JPH058775B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a gas detection alarm calibration device for checking or calibrating the operation of a gas detection alarm.

(Prior Art) When performing work such as inland raids where toxic gases such as carbon monoxide may be generated, it is customary to carry a gas detection alarm to ensure safety. This gas detection alarm generates an alarm with a buzzer or the like when a predetermined toxic gas exceeds a certain concentration in the surrounding air. The sensors used in this type of gas detection alarm gradually deteriorate after long-term use, and are no longer able to maintain predetermined performance. Therefore,
To ensure safety, this type of gas detection alarm device is checked for operation at regular intervals, and if the sensor has deteriorated, electrical methods such as adjusting the gain of the amplifier circuit are carried out to meet the specified standards. Calibration is performed to satisfy the following.

Conventionally, in order to check or calibrate the operation of such a gas detection alarm, as shown in FIGS. 5 and 6, standard gas is first taken from a cylinder or the like into a sampling bag 51,
A gas detection alarm 57 to be calibrated by connecting a pump 53 to the chamber 55 and supplying standard gas to the chamber 55.
This was generally done by bringing the sensor section 59 of the chamber into contact with the chamber 55.

That is, when the pump 53 connected to the sampling bag 51 containing the standard gas is operated,
Standard gas flows into chamber 55 at a constant flow rate. When the sensor section 59 of the gas detection alarm 57 is set in this chamber 55, the indicated value of the gas detection alarm 57 increases in accordance with the concentration of the standard gas. This increase in the indicated value is accompanied by a time delay, and the relationship between the indicated value and time after it is set is generally as shown in FIG. 7. . Regarding the time delay of this indicated value, standards are determined depending on the type of gas. For example, the Japan Electrical Measuring Instruments Manufacturers Association's standards for "electrochemical toxic gas leak detection alarms" require that an alarm begin to be emitted when the detection unit comes into contact with a standard gas at a concentration 2 to 3 times the alarm setting concentration. or the indicated value is the gas concentration.
The time it takes to reach 50% is supposed to be within 1 minute.

Therefore, when checking the operation of the gas detection alarm 57, set the gas detection alarm 57 in the chamber 55 through which the standard gas is flowing at a constant flow rate, wait for a certain period of time, or check the time or instructions before issuing the alarm. The time it takes for the value to rise to a certain value is measured using a stopwatch or the like, and it is determined whether the performance of the gas detection alarm meets a predetermined standard. If the standard is not satisfied, the gas detection alarm 57 is calibrated by electrically adjusting so that the concentration value of the standard gas and the indicated value match. If the sensor has deteriorated to the extent that the above calibration is no longer possible due to electrical adjustment, replace it with a new sensor and perform electrical adjustment again to make the indicated value match the concentration value of the standard gas and calibrate. end.

(Problems to be Solved by the Invention) However, although the operation check and calibration in this type of gas detection alarm calibration device are performed as described above, the standard gas is kept flowing into the chamber. Since the operator was responsible for checking the operation and determining the timing of calibration, it took a long time to calibrate unless the operator was proficient, and it was susceptible to individual differences among operators.
Not only was accuracy lacking, but there were also problems such as the need to collect standard gas from the cylinder into a sampling bag each time calibration was performed.

The present invention has been made with these points in mind, and it is an object of the present invention to provide a gas detection and alarm device that can be easily checked and calibrated in a short time and without individual differences.

(Means for Solving the Problems) Therefore, in the present invention, the gas detection alarm calibration device includes a gas inlet fitting to which a standard gas supply source is connected, and a gas detection alarm whose operation is checked and calibrated. A chamber to be set, a solenoid valve placed in the standard gas flow path from the gas inlet fitting to the chamber to control the supply and stop of the standard gas, and a gas detection alarm set to the chamber. an operation confirmation control means that detects the solenoid valve, sends a signal to open the solenoid valve, and stops sending the signal to open the solenoid valve after a preset certain period of time has elapsed;
It has a switch that is operated when the gas detection alarm set in the chamber needs to be calibrated, and in response to the operation of the switch, a signal is sent to open the solenoid valve, and the solenoid valve is opened for a predetermined period of time. After the elapse of time, the calibration control means displays that the calibration preparation is completed, and stops sending out the signal for opening the solenoid valve after a preset certain period of time has elapsed.

(Function) In the gas detection alarm calibration device of the present invention configured as described above, a standard gas supply source is connected to the gas inlet fitting, and the gas detection alarm whose operation is to be checked and calibrated is set in the chamber. Then,
The solenoid valve placed in the standard gas flow path from the gas inlet fitting to the chamber is opened for a preset period of time by the signal generated by the operation confirmation control means that detects this, and the standard gas is detected for a certain period of time. If a predetermined function is confirmed during this period, the gas detection alarm is judged to have passed, and calibration of the gas detection alarm that has not passed is performed by the calibration control means by operating a switch. Keep the solenoid valve open for a certain period of time using the signal that indicates that the calibration preparation is complete, and then make electrical adjustments such as amplifier gain adjustment until the solenoid valve closes. This calibrates the detection alarm, thereby eliminating the possibility of operator skill level or individual differences, and eliminating the need to collect standard gas into a sampling bag, allowing for accurate operation checks and This allows anyone to easily perform calibration in a short time.

