JP3390488B2 - Gas leak alarm system - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas meter having a measuring section for measuring a gas flow rate and a shutoff valve, and a sensor circuit connected to the gas meter via a signal line. And a gas leak alarm device for transmitting a shut-off signal to a gas meter to shut off a shut-off valve when a gas leak is detected. 2. Description of the Related Art A conventional gas leak alarm system of this type has no function of notifying a user that a sensor circuit of a gas leak alarm device has exceeded an effective use time (lifetime). It is used as it is after the end of its useful life,
Lack of consideration for long-time users. Also,
Regardless of whether the gas flow is detected by the gas meter or not, the power is always supplied to the sensor circuit of the gas leak alarm, so that the life of the sensor circuit is wasted. [0003] In view of the above-mentioned problems, the present invention has been made in view of the above circumstances, and has been made to extend the life of a sensor circuit of a gas leak alarm and to reduce the effective use time of the sensor circuit. It is an object of the present invention to be able to notify the user of the arrival. [0004] In the gas leak alarm system according to the present invention, the gas meter is provided with a transmission section for transmitting a signal indicating whether or not the gas flow rate is present at predetermined time intervals. Further, the gas leak alarm device, a flow rate presence / absence determination means for determining whether or not the flow rate presence / absence signal has been transmitted from the gas meter,
A sensor power supply shutoff unit that shuts off power supply to the sensor circuit when the determination result of the flow rate presence / absence determination unit is absent,
And a notifying unit for notifying when the total energizing time reaches a preset effective use time. When a gas flow rate signal indicating the presence or absence of a gas flow rate is transmitted from the gas meter to the gas leak alarm device, power is supplied to the sensor circuit of the gas leak alarm device. Is done. However, when the flow rate presence / absence signal is not transmitted to the gas leak alarm device, power is not supplied to the sensor circuit of the gas leak alarm device, and the measurement of the energization time is interrupted. When the integrated value of the energization time, that is, the total energization time reaches a preset effective use time, the user is notified by the notification means. Next, an embodiment of the present invention will be described in detail with reference to the drawings. In FIG. 1, a gas meter 10 and a gas leak alarm 1
1 is connected via two signal lines 12. Although not shown, the gas meter 10 includes a measurement unit for measuring a gas flow rate, a shutoff valve, and a transmission unit for transmitting a gas flow rate presence / absence signal at predetermined time intervals. The gas leak alarm 11 includes a one-chip microcomputer 13, a sensor circuit 14 for detecting gas leak, an amplifier circuit 15 for amplifying an output of the sensor circuit 14 and inputting the output to the microcomputer 13, A relay 16 for turning on / off the power supply to the sensor circuit 14,
An alarm circuit 17 such as a buzzer for issuing an alarm, a display circuit 18 for displaying a power supply state, and the external input / output circuit 1 serving as an interface for transmitting and receiving signals to and from the gas meter 10.
9, a voltage stabilizing circuit 20 for stabilizing the voltage supplied to each circuit, and a battery backup circuit 21 for the microcomputer 13. Note that a semiconductor switching element may be used instead of the relay 16. The display circuit 18 includes a main power supply display light emitting diode LED ₁ that is turned on when an AC power supply (AC 100 V) is supplied to the gas leak alarm device 11, a relay 16 is turned on and its contact 16 a is closed, The sensor circuit 14 includes a light-emitting diode LED ₂ for displaying a sensor power supply that is turned on when power is supplied to the sensor circuit 14. The external output circuit 19 includes a transmission photo-coupler PC ₁ and reception photo-coupler PC _2. The microcomputer 13 can be forcibly reset through the external reset terminal 23. Next, the gas meter 10 and the gas leak alarm 1
The outline of the operation 1 will be described with reference to the time chart of FIG. When the gas meter 10 does not detect the gas flow, the flow rate signal is not transmitted from the gas meter 10 to the gas leak alarm 11, so that the receiving photocoupler PC ₂ of the external input / output circuit 19 of the gas leak alarm 11 is used. Remains off. At this time, since the microcomputer 13 turns off the relay 16, the contact 16a of the relay 16 is turned off.
