JPS6327276Y2 - - Google Patents

Description

[Detailed explanation of the idea] The present invention relates to a gas leak signal repeater.

Gas detectors are generally supplied with operating power from a commercial power source at each installation location, and when detecting a gas leak, send out a constant voltage (DC) to notify a remote location of a gas leak. Under normal conditions, a voltage different from the above-mentioned constant voltage is sent out to notify that the device is operating normally. This notifies you of troubles such as unplugged outlets or power outages. Then, during normal operation, a constant first voltage is sent out,
A sensor that sends out a second voltage higher than the first voltage when detecting a gas leak, and vice versa (higher) during normal operation.
There is one that sends out a second voltage and sends out a (lower) first voltage when detecting a gas leak. Since any of the gas sensors sends out a constant voltage during normal operation, it is not possible to connect the outputs of two or more gas sensors to the receiver via a pair of alarm wires. To solve this problem, each repeater is equipped with an oscillator that oscillates a unique frequency assigned to it, and by making the oscillator continuously oscillate or output intermittently depending on the output of the gas sensor, a large number of It is conceivable to connect multiple repeaters and monitor the oscillation frequency and intermittent state of each repeater to monitor alarms from gas sensors connected to each repeater. However, as mentioned above, gas detectors have
Since there are two types in which the relationship between the normal sending voltage and the sending voltage during gas detection is opposite, it is difficult to provide a repeater that can be used for any type of gas sensor.

The purpose of the present invention is to provide a gas leak signal repeater that can be used for either of two types of gas detectors in which the relationship between the sending voltage during normal operation and during gas detection is reversed. The purpose of the present invention is to enable monitoring using a pair of relay lines even when multiple gas detectors are used together.

The repeater of the present invention includes a natural frequency oscillator that oscillates a unique frequency, a sending circuit that sends the output of the natural frequency oscillator to the relay line, a square wave oscillator that turns the sending circuit on and off intermittently, and a gas sensing a drive circuit that turns on and enables the natural frequency oscillator to operate at a constant first voltage sent from the gas sensor; and a second drive circuit that is higher than the first voltage sent from the gas sensor.
A second voltage detection circuit that detects a voltage, a negation circuit that negates the output of the second voltage detection circuit, and a switch that shorts the input and output of the negation circuit, Accordingly, the rectangular wave oscillator is enabled to operate.

Next, the present invention will be explained in detail with reference to the drawings.

FIG. 1 is a circuit diagram showing an embodiment of the present invention. That is, terminals L and C are connected to a pair of relay wires wired from a receiver (not shown), and DC voltage is supplied from the receiver side. A positive voltage is supplied from the terminal L through the resistor to the natural frequency oscillator 1 and the charging capacitor, and when the transistor _T1 is turned on, the natural frequency oscillator 1 becomes operational. That is, the collector of the transistor _T1 is connected to the negative side of the natural frequency oscillator 1, and the emitter is connected to the terminal C. At the base of the transistor T ₁ there is
For example, a constant first voltage is applied through a resistor from a gas sensor (not shown) connected between terminals P and C. At this time, the transistor _T1 is in an on state, and the natural frequency oscillator 1 is operable. The output of natural frequency oscillator 1 is connected to a capacitor
input through C ₁ to the base of transistor T ₂ ,
The base is connected through a resistor to the collector of transistor _T1 . An appropriate bias is applied by the emitter resistance of the transistor _T2 , and the transistor _T2 performs an amplification operation. The collector of the transistor _T2 is connected to the terminal L via a resistor. Furthermore, as will be described later, the rectangular wave oscillator 5 is not oscillating at this time. Therefore, the natural frequency signal output from the natural frequency oscillator 1 is continuously sent out between the terminals LC,
It is received by a receiver (not shown) via a trunk line. This allows it to be recognized that normal operation is in progress. When a second voltage higher than the first voltage is input from the gas sensor to the terminal P, the Zener diode ZD is turned on through the resistor, and current flows into the base of the transistor _T3 . Since the collector of the transistor _T3 is applied with a positive voltage from the terminal L via the resistor _R1 , and the emitter is connected to the terminal C, the transistor _T3 is turned on when the second voltage is input. By turning on the transistor _T3 , the logic state of the input of the NOT circuit 2 becomes "0". Since the switch 3 connected between the input and output of the NOT circuit 2 is now open, the logic on the output side of the NOT circuit 2 becomes "1". Since the output of the NOT circuit 2 is connected to one input of the NAND circuit 4 via a resistor, the rectangular wave oscillator 5 oscillates at this time. Due to the oscillation of the square wave oscillator 5, the output logic of the inverter 6 connected to its output becomes "1" and "0".
The situation is repeated. Since the output of the inverter 6 is connected to the base of the transistor T ₂ via the diode D ₁ , the output signal of the natural frequency oscillator 1 is interrupted by the oscillation frequency of the rectangular wave oscillator 5 . Therefore, the receiver side can recognize that the gas sensor has issued an alarm. Further, when the gas sensor is in trouble such as being unplugged, the terminal P becomes non-voltage, so the transistor _T1 is turned off and the natural frequency oscillator 1 stops oscillating. As a result, the natural frequency is no longer detected on the receiver side, so the above-mentioned trouble can be recognized. The oscillation frequency of the natural frequency oscillator 1 differs for each repeater, and multiple repeaters can be connected to a pair of relay wires, so a gas sensor connected to multiple repeaters via a pair of relay wires. can be monitored. Note that under normal conditions, the transistor
Since _T3 is in the off state, a positive potential is applied to the input of the negation circuit 2 via the resistor _R1 , so its output logic is "0" and the square wave oscillator 5 does not oscillate. , as mentioned above, the terminal L
-C, continuous natural frequencies are transmitted.

