4. An air bag sampling intermittent flue gas measuring system according to claim 1, characterized in that a filter (1) is arranged between the first check valve (2) and the flue gas sampling tube (14).

5. The air bag sampling intermittent flue gas measuring system of claim 1, wherein the air storage device (4) is an air bag.

6. The air bag sampling intermittent smoke measuring system according to claim 2, further comprising a controller (10), wherein the controller (10) is connected with the first solenoid valve (5), the second solenoid valve (6), the third solenoid valve (7), the fourth solenoid valve (8), the fifth solenoid valve (16), the air pump (9) and the computer (13).

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