Is opened, and the power supply to the sensor circuit 14 is cut off.
Therefore, at this time, gas detection by the sensor circuit 14 is not performed, and no alarm operation by the alarm circuit 17 occurs. The energization time timer in the microcomputer 13 does not measure the energization time (the state in FIG. 2). On the other hand, when the gas meter 11 is detecting a gas flow, a flow rate presence / absence signal is transmitted from the gas meter 10 to the gas leak alarm 11 and the receiving photocoupler P is detected.
C ₂ repeats on and off in response. At this time,
Since the microcomputer 13 turns on the relay 16, the contact 16a of the relay 16 is closed, and power is supplied to the sensor circuit 14. Accordingly, at this time, the sensor circuit 14 enters a gas leak monitoring state. Further, the energization time timer counts the energization time, and time TN0 stored in the memory is added to the time of the time TN ₁ and the previous timing, the added value is stored newly in the memory (Figure 2 When the power supply to the sensor circuit 14 is switched from the cut-off state to the applied state, the initial ringing is suppressed for several seconds until the sensor circuit 14 is stabilized. After a time ΔT, the gas leak can be detected. In this case, the alarm circuit 1 for ΔT time
7 is suspended, but even if a gas leak occurs, the alarm level does not immediately reach the alarm level, that is, the alarm circuit 17 usually does not immediately start the alarm operation. No. When the sensor circuit 14 detects a gas leak, the microcomputer 13 activates the alarm circuit 17 and at the same time transmits the photocoupler PC _1.
Is turned on / off in a short cycle, and a shutoff signal for shutting off the shutoff valve is transmitted to the gas meter 11. (State in FIG. 2) Next, when the gas meter 10 does not detect the gas flow and the gas is generated by the insecticide spray or the like, the power is not supplied to the sensor circuit 14 because the power is not supplied to the sensor circuit 14. Since the gas detection signal is not output from the sensor circuit 14 and the flow rate presence / absence signal is not transmitted before and after that, the microcomputer 13 determines that there is no true gas leak and does not operate the alarm circuit 17. . Therefore, no alarm is issued in this case. The energization time timer stops measuring the energization time. The total energization time measured by the energization time timer, ie, the total energization time (TN0 + TN1 + TN2... +
When TNX) reaches a preset effective use time (durable time) CN, the microcomputer 13 activates the alarm circuit 17 intermittently, and the sensor is activated by the intermittent alarm sounding which is different from the sounding mode at the time of the gas leak alarm. The state in which the circuit 14 has exceeded the effective use time is notified. However,
When the effective use time is reached, if gas leak detection is in progress,
Give priority to gas leak alarm operation. Further, the transmission photocoupler PC ₂ of the external input / output circuit 19 is turned on / off at a cycle different from that at the time of gas leakage, and a signal indicating the elapse of the effective use time of the sensor circuit 14 is transmitted to the gas meter 10. The management information of the use time of the sensor circuit 14 can be transmitted through the connected telephone line. FIG. 3 shows a flowchart of control by the microcomputer 13. The operation as described above will be described again based on this. First, in step S1, the microcomputer 13 is initialized, the light emitting diode LED ₁ for displaying the main power is turned on, the light emitting diode LED ₂ for displaying the sensor power is turned off, and the relay is turned off. 16, the energization time timer is cleared, the effective use time CN of the sensor circuit 14
Make the settings for Next, at step S2, it is confirmed whether or not there is a count value of the flow timer in the microcomputer 13. The flow rate timer counts the flow absence signal received by the reception photo-coupler PC ₂ is transmitted from the gas meter 10. If there is a count value, step S3
In addition to the power supply to the sensor circuit 14 to the relay 16 as ON, it counts the energized time TN energized time timer, further turns on the power display light-emitting diode LED _2. Further, in order to stabilize the output of the sensor circuit 14, in step S5, the alarm operation is suspended for ΔT time by operating the initial sound suppression timer. In the next step S6, the energization time measured by the energization time timer is added, and it is determined in a step S7 whether or not the value has reached the effective use time CN. The microcomputer 13 operates the battery backup circuit 2 even during a power failure.
