JP5350868B2 - Gas alarm - Google Patents

Description

  The present invention relates to a gas alarm device, and in particular, a gas sensor for detecting a gas concentration of a detection target gas, an alarm generating means for generating an alarm when the gas concentration detected by the gas sensor is equal to or higher than an alarm value, and the alarm An alarm stop operation means for performing an operation for stopping the alarm, and an alarm stop means for forcibly stopping the alarm for a certain time when the operation of the alarm stop operation means is performed when the alarm is generated. The present invention relates to a gas alarm provided with

  Examples of the gas alarm device described above include a gas leak alarm device that generates an alarm by detecting the gas concentrations of LP gas and city gas (detection target gas), and carbon monoxide gas (detection target gas) that is generated during incomplete combustion. Incomplete combustion alarms that detect gas concentrations and generate alarms have been proposed. The gas leak alarm device is provided to start an alarm when the gas concentration of LP gas or city gas is equal to or higher than an alarm value, and then stop when the alarm gas value is equal to or lower than the alarm value. Note that the alarm value of the gas leak alarm is set to a value equal to or less than 1/4 LEL (explosive lower limit). Similarly, the incomplete combustion alarm device is also provided to start an alarm when the gas concentration of the carbon monoxide gas exceeds the alarm value and then stop when the gas concentration becomes the alarm value or less. ing.

  Due to the characteristics of the gas sensor, the gas leak alarms and incomplete combustion alarms mentioned above may cause a temporary gas to be generated during cooking, or an insecticide containing a detection target gas may be sprayed. An alarm may be generated even though no leak has occurred. This alarm continues until the gas concentration detected by the gas sensor falls below the alarm value. If the alarm continues in spite of the fact that the detection target gas has not leaked in this way, there is a risk of inconvenience or panic.

  Thus, a gas alarm device provided with an alarm stop switch (alarm stop operation means) for temporarily stopping an alarm has been proposed (Patent Document 1). According to this gas alarm device, if it is clear that an alarm is generated and the cause of the alarm is, for example, spraying of an insecticide, the user operates the alarm stop switch to force the alarm for a certain time. Can be stopped.

  However, as shown in FIG. 8, there may be a situation in which gas leakage actually occurs while the alarm is forcibly stopped for a certain time T1 by operating the alarm stop switch. In the event that such a situation occurs, in the conventional gas alarm device described above, an alarm is not generated even though the gas concentration is rising above the alarm value, and the alarm stop switch is operated. An alarm is finally generated after a certain time T1 has elapsed. For this reason, in the conventional gas alarm device, there is a risk that the alarm will be delayed and a very dangerous situation will occur.

JP 2005-208957 A

  Therefore, the present invention provides a gas alarm provided with an alarm stop operation section, which can prevent the delay of the alarm and ensure safety even if the detection target gas leaks during the alarm stop. It is an object to provide a vessel.

The invention according to claim 1, which has been made to solve the above-described problem, includes a gas sensor that detects a gas concentration of a detection target gas, and an alarm that generates an alarm when the gas concentration detected by the gas sensor is greater than or equal to an alarm value. Generating means, alarm stop operating means for performing an operation for stopping the alarm, and forcing the alarm for a certain period of time when the alarm stop operating means is operated when the alarm is generated. An alarm stop means for stopping, further comprising a re-alarm generating means for generating an alarm again when the gas concentration detected by the gas sensor rises after the alarm stop by the alarm stop means , The re-alarm generating means is detected by the gas sensor between the time when the alarm is stopped by the alarm stop means and the elapse of a predetermined time shorter than the predetermined time. Without generating re alarm also increased the gas concentrations, characterized in that the gas concentration detected by the gas sensor after a lapse of the predetermined time is provided to generate an alarm again when elevated Located in gas alarm.

According to a second aspect of the present invention, when the re-alarm generating means has detected that the gas concentration exceeds the threshold value larger than the alarm value after the alarm is stopped by the alarm stop means, the gas concentration is increased. The gas alarm device according to claim 1, wherein the gas alarm device is provided so as to generate an alarm again when it is determined that the gas is rising.

The invention according to claim 3 further includes an increase rate calculating means for calculating an increase rate of the gas concentration detected by the gas sensor after the alarm stop by the alarm stop means, and the re-alarm generating means is the increase rate calculating means. A re-alarm is not generated while the rate of increase calculated by the above is equal to or less than a value obtained by adding a predetermined value to the rate of increase calculated first after the alarm stops, and the rate of increase calculated by the rate of increase calculation means 3. The gas alarm device according to claim 1, wherein an alarm is generated again when a value obtained by adding a predetermined value to a rate of increase calculated first after the stop is exceeded. 3. .

