JP2006118939A - Gas sensor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gas sensor capable of acquiring short-period data at a proper time in detail even during monitoring operation over a long period of time to grasp the situation of a change in the concentration of a gas to be sensed in detail. <P>SOLUTION: In the gas detector constituted so as to perform monitoring operation due to an intermittent measuring mode for intermittently measuring at least the concentration of the gas to be sensed in an environmental atmosphere at every predetermined measuring interval time, when it is sensed that the concentration value of the gas measured by an initial intermittent measuring mode set at the start time of monitoring operation is within a predetermined concentration range, the initial intermittent measuring mode is automatically altered to a measuring mode of which the measuring interval time is shorter than that of the initial intermittent measuring mode. In this gas sensor, the initial intermittent measuring mode is automatically altered to the measuring mode of which the measuring interval time is shorter than that of the initial intermittent measuring mode or a continuous measuring mode for continuously measuring the concentration of the gas. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a gas detector used for monitoring (monitoring) a detection target gas in an environment such as a manhole, a cave, a tunnel, or a volcano.

For the purpose of analyzing the occurrence of gas leaks and preventing disasters due to gas leaks, and for human protection, monitoring the status of changes in the concentration of the gas to be detected in the environmental atmosphere. A method using the continuous measurement mode in which the gas concentration is continuously measured and a method using the intermittent measurement mode in which the gas concentration measurement is intermittently performed at predetermined time intervals are appropriately selected according to the purpose.
And according to the measurement mode set at the start of the monitoring operation, for example, a recording of concentration values measured at regular time intervals (interval trend data), a predetermined time before and after the alarm is issued Recorded peak values at regular time intervals (alarm trend data), recorded alarm type and time when an alarm was issued, and type of failure when a failure occurred Recorded time (event data) is acquired.

  For example, when monitoring the environment over a long period of time, an intermittent measurement mode is used in which the concentration of the detection target gas is intermittently measured at predetermined time intervals. The reason for this is that monitoring over a long period of time is usually performed by collecting data after a certain period of time, since workers do not always stay at the place where the gas detector is installed. This is because it is necessary to reduce the power consumption of the gas detector (extend the life of the battery for driving the gas detector). And as a means to reduce the power consumption of a gas detector, the function of the functional member which concerns on gas measurement, such as CPU and a gas sensor, is performed at the measurement interval, for example.

  And when the monitoring operation is performed in the intermittent measurement mode, an event such as an alarm may occur during the measurement interval, in order to grasp the status of concentration change (change in concentration over time). In addition, it is often the case that detailed data for a short period before and after the event occurs is required.

  In response to such a request, in the monitoring method using the intermittent measurement mode, it is possible to roughly grasp the change in the concentration of the detection target gas in the environment by acquiring data over a long period of time. Since the concentration is measured every predetermined time interval, it is a fact that it is not possible to acquire detailed data for a short time in detail.

  The present invention has been made based on the circumstances as described above, and can obtain detailed short-term data in a timely manner even during a monitoring operation over a long period of time. An object of the present invention is to provide a gas detector that can grasp the state of change in detail.

  The gas detector according to the present invention starts the monitoring operation when the monitoring operation in the intermittent measurement mode in which the concentration of the detection target gas at least in the environmental atmosphere is intermittently measured every predetermined measurement interval time can be performed. When it is detected that the gas concentration value measured in the initial intermittent measurement mode set at the time is within the predetermined concentration range, the measurement mode is automatically changed to the measurement mode with a shorter measurement interval time than the initial intermittent measurement mode. It is characterized by being.

The gas detector of the present invention can be configured to be automatically changed to the intermittent measurement mode in which the measurement interval time is shorter than the initial intermittent measurement mode.
In addition, the monitoring operation in the continuous measurement mode that continuously measures the concentration of the gas to be detected in the environmental atmosphere is set to be executable, and it is configured to automatically change from the initial intermittent measurement mode to the continuous measurement mode. May be.

  Further, in the gas detector of the present invention, when it is detected that the measured gas concentration value has deviated from the predetermined concentration range during the monitoring operation in the changed measurement mode, or the measurement mode is changed. Then, it is preferable that the apparatus is automatically changed to the initial intermittent measurement mode when a certain time has passed.

  Furthermore, the gas detector of the present invention can be configured such that a plurality of types of detection target gases are simultaneously monitored in parallel.

  According to the gas detector of the present invention, when the monitoring operation for the detection target gas in the environmental atmosphere is performed in the intermittent measurement mode, based on the concentration value measured in the initial intermittent measurement mode set when starting the monitoring operation. Since the measurement mode is changed in a timely manner and monitoring is performed in a measurement mode having a measurement interval shorter than the initial intermittent measurement mode, long-term data over a required period can be acquired. Data in a short time in a timely manner before and after the occurrence of an event such as an alarm can be subdivided and acquired. Therefore, the state of the concentration change of the detection target gas in the environmental atmosphere can be grasped in detail.

