JP2018040614A - Gas sensor unit and gas detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a gas sensor unit having a sensitivity check function using an actual gas, and a gas detector including the gas sensor unit.SOLUTION: In a gas sensor unit, a gas sensor for reacting to a hydrogen gas and a hydrogen gas supply part for supplying the hydrogen gas as a gas for checking the sensitivity of the gas sensor to the gas sensor are provided in a common housing. The hydrogen gas supply part includes: a hydrogen gas generation source for electrochemically generating the hydrogen gas; and a buffer chamber for storing the hydrogen gas from the hydrogen gas generation source.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a gas sensor unit having a self-diagnosis function, which includes a gas sensor sensitive to hydrogen gas, and a gas detection device including the gas sensor unit.

  In general, in order to maintain the reliability of a gas sensor, a standard gas prepared at a constant concentration is brought into the field, and its detection sensitivity is checked at regular intervals. Even if such a method is possible when the number of gas sensors is small, for example, in a large-scale gas leak monitoring system that monitors gas leaks in production facilities, the number of gas sensors becomes several tens or more. Therefore, there is a problem that not only the inspection takes time but also a lot of manpower is required.

  In response to such a problem, for example, if the gas sensor itself has a self-diagnosis function, the state of the gas sensor is changed, for example, at regular intervals using a network to which a gas detection device equipped with the gas sensor is connected. It becomes possible to grasp. For this reason, for example, when a gas leak monitoring system is constructed, for example, the gas sensor itself is required to have a self-diagnosis function.

  For example, Patent Document 1 describes a catalytic combustion type gas sensor that can perform self-diagnosis of deterioration and abnormal operation due to long-term use. Specifically, in a catalytic combustion type gas sensor having a Wheatstone bridge circuit composed of a detection element, a compensation element, and two resistance elements, the voltage change of the detection signal relative to the change in the applied voltage value in the initial state. It is described that a configuration including a self-diagnosis unit that diagnoses sensor abnormality by comparing the inclination and the inclination of the voltage change due to the measurement value of the detection signal with respect to the change in the applied voltage value in the use state is described.

JP 2006-337243 A

  Thus, the measured value by the gas sensor is usually obtained from a calibration curve indicating the relationship between the standard gas concentration and the indicated value of the gas sensor. However, if the performance of the gas sensor deteriorates due to factors over time, the calibration curve will also fluctuate, so use standard gas when diagnosing whether the gas sensor is operating normally or checking the sensitivity of the gas sensor. Is desirable. That is, the gas sensor diagnostic method as described above has a problem that a highly reliable result may not be obtained.

  The present invention has been made based on the above circumstances, and an object thereof is to provide a gas sensor unit having a sensitivity check function using real gas and a gas detection device including the gas sensor unit.

The gas sensor unit of the present invention is a gas sensor unit in which a gas sensor sensitive to hydrogen gas and a hydrogen gas supply unit that supplies hydrogen gas as a sensitivity check gas of the gas sensor to the gas sensor are provided in a common housing. There,
The hydrogen gas supply unit includes a hydrogen gas generation source that generates hydrogen gas electrochemically and a buffer chamber that stores the hydrogen gas from the hydrogen gas generation source.

In the gas sensor unit of the present invention, the hydrogen gas inflow passage through which the hydrogen gas from the hydrogen gas supply unit is circulated is provided to be switchable with the test gas inflow passage for the gas sensor,
It is preferable that the hydrogen gas inflow path is connected to the gas sensor after a predetermined time has elapsed after the hydrogen gas generation source is driven.

  Furthermore, in the gas sensor unit of the present invention, the gas sensor is selected from a contact combustion type gas sensor, a semiconductor type gas sensor, a heat conduction type gas sensor, a constant potential electrolytic type gas sensor, a detection tape type gas sensor and an infrared type gas sensor. Can be used.

  The gas detection device of the present invention includes the gas sensor unit described above.

According to the gas sensor unit of the present invention, since the sensitivity check of the gas sensor is basically performed using the real gas, that is, the hydrogen gas from the hydrogen gas supply unit, the response status of the gas sensor to the real gas is confirmed. Thus, it can be checked with high reliability whether or not the gas sensor operates normally. Moreover, the hydrogen gas generated from the hydrogen gas generation source is temporarily stored in the buffer chamber, and the hydrogen gas as the sensitivity check gas is supplied to the gas sensor under the supply conditions necessary for the sensitivity check of the gas detection unit. The above effects can be obtained with certainty.
Therefore, according to the gas detection apparatus provided with such a gas sensor unit, when it is confirmed that the detection performance of the gas sensor deteriorates with use or for other reasons, for example, calibration of the gas sensor is performed. Thus, it is possible to promptly take measures such as performing the above, and it is possible to always maintain the gas detection device in a normal operating state.

It is a block diagram which shows roughly the structure in an example of the gas detection apparatus of this invention.

  Hereinafter, embodiments of the present invention will be described in detail.