  As described above, according to the first aspect of the present invention, when the re-alarm generating means leaks the detection target gas after the alarm stop by the alarm stop means and the gas concentration detected by the gas sensor rises again, Generate an alarm. As a result, even if the detection target gas leaks while the alarm is stopped, a re-alarm can be generated immediately, and the delay of the alarm can be prevented to ensure safety.

  By the way, when the gas alarm is alarmed due to an insecticide or the like, the gas concentration does not decrease immediately even if it is ventilated, but starts decreasing after a while. That is, there is a time lag from when the gas is ventilated until the gas concentration starts to decrease. Due to this time lag, there is a possibility that the gas concentration will rise even if the detection target gas does not leak while the alarm is stopped.

Therefore, according to the first aspect of the present invention, the gas concentration detected by the gas sensor rises after a predetermined time elapses after an alarm that may increase the gas concentration due to the time lag is stopped. Does not generate a re-alarm. Therefore, it is possible to prevent an increase in the gas concentration from when ventilation is performed until the gas concentration starts to be reduced, from being erroneously re-alarmed as leakage of the detection target gas.

According to the second aspect of the present invention, when the gas concentration detected by the gas sensor after the alarm is stopped exceeds a threshold value greater than the alarm value, it is determined that the gas concentration has increased, and the alarm is issued again. Is provided to generate. Therefore, if the gas concentration between the start of ventilation and the gas concentration starts to decrease does not exceed the threshold value, the increase in gas concentration from the start of ventilation until the gas concentration starts to decrease is detected gas. Leakage and false alarms can be prevented.

According to the third aspect of the present invention, the re-alarm is not generated while the increase rate calculated by the increase rate calculating means is equal to or less than a value obtained by adding a predetermined value to the increase rate first calculated after the alarm is stopped. Therefore, it is possible to prevent an increase in the gas concentration from when ventilation is performed until the gas concentration starts to be reduced, from being erroneously re-alarmed as leakage of the detection target gas.

It is a block diagram which shows the structure of the gas alarm device of this invention. It is a flowchart which shows the process sequence of CPU which comprises the gas alarm device in 1st Embodiment. (A)-(C) is a time chart which respectively shows the gas concentration in 1st Embodiment, the output of the gas sensor shown in FIG. 1, and the alarm generation state of the gas alarm device shown in FIG. It is a flowchart which shows the process sequence of CPU which comprises the gas alarm device in 2nd Embodiment. (A)-(C) is a time chart which respectively shows the gas concentration in 2nd Embodiment, the output of the gas sensor shown in FIG. 1, and the alarm generation state of the gas alarm device shown in FIG. It is a flowchart which shows the process sequence of CPU which comprises the gas alarm device in 3rd Embodiment. (A)-(C) is a time chart which respectively shows the gas concentration in 3rd Embodiment, the output of the gas sensor shown in FIG. 1, and the alarm generation state of the gas alarm device shown in FIG. (A)-(C) is a time chart which shows gas concentration, the output of the gas sensor of the conventional gas alarm device, and the alarm generation state of the conventional gas alarm device, respectively.

1st Embodiment Hereinafter, the gas alarm device of the present invention in the first embodiment will be described with reference to FIGS. As shown in the figure, the gas alarm device 1 includes a gas sensor 2, a microcomputer 3 (hereinafter referred to as μCOM), an alarm buzzer 4, an alarm lamp 5, and an alarm stop button 6 as an alarm stop operation means. ing. The gas sensor 2 is a known catalytic combustion type or semiconductor type sensor, and detects the gas concentration of a detection target gas such as city gas, LP gas, or carbon monoxide gas. The μCOM 3 is a computer that controls the entire gas alarm device 1, monitors the gas concentration detected by the gas sensor 2, and controls an alarm buzzer 4 and an alarm lamp 5 described later when the gas concentration exceeds an alarm value. To generate an alarm.

  The μCOM 3 includes a central processing unit (CPU) 31 that performs various processes according to a program, a ROM 32 that is a read-only memory storing a program for processing performed by the CPU 31, and a work that is used in various processes in the CPU 31. And a RAM 33 which is a readable / writable memory having an area, a data storage area for storing various data, and the like. The alarm buzzer 4 is a device that generates a buzzer sound (alarm sound) in accordance with the control of the μCOM 3. The alarm lamp 5 is a light emitting element that emits light according to the control of μCOM 3. The alarm stop button 6 is a button operated when the user wants to stop the alarm.

