JPH0648379Y2 - Gas analyzer - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of use] The present invention relates to a gas analyzer which uses exhaust gas of an internal combustion engine as a sample gas.

[Prior Art] Conventionally, a gas analyzer using exhaust gas of an internal combustion engine as a sample gas has been used.

An example of this is shown in Fig. 7 (Jpn.
64-27641).

This gas analyzer uses a sample gas suction unit J1 that uses a diaphragm pump, an ejector pump, etc., sucks sample gas from the sample gas sampling unit J2, and analyzes unit J3 through the main flow path.
Is configured to supply.

Further, a sample gas pressure adjusting unit J4 for adjusting the fluctuation of the sample gas pressure collected is provided between the sample gas collecting unit J2 and the analyzing unit J3 and the sample gas suction unit J1.

This conventionally used sample gas pressure adjusting unit J4 is a pressure sensor that detects the gas pressure in the bypass flow path branched from the main flow path.
It includes J5 and a solenoid valve J6 controlled by a pressure sensor J5.

Then, the detected gas pressure is higher than a predetermined value (for example, 0.1k
g / cm ² or more), the solenoid valve 16 is opened to reduce the gas pressure supplied to the analysis section J3 to the same level as the atmospheric pressure, and conversely, the detected gas pressure is below a predetermined value (for example, 0.02 (kg / cm ² or less), the solenoid valve L6 is closed to operate to prevent the inflow of air from the bypass flow passage.

[Problems to be solved by the invention] When the sample gas suction unit J1 is located downstream of the analysis unit J3,
As the sample gas pressure supplied to the analysis section J3 increases, the measured value will be slightly higher than the correct value due to the pressure. Therefore, it is necessary to adjust (maintain) the sample gas pressure.

However, in the above sample gas pressure adjustment unit J4, the pressure sensor
Since the solenoid valve J6 is opened / closed according to the value detected by J5, the pressure in the sample flow path fluctuates, and the measured value fluctuates as shown in FIG.

That is, when the pressure sensor J5 detects that the gas pressure is equal to or higher than the predetermined value, the solenoid valve J6 is opened, and the gas pressure is reduced to the same level as the atmospheric pressure.

As a result, the gas pressure detected by the pressure sensor J5 becomes equal to or lower than a predetermined value, and it is determined that the air flows in, and the solenoid valve J6 is closed.

When the solenoid valve J6 is closed, the gas pressure rises to a predetermined value or higher, and the above operation is repeated.

The present invention is provided with a sample gas pressure adjusting section that suppresses fluctuations in measured values due to fluctuations in sample gas pressure as much as possible, enables accurate measurement, and prevents atmospheric air from flowing even when the sample gas pressure becomes low. An object is to provide a gas analyzer.

[Means for Solving the Problems] The present invention has been made to achieve the above objects.

The first gas analyzer of the present invention is, as illustrated in FIG. 1, an analysis part M1 for analyzing a sample gas, and a main gas M3 for sucking the sample gas from the sample gas sampling part M2 to the analysis part M1. And a sample gas suction section M4 supplied via the sample gas sampling section M2, and the analysis section M1.
And a sample gas pressure adjusting unit M10 which is provided upstream of the sample gas suction unit M4 and which constantly adjusts the fluctuation of the sample gas pressure collected, and the sample gas pressure adjusting unit M10, The ejector pump M12, which is provided in the bypass flow passage M11 that connects the main flow passage M3 and the atmosphere, and operates to release the sample gas in the main flow passage M3 to the atmosphere, and the pressure of the air for driving the ejector pump M12. And a drive air pressure adjusting means M13 that adjusts to a constant value.

In addition, the second gas analyzer of the present invention, as illustrated in FIG. 2, has an analysis unit M1 for analyzing the sample gas, and a main unit for sucking the sample gas and flowing the sample gas sampling unit M2 to the analysis unit M1. A sample gas suction part M4 supplied via a path M3, and a downstream of the sample gas sampling part M2, and the analysis part M1
And a sample gas pressure adjusting section M20 which is provided upstream of the sample gas suction section M4 and which constantly adjusts the fluctuation of the sample gas pressure sampled, and the sample gas pressure adjusting section M20, An electromagnetic valve M22 provided in a bypass flow passage M21 that communicates the main flow passage M3 with the atmosphere and a direction of the fluid flowing through the solenoid valve M22 are detected from the main flow passage M3 toward the atmosphere. Flow direction detection means 23
When the flow direction of the fluid detected by the flow direction detection means M23 is from the main flow path M3 to the atmosphere, the solenoid valve M22 is opened, and in other cases, the solenoid valve M22 is closed. And a solenoid valve control means M24 for controlling.

