JPH09251588A - Fire alarm system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To exclude the influence of noises in discriminating the stain of a smoke sensor outputting a value corresponding to a smoke density from its output value. SOLUTION: A fire alarm system is provided with a high stain discriminating part 6 discriminating the stain which ascends the output value of the smoke sensor 1 and a low stain discriminating part 7 discriminating the stain which descends the value. The high stain discriminating part 6 repeats the comparison of the whole output values of the smoke sensor 1 within a prescribed time with a least upper bound value at every prescribed time. When the whole output values continuously exceeds the least upper bound value for the portion of a prescrived number, it is judged that the smoke sensor 1 is stained. The low stain discriminating part 7 repeats the comparison of the lowest output value within the output values of the smoke sensor 1 within the prescribed time with a low limit value at every prescribed time. Then, it is judged that the smoke sensor 1 is stained when the lowest output value continuously exceeds the lower limit value for the portion of the prescribed number. When the stain for descending the output value is discriminated, alarm which is different from that at the time of discriminating the stain for ascending the output value is issued.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fire alarm system equipped with a smoke detector that outputs a value according to smoke concentration, and more particularly, to a fire that detects dirt in a detection chamber of a scattered light smoke detector. Regarding alarm system.

[0002]

2. Description of the Related Art A scattered light type smoke detector that outputs a value according to smoke concentration is a detection chamber into which smoke flows, a light emitting element arranged in the detection chamber, and a light directly receiving light from the light emitting element. The light receiving element is arranged in the detection chamber so as not to do so.
And in the smoke sensor, when smoke flows into the detection chamber, the light from the light emitting element is scattered by the smoke particles,
The scattered light is received by the light receiving element,
The smoke density is detected based on the light receiving level of the light receiving element.

The smoke detector outputs a value corresponding to the received light level to a receiver of the fire alarm system, and the input value is preset in the receiver. If it is more than the value, it is judged that a fire has occurred. Further, in the above smoke detector, when there is no smoke in the detection chamber, the light receiving element receives a certain level of light based on the reflection on the inner wall surface of the detection chamber. Although the output value should be constant, if the inside of the detection chamber becomes dirty with dust, soot, or the like, the amount of reflected light on the inner wall surface of the detection chamber changes, and the output value changes.

Further, when whitish dust or the like adheres to the detection chamber, the amount of reflected light in the detection chamber increases, and when black soot or the like adheres to the detection chamber, the amount of reflected light in the detection chamber decreases. Depending on how dirty the detection chamber is, the output value from the smoke detector may change in the ascending direction or in the decreasing direction. It is difficult to predict.

As described above, in the fire alarm system, a fire is judged when the output value from the smoke detector exceeds a predetermined value, but when there is no smoke in the detection room. When the output value of the smoke detector changes in the upward direction due to dirt, the output value may reach the above-mentioned predetermined value even if the scattered light slightly increases in the detection chamber. That is, the smoke detector may become sensitive and the number of false alarms may increase.

On the contrary, when the output value of the smoke sensor changes in a downward direction due to dirt in a state where there is no smoke in the detection chamber, even if the scattered light in the detection chamber increases due to a fire, the output is increased. The value may not reach the above predetermined value. In other words, the smoke detector becomes insensitive and may not be judged as a fire even if a fire actually occurs, or it may not be judged as a fire until the amount of smoke due to the fire increases and the judgment of the fire may be delayed. There is.

Proposals have already been made for such a problem. For example, in the self-ignition alarm system disclosed in Japanese Patent Laid-Open No. 7-6274, the value output from the smoke detector for each predetermined time (one hour). In addition to obtaining the average value, the minimum value within a certain period (8 days from the present time) of the average values is obtained, and it is determined whether or not the obtained minimum value exceeds the preset judgment level range of dirt. ing.

The judgment level is an upper judgment level for white dirt (dirt that increases the output value of the smoke sensor) and a lower limit for black dirt (dirt that decreases the output value of the smoke sensor). If the minimum value exceeds the upper or lower judgment level range, the smoke sensor will be notified of the contamination, or the output from the smoke sensor due to the contamination will be output. The output value (fire determination level) of the smoke detector determined to be a preset fire is corrected upward or downward according to the deviation of the value level.

[0009]

By the way, in the above-mentioned self-fire alarm system, the minimum value is obtained from these average values after obtaining the average value for each predetermined time. For example, there is a high possibility that it will be affected and changed by external noise such as cigarette smoke, steam, and vehicle exhaust gas.