Contrary to the above, when a gas sensor is connected between terminals P and C, which sends out the (high) second voltage during normal times and sends out the (low) first voltage when detecting a gas leak, the switch 3 can be turned on manually. Turn it on. In this case, since the second voltage under normal conditions is higher than the first voltage, the transistor _T1 is naturally on.
Also, even in normal conditions, the Zener diode ZD is conductive and the transistor _T3 is turned on, but since the negative circuit 2 is short-circuited by the switch 3,
One input of the NAND circuit 4 is logic “0”,
The square wave oscillator 5 does not oscillate. Therefore, under normal conditions, a continuous natural frequency is transmitted from the natural frequency oscillator 1 between the terminals LC and C. Also, if the (low) first voltage is input to terminal P when detecting a gas leak,
The transistor _T1 remains on, and the natural frequency oscillator 1 continues its oscillation operation. However, since the Zener diode ZD is turned off, the transistor _T3 is turned off. Therefore, one input of the NAND circuit 4 becomes high level through the resistor _R1 and the switch 3, and the rectangular wave oscillator 5 starts oscillating. Therefore, as described above, the natural frequency is intermittently output between terminals LC. In addition, due to problems such as the gas detector being unplugged,
As described above, when the terminal P becomes non-voltage, the transistor _T1 is turned off and the natural frequency oscillator 1 stops oscillating. That is, by operating the switch 3, it is possible to connect to any of the two types of gas sensors. Furthermore, even when two types of gas sensors are used together, by connecting the repeaters to each other, monitoring can be performed from a remote receiver via a pair of relay lines.

Note that in this example, the transistor T ₂
A transmission circuit that transmits the output of the natural frequency oscillator to the relay line is composed of resistors connected to the base, emitter, and collector of the oscillator. Transistor T ₁ is also connected to a constant first signal sent from the gas sensor.
A drive circuit is configured that turns on at a voltage higher than the voltage and enables the natural frequency oscillator to operate. In addition, a Zener diode ZD, transistor _T3 , resistor R1 _, etc.
It constitutes a voltage detection circuit. Note that the square wave oscillator can, for example, convert the output of the NAND circuit 4 to the inverter 7.
and connect the output of inverter 7 to capacitor C ₂
and is fed back to the input of the inverter 7 through a resistor R ₂ , and connected to the input of the NAND circuit _{4 through a resistor R 3 from} the connection point between the capacitor C ₂ and the resistor R 2 . This rectangular oscillator is
When the logic of one input of the NAND circuit 4 is "1", it oscillates, and when it is "0", it does not oscillate.