Since the operation is maintained by 1, the use time TN of the sensor circuit 14 and the effective use time CN to be compared with this are stored and held in the memory even during a power failure. When the actual use time TN is equal to or longer than the effective use time CN, the process proceeds to step S8, and the elapse of the effective use time is reported by an intermittent alarm sound. In the next step S9, the sensor circuit 14 determines whether or not a gas leak has been detected. If a gas leak has been detected, the flow advances to step S11 to activate the alarm circuit 17, to issue an alarm, and in step S12 to transmit a photo for transmission. Coupler PC
₁ is turned on and off, and a shutoff signal is transmitted to the gas meter 10. Next, in step S13, it is confirmed again whether or not the flow timer has a count value, and if there is a count value, the process returns to step S6. If there is no count value, step S1
Proceed to 4. On the other hand, if it is determined in step S9 that there is no gas leakage, the flow advances to step S10 to check whether or not the flow timer has a count value. If there is a count value, the flow returns to step S6, and there is no count value. When step S1
Proceed to 4. In step S14, the power supply to the sensor circuit 14 is cut off by turning off the relay 16, and at the same time,
In step S15, the light emitting diode LE for displaying the sensor power supply
D ₂ is turned off, indicating that a gas leak detection impossible state. In the flowchart of FIG. 3, a flow rate presence / absence signal check step and a flow rate timer countdown start step as shown in FIG. 4 are provided so that the flow rate presence / absence signal from the gas meter 10 can be immediately detected. , Are inserted everywhere. That is, checks the operation of the reception photo-coupler PC ₂ is fine, in presence determination portion of flow timer count value, the flow rate timer or counting to determine at all times the presence or absence of the reception of the flow absence signal by matching or count end It has become. According to the present invention, when the flow rate presence / absence signal is not transmitted to the gas leak alarm, the power supply to the sensor circuit of the gas leak alarm is cut off, so that the life of the sensor circuit is reduced. Can be extended. In addition, the energization time to the sensor circuit is measured, and when the total energization time exceeds a preset effective use time, the fact can be notified to the user. A secure security system can be built for the users who use it.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram mainly showing a configuration of a gas leak alarm device side of a gas leak alarm system according to the present invention. FIG. 2 is a time chart of the operation of the system. FIG. 3 is a flowchart showing control by a microcomputer in the gas leak alarm. FIG. 4 is a flowchart of some steps inserted in the flowchart of the above. [Description of Signs] 10 Gas meter 11 Gas leak alarm 12 Signal line 13 Microcomputer 14 Sensor circuit 16 Relay (sensor power cutoff means) 17 Alarm circuit

──────────────────────────────────────────────────続 き Continued on the front page (58) Field surveyed (Int. Cl. ⁷ , DB name) G08B 21/16

Claims (1)

(57) [Claims 1] A gas meter provided with a measuring unit for measuring a gas flow rate and a shut-off valve, connected to the gas meter via a signal line, and detecting a gas leak in a sensor circuit. ,
A gas leak alarm system configured to transmit a shut-off signal for shutting off the shut-off valve to a gas meter, wherein the gas meter includes a transmission unit that transmits a gas flow rate presence / absence signal at predetermined time intervals; A flow rate presence / absence determining means for determining whether or not the flow rate presence / absence signal is transmitted from the gas meter to the gas leak alarm, and power supply to the sensor circuit when the flow rate presence / absence determination means does not determine Sensor power cutoff means for shutting off the power supply, energization time timer means for measuring the total energization time to the sensor circuit, and notification means for notifying when the total energization time reaches a preset effective use time. A gas leak alarm system, characterized in that: