JP3866390B2 - Gas leak alarm - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a gas leak alarm that issues an alarm when the detected gas concentration of city gas or the like exceeds a predetermined gas concentration.
[0002]
[Prior art]
Conventionally, there is a gas leak alarm as a safety device for gas, for example, city gas, propane gas, incomplete combustion gas such as gas equipment, and the like. As this gas leak alarm, for example, the one shown in FIG. 4 is known.
When the AC power is turned on, the voltage of the constant voltage circuit 47 is applied to the microcomputer 48, and when the microcomputer 48 is stabilized, the display lamp 451 is turned on by the microcomputer 48, and the gas detector 41 is switched by the switching of the transistor 49. The rated RMS voltage is applied to The gas detection unit 41 is a bridge circuit including resistors 411 and 412, a variable resistor 413, a temperature compensation sensor 414, and a gas detection sensor 415 . As the gas detection sensor 415 , a contact combustion sensor, a semiconductor sensor, a hot wire semiconductor sensor, or the like is used.
[0003]
When the gas concentration detected by the gas detection unit 41 exceeds a predetermined reference low gas concentration, a high level signal is supplied from the comparator 42 to the microcomputer 48, and the display lamp 452 blinks by the microcomputer 48. The low-concentration gas is detected. When the gas concentration detected by the gas detector 41 exceeds a predetermined reference high gas concentration, a high level signal is supplied from the comparator 43 to the microcomputer 48, and the microcomputer 48 displays the display lamp 451. In a state where is turned on, the alarm output unit 454 drives the speaker 455 to generate a predetermined electronic sound, thereby notifying that a high-concentration gas has been detected. When a high-concentration gas is detected, it is also notified to a monitoring unit connected to the external output unit 46.
[0004]
When the gas detection sensor 415 or the circuit breaks down, the alarm output unit 454 drives the speaker 455 to generate a predetermined electronic sound, or the display lamp 451 is turned off.
[0005]
[Problems to be solved by the invention]
If the gas leak alarm is a 1st stage alarm, a 2nd stage alarm, or an abnormal alarm is issued, the user will be informed that the gas leak alarm has issued an alarm. This is because the gas leak alarm was dropped. In this case, since the appearance is damaged, the printed circuit board or the like is damaged, the sensor is damaged, etc., the cause of the abnormal alarm is often known directly. However, if the gas leak alarm device issues a 1-stage alarm, 2-stage alarm, or an abnormal alarm due to the attached state of the gas leak alarm or due to external factors such as the installed environment In many cases, even if a claim return product is evaluated, there is often no abnormality in the gas leak alarm, the complaint status is often not reproduced, and the cause of the gas leak alarm cannot be identified. It was. In addition, there are many reports from users that “the alarm sounded”, and when the gas leak alarm sounded, the status and situation were often not reported. In that case, I did not know at all what situation and situation the gas leak alarm sounded.
[0006]
Among gas leak alarms, there is a combined type gas leak alarm such as city gas and incomplete combustion gas. In such a gas leak alarm, it is also possible to grasp the cause of the alarm. It was difficult.
[0007]
Accordingly, an object of the present invention is to provide a gas leak alarm device that solves the above problems and makes it easier to specify the cause of the alarm.
[0008]
[Means for Solving the Problems]
The present invention is based on a nonvolatile memory, a gas concentration detection means for detecting a gas concentration, a temperature detection means for detecting a temperature in the vicinity of the gas concentration detection means, and a temperature detected by the temperature detection means. A gas concentration correction unit that corrects the gas concentration detected by the gas concentration detection unit, and a corresponding alarm among a plurality of predetermined alarms based on the gas concentration obtained by the gas concentration correction by the gas concentration correction unit. In a gas leak alarm having an alarm determining means for determining, an alarm means for issuing an alarm according to the alarm determined by the alarm determining means, and a built-in timer,
When an alarm is determined by the alarm determination means, the time set in the built-in timer is written in the nonvolatile memory with the content of the determined alarm and the gas concentration detected by the gas concentration detection means. While it does not elapse, it repeats at a predetermined time period, and when there is no alarm, it stops writing to the non-volatile memory, and when the time set in the built-in timer elapses, it writes time data to the non-volatile memory When it is recognized that the time data has been counted for several days, the gas concentration detection unit output data is written in the nonvolatile memory.