[Operation] The first gas analyzer uses the ejector pump M12 for the sample gas pressure adjusting unit M10.

The ejector pump M12 does not backflow up to the negative pressure limit determined by the structure and the driving air pressure.

Therefore, by adjusting the driving air pressure by the driving air pressure adjusting means M13 so that the ejector pump M12 reaches a desired negative pressure limit, even if the sample gas pressure is lowered, the inflow of the atmosphere into the main channel M3 is achieved. Can be prevented.

Moreover, since the main flow path M3 is always in communication with the atmosphere via the ejector pump M12, the sample gas pressure is maintained at about atmospheric pressure.

The second gas analyzer includes a sample gas pressure adjusting unit M20, a flow direction detecting means M23 and a solenoid valve.
I am using M22 and.

Then, even if the solenoid valve M22 is opened and the sample gas pressure supplied to the analysis unit M1 is about the same as the atmosphere, if there is a flow from the main channel M3 to the atmosphere through the bypass channel M21, the solenoid valve M22 M
22 is never closed.

Therefore, when the sample gas pressure is higher than the atmospheric pressure, the sample gas pressure supplied to the analysis unit M1 is always the same as the atmospheric pressure.

Further, when the sample gas pressure becomes lower than the atmosphere, the flow direction detection means M23 detects that the fluid flow is in the main flow path M3 direction from the atmosphere, and the solenoid valve M22 is controlled by the solenoid valve control means M24. To be closed.

Therefore, the atmosphere does not flow into the main flow path M3.

[Example] An example of the first gas analyzer will be described.

FIG. 3 is a functional block diagram of the gas analyzer of the present embodiment.

This analyzer is equipped with a dust filter 1,
Dehumidifying cooler 3, analysis unit 5, flow meter 7, ejector pump 9
Equipped with.

Then, a drive air pressure adjusting means 11 is provided on the drive air supply side of the ejector pump 9, and a differential pressure adjusting means 13 is provided in parallel with the analysis unit 5, and a space between the dust filter 1 and the dehumidifying cooler 3 is provided. A sample gas pressure adjusting means 15 to be described later is provided, and a solenoid valve 17 and a calibration gas pressure correcting means 19 are provided in the calibration gas line connected between the dehumidifying cooler 3 and the analyzing section 5.

The sample gas pressure adjusting means 15 is for adjusting the pressure of the sample gas to a constant value when the discharge pressure of the sample gas from a sample gas supply source (not shown) fluctuates. To prevent the occurrence of.

The sample gas pressure adjusting means 15 includes a pressure sensor 21, a solenoid valve 23, an ejector pump 25, and an air pressure adjusting means 27 for driving the ejector pump 25 in the bypass flow path BP.

The ejector pump 25 is a drive air pressure adjusting means.
The negative pressure limit is adjusted to −300 mmAq by 27, and the solenoid valve 23 is closed when the gas pressure detected by the pressure sensor 21 is −15 mmHg or lower, and is opened when it is −5 mmHg or higher.

Therefore, the sample gas pressure supplied to the dehumidifying cooler 3 becomes substantially atmospheric pressure (when the sample gas pressure at the outlet of the filter 1 is higher than atmospheric pressure, it is brought to atmospheric pressure by the bypass flow path BP, and at the inlet of the filter 1). If the sample gas pressure is atmospheric pressure,
At the same time, the pressure loss corresponding to the pressure loss of the filter 1 becomes a negative pressure), and the atmosphere does not flow up to the negative pressure limit of the ejector pump 25.

In addition, the gas pressure at the point A is changed by the ejector pump 25 when the dust filter 1 is clogged for some reason.
Even if the negative pressure limit is exceeded and the pressure becomes extremely negative, the bypass passage BP is closed by the solenoid valve 23, so that the atmosphere does not flow from the ejector pump 25.

The drive air pressure adjusting means 11 and 27 adjust the pressure of the drive air to be constant even if the pressure of the drive air fluctuates so that the drive air of a constant pressure is always introduced to the ejector pumps 9 and 25. Of the ejector pump 9,25
The amount of the sample gas sucked by is stabilized.

The differential pressure adjusting means 13 is for adjusting the differential pressure of the sample gas at the inlet and outlet of the analyzing section 5 to a constant value, and thereby keeps the sample gas flow rate inside the analyzing section 5 constant. .