That is, even if the noise is transient, the average value per predetermined time will change, so that the fluctuation of the output value of the smoke sensor due to the noise is judged to be dirty of the smoke sensor and is erroneously reported. There is a possibility. In addition, in the above-mentioned self-fire alarm system, since the minimum value of each average value within a certain period is compared with the dirt determination level,
If there is a time period during which noise that increases the smoke detector output value does not occur within a certain period, noise that increases the smoke detector output value may be removed, but even once within a certain period. If noise occurs in the direction of decreasing the output value of the smoke sensor, the average value including the noise is likely to be selected as the minimum value to be compared with the determination level within a certain period.

That is, the average value including noise in the direction of decreasing the output value of the smoke sensor is compared with the determination level, and the average value including the noise exceeds the determination level on the lower limit side, and it is determined that the noise is dirty. Actually, although most of the average values within a certain period exceed the upper limit judgment level, the minimum average value lowered by the noise is below the upper limit judgment level. Dirt may not be reported.

Therefore, the determination of dirt is inaccurate due to noise, and in particular, work is performed 24 hours a day, noise is generated regardless of day or night, and noise is not generated at all for a predetermined time or longer. It is difficult to determine the dirt in a place where there is a possibility that there is no belt or in an indoor parking lot where black exhaust gas may be generated.

Further, as described above, when white stains that increase the output value of the smoke detector occur, the damage may be such that the number of false alarms increases, but black that decreases the output value of the smoke detector. If a stain occurs, the alarm may not work even if a fire occurs.While the importance of white stains and black stains is different, the upper limit side of the self-fire alarm system The same process of notifying the dirt or correcting the fire judgment level is performed depending on whether the judgment level is exceeded or the lower judgment level is exceeded. Differences in importance are not considered.

The present invention has been made in view of the above circumstances, and it is possible to accurately determine the dirt of a smoke sensor in consideration of the influence of noise, and also, based on the difference in importance depending on the kind of dirt. It is an object of the present invention to provide a fire alarm system that informs of stains.

[0015]

A fire alarm system according to claim 1 of the present invention has a smoke detector for outputting a value according to smoke concentration and a means for detecting dirt on the smoke detector. A predetermined output value of the output values input from the smoke sensor within a predetermined time set in advance and a preset lower limit value and upper limit value are repeatedly compared every predetermined time period. And, the output value comparing means for repeatedly determining whether or not the predetermined output value exceeds one of the lower limit value and the upper limit value, and the predetermined value by the output value comparing means. When it is determined that the output value continuously exceeds one of the upper limit value and the lower limit value, the number of determinations is counted, and the predetermined output value is the upper limit value by the output value comparison means. And of the lower limit Counting means for clearing the number of judgments counted when it is not judged to have continuously exceeded one range, and whether or not the number of judgments counted by the counting means exceeds a preset predetermined number. A count value comparing means for determining whether the smoke detector is dirty when the count value comparing means determines that the number of determinations exceeds the predetermined number. This is the means for solving the above problems.

According to the above-mentioned structure, every predetermined time, a predetermined output value among the output values of the smoke detector input within the predetermined time is compared with the upper limit value and the lower limit value, and the predetermined value is compared. It is determined whether or not the output value of 1 exceeds one of the upper limit value and the lower limit value. When it is determined that the predetermined output value continuously exceeds one of the upper limit value and the lower limit value, the number of determinations is counted.

If it is not determined that the predetermined output value continuously exceeds one of the upper limit value and the lower limit value, the determination count is cleared. Then, when the number of determinations exceeds the predetermined number, it is notified that the smoke detector is dirty. That is, when the predetermined output value within the predetermined time exceeds the one of the upper limit value and the lower limit value continuously over the predetermined number of times or more, the smoke sensor is contaminated. It is decided that it will be reported.

Therefore, if the predetermined number is set to be sufficiently large, even if the output value of the smoke sensor temporarily exceeds the upper limit value and the lower limit value due to transient noise, the When the predetermined output value within the predetermined time and the upper limit value and the lower limit value are repeatedly compared at predetermined time intervals, due to transient noise, the predetermined output value is continuously increased by the predetermined number by the predetermined number. Since it is unlikely that either one of the lower limit values will be exceeded continuously, fluctuations in the output value of the smoke sensor due to transient noise are not judged as contamination of the smoke sensor.

In other words, while the output value of the smoke sensor fluctuates continuously due to dirt, the output value of the smoke sensor fluctuates temporarily due to transient noise, so the smoke sensor output is fluctuated. By determining whether or not the fluctuation of the output value of the smoke detector continues for a relatively long period of time, it is possible to prevent the transient noise from being mistakenly determined to be the smoke detector. it can.

The smoke detector may be of any type as long as it can output a value corresponding to smoke density.
In addition, each means is a dedicated logic circuit or a general-purpose MP.
It is realized by U (microprocessor unit) or the like. The above-mentioned predetermined time and the above-mentioned predetermined number are determined in consideration of the time during which transient noise continuously occurs, the frequency of noise, and the like.

The predetermined output value may be, for example, all output values within a predetermined time period, the lowest output value within the predetermined time period, or the output value within the predetermined time period. Of these, the highest output value may be used, or in some cases, the output value arbitrarily selected from the output values within a predetermined time period.

In the fire alarm system according to claim 2 of the present invention, the output value comparing means is the minimum output value input within the predetermined time as the predetermined output value to be compared with the lower limit value. Was selected and the selected lowest output value was compared with the lower limit value as the means for solving the above problems.

According to the above configuration, since the lowest output value of the output values input within the predetermined time is used as the predetermined output value to be compared with the lower limit value, for example, within the predetermined time. When noise that increases the output value is mixed in, it is highly possible that the output value that was not affected by the noise can be selected as the predetermined output value instead of the output value that was increased by the noise. The effect of can be eliminated.

When noise that lowers the output value is mixed within a predetermined time, there is a high possibility that the output value affected by the noise will be selected as the predetermined output value. Only when the predetermined output value exceeds the lower limit value continuously for the above predetermined number, it is judged as dirty,
Eventually, it is possible to eliminate the influence of noise that lowers the output value.

Further, the lowest output value among the output values input within the predetermined time is compared with the lower limit value to determine whether or not the lowest output value exceeds the range of the lower limit value. This is the same configuration as determining whether or not one of the output values within the predetermined time has exceeded the lower limit value.

In the fire alarm system according to claim 3 of the present invention, the output value comparing means is the highest output value input within the predetermined time as the predetermined output value to be compared with the upper limit value. Was selected and the highest output value selected was compared with the upper limit value as the means for solving the above problem.

According to the above configuration, since the highest output value of the output values input within the predetermined time is used as the predetermined output value to be compared with the upper limit value, for example, within the predetermined time. When noise that lowers the output value is mixed in, the output value that is not affected by the noise is more likely to be selected as the predetermined output value instead of the output value that is reduced by the noise. The effect of can be eliminated.

When noise that raises the output value is mixed within a predetermined time, there is a high possibility that the output value affected by the noise will be selected as the predetermined output value. Only when the predetermined output value exceeds the upper limit value continuously for the predetermined number, it is judged as dirty,
Finally, the influence of noise that raises the output value can be eliminated.

The highest output value among the output values input within the predetermined time is compared with the upper limit value to determine whether or not the highest output value exceeds the upper limit range. This is the same configuration as determining whether or not even one of the output values within the predetermined time exceeds the upper limit value.

In the fire alarm system according to claim 4 of the present invention, the output value comparison means selects all output values input within the predetermined time as the predetermined output value to be compared with the upper limit value. Then, the means for solving the above-mentioned problems is to compare all of these output values with the above upper limit value and determine whether or not all the output values have exceeded the above upper limit value.

According to the above configuration, as the predetermined output value to be compared with the upper limit value, all output values input within the predetermined time are selected, and all the output values are compared with the upper limit value. , It is determined whether or not all the output values exceed the above upper limit value, so, for example, noise that increases the output value within a predetermined time is mixed, and some output values within the predetermined time increase. Also, the influence of noise can be eliminated unless all output values within a predetermined time are increased by noise.

Even if all the output values within a predetermined time increase due to noise, it is judged as dirty only when the predetermined output value continuously exceeds the upper limit value by the predetermined number as described above. Therefore, it is possible to eliminate the influence of noise that eventually increases the output value. Further, determining whether or not all the output values within the predetermined time exceeds the upper limit value means determining whether or not the lowest output value of the output values within the predetermined time exceeds the upper limit value. It has the same structure as

In the fire alarm system according to a fifth aspect of the present invention, the output value comparing means selects all the output values input within the predetermined time as the predetermined output value to be compared with the lower limit value. Then, the means for solving the above problems is to compare all of these output values with the lower limit value and determine whether or not all the output values have exceeded the lower limit value.

According to the above construction, as the predetermined output value to be compared with the lower limit value, all output values input within the predetermined time are selected, and all of these output values are compared with the lower limit value. , It is determined whether or not all the output values have exceeded the above lower limit value, so, for example, noise that decreases the output value within a predetermined time is mixed, and some output values within the predetermined time decrease. Also, the influence of noise can be eliminated unless all output values within a predetermined time are reduced by noise.