FIG. 1 is a block diagram schematically showing a configuration in an example of a gas detection device of the present invention.
This gas detector is configured as a stationary type, and includes a gas sensor 20 that is sensitive to hydrogen gas, and a hydrogen gas supply unit 25 that supplies hydrogen gas as a sensitivity check gas for the gas sensor 20 to the gas sensor 20. A gas sensor unit 10 provided in a common housing 11 is provided.

  The housing 11 in the gas sensor unit 10 is formed with a gas introduction portion 12a and a gas discharge portion 12b. The gas discharge portion 12b draws air in the ambient atmosphere of the detection target space as a test gas, and the gas sensor unit 10 A pump 40 to be supplied to is detachably connected. In this example, the flow sensor 45 that monitors the flow rate of the test gas with respect to the gas sensor unit 10 is connected to a position downstream of the gas sensor unit 10 and upstream of the pump 40 in the gas flow direction.

A gas distribution line is formed in the housing 11 from the gas introduction part 12a to the gas discharge part 12b via the gas detection part 20. In this gas distribution line, a hydrogen gas inflow path 15 through which hydrogen gas as a sensitivity check gas for the gas sensor 20 is circulated is provided so as to be switchable with a test gas inflow path 14 extending from the gas introduction part 12 a to the gas sensor 20. ing.
In this example, a T-shaped three-way joint 13 is provided, for example, at a position upstream of the gas sensor 20 in the gas distribution line, and a hydrogen gas inflow path 15 is a flow path opening / closing valve including, for example, a two-way electromagnetic valve 16. To the three-way joint 13. The hydrogen gas inflow passage 15 is provided with a hydrogen gas supply unit 25 described later.
The hydrogen gas inflow path 15 may be configured to be switchable with the test gas inflow path 14 with respect to the gas distribution line by using a flow path switching valve made of, for example, a three-way solenoid valve. Further, a flow path opening / closing valve that is opened and closed in conjunction with a flow path opening / closing valve (two-way electromagnetic valve 16) provided in the hydrogen gas inflow path 15 may be provided in the test gas inflow path 14.

  As the gas sensor 20, for example, a gas selected from a catalytic combustion type gas sensor, a semiconductor type gas sensor, a heat conduction type gas sensor, a constant potential electrolysis type gas sensor, a detection tape type gas sensor and an infrared type gas sensor is used.

  The hydrogen gas supply unit 25 includes a hydrogen gas generation source 26 that generates hydrogen gas electrochemically, and a buffer chamber 27 that temporarily stores the hydrogen gas from the hydrogen gas generation source 26, and generates hydrogen gas. The source 26 is disposed in the buffer chamber 27. 1 in FIG. 1 is a check valve.

  The whole hydrogen gas generation source 26 in this example is constituted by a coin-type hydrogen generation cell. In this hydrogen generation cell, the anode and the cathode are short-circuited to cause an oxidation reaction at the anode and a reduction reaction at the cathode, thereby generating hydrogen gas. And the amount of hydrogen generation is controlled by controlling the magnitude of the discharge current flowing between the anode and the cathode.

  The configuration of the buffer chamber 27 is not particularly limited as long as it has a capacity capable of storing the hydrogen gas generated from the hydrogen gas generation source 26 to a predetermined amount or a predetermined gas pressure. Good. The capacity of the buffer chamber 27 is preferably 5 to 50 cc, for example.

  The gas sensor unit 10 includes a control unit 30 including a microcomputer 31 having a function of performing a sensitivity check of the gas sensor 20 (self-diagnosis function) and a hydrogen generation source driving unit.

  The hydrogen generation source drive unit is configured by, for example, a short circuit 35 including an open / close switch 36 and a variable resistor 37, and the open / close switch 36 is closed by an operation command signal from the microcomputer 31. The anode and cathode of the hydrogen generation cell are short-circuited, and the hydrogen gas generation source 26 is driven.