The calibration gas pressure compensating means 19 decompresses the calibration gas pressure supplied from a cylinder or the like in a pressurized state corresponding to the adjusted pressure of the sample gas, and adjusts the calibration gas suction amount to the analysis unit 5 to the sample. It is almost the same as the gas suction amount.

The details of the configuration of the analysis unit 5 and the like are described in Japanese Patent Application No. 62-121997 “Gas Analyzer” (filed on August 7, 1987) filed by the present application.

When measuring a sample gas with this gas analyzer, first, the ejector pump 9 is driven so that the exhaust gas from the automobile is sucked from the dust filter 1 which is the sample gas sampling unit.

Before being introduced into the dehumidifying cooler 3, the sucked sample gas is made constant by the sample gas pressure adjusting means 15 as described above.

Then, the differential pressure before and after the analysis unit 5 is introduced into the analysis unit 5, but is controlled to be constant by the differential pressure adjusting means 13 such as a differential pressure regulator, so that the sample gas suction amount to the analysis unit 5 is constant. Held in.

As a result, gas analysis can be performed without being affected by the sample gas pressure.

Further, the calibration of the analysis unit 5 can be performed by opening the solenoid valve 17 and making the calibration gas pressure correction means 19 set the calibration gas pressure to the same pressure as when measuring the sample gas.

FIGS. 4 (A) and 4 (B) are views showing changes in the inlet pressure of the dehumidifying cooler 3 and changes in the measurement value of the analysis unit 5 when the inlet pressure of the dust filter 1 is changed in this embodiment. Is.

In this case, the diameter of the sample gas inflow portion of the ejector pump 25 was 10 mmφ and the driving air pressure was 1.0 kg / cm ² .

The solid line in the figure shows the solenoid valve 23 open, and the broken line shows the solenoid valve 23.
23 shows a closed state.

As is apparent from FIG. 4, since the sample gas pressure adjusting means 15 using the ejector pump 25 is used in this embodiment, the sample gas pressure at the point A is constant at a pressure substantially equal to the atmospheric pressure. It is possible to reduce the fluctuation of the measured value to such an extent that it does not pose a practical problem.

Although the ejector pump 9 is used as the sample gas suction device in the present embodiment, a diaphragm pump may be used instead of the ejector pump 9.

When using a diaphragm pump, a sample gas suction unit may be provided between the dehumidifying cooler 3 and the analyzing unit 5.

An example of the second gas analyzer will be described.

FIG. 5 is a functional block diagram of the gas analyzer of the present embodiment.

In this figure, the same reference numerals as those given in FIG. 3 indicate the same parts or corresponding parts.

The present embodiment has the same structure as the above embodiment except that the structure of the sample gas pressure adjusting means 30 is different.

The sample gas pressure adjusting means 30, like the sample gas pressure adjusting means 15, adjusts the pressure of the sample gas to a constant value when the discharge pressure of the sample gas from the sample gas supply source fluctuates. It is arranged to prevent the instruction error of the analysis unit 5 from being caused by the pressure fluctuation.

The sample gas pressure adjusting means 30 includes a pressure sensor 31, a solenoid valve 33, a solenoid valve control circuit 35, and a flow direction detector 37 described below in the bypass flow path BP.

FIG. 6 is an illustration of an example of the flow direction detector 37.

The flow direction detector 37 includes a tubular body 39 and a moving body 41 that moves by a fluid flow inside the tubular body 39.

The tubular body 39 includes an atmosphere side connection port 43 and a sample gas side connection port 45, and an annular closing member 47 protruding in the direction of the connection port 43 from the connection port 45 inside the tubular body 39, similarly, from the connection port 43. It is provided with four stoppers 49 protruding toward the connection port 45. Electrodes 51 are provided on the end surfaces of the pair of stoppers 49 facing each other on the connection port 45 side, and are connected to the lead wires 53.
Further, the side of the connection port 43 of the moving body 41 is covered with a conductive member 55.

Therefore, when the gas flows from the sample gas side to the atmosphere side, the moving body 41 moves to the atmosphere side, the conductive member 55 of the moving body 41 and the electrode 51 of the stopper 49 contact each other, and by detecting this contact, The presence or absence of flow from the sample gas side to the atmosphere side can be detected.

At this time, the gas flows from the sample gas side to the atmosphere side through the gap 57 of the stopper 49.