Even if all the output values within the predetermined time are reduced by noise, it is judged as dirty only when the predetermined output value continuously exceeds the lower limit value by the predetermined number as described above. Therefore, it is possible to eliminate the influence of noise that finally reduces the output value. Further, determining whether or not all the output values within the predetermined time period have exceeded the above lower limit value means determining whether or not the highest output value among the output values within the predetermined time period has exceeded the above lower limit value. It has the same structure as

In the fire alarm system according to a sixth aspect of the present invention, the alarm means outputs the predetermined output value continuously exceeding the upper limit value, and the number of determinations counted by the counting means is a predetermined number. Means for solving the above-mentioned problem is to make different notifications when the predetermined output value exceeds the lower limit value and when the determination count counted by the counting means exceeds the predetermined number. And

According to the above configuration, the case where the output value exceeds the upper limit value, that is, the above-mentioned white stain occurs, and the case where the output value exceeds the lower limit value, that is, the above-mentioned black stain occurs. Then, a different notification is given.
As mentioned above, the influence of white stains is a problem that false alarms increase, while the influence of black stains is a serious problem that the fire alarm system does not operate even if a fire occurs. By giving different notifications depending on the stain, it is possible to deal more urgently when it is notified that black stain has occurred than when it is notified that white stain has occurred.

[0038]

BEST MODE FOR CARRYING OUT THE INVENTION A fire alarm system according to an embodiment of the present invention will be described below with reference to the drawings. FIG.
FIG. 3 is a block diagram for explaining the basic configuration and function of the fire alarm system of this example.

As shown in FIG. 1, the fire alarm system of this example has a plurality of smoke detectors 1 ...
, And the smoke detectors 1 ... Connected by a signal line 2 and a receiver 3 provided in a management room or the like. The smoke detectors 1 ... are the scattered light type smoke detectors described in the above-mentioned conventional example, and are well-known ones adapted to transmit an output value corresponding to the smoke concentration to a receiver, and a light receiving device (not shown). The analog value output from the element is converted into a digital value, and the output value converted by the data communication is transmitted to the receiver 3 via the signal line 2.

Further, the receiver 3 has an interface 4 for receiving data such as output values output from the smoke detectors 1 ... And whether or not a fire has occurred from the output values of the smoke detector 1. Of the smoke detector 1 of the smoke detector 1 ... from the output value of the smoke detector 1 ... The high-smudge determination unit 6 that determines whether or not stains (hereinafter, may be abbreviated as high-smudge) that increase the output value of the high-smudge has occurred, and notifies when the high-smudge has occurred; From the output value of ..., it is determined whether or not dirt (which may be abbreviated as low pollution hereinafter) that reduces the output value of the smoke sensor 1 ... out of the dirt in the detection chamber (not shown) of the smoke sensor 1 ... However, when the low-smudge has occurred, the low-smudge determination unit 7 that notifies the low-smudge is provided.

The interface 4 is for data communication with the smoke detectors 1 ... And performs data communication with the smoke detector 1 by a polling method. That is, the receiver 3 side sequentially sends a command indicating the transmission permission with the address of each smoke detector 1 ..., and each smoke detector 1 ... Outputs in response to the command with its own address. The data including the value is sent back to the receiver 3.

In this example, each smoke sensor 1 ... Sends data to the receiver 3 at a rate of once for about 3 seconds. Although various information is incorporated in the data transmitted from the smoke detectors 1, ..., The fire discrimination unit 5, the high contamination discrimination unit 6, and the low contamination discrimination unit 7 are connected via the interface 4. The output value data indicating the smoke density is input.

Now, the data of the output value indicating the smoke density will be described. FIG. 2 shows the correspondence between the output level (hexadecimal number) and the determination result. As shown in FIG. 2, the level of “0C” or higher in the output value levels is a level determined to be a fire, and “0C” is a fire determination level for determining a normal state and a fire state. Becomes In addition, in FIG. 2, the fire determination level "0C"
Illustration of the above parts is omitted.

The level range of "04" to "07" is a normal level. Also, "01" to "03"
The level range of is a level at which the smoke sensor 1 is determined to be low-smudged by the low-smudge determination unit 7, and is “03”.
Is a low stain determination level (lower limit). In addition, "0
The level range of 8 "or higher is the level at which the smoke detector 1 is determined to be highly soiled by the highly soiling determination unit 6,
"08" is the high stain determination level (upper limit value). As described above, when the level becomes "0C" or higher, the fire determination unit 5 determines that there is a fire.

When the level of the output value is "00", no light can be detected by the light receiving element (not shown) of the smoke detector 1 ... Since this is not possible, a failure determination unit (not shown) determines that the light receiving element (not shown) or the light emitting element (not shown) is in failure. The fire determination unit 5 includes a fire determination unit 5a that determines whether or not there is a fire based on the output values from the smoke detectors 1 ...
This is a well-known device including a fire alarm unit 5b for notifying the occurrence of a fire.