[0010]
In the non-volatile memory, a predetermined reference gas concentration value, a temperature offset value of the temperature detecting means, and a detected gas concentration value by the gas concentration detecting means in a non-gas state can be stored in advance.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1 shows an embodiment of the present invention. In FIG. 1, reference numeral 1 denotes a gas concentration detection unit, which includes a resistor 101, a variable resistor 102, a temperature compensation sensor (TC) 103, and a gas sensor (GS) 104. It has a bridge circuit and an amplifier 105 that amplifies the output of the bridge circuit. As the gas detection sensor 104, a contact combustion type sensor is preferable. Reference numeral 4 denotes a temperature sensor that detects the temperature in the vicinity of the gas detection sensor. A communication control unit 10 controls communication with other computers.
[0012]
Reference numeral 8 denotes a microcomputer having a central processing unit (CPU) 801, a read only memory (ROM) 802, and a random access memory (RAM) 803. A control program is stored in the ROM 802. The CPU 801 controls the EEPROM 9, the alarm unit 5, and the communication control unit 10 according to the program, and the RAM 803 is used as a work area. The microcomputer 8 has a built-in A / D conversion port for converting the analog output of the gas concentration detector 1 into a digital value. The microcomputer 8 is in a normal “monitoring state”, a “first-stage alarm” for alarming low-concentration gas detection, a “second-stage alarm” for alarming high-concentration gas detection, or a failure of the gas detection sensor 104 If it is “monitoring state”, the green alarm display LED 501 of the alarm unit 5 is steadily lit, and if it is “first alarm”, the green alarm display of the alarm unit 5 is displayed. The red alarm display LED 502 blinks while the LED 501 is steadily lit, and in the case of “second stage alarm”, the alarm output unit 504 is in a state where both the green and red alarm display LEDs 501 and 502 of the alarm unit 5 are steadily lit. To drive the speaker 505 to generate a predetermined electronic sound, and in the case of “abnormal alarm”, the alarm output unit 504 keeps the green alarm display LED 501 steadily lit and the speaker 5 5 drives are those which generate a predetermined electronic sound. In the case of “abnormal alarm”, the green and red alarm display LEDs 501 and 502 of the alarm unit 5 may be turned off so that no electronic sound is generated from the speaker 505. When the data setting mode is set by the mode setting switch 6, the microcomputer 8 receives 0-point data (the output value of the gas concentration detection unit 1 in the non-gas state) input via the communication control unit 10, a temperature sensor 4 is stored in an EEPROM (electrically erasable and programmable ROM) 9.
[0013]
2 and 3 are flowcharts showing an example of a control program stored in the ROM 802 shown in FIG. When the alarm device is turned on, the microcomputer 8 is turned on, resets, and reads from the EEPROM 9 zero-point data, temperature data, gas sensitivity data, energization time data, and so on. (S201), it is determined whether or not the read data is abnormal (S202). If there is an abnormality in the data, the green alarm display LED 501 of the alarm unit 5 is steadily lit and a predetermined electronic sound is generated from the speaker 505 to generate an “abnormal alarm” (S203). If not, it is determined whether or not the data setting mode is set by the mode setting switch 6 (S204).
[0014]
When the data setting mode is set and the zero point data is set (S205), the zero point data is written to the EEPROM 9 (S206), and the temperature data (temperature offset value of the temperature sensor 4 ) is set. (S207) The temperature data is written in the EEPROM 9 (S208), and when the gas sensitivity is set (S209), the gas sensitivity data is written in the EEPROM 9 (S210), and the data is output from the EEPROM 9 (S211). Then, data is read from the EEPROM 9 and the read data is supplied to an external device such as a personal computer via the communication control unit 10. When a data setting mode end signal is input or when a predetermined time has elapsed, the data setting mode is reset.
On the other hand, when the data setting mode is not set (S204), that is, in the normal mode, the gas concentration detected by the gas concentration detector 1 and the temperature detected by the temperature sensor 4 are read (S301). Then, the detected gas concentration is corrected by the detected temperature (S302), the obtained corrected gas concentration is compared with the gas sensitivity data stored in the EEPROM 9, and an alarm is determined according to the comparison result. . That is, when a low gas concentration is detected, it is determined as “first stage alarm” (S303), the red alarm display LED 502 is blinked while the green alarm display LED 501 is steadily lit, and the first stage alarm is generated. The alarm content (in this case, the first-stage alarm), the correction gas concentration, and the temperature value are stored in the EEPROM 9 (S310). When a high gas concentration is detected, it is determined as “second stage alarm” (S304), the green and red alarm display LEDs 501 and 502 are steadily lit, and a predetermined electronic sound is generated from the speaker 505 to A stage warning is issued (S306), and the process proceeds to step S310. If it is determined that the gas detection sensor 104 is malfunctioning (abnormal alarm) (S307), the alarm output unit 504 drives the speaker 505 with the green alarm display LED 501 steadily lit, and “abnormal alarm” is generated by a predetermined electronic sound. ”(S308), and the process proceeds to step S310. If it is neither, the alarm operation is reset (S309), and the process proceeds to step S311.