  In addition, when monitoring conditions in the changed measurement mode are reached, when a state that satisfies a specific condition is reached, the initial intermittent measurement mode is automatically changed again so that the detection target gas can be monitored. Because it is performed in a controlled state so that the degree of increase in power consumption due to changes in the system is as small as possible, it will not interfere with long-term data acquisition and ensure monitoring over the required period Can do.

Hereinafter, the present invention will be described in detail with reference to the drawings.
FIG. 1 is a front view showing an appearance of a configuration example of the gas detector of the present invention, FIG. 2 is a cross-sectional view of the gas detector shown in FIG. 1, and FIG. FIG. 4 is a block diagram for explaining the operation of the gas detector shown in FIGS. 1 to 3.
This portable gas detector (hereinafter simply referred to as “gas detector”) includes a long and flat box-shaped housing 10 that can be held and held by hand, and the front side of the inside of the housing 10. A control circuit board 11 including a gas detection signal processing circuit (CPU 11A) for processing a signal from the gas sensor, and a circuit board 12 including a power feeding circuit and a charging circuit are parallel to each other in the housing 10. For example, a dry battery 74 in which the front half of the housing 10 is a functional part area in which a functional member related to gas detection operation is arranged and the rear half is a drive source. Is the battery part region in which is disposed. Reference numeral 16 denotes a filter unit for introducing the test gas in a state in which dust is removed, and reference numeral 17 denotes a gas discharge part having a gas discharge port 18 opened on the back surface.

On the front side of the control circuit board 11 in the functional part region, a panel-like display mechanism 13A composed of, for example, a liquid crystal display panel for displaying the type of gas detected and its concentration is arranged. In addition, a display unit 13 is formed, and an alarm light-emitting unit 14 is formed on each of the front end surface of the housing 10, the front region, and both side regions subsequent thereto. The alarm light-emitting unit 14 includes a light source made of a light-emitting diode (not shown) and a window plate 14A held by the housing 10 so as to cover the light source.
In addition, an operation button 15A is provided in the rear half of the front surface of the housing 10, whereby an operation portion 15 is formed.

Further, on the back side of the control circuit board 11 in the functional area, there are a plurality of gas sensors and a pump unit which is a gas suction means for sucking the test gas from the outside and sequentially supplying it to each gas sensor. The gas detection part S is formed by this.
More specifically, as shown in FIG. 3, in the state where the five button type gas sensors SA to SE are received by the sensor holder 20 having the L-shaped gas sensor arrangement region as a whole, A corner close to the gas sensor arrangement area in the area where the pump unit 40, which is a gas suction means, is divided into two sides by the gas sensor arrangement area while being fixedly held by the sensor cap 30 attached from the side. The pump unit mounting portion 21 formed in is mounted and arranged. In FIG. 3, for convenience, the sensor cap 30 is omitted.
The pump unit 40 includes a gas suction pump 41 mounted at the front end of the pump unit mounting part 21 in the sensor holder 20 and a pump driving unit disposed along the side surface of the pump unit mounting part 21 so that the drive shaft extends in the front-rear direction. The motor 42 and a pressure sensor 43 that detects the exhaust pressure of the test gas are configured.

  As the gas sensor, a gas sensor element corresponding to the type of gas to be detected can be used. An example of a combination of gas sensors is, for example, a gas sensor SA for oxygen gas detection, such as a galvanic gas sensor element, in order from the upstream side with respect to the flow direction of the test gas, for example, a constant potential electrolytic gas. A gas sensor SB for detecting hydrogen sulfide gas comprising a sensor element, for example, a gas sensor SC for sensing carbon monoxide gas comprising a constant potential electrolytic gas sensor element, for example, a hydrocarbon gas comprising a catalytic combustion type gas sensor element is% LEL A gas sensor SD that detects in the (explosive lower limit concentration) measurement range, and a gas sensor SE that detects, for example, a hydrocarbon gas composed of a heat conduction type gas sensor element in a volume% measurement range are used.

  This gas detector has a continuous measurement mode in which the concentration of the detection target gas in the ambient atmosphere is continuously measured for a predetermined time, and an intermittent measurement mode in which the concentration of the detection target gas is measured at regular intervals. Can be selected and set according to the purpose. In the intermittent measurement mode, the measurement interval time (measurement interval) can be appropriately set according to the purpose, and can be set, for example, at intervals of 30 minutes and 1 minute intervals between 1 to 5 minutes. Further, during the measurement interval, the functions of the CPU 11A, the gas sensors SA to SE, the pump unit 40, and other functional members related to gas measurement are stopped.