The fire judging section 5a judges whether or not the level of the output value inputted from each smoke detector 1 ... Through the interface 4 is the above-mentioned fire judging level "0C" or more. If the output value is "0C" or more, a signal indicating the occurrence of a fire is output to the fire alarm unit 5b. Fire alarm part 5
b is equipped with a buzzer, a sound emitting device such as a siren, a warning light, etc., and when a signal indicating the occurrence of a fire is input from the fire determination unit 5a, the occurrence of a fire is notified. There is.

The above-mentioned high dirt determination unit 6 is provided with the interface 4
An input unit 6a for storing an output value input from each smoke detector 1 through a storage unit 6b, which will be described later, and an input output value for each smoke detector 1 ... High-level comparison for determining whether or not the output value stored in the storage unit 6b for each smoke sensor 1 in the storage unit 6b within a predetermined time is equal to or higher than the high stain determination level "08". Part 6c
And a counter 6d that increments (+1) the count value when the high-level side comparison unit 6c determines that the count value is high, and whether or not the count value of the counter 6d is equal to or greater than a preset predetermined number. A count value comparing unit 6e for determining whether the high stain resistance is high and a high stain warning unit 6f for notifying that high stain has occurred when the count value comparing unit 6e determines that the count value is equal to or greater than a predetermined number. Is.

It should be noted that the high pollution determination unit 6 determines the occurrence of the high pollution for each smoke sensor 1 ... However, since the description is complicated, one smoke sensor 1 will be described below. Correspondingly explained. The input unit 6a is provided in the receiver 3,
Each time a signal is input from the timing unit 8 that generates timing, the output value (stored value) of the smoke detector 1 stored in the storage unit 6b is cleared until the next signal is input from the timing unit 8. During the predetermined time, all output values input from the smoke detector 1 are stored in the storage unit 6b about every 3 seconds.

The storage section 6b stores all output values from the smoke sensor 1 input within a predetermined time as described above. The high-level side comparing unit 6c receives all the output values within the predetermined time before the output value of the smoke sensor 1 within the predetermined time stored in the storage unit 6b after the signal is input from the time counting unit 8 is erased. Is higher than "08" which indicates high pollution.

Then, the high-level side comparing section 6c instructs the counter 6d to count up when all the levels of the output values stored in the storage section 6b within a predetermined time indicate high pollution. A signal is output, and if not, a reset signal is output to the counter 6d to clear the count value. Therefore, when all the output values continuously show high pollution at every predetermined time, the count value of the counter 6d is incremented at every predetermined time, and all the output values are high pollution determination level (08) even once. When the above state is not reached, the count value of the counter 6d is cleared.

The count value comparison unit 6e determines whether or not the count value of the counter 6d is equal to or greater than a preset predetermined number, and the count value of the counter 6d is equal to or greater than the predetermined number. In this case, a signal indicating that high pollution has occurred is output to the high pollution alarm unit 6f. The high-fouling alarm unit 6f includes a sound emitting device, a warning light, a display device, a printing device, and the like, and notifies that the smoke sensor 1 is dirty (highly dirty) for increasing its output value. It is a thing.

According to the high contamination determination unit 6 as described above, when the output value of the smoke sensor 1 is temporarily increased due to transient noise, the count value of the counter 6d is increased during that time. However, if the output value from the smoke detector becomes equal to or lower than the high pollution level even once even after the transient noise disappears, the count value is reset, so the count value comparison unit 6e If the predetermined number in 1 is set to be sufficiently large, transient noise will not be determined to be highly dirty. The predetermined time and the predetermined number are determined in consideration of the continuous occurrence time and frequency of transient noise.

The low-fouling discrimination section 7 is the interface 4
And a comparison input unit 7a for storing the lowest output value of the output values within a predetermined time input from each smoke detector 1 through a low output value storage unit 7b described later, and finally within a predetermined time. The lowest output value among the above output values of each smoke detector 1 ...
The low output value storage section 7b stored for each smoke detector, and the lowest output value within a predetermined time stored for each smoke sensor 1 ... In the low output value storage section 7b is the low stain determination level "03" or less. The low-level side comparison unit 7c that determines whether or not the counter 7 and the counter 7 that increments the count value (+1) when the low-level side comparison unit 7c determines low pollution.
d and a count value comparison unit 7 for determining whether or not the count value of the counter 7d is equal to or greater than a predetermined value set in advance.
e, and a low stain warning unit 7f for notifying that low stain has occurred when the count value comparing unit 7e determines that the count value is equal to or greater than a predetermined value.