[0015]
On the other hand, when the data setting mode is not set (S204), that is, in the normal mode, the gas concentration detected by the gas concentration detector 1 and the temperature detected by the temperature sensor 4 are read (S301). Then, the detected gas concentration is corrected by the detected temperature (S302), the obtained corrected gas concentration is compared with the gas sensitivity data stored in the EEPROM 9, and an alarm is determined according to the comparison result. . That is, when a low gas concentration is detected, it is determined as “first stage alarm” (S303), the red alarm display LED 502 is blinked while the green alarm display LED 501 is steadily lit, and the first stage alarm is generated. The alarm content (in this case, the first-stage alarm), the correction gas concentration, and the temperature value are stored in the EEPROM 9 (S310). When a high gas concentration is detected, it is determined as “second stage alarm” (S304), the green and red alarm display LEDs 501 and 502 are steadily lit, and a predetermined electronic sound is generated from the speaker 505 to A stage warning is issued (S306), and the process proceeds to step S310. If it is determined that the gas detection sensor 104 is malfunctioning (abnormal alarm) (S307), the alarm output unit 504 drives the speaker 505 with the green alarm display LED 501 steadily lit, and “abnormal alarm” is generated by a predetermined electronic sound. ”(S308), and the process proceeds to step S310. Subsequently, the process proceeds to step 311. If the predetermined time set in the built-in timer has not elapsed (S312), the process returns to reading of gas concentration and temperature (S301).
If there is no first-stage alarm determination in step S303 (when no gas concentration is detected) and there is no abnormality alarm in the next step S307, the alarm operation is reset (S309), and the process proceeds to step S311.
[0016]
The time is counted by the internal timer of the microcomputer 8 (S311), and while the time set in the internal timer has not elapsed (NO in S312), the process returns to reading the gas concentration and temperature (S301), and the alarm determination and the alarm operation are performed. After the repetition, various data are written to the EEPROM 9 (S310). When the time set in the internal timer has elapsed (YES in S312), the time data is written to the EEPROM 9 (S313).
Thus, when various alarms are generated, various data are written in the EEPROM 9 (S310), thereby making it easy to specify the cause of the alarm in which state or situation the gas leak alarm has occurred. Further, when it is recognized that the time data has been divided for several days (S314), the output data of the gas concentration detector 1 is written in the EEPROM 9 (S315).
[0017]
Thereafter, steps S301 to S315 are repeated, and data is stored in the EEPROM 9.
[0018]
【The invention's effect】
As described above, according to the present invention, since it is configured as described above, it becomes easier to specify the cause of the alarm.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an embodiment of the present invention.
FIG. 2 is a flowchart (part 1) illustrating an example of a control program stored in a ROM 802 shown in FIG.
FIG. 3 is a flowchart (part 2) illustrating an example of a control program stored in a ROM 802 shown in FIG. 1;
FIG. 4 is a block diagram showing a configuration of a conventional gas leak alarm.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Gas concentration detection part 3 Transistor 4 Temperature sensor 5 Alarm part 6 Mode setting switch 7 Constant voltage circuit 8 Microcomputer 9 EEPROM
10 Communication Control Unit 101 Resistor 102 Variable Resistor 103 Temperature Compensation Sensor 104 Gas Detection Sensor 105 Amplifier 501 Alarm Display LED
502 Green alarm indicator LED
503 Red alarm indicator LED
504 Alarm output unit 505 Speaker 801 CPU
802 ROM
803 RAM

Claims (1)

Non-volatile memory, gas concentration detecting means for detecting gas concentration, temperature detecting means for detecting the temperature in the vicinity of the gas concentration detecting means, and the gas concentration detecting means based on the temperature detected by the temperature detecting means A gas concentration correction unit that corrects the gas concentration detected by the gas concentration, and an alarm determination that determines a corresponding alarm among a plurality of predetermined alarms based on the gas concentration obtained by the gas concentration correction by the gas concentration correction unit A gas leak alarm device comprising: means; alarm means for issuing an alarm according to the alarm determined by the alarm determination means; and a built-in timer.
When an alarm is determined by the alarm determination means, the time set in the built-in timer for writing the content of the determined alarm and the gas concentration detected by the gas concentration detection means to the nonvolatile memory While it does not elapse, it repeats with a predetermined time period, and when there is no alarm, it stops writing to the non-volatile memory ,
When the time set in the built-in timer has elapsed, write time data to the nonvolatile memory,
If we recognize that the time data has been counted for several days,
Write the output data of the gas concentration detector to the nonvolatile memory.
A gas leak alarm characterized by that.

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