(Example) Next, an example of implementation of the present invention will be described with reference to the drawings. Fig. 1 is a block diagram showing an embodiment of the gas detection alarm calibration device according to the present invention, Fig. 2 is a flowchart for explaining its operation, and Figs. 3 and 4 show the operation timing of each part. This is a time chart.

In FIG. 1, 11 is a gas inlet fitting, 13 is a chamber, 15 is a solenoid valve, 17 is an operation confirmation control means, and 19 is a calibration control means. A standard gas cylinder (not shown), which is a standard gas supply source, is connected to the gas inlet fitting 11, and the chamber 13
A gas detection alarm (not shown) whose operation is to be checked and calibrated is now set. The solenoid valve 15 is arranged in the standard gas flow path from the gas inlet fitting 11 to the chamber 13,
It controls the supply and stop of the standard gas from the standard gas cylinder to the detection alarm device, and its opening and closing is controlled by signals from the operation confirmation control means 17 or the calibration control means 19.

The operation confirmation control means 17 includes a micro switch 21, a first relay 23, and a first delay relay 2.
5. This micro switch 21 is attached to the chamber 13 and is activated when it detects that a gas detection alarm is set in the chamber 13. In addition, the first relay 23 responds to the operation of the micro switch 21 by creating a signal for opening the solenoid valve 15 and transmitting it. The first relay 23 starts operating after a certain preset time _T1 has elapsed, and stops the first relay 23 from operating, and stops sending the signal for opening the solenoid valve 15. Here, the delay time _T1 of the first delay relay can be appropriately set to a desired value, and is set to, for example, about 15 seconds, which is required to check the operation of the gas detection alarm.

Further, the calibration control means 19 includes a calibration switch 31, a second relay 33, a second delay relay 35, a third delay relay 37, and a lamp 39. The calibration switch 31 is a switch that is operated when the gas detection alarm set in the chamber needs to be calibrated, and is, for example, a non-locking push button switch. The second relay 33 sends out a signal to open the solenoid valve 15 in response to the operation of the switch 31, and the second delay relay 35
The solenoid valve ₁₅ is operated after a predetermined period of time T3 has elapsed since the calibration switch 31 was activated, and stops sending out the signal for opening the solenoid valve 15. Further, the third delay relay 37 also operates after a predetermined period of time _T2 has elapsed since the calibration switch 31 was activated, and lights up the lamp 39 to notify the completion of calibration preparation. Both the delay time T ₃ of the second delay relay 35 and the delay time T ₂ of the third delay relay 37 can be set to desired values as desired, as in the case described above _. The time required for preparing the instrument for calibration is set, for example, about 1 minute.
_The delay time T ₃ is set to, for example, about 2 minutes, which is sufficient to calibrate the gas detection alarm.

Next, the operation of the gas detection alarm calibration device of this embodiment configured as described above will be explained with reference to FIGS. 2 to 4.

First, a standard gas cylinder of standard gas is connected to the gas inlet fitting 11, and a gas detection alarm whose operation is to be checked and calibrated is set in the chamber 13. A micro switch 21 attached to the chamber 13 operates upon detecting that this gas detection alarm is set. In response to the operation of this micro switch 21, the first relay 2
3 is activated, and the first delay relay is also activated. The solenoid valve 15 disposed in the standard gas flow path from the gas inlet fitting 11 to the chamber 13 is opened by the signal generated and sent by the operation of the first relay 23, and the standard gas is activated to generate a gas detection alarm. supplied to the vessel.

Further, the first delay relay operates when a predetermined time _T1 has elapsed after being activated, and the first delay relay 23
stop the operation. Therefore, the first relay 23
The signal sent by the solenoid valve 15 is also stopped, and therefore the solenoid valve 15 is opened for this predetermined time _T1 to supply standard gas to the gas detection alarm. During this time, the gas detection alarm will issue an alarm,
If the indicated value rises to a certain value and the predetermined function can be confirmed, the gas detection alarm is determined to have passed the test. The time chart in FIG. 3 shows the operation timing.