The low-smudge determination unit 7 determines the occurrence of low-smudge for each smoke sensor 1. However, since the description is complicated, one smoke sensor 1 will be described below. And explain. The comparison input unit 7a is provided in the receiver 3,
The output value of the smoke sensor 1 stored in the low output value storage unit 7b is cleared every time a signal is input from the timing unit 8 that generates timing.

Further, the comparison input unit 7a stores the input output value as a low output value when the output value is input from the smoke sensor 1 with the data in the low output value storage unit 7b being cleared. It is stored in the section 7b. Further, the comparison input unit 7a, when data is stored in the low output value storage unit 7b, when the output value is input from the smoke sensor 1, the output value input from the smoke sensor 1 and the low output The output value stored in the storage unit 7b is compared, and the lower output value is stored in the low output value storage unit 7b (in the case of the same value, the same).

The low output value storage unit 7b stores the minimum output value among the output values finally input from the smoke sensor 1 within a predetermined time by the processing of the comparison input unit 7a as described above. It is like this. The low-level side comparison section 7c
Before the minimum output value of the smoke sensor 1 within a predetermined time stored in the low output value storage unit 7b by the signal input from the timer unit 8 is erased, the minimum output value is the low stain determination level “03”. "
It is determined whether or not the following ("01" to "03").

When the level of the minimum output value within the predetermined time stored in the low output value storage section 7b indicates low stain, the low level side comparing section 7c displays the counter 7
A signal indicating a count-up is output to d, and if not, a reset signal is output to the counter 7d to clear the count value. Therefore, when even one level of the output value shows low pollution every predetermined time, the count value of the counter 7d is increased every predetermined time, and all output values are lower than the level showing low pollution even once. When it becomes higher, the count value of the counter 7d is cleared.

The count value comparing section 7e determines whether or not the count value of the counter 7d exceeds a preset predetermined number, and the count value of the counter 7d exceeds the predetermined number. In such a case, a signal indicating that low pollution has occurred is output to the low pollution alarm unit 7f. The low-fouling alarm unit 7f is provided with a sound emitting device, a warning light, a display device, and the like, and these are used to notify that the smoke sensor 1 has become dirty (low pollution) that raises its output value. .

According to the low stain determination section 7 as described above, when the output value of the smoke sensor 1 temporarily becomes low due to transient noise, the count value of the counter 7d increases during that time. However, since the count value is reset when the output value from the smoke sensor 1 becomes equal to or higher than the low pollution level for a predetermined time after the transient noise disappears, the count value comparison unit 7e If the predetermined number in 1 is set to be sufficiently large, transient noise will not be determined to be low pollution.

The description of the receiver 3 of the fire alarm system has been given according to the block diagram showing the function of FIG. 1, and in the fire discrimination unit 5, the high pollution discrimination unit 6 and the low pollution discrimination unit 7. These functions can be realized by providing a logic circuit or a memory corresponding to each block except the fire alarm unit 5b, the high pollution alarm unit 6f, and the low pollution alarm unit 7f. The control unit 9 connected to the interface 4 in the unit 3 performs the processing of each block described above.

That is, the control unit 9 is a CPU (not shown).
(Central processing unit), RAM (random access
memory), a ROM (read-only memory), an oscillation circuit, a frequency dividing circuit, and the like, and the storage unit 6b, the low output value storage unit 7b, and the like are memory areas secured on the RAM. Fire determination unit 5a, input unit 6a, high level side comparison unit 6c, comparison input unit 7a, low level side comparison unit 7c, counters 6d, 7d, count value comparison units 6e, 7
Functions such as e are realized by the CPU.

Further, the fire alarm unit 5b and the low pollution alarm unit 7 are also provided.
The f and the high pollution alarm unit 6f are alarm devices connected to the control unit 9. It should be noted that the fire alarm unit 5b and the low pollution alarm unit 7f
The high-fouling alarm unit 6f may be different alarm devices, and if it is possible to issue a distinguishable alarm when a fire occurs, low pollution occurs, or high pollution occurs. For example, it may be one alarm device.

Next, a method of discriminating the dirt of the smoke sensor 1 in the fire alarm system as described above will be described. In addition, in the above-mentioned fire alarm system, a plurality of smoke detectors 1 ... Are provided, and the determination of dirt is performed on each smoke detector 1. However, in order to simplify the description, one smoke detector 1 ... A method for discriminating dirt on the smoke sensor 1 will be described.

First, a method for determining dirt (high dirt) which raises the output value of the smoke detector in the high dirt judging section 6 will be described with reference to the flowchart of FIG. First, by turning on the power of the fire alarm system, the high pollution determination unit 6 starts the high pollution determination process. In this case,
All the stored values in the storage unit 6b are erased (step A
1).