FIG. 2 is a circuit diagram showing an example of a receiver that supplies DC voltage to the repeater via a relay line and monitors the natural frequency signal sent out from the repeater. That is, the DC power supply V is connected to one of the pair of relay wires through one winding of the transformer 8, and the other one is grounded. One end of the other winding of transformer 8 is grounded, and the other end is connected to the input of amplifier 9. The output of the amplifier 9 is connected to a plurality of bandpass filters 10. The passband of the bandpass filter 10 is made to match the natural frequency assigned to each repeater. band pass filter 10
Only the positive side of the output is taken out by diode D ₂ and integrated by an integrating circuit consisting of resistor R ₄ and capacitor C ₃ . The integrated voltage of capacitor C ₃ is compared with a predetermined voltage by comparators 11 and 12, respectively. The comparator 11 is a bandpass filter 10
It is set so that the integrated voltage is not output when the natural frequency signal outputted by the natural frequency signal is input continuously and when there is no input, but the integrated voltage is output when the natural frequency signal is inputted intermittently. The comparator 12 is set to output when the above-mentioned natural frequency signal is not output, that is, when there is zero input. The output of the comparator 12 is used as one input of an AND circuit 13, and the other input of the AND circuit 13 is connected to the output of a flash signal generator 14. The output of the AND circuit 13 and the output of the comparator 11 are both input to an OR circuit 14, and the output of the OR circuit 14 lights up the district indicator light 15. Therefore, when the natural frequency signal is continuously input from the repeater, it is not lit, and when the signal is intermittent, the district indicator light 15 is lit continuously. Further, when the signal is not inputted, the output of the AND circuit 13 is intermittent and the district indicator light 15 flashes.
Thereby, a gas leak signal or a trouble signal from a gas sensor connected to the relevant repeater can be identified. Further, each output of the plurality of band pass filters 10 is similarly displayed by a district indicator light 15, respectively. Then, all the outputs of the comparator 11 are input to the OR circuit 16, and the output of the OR circuit 16 causes the gas alarm bell 17 to ring. All the outputs of the comparator 12 are inputted to an OR circuit 18, and a failure indicating bell 20 is rung via an AND circuit 19. Since a signal obtained by inverting the output of the flash signal generator 14 and the output of the OR circuit 16 is input to the AND circuit 19, the bell 20 will ring intermittently if a problem occurs in any of the gas sensors. , to be distinguished from the continuous ringing of the bell 17 in the case of a gas leak. Also, even if there is a problem, the OR circuit 16
Since one input of the AND circuit 19 becomes low level due to the output signal of the bell 20, the ringing of the bell 20 is stopped. In other words, gas leaks are prioritized.

As described above, in the present invention, no matter which type of gas sensor is connected, the input/output of the inverting circuit interposed between the second voltage detection circuit and the square wave oscillator is controlled by the switch. It can be operated adaptively by shorting or opening. That is, it can be used even when different types of gas sensors are used. Since the output of the natural frequency oscillator is continuously sent to the relay line during normal times, and the output is interrupted when a gas leak is detected, multiple repeaters can be connected to a pair of relay lines. is possible. That is, less wiring is required between the repeater and the receiver. Further, it is possible to distinguish and recognize which sensor has issued the alarm based on the natural frequency.

[Brief explanation of the drawing]

FIG. 1 is a circuit diagram including a partial block diagram showing an embodiment of the present invention, and FIG. 2 is a circuit diagram showing an example of a receiver connected to the gas leakage signal repeater of the above embodiment. In the figure, 1...natural frequency oscillator, 2...
Negation circuit, 3... switch, 4... NAND circuit,
5...Square wave oscillator, 6,7...Inverter,
_T1 to _T3 ...Transistor, _C1 , _C2 ...Capacitor, _R1 to _R3 ...Resistor, ZD...Zener diode, _D1 ...Diode.

Claims (1)

[Scope of utility model registration request] a natural frequency oscillator that oscillates a unique frequency;
a sending circuit that sends the output of the natural frequency oscillator to a relay line; a square wave oscillator that turns on and off the sending circuit intermittently; a second drive circuit for detecting a second voltage higher than the first voltage sent from the gas sensor;
A voltage detection circuit, a negation circuit that negates the output of the second voltage detection circuit, and a switch that short-circuits the input and output of the negation circuit, the square wave oscillator being driven by the output of the negation circuit or the switch. A gas leak signal repeater characterized in that it is operable.