  Next, operation | movement of the gas alarm device 1 of the structure mentioned above is demonstrated below with reference to FIG. In response to the power-on of the gas alarm device 1, the CPU 31 starts the operation shown in FIG. First, the CPU 31 controls the gas sensor 2 to detect the gas concentration of the detection target gas, and takes in the gas concentration (step S1). Thereafter, the CPU 31 determines whether or not the taken-in gas concentration is equal to or higher than an alarm value (step S2). When the gas concentration detected by the gas sensor 2 is equal to or higher than the alarm value (Y in step S2), the CPU 31 functions as an alarm generation means, sounds the alarm buzzer 4 and lights the alarm lamp 5 to start generating an alarm. (Step S3).

  Thereafter, the CPU 31 determines whether or not the operation of the alarm stop button 6 is being performed (step S4). If the operation of the alarm stop button 6 is not performed (N in step S4), the CPU 31 controls the gas sensor 2 again to detect the gas concentration of the detection target gas, and takes in the gas concentration (step S5). When the user opens the door or window and performs ventilation according to the alarm in step S3, the gas concentration of the detection target gas in the atmosphere around the gas alarm device 1 decreases. Accordingly, when the gas concentration detected by the gas sensor 2 becomes equal to or lower than the alarm value (Y in Step S6), the CPU 31 stops the alarm by the alarm buzzer 4 and the alarm lamp 5 (Step S7), and then returns to Step S1. . Therefore, if the alarm stop button 6 is not operated, the alarm generated from the gas alarm device 1 is generated after the gas concentration becomes equal to or higher than the alarm value and thereafter decreases to the alarm value or lower.

On the other hand, when the gas alarm 1 generates an alarm during spraying of an insecticide or the like, the user operates the alarm stop button 6 and starts ventilation because it is a false alarm due to spraying of an insecticide or the like. When the operation of the alarm stop button 6 is performed (Y in step S4), the CPU 31 functions as an alarm stop unit and immediately stops the alarm even if the gas concentration is not below the alarm value (step S8). Thereafter, the CPU 31 determines whether or not a predetermined time T2 shorter than the predetermined time T1 has elapsed since the alarm was stopped in step S8 (step S9). When the predetermined time T2 has elapsed (Y in step S9), the CPU 31 controls the gas sensor 2 again to detect the gas concentration of the detection target gas, and takes in the gas concentration (step 10).

  At this time, if no new leakage of the detection target gas has occurred and the gas concentration has not increased (N in step S11), the CPU 31 determines whether or not a fixed time T1 has elapsed since the alarm stop in step S8. Judgment is made (step S12). If the predetermined time T1 has elapsed (Y in step S12), the CPU 31 returns to step S1 again. When the process returns to step S1, if the gas concentration is equal to or higher than the alarm value, the process proceeds to step S3 again and an alarm is generated again. Therefore, when the alarm stop button 6 is operated, the alarm is forcibly stopped for a certain period of time T1 unless a new detection target gas leaks after the stop.

  On the other hand, when the detection target gas leaks after the alarm stop in step S8 and the gas concentration increases (Y in step S11), the CPU 31 functions as a re-alarm generating means, and the detection target gas leaks. It is determined that the alarm has occurred, the alarm buzzer 4 is sounded again, and the alarm lamp 5 is turned on to generate a re-alarm (step S13). This re-alarm can notify the user that the detection target gas is leaking. After the re-alarm is generated, the CPU 31 controls the gas sensor 2 again to detect the gas concentration of the detection target gas, and takes in the gas concentration (step 14). If the user has already stopped the ventilation by the re-alarm in step S13, the ventilation is started again. As a result, when the gas concentration becomes equal to or lower than the alarm value (Y in step S15), the CPU 31 stops the alarm (step S16) and returns to step S1 again.

  Next, operation | movement of the gas alarm device 1 mentioned above is demonstrated in detail with reference to FIG. When a user sprays an insecticide containing a detection target gas around the gas alarm device 1, the gas concentration of the detection target gas of the gas alarm device 1 rises and the gas concentration detected by the gas sensor 2 exceeds the alarm value. Then, an alarm is generated from the gas alarm device 1. When the user starts ventilation in response to this alarm and operates the alarm stop button 6, the alarm from the gas alarm device 1 stops. By the way, even if ventilation is started, the gas concentration does not decrease immediately but begins to decrease after a while. That is, there is a time lag T3 from when the air is ventilated until the gas concentration starts to decrease. This time lag T3 may increase the gas concentration after ventilating and stopping the alarm.