Then, an output value is input from the smoke detector 1 to the high contamination determination section 6 via the interface 4 (step A2). And the input output value, that is,
The input value is stored in the storage unit 6b (step A3). Next, it is determined whether or not the predetermined time has expired based on the signal from the timer unit 8 (step A4).

At this time, if the predetermined time has not elapsed, the process returns to step A2 and the input output value is again stored in the storage section 6b as an input value. That is, all the input values input from the smoke sensor 1 during the predetermined time are stored in the storage unit 6b. Then, when the predetermined time has elapsed, it is determined whether or not all the stored values stored in the storage unit 6b are equal to or higher than the high stain level (08) (step A5).

At this time, if there is even one stored value which is not higher than the high stain level (08), the counter 6d
To clear the count value (step A
6). Then, returning to step A1, the process of deleting all the stored values in the storage unit 6b and storing all the output values from the smoke sensor 1 input within the predetermined time in the storage unit 6b is performed again. On the other hand, if all the stored values stored in the storage unit 6b are equal to or higher than the high stain level (08), the counter 6
The count value of d is incremented (+1) (step A7).

Next, it is determined whether or not the count value of the counter 6d is equal to or greater than a preset predetermined number (step A8). Then, when the count value of the counter 6d is not equal to or larger than the predetermined number, the process returns to step A1, all the stored values in the storage unit 6b are erased, and the output value from the smoke sensor 1 input within the predetermined time The process of storing all the data in the storage unit 6b is performed again.

When the count value of the counter 6d is equal to or larger than the predetermined number, dirt that raises the output value of the smoke sensor 1 occurs, and if the smoke sensor 1 is used as it is, the number of false alarms may increase. The high-fouling alarm unit 6f notifies that there is a possibility (step A9). According to the above high-dirt determination processing, when all the output values of the smoke detector 1 within the predetermined time become the high-dirt level (08) or more, when the predetermined number continues, the high-dirt alarm is issued. The part 6f will operate.

Therefore, when the detection chamber of the smoke sensor 1 becomes white and dirty, the output value of the smoke sensor is naturally high level (08).
Since the above sequence continues, the high stain determination unit 6 determines that the stain (high stain) has occurred. If the predetermined number is set to be sufficiently large, even if the output value of the smoke detector 1 is temporarily increased due to transient noise, all output values of the smoke detector within the predetermined time will be Since it is highly unlikely that the high pollution level (08) or more will continue for the above-mentioned predetermined number, it is possible to reliably prevent the smoke sensor 1 from being erroneously determined to be dirty due to transient noise. You can

Next, a method of discriminating the stain (low stain) that reduces the output value of the smoke sensor in the low stain determining section 7 will be described with reference to the flowchart of FIG. First, by turning on the power of the fire alarm system, the low stain determination unit 7 starts the low stain determination processing. In this case,
The stored value in the low output value storage unit 7b is erased (step B1).

Then, an output value is input from the smoke sensor 1 to the low stain determination section 7 via the interface 4 (step B2). Next, it is determined whether or not the stored value is stored in the low output value storage unit 7b (step B3). At the first stage, since the stored value in the low output value storage unit 7b is erased, it is determined that the stored value is not stored in the low output value storage unit 7b, and the input output value, that is, the input value is Store in the low output value storage unit 7b (step B
5).

Next, based on the signal from the clock section 8, it is judged whether or not the predetermined time has ended (step B6).
At this stage, since the first output value has just been input,
Since there is a margin before the predetermined time, it is determined that the predetermined time has not ended, and the process returns to step B2. And
The output value is again input to the low stain determination unit 7 (step B
2) It is determined whether or not the stored value is stored in the low output value storage unit 7b (step B3).

At this stage, since the input value is previously stored in the low output value storage section 7b, it is determined that the stored value is stored in the low output value storage section 7b. Then, the stored value stored in the low output value storage unit 7b and the output value just input,
That is, the input value is compared and it is determined whether the input value is smaller than the stored value (step B4). When the input value is smaller than the stored value, the stored value stored in the low output value storage unit 7b is erased and the input value is stored in the low output value storage unit 7b.

That is, the value stored in the low output value storage section 7b is updated to the input value, and the process proceeds to the next step B6 (step B5). On the other hand, if it is not determined that the input value is smaller than the stored value, that is, if the input value is determined to be equal to or larger than the stored value, the stored value in the low output value storage unit 7b is not updated. , And proceeds to step B6.