In addition, when calibrating a gas detection alarm,
The calibration switch 31 may be pressed to operate. It is possible to automatically start the calibration process after checking the operation, but if you use a circuit like this, the gas detection alarm that issued an alarm after T ₁ hour will inadvertently issue an alarm within T ₁ hour. There is a risk of misunderstanding that this is the case. Furthermore, since there are cases where only the gas detection alarm is calibrated, the calibration is activated by a calibration switch. In this embodiment, a case will be described in which the calibration switch 31 is pressed to operate before the first delay relay 25 starts operating. This is because setting up the gas detection alarm in chamber 13 does not require much effort, so after confirming its operation, set the gas detection alarm again and perform calibration immediately to eliminate human errors and ensure accurate calibration. There is a purpose.

When the calibration switch 31 operates, the second relay 33 operates in response, and the second delay relay 35 and the third delay relay 37 are also activated. Due to the signal generated and sent by the operation of the second relay 33, the solenoid valve 15 remains open even when the signal from the first relay 23 stops, and the standard gas is sent to the gas detection alarm. continue to be supplied.

When the third delay relay 37 is activated and a predetermined time _T2 necessary for preparing for calibration of the gas detection alarm device has elapsed, it starts operating and lights up the lamp 39 to inform the operator that preparation for calibration is complete. . The operator confirms that the lamp 39 is lit and calibrates the gas detection alarm by electrical adjustment such as amplifier gain adjustment. The second delay relay 35 starts operating when a predetermined time _T3 has elapsed since it was activated, stops the operation of the second relay 33, stops sending out the signal, and stops the supply of the standard gas for this predetermined time. Limited to within T ₃ only. The calibration work of the gas detection alarm is completed during this time. Here, if the gas detection alarm device is removed from the chamber 13, the micro switch 21
Due to the action of the first relay 23 and the second relay 3
3 stops and the solenoid valve is closed. Therefore, the standard gas will not be released unnecessarily. The time chart in FIG. 4 shows the operation timing during this period.

Although the present invention has been described in detail in accordance with the illustrated embodiments, the present invention is not limited thereto.
For example, in the above embodiment, the pressing operation of the calibration switch was explained in the case before the first delay relay operation started, but after the first delay relay operation, the calibration switch is pressed with the gas detection alarm set in the chamber. Alternatively, each delay relay can be replaced with an electronic or electromagnetic timer, each relay can be replaced with an electronic drive circuit, and the lamp that indicates the completion of calibration preparation can be replaced with a buzzer. It is also possible to branch out the standard gas flow path between the gas inlet fitting and the solenoid valve so that the operation of multiple gas detection alarms can be checked and calibrated at the same time. It includes various variations.

(Effects of the Invention) The present invention is configured as described above, and a solenoid valve is disposed in a standard gas flow path, and the solenoid valve is opened and closed based on a predetermined time set in the operation confirmation control means or the calibration control means. Since it is automatically controlled by the gas detection alarm, when checking or calibrating the operation of the gas detection alarm, it is necessary to manage the time using a stopwatch, etc., or turn the pump switch on and off to open and close the supply of standard gas. The operator only needs to set the gas detection alarm in the chamber and operate the calibration switch as necessary.Therefore, there is no room for operator skill or individual differences. Furthermore, there is no need to collect the standard gas into a sampling bag one by one, and an excellent effect can be obtained in that anyone can easily perform accurate operation checks and calibrations in a short time.

[Brief explanation of the drawing]

Fig. 1 is a block diagram showing an embodiment of the gas detection alarm calibration device according to the present invention, Fig. 2 is a flowchart for explaining its operation, and Fig. 3 shows the operation timing of each part during an operation check. Figure 4 is a time chart showing the operation timing of each part during calibration, and Figures 5 and 6 are schematic configuration diagrams for explaining the operation check and calibration method of a conventional gas detection alarm. , FIG. 7 is a graph showing the time delay characteristic of the support value of the gas detection alarm sensor. 11...Gas inlet fitting, 13...Chamber, 15...
Solenoid valve, 17...operation confirmation control means, 1
9... Calibration control means, 21... Micro switch, 2
3...first relay, 33...second relay, 25...first
Delay relay, 35...second delay relay, 37...third
Delay relay, 31...calibration switch, 39...lamp.

Claims (1)

[Claims] 1. A gas inlet fitting to which a standard gas supply source is connected, a chamber in which a gas detection alarm whose operation is checked and calibrated is set, and a standard gas flow path from the gas inlet fitting to the chamber. A solenoid valve controls the supply and stop of the standard gas, and a signal is sent to open the solenoid upon detecting that a gas detection alarm is set in the chamber, and a signal is sent to open the solenoid for a preset period of time. comprising an operation confirmation control means for stopping the sending of a signal for opening the solenoid valve after a period of time has elapsed, and a switch that is operated when a gas detection alarm set in the chamber needs to be calibrated;
In response to the operation of this switch, a signal is sent to open the solenoid valve, and after a predetermined period of time, it is displayed that the calibration preparation is complete, and the solenoid valve is opened after a preset period of time has elapsed. and a calibration control means for stopping the transmission of the signal.