The data acquired by the gas detector includes, for example, a record of concentration values measured at regular time intervals (interval trend data), and regular time intervals before and after a warning is issued. Records each peak value (alarm trend data), or records the type and time of alarm when an alarm is triggered, or records the type and time of failure when a failure occurs ( Event data) and the like, and is recorded in the recording unit 11B made of an appropriate recording element.
Further, the recording unit 11B can record, for example, calibration history data such as a pre-calibration concentration instruction value, a post-calibration concentration instruction value, a calibration date and time, and a calibration deadline.

In the gas detector having the above-described configuration, a measurement mode corresponding to the purpose is selected when a series of operation setting operations are performed, and the concentration of the detection target gas is measured according to the measurement conditions in the selected measurement mode. The detection target gases are simultaneously monitored in parallel.
For example, when the continuous measurement mode is selected and set by the user when starting the monitoring operation, the gas to be detected is sequentially supplied to each of the gas sensors SA to SE, and the detection target gas is measured and displayed. The type and concentration of the gas detected by the unit 13 are displayed, and the concentration of any of the detection target gases exceeds a reference concentration value (hereinafter also referred to as “alarm signal output concentration value”). When detected, an alarm is generated by the light emission of the alarm light emitting unit 14.
For example, when the detection target gas is oxygen gas (O ₂ gas), the reference concentration value is set to 18.0% by volume (vol%), for example, and an alarm signal is issued when the reference concentration value falls below that. The reference concentration value is, for example, 10% LEL (gas concentration with respect to the lower explosion limit concentration) when the detection target gas is hydrocarbon gas (HC gas), and when the detection target gas is carbon monoxide gas (CO gas). For example, it is set to 25 ppm, and in the case of hydrogen sulfide gas (H ₂ S gas), for example, it is set to 10 ppm. When the reference concentration value is exceeded, an alarm signal is issued.
In this continuous measurement mode, when an event such as an alarm is generated, for example, alarm trend data in which peak concentration values are recorded at predetermined time intervals for a fixed time before and after the event occurs. Are recorded in the recording unit 11B.

On the other hand, when the intermittent measurement mode is selected and set by the user, it is necessary for gas measurement of the CPU 11A and the gas sensors SA to SE at every measurement interval time in the intermittent measurement mode according to the time measured by the time measuring unit 19. The functional member is activated to measure the concentration of the detection target gas.
Thus, in the above gas detector, for example, as shown in FIG. 5, when the monitoring operation is performed in the initial intermittent measurement mode, the measured gas concentration value is compared with the alarm signal output concentration value. If it is detected that it is within the predetermined concentration range, the measurement interval shorter than the measurement interval time t1 related to the initial intermittent measurement mode, for example, from the initial intermittent measurement mode set by the user when starting the monitoring operation. The measurement mode at time t2 (hereinafter, referred to as “detailed measurement mode”), specifically, for example, is automatically changed to the intermittent measurement mode in which the measurement interval time is shorter than the initial intermittent measurement mode. Thus, while the monitoring operation is being performed in the intermittent measurement mode set to obtain long-term data over a long period of time, for example, detailed data for a short period of time (in FIG. (Indicated by dots in the solid line portion) is acquired.

  The concentration setting value D0, which serves as a reference for changing the measurement mode from the initial intermittent measurement mode to the detailed measurement mode, reduces the increase in power consumption associated with the change of the measurement mode as much as possible, and provides long-term data for a required period. Can be set appropriately according to the purpose so as to be acquired reliably.

  Then, during the monitoring operation in the detailed measurement mode, when it is detected that the measured gas concentration has deviated from the concentration range, that is, the measured gas concentration value is lower than the concentration setting value D0, or initial intermittent When a certain time has passed since the measurement mode was changed to the detailed measurement mode, the initial intermittent measurement mode is automatically changed again, and the monitoring operation is continuously performed in this state. Here, when the change of the measurement mode is performed based on the elapsed time after the initial intermittent measurement mode is changed to the detailed measurement mode, the elapsed time can be appropriately set according to the purpose. However, for example, it is about 30 minutes.

  The automatic change function of the measurement mode as described above is manifested when one of a plurality of detection target gases satisfies the above conditions.

  According to the gas detector having the above-described configuration, when the monitoring operation for the detection target gas in the environmental atmosphere is performed in the intermittent measurement mode in which the gas concentration is measured at predetermined time intervals, the monitoring is performed in a timely manner based on the measured concentration value. Since the measurement mode is changed to the detailed measurement mode, for example, the intermittent measurement mode in which the measurement interval is shorter than the initial intermittent measurement mode, and monitoring is performed by the detailed measurement mode, long-term data over a required period can be acquired. However, it is possible to subdivide and acquire timely and short-term data before and after the occurrence of an event, such as an alarm, for example, and therefore grasp in detail the state of concentration change of the detection target gas in the environmental atmosphere be able to.