Further, the solenoid valve control circuit 35 opens the solenoid valve 33 when the pressure of the bypass flow passage BP detected by the pressure sensor 31 is 5 mmHg or more, and the flow direction detector 37 moves from the sample gas side to the atmosphere side. When there is no flow, that is, when the flow is stopped or there is a flow from the atmosphere side to the sample gas side, the solenoid valve 33 is closed.

Therefore, the pressure of the sample gas at the inlet of the dehumidifying cooler 3 is almost the same as the atmospheric pressure, and the inflow of air does not occur.

Therefore, also in the present embodiment, it is possible to reduce the fluctuation of the measured value to such an extent that there is no practical problem.

Although the ejector pump 9 is used as the sample gas suction unit in the present embodiment, a diaphragm pump may be used instead of the ejector pump 9.

When a diaphragm pump is used, a sample gas suction device may be provided between the dehumidifying cooler 3 and the analysis unit 5.

[Advantages of the Invention] As described above, the pressure of the sample gas supplied to the analysis unit is made approximately equal to the atmospheric pressure in both the first gas analyzer and the second gas analyzer of the present invention. It is possible to suppress the pressure fluctuation.

Further, even if the pressure of the sample gas becomes extremely low, it is possible to prevent the atmosphere from flowing in from the sample gas pressure adjusting unit.

Therefore, even if the pressure of the sample gas collected by the sample gas sampling unit fluctuates, accurate gas analysis can be performed.

[Brief description of drawings]

FIG. 1 is a block diagram illustrating a first gas analyzer of the present invention, FIG. 2 is a block diagram illustrating a second gas analyzer, and FIG. 3 is an embodiment of the first gas analyzer. Configuration diagram, FIG. 4 is a diagram for explaining the effect, FIG. 5 is a configuration diagram of an embodiment of the second gas analyzer, FIG. 6 is an explanatory diagram of a flow direction detector used therein, and FIG. FIG. 8 is a block diagram of a conventional gas analyzer, and FIG. 8 is a diagram showing variations in the measured values. J1, M4,9 ... Sample gas suction unit (ejector pump), J2, M2,1
… Sample gas sampling unit (dust filter), J3, M1,5… Analysis unit, J4… Sample gas pressure adjusting unit J5… Pressure sensor J6… Solenoid valve M10,15… Sample gas pressure adjusting unit (Sample gas pressure adjusting means) ) M11,25 ... Ejector pump M13, 27 ... Driving air pressure adjusting means M20, 30 ... Sample gas pressure adjusting section (sample gas pressure adjusting means) M22, 33 ... Solenoid valve M23, 37 ... Flow direction detecting means M24, 35 ...... Electromagnetic valve control means 21 ... Pressure sensor, 23 ... Electromagnetic valve, 31 ... Pressure sensor, 39 ... Cylindrical body, 41 ... Moving body, 47 ... Annular closing member, 49 ... Stopper,
51 ... Electrode, 55 ... Conductive member, 57 ... Gap

Claims (2)

[Scope of utility model registration request] 1. An analysis unit for analyzing a sample gas, a sample gas suction unit for sucking the sample gas and supplying it from the sample gas sampling unit to the analysis unit via a main flow path, and a sample gas sampling unit downstream of the sample gas sampling unit. And a sample gas pressure adjusting unit that is provided upstream of the analyzing unit and the sample gas suction unit and that adjusts the fluctuation of the sample gas pressure collected, to a constant value. An adjusting unit is provided in a bypass flow passage that communicates the main flow passage with the atmosphere, and an ejector pump that operates to discharge the sample gas in the main flow passage to the atmosphere; and a constant pressure of the air for driving the ejector pump. A drive air pressure adjusting means for adjusting, and a gas analyzer. 2. An analysis section for analyzing a sample gas, a sample gas suction section for sucking the sample gas and supplying the sample gas from the sample gas sampling section to the analyzing section through a main flow path, and a sample gas sampling section downstream of the sample gas sampling section. And a sample gas pressure adjusting unit that is provided upstream of the analyzing unit and the sample gas suction unit and that adjusts the fluctuation of the sample gas pressure collected, to a constant value. A solenoid valve provided in a bypass passage that connects the main passage and the atmosphere, and a flow direction that detects whether the direction of the fluid flowing through the solenoid valve is from the main passage to the atmosphere. The flow direction of the fluid detected by the detection means and the flow direction detection means,
And a solenoid valve control means for controlling the solenoid valve to open when it is in the atmosphere direction from the main flow path and to close the solenoid valve in other cases.