  The above-described gas alarm device 1 prevents a re-alarm from being generated even if the gas concentration rises after a predetermined time T2 elapses after an alarm stop that may increase the gas concentration due to the time lag T3. . Accordingly, it is possible to prevent an erroneous false alarm that a gas concentration increase during the period from when ventilation is performed until the gas concentration starts to decrease as a new detection target gas leaks. When the gas alarm device 1 detects an increase in gas concentration after a predetermined time T2 has elapsed after stopping the alarm, the gas alarm device 1 determines that a new gas to be detected has leaked and generates a re-alarm. As a result, even if the detection target gas leaks while the alarm is stopped, a re-alarm can be generated immediately, and the delay of the alarm can be prevented to ensure safety.

Second Embodiment Next, the gas alarm device of the present invention in the second embodiment will be described. In addition, since the structure of the gas alarm device 1 in 2nd Embodiment is the same as that of 1st Embodiment, detailed description is abbreviate | omitted here. Next, operation | movement of the gas alarm device 1 of 2nd Embodiment is demonstrated below with reference to FIG.4 and FIG.5. In FIG. 4, the same steps as those performed by the gas alarm device 1 already described in the first embodiment with reference to FIG. 2 described above are denoted by the same reference numerals, and detailed description thereof is omitted. In response to the power-on of the gas alarm device 1, the CPU 31 starts the operation shown in FIG.

  Since the operation of the CPU 31 from step S1 to S8 is the same as that in the first embodiment described above, detailed description thereof is omitted. After stopping the alarm in step S8, the CPU 31 controls the gas sensor 2 again to detect the gas concentration of the detection target gas, and takes in the gas concentration (step S17). Next, as shown in FIG. 5, when the captured gas concentration becomes equal to or greater than a threshold value that is larger than the alarm value (Y in Step S <b> 18), the CPU 31 newly detects the detection target gas while the alarm is stopped. It is determined that the gas concentration has increased due to leakage, and a re-alarm is generated (step S13). Thereafter, the CPU performs the operations of steps S14 to S16 as in the first embodiment. On the other hand, if the gas concentration taken in is less than or equal to the threshold value (N in step S18), the CPU 31 proceeds to step S12, and after a certain time T1 has elapsed since the alarm was stopped (Y in step S12), returns to step S1 again. .

  As described above, according to the gas alarm device 1, it is determined that the gas concentration has increased when the gas concentration detected by the gas sensor 2 after the alarm is stopped exceeds a threshold value greater than the alarm value, and then again. It is provided to generate an alarm. Therefore, if the gas concentration between the start of ventilation and the gas concentration starts to decrease does not exceed the threshold value, the increase in gas concentration from the start of ventilation until the gas concentration starts to decrease is detected gas. Leakage and false alarms can be prevented.

Third Embodiment Next, a gas alarm device according to a third embodiment of the present invention will be described. In addition, since the structure of the gas alarm device 1 in 3rd Embodiment is the same as that of 1st Embodiment, detailed description is abbreviate | omitted here. Next, operation | movement of the gas alarm device 1 of 3rd Embodiment is demonstrated below with reference to FIG.6 and FIG.7. In FIG. 6, the same steps as those performed by the gas alarm device 1 already described in the first embodiment with reference to FIG. 2 are given the same reference numerals, and detailed description thereof is omitted. In response to the power-on of the gas alarm device 1, the CPU 31 starts the operation shown in FIG.

Since the operation of the CPU 31 from step S1 to S8 is the same as that in the first embodiment described above, detailed description thereof is omitted. After stopping the alarm in step S8, the CPU 31 waits for the ΔT time to elapse (Y in step S19), and again controls the gas sensor 2 to detect the gas concentration of the detection target gas. A value obtained by subtracting the detected gas concentration is calculated as an increase rate ΔV ₀ detected first after the alarm is stopped (step S20).

Thereafter, after waiting for ΔT time since the previous rate of increase was calculated (Y in step S21), the CPU 31 controls the gas sensor 2 again to detect the gas concentration of the detection target gas, and the gas concentration detected this time A value obtained by subtracting the gas concentration detected last time is calculated as an increase rate ΔV _n (step S22). Thereafter, the CPU 31 determines whether or not the increase rate ΔV _n calculated in step S22 exceeds a value (ΔV ₀ + α) obtained by adding a predetermined value α to the increase rate ΔV ₀ calculated in step S20 (step S23).