Hereinafter, the sensitivity check function (self-diagnosis function) in the gas sensor unit 10 will be described.
The open / close switch 36 is closed in a state where the resistance value of the variable resistor 37 in the short circuit 35 constituting the hydrogen generation source drive unit is properly adjusted by the operation command signal from the microcomputer 31. As a result, the anode and cathode of the hydrogen generation cell constituting the hydrogen gas generation source 26 are short-circuited to generate hydrogen gas from the hydrogen generation cell. At this time, since the two-way solenoid valve 16 is closed, the hydrogen gas generated from the hydrogen generation cell is stored in the buffer chamber 27. After a predetermined time has elapsed since the hydrogen gas generation source 26 was driven, that is, when the hydrogen gas stored in the buffer chamber 27 reaches a predetermined amount or a predetermined gas pressure, the microcomputer 31 The two-way solenoid valve 16 is opened by the operation command signal. Here, the timing at which the two-way solenoid valve 16 is opened can be set, for example, in relation to the amount of hydrogen gas generated by the hydrogen gas generation source 26 and the capacity (volume) of the buffer chamber 27. When the two-way solenoid valve 16 is opened, the hydrogen gas inflow path 15 is connected to the gas distribution line, and the hydrogen gas in the buffer chamber 27 is supplied to the gas sensor 20 as a sensitivity check gas. Then, based on the gas detection signal acquired by the gas sensor 20 for the sensitivity check gas, the degree of deterioration of the detection performance of the gas sensor 20 is confirmed. Specifically, the sensitivity check is performed by confirming whether or not the output value of the gas sensor 20 for the sensitivity check gas (hydrogen gas) is appropriate, and the output value of the gas sensor 20 is within the set allowable range. If it is within the range, it is determined that the sensitivity of the gas sensor 20 is normal. On the other hand, when the output value of the gas sensor 20 deviates from the setting allowable range, it is determined that the sensitivity of the gas sensor 20 is lowered (abnormal), and for example, the calibration process of the gas sensor 20 in the gas detection device. It is also notified by an alarm display indicating that replacement is necessary. In addition, when the gas detection device is configured to include a communication unit that performs data communication with, for example, the central management device (when a gas leak detection system is constructed), the result of the sensitivity check is It can also be configured to output to a central management device.

  After the sensitivity check of the gas sensor 20 by the gas sensor unit 10 itself is completed, the open / close switch 36 in the short circuit 35 constituting the hydrogen generation source drive unit is opened by the operation command signal from the microcomputer 31 to generate hydrogen gas. The driving of the source 26 is stopped. Further, the two-way solenoid valve 16 is closed and the hydrogen gas inflow passage 15 is closed.

  In the above, the sensitivity check operation of the gas sensor 20 by the gas sensor unit 10 is performed, for example, at the time of periodic inspection of the gas detection device, but may be automatically performed, for example, every time interval set by providing a timer. Good. Sensitivity adjustment may be performed together with the sensitivity check based on the output value of the gas sensor 20 obtained for the sensitivity check gas.

Thus, according to the gas sensor unit 10 described above, since the sensitivity check of the gas sensor 20 is basically performed using the actual gas, that is, the hydrogen gas from the hydrogen gas supply unit 25, the actual gas of the gas sensor 20 is used. By checking the status of the response to, whether or not the gas sensor unit 10 operates normally can be checked with high reliability.
Moreover, the hydrogen gas generated from the hydrogen gas generation source 26 is temporarily stored in the buffer chamber 27, and the hydrogen gas as the sensitivity check gas is supplied to the gas sensor 20 under supply conditions necessary for the sensitivity check of the gas sensor 20. Therefore, the above effect can be obtained with certainty. Such an effect is ensured by the two-way solenoid valve 16 being opened and the hydrogen gas inflow passage 15 being connected to the gas sensor 20 after a predetermined time has elapsed since the hydrogen gas generation source was driven. Can be obtained.

  Therefore, according to the gas detection device provided with such a gas sensor unit 10, when it is confirmed that the detection performance of the gas sensor 20 deteriorates with use or for other reasons, for example, the gas sensor 20 Thus, it is possible to promptly take measures such as performing calibration work or replacement, and the gas detection device can always be maintained in a normal operating state.

DESCRIPTION OF SYMBOLS 10 Gas sensor unit 11 Housing 12a Gas introduction part 12b Gas discharge part 13 Three-way joint 14 Test gas inflow path 15 Hydrogen gas (sensitivity check gas) inflow path 16 Two-way solenoid valve 18 Check valve 20 Gas sensor 25 Hydrogen gas supply part 26 Hydrogen gas generation source 27 Buffer chamber 30 Control unit 31 Microcomputer 35 Short circuit 36 Open / close switch 37 Variable resistor 40 Pump 45 Flow sensor

Claims (4)

A gas sensor unit comprising a gas sensor that is sensitive to hydrogen gas and a hydrogen gas supply unit that supplies hydrogen gas as a gas for sensitivity check of the gas sensor to the gas sensor.
The hydrogen gas supply unit includes a hydrogen gas generation source that electrochemically generates hydrogen gas, and a buffer chamber that stores the hydrogen gas from the hydrogen gas generation source. A hydrogen gas inflow path through which hydrogen gas from the hydrogen gas supply unit is circulated is provided to be switchable with a test gas inflow path for the gas sensor,
2. The gas sensor unit according to claim 1, wherein the hydrogen gas inflow passage is connected to the gas sensor after a predetermined time has elapsed after the hydrogen gas generation source is driven.   2. The gas sensor according to claim 1, wherein the gas sensor is selected from a contact combustion gas sensor, a semiconductor gas sensor, a heat conduction gas sensor, a constant potential electrolysis gas sensor, a detection tape gas sensor, and an infrared gas sensor. The gas sensor unit according to claim 2. A gas detection device comprising the gas sensor unit according to any one of claims 1 to 3.

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