  Also, during the monitoring operation in the detailed measurement mode, when it is detected that the concentration value obtained in the detailed measurement mode has deviated from the predetermined concentration range, or the measurement mode is changed from the initial intermittent measurement mode to the detailed measurement mode. After a certain period of time has elapsed, the system automatically switches to the initial intermittent measurement mode again, so that the degree of increase in power consumption due to the change in the measurement mode is monitored as much as possible. Therefore, it is possible to reliably perform monitoring over a required period without impeding long-term data acquisition.

  In the above, when the monitoring operation in the initial intermittent measurement mode is performed, when it is detected that the measured gas concentration value is within a predetermined concentration range with respect to the alarm signal output concentration value, The initial intermittent measurement mode may be set to be automatically changed to the continuous measurement mode in which the gas concentration is continuously measured. In this case, it is possible to acquire data in a short time in a timely manner (for example, continuous data indicated by a solid line in FIG. 5 can be acquired), and the concentration change of the detection target gas in the environment can be obtained. The situation can be grasped in more detail.

As mentioned above, although embodiment of this invention was described, this invention is not limited to said embodiment, A various change can be added.
For example, the intermittent measurement mode to be changed only needs to have a measurement interval time shorter than that in the initial intermittent measurement mode, and is selected from set values that can be selected by the user when starting the monitoring operation. Even if it is set separately (for exclusive use) for short-term data acquisition, either may be sufficient.
Further, it is not essential that the continuous measurement mode is set, and only the intermittent measurement mode may be set.
Furthermore, after the measurement mode is changed from the initial intermittent measurement mode, the measurement mode may be set to be changeable to a measurement mode having a measurement interval time shorter than that related to the measurement mode.

Further, the present invention can be applied not only to the suction type gas detector as described above but also to a diffusion type gas detector.
Furthermore, the specific numerical values relating to the types and combinations of the gas sensors and the measurement conditions of the gas measurement are not particularly limited, and can be appropriately changed according to the purpose.

It is a front view which shows the external appearance in the example of 1 structure of the gas detector of this invention. It is sectional drawing of the gas detector shown in FIG. It is a perspective view which shows the structure of a sensor holder in the state in which the gas sensor and the pump unit were mounted | worn with the said sensor holder. It is a block diagram for demonstrating operation | movement of the gas detector shown in FIG. 1 thru | or FIG. It is explanatory drawing which shows typically the data acquired by the monitoring operation | movement by the gas detector of this invention.

Explanation of symbols

10 Housing 11 Control Circuit Board 11A CPU
DESCRIPTION OF SYMBOLS 11B Recording part 12 Circuit board 13 Display part 13A Panel-like display mechanism 14 Alarm light emission part 14A Window board 15 Operation part 15A Operation button 16 Filter unit 17 Gas exhaust part 18 Gas exhaust port 19 Time measuring part S Gas detection part SA-SE Gas sensor 20 Sensor holder 21 Pump unit mounting part 30 Sensor cap 40 Pump unit 41 Gas suction pump 42 Pump drive motor 43 Pressure sensor 74 Dry cell

Claims (6)

In the gas detector capable of performing the monitoring operation in the intermittent measurement mode for intermittently measuring the concentration of the detection target gas at least at a predetermined measurement interval time in the environmental atmosphere,
Measurement mode in which the measurement interval time is shorter than the initial intermittent measurement mode when it is detected that the gas concentration value measured in the initial intermittent measurement mode set when starting the monitoring operation is within the predetermined concentration range Gas detector, which is automatically changed to   The gas detector according to claim 1, wherein the gas detector is automatically changed to an intermittent measurement mode in which a measurement interval time is shorter than an initial intermittent measurement mode. The monitoring operation in the continuous measurement mode that continuously measures the concentration of the detection target gas in the environmental atmosphere is set to be possible.
The gas detector according to claim 1, wherein the gas detector is automatically changed from the initial intermittent measurement mode to the continuous measurement mode.   The monitoring mode is changed to the initial intermittent measurement mode when it is detected that the measured gas concentration value has deviated from the predetermined concentration range during the monitoring operation in the changed measurement mode. The gas detector according to any one of claims 1 to 3.   The gas detector according to any one of claims 1 to 3, wherein the gas detector is automatically changed to an initial intermittent measurement mode when a predetermined time elapses after the measurement mode is changed.   The gas detector according to any one of claims 1 to 5, wherein a plurality of types of detection target gases are simultaneously monitored.