As long as no new detection gas leaks after the alarm is stopped and the rate of increase in the gas concentration detected by the gas sensor 2 is low, ΔV ₀ + α ≧ ΔV _n (N in step S23), and the CPU 31 proceeds to step S12. . In step S12, the CPU 31 returns to step S21 again if a fixed time has not elapsed since the alarm stop (N in step S12). By repeating these steps S21 and S22, as shown in FIG. 7, the calculation is performed as increasing rates ΔV ₁ , V ₂ ... Every ΔT time after the alarm is stopped.

On the other hand, when a new detection gas leaks after the alarm is stopped and the gas concentration detected by the gas sensor 2 rapidly increases, ΔV ₀ + α <ΔV _n (Y in step S23), and the CPU 31 proceeds to step S13. Generate a re-alarm. Thereafter, the CPU 31 performs the operations of steps S14 to S16 as in the first embodiment. The predetermined value α described above does not satisfy ΔV ₀ + α <ΔV _n even if a measurement error and fluctuation of the gas concentration occur during the time lag T3 described above and the gas concentration rises. Is set to a value.

According to the gas alarm device 1 described above, a re-alarm is generated while the rate of increase ΔV _n calculated every ΔT time is equal to or less than the value obtained by adding the predetermined value α to the rate of increase ΔV ₀ calculated first after the alarm is stopped. do not do. Therefore, it is possible to prevent an increase in the gas concentration from when ventilation is performed until the gas concentration starts to be reduced, from being erroneously re-alarmed as leakage of the detection target gas.

Further, in the first embodiment described above, a re-alarm is not generated even if the gas concentration detected by the gas sensor 2 increases during a predetermined time T2 after the alarm is stopped. In combination with the second embodiment, the alarm may be re-alarmed if the gas concentration is equal to or higher than the threshold even after the predetermined time T2 has elapsed since the alarm was stopped. In combination with the third embodiment, a re-alarm may be generated if ΔV ₀ + α <ΔV _n even before the predetermined time T2 has elapsed since the alarm was stopped.

In the second embodiment described above, the re-alarm is not generated until ΔV ₀ + α <ΔV _n is satisfied. However, even before ΔV ₀ + α <ΔV _n is satisfied in combination with the third embodiment, for example. A re-alarm may be generated if the gas concentration exceeds a threshold value.

  Further, the above-described embodiments are merely representative forms of the present invention, and the present invention is not limited to the embodiments. That is, various modifications can be made without departing from the scope of the present invention.

2 Gas sensor 6 Alarm stop button (alarm stop operation means)
31 CPU (alarm generating means, alarm stopping means, re-alarm generating means)
T1 fixed time

Claims (3)

A gas sensor for detecting the gas concentration of the detection target gas, an alarm generating means for generating an alarm when the gas concentration detected by the gas sensor is equal to or higher than an alarm value, and an alarm stop operation for performing an operation for stopping the alarm A gas alarm device comprising: and an alarm stop means for forcibly stopping the alarm for a predetermined time when the alarm stop operation means is operated when the alarm is generated,
Re-alarm generating means for generating an alarm again when the gas concentration detected by the gas sensor rises after the alarm stop by the alarm stop means ,
The re-alarm generating means generates a re-alarm even if the gas concentration detected by the gas sensor rises between the time when the alarm is stopped by the alarm stop means and the elapse of a predetermined time shorter than the predetermined time. In addition, the gas alarm device is provided so that an alarm is generated again when the gas concentration detected by the gas sensor increases after the predetermined time has elapsed. The re-alarm generating means determines that the gas concentration has increased when the gas concentration detected by the gas sensor has exceeded a threshold value greater than the alarm value since the alarm was stopped by the alarm stop means. The gas alarm device according to claim 1, wherein the gas alarm device is provided so as to generate an alarm again. Further comprising an increase rate calculating means for calculating an increase rate of the gas concentration detected by the gas sensor after the alarm stop by the alarm stop means;
The re-alarm generating means does not generate a re-alarm while the rate of increase calculated by the rate of increase calculating means is equal to or less than a value obtained by adding a predetermined value to the rate of increase calculated first after the alarm stop, and the increase The alarm is generated again when the rate of increase calculated by the rate calculation means exceeds a value obtained by adding a predetermined value to the rate of increase calculated first after the alarm is stopped. Item 3. The gas alarm device according to Item 1 or 2.

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