Therefore, since the stored value is updated to the input value only when the input value is smaller than the stored value, the lowest input value is stored in the low output value storage section 7b when this process is repeated. Will be done. Next, it is determined based on the signal from the timekeeping section 8 whether or not the predetermined time has expired (step B6). At this time, if the predetermined time has not elapsed, the process returns to step B2, and again, only the input value lower than the stored value is updated and stored in the low output value storage unit 7b.

That is, the lowest input value of the input values input from the smoke sensor 1 during a predetermined time is extracted and stored in the low output value storage section 7b. Then, when the predetermined time has elapsed, it is determined whether or not the stored value stored in the low output value storage unit 7b as the lowest input value is equal to or lower than the low stain level (03) (step B7). . At this time, if the stored value is not lower than the low stain level (03), the counter 7d is reset to clear the count value (step B8).

Then, returning to step B1, the stored value in the low output value storage section 7b is erased, and the lowest output value out of the output values from the smoke sensor 1 input within the predetermined time is stored in the low output value storage. The processing stored in the unit 7b is performed again. On the other hand, when the stored value stored in the low output value storage unit 7b is equal to or lower than the low stain level (03), the count value of the counter 7d is incremented (+1) (step B9).

Then, it is determined whether or not the count value of the counter 7d is equal to or larger than a preset predetermined number (step B10). If the count value of the counter 7d is not equal to or more than the predetermined number, step B1
Returning to step 1, the stored value in the low output value storage unit 7d is erased, and the lowest output value of the output values from the smoke sensor 1 input within a predetermined time is stored in the low output value storage unit 7d. Do it again.

When the count value of the counter 7d is equal to or more than a predetermined number, dirt that reduces the output value of the smoke detector 1 occurs, and if the smoke detector is used as it is, no alarm is output when a fire occurs. The low-fouling alarm unit 7f notifies that there is a possibility (step B11). Note that, as described above, the dirt that reduces the output value of the smoke sensor is more important than the dirt that increases the output value, so the low-fouling alarm unit 7f
A warning that is clearly different from the warning of the high-fouling warning section 6f is given to notify that urgent action is required.

That is, the level of the alarm when the stain that reduces the output value of the smoke detector 1 is higher than the level of the alarm when the stain that increases the output value of the smoke detector 1 occurs. There is. According to the above low stain determination processing, when the minimum output value of the smoke detector within the predetermined time is equal to or lower than the low stain level (03), the low stain alarm is issued when the above predetermined number continues. The part 7f will operate.

Therefore, when the detection chamber of the smoke detector 1 is stained black, the output value of the smoke detector is naturally low level (0.
Since 3) or less will continue, the low stain determination unit 7 will determine the stain (low stain). Further, if the predetermined number is made sufficiently large, even if the output value of the smoke detector 1 is temporarily reduced due to transient noise, noise is mixed for a predetermined number of times at every predetermined time, It is unlikely that the minimum value of the output values of the smoke detector within the predetermined time will be lower than the low pollution level (08) by the above predetermined number in a row. It can be reliably prevented that the sensor is judged to be dirty.

As described above, in the fire alarm system of this example, when the smoke sensor 1 becomes dirty and the output value of the smoke sensor 1 increases or decreases, it is possible to notify it. It is possible to reliably prevent erroneous determination of noise as dirt. Further, in the fire alarm system of this example, different notifications are performed depending on whether dirt that increases the output value of the smoke sensor 1 is detected or when dirt that decreases the output value of the smoke sensor 1 is detected. Therefore, as a result of the alarm indicating dirt, it is possible to know whether the type of dirt that has occurred increases or decreases the output value of the smoke sensor 1.

Therefore, if it is recognized that the dirt that lowers the output value of the smoke sensor 1 is more important than the dirt that raises it, it is notified that the dirt that lowers the output value of the smoke sensor 1 has occurred. By doing this, you can recognize that you must take immediate action. In addition, in the fire alarm system of this example, when the dirt that reduces the output value of the smoke detector 1 is informed to take an emergency, the dirt that lowers the output value of the smoke detector 1 increases. You can recognize that you have to deal with it urgently, even if you are not aware that it is more important than the stains you cause.

In the above example, the high stain determination unit 6 and the low stain determination unit 7 perform different determination processes, but the high stain determination unit 6 and the low stain determination unit 7 are similar. The determination process may be performed, or the processing method of the high stain determination unit 6 and the processing method of the low stain determination unit 7 may be interchanged. That is, in the high pollution determination unit 7, the output values of all the smoke detectors 1 input within the predetermined time are stored, and whether all the output values within the predetermined time are equal to or higher than the high pollution level (08). Instead of determining whether or not the maximum output value input within a predetermined time is extracted and stored, this maximum output value may be compared with the high pollution level (08).

Further, in the low stain determination section 6, the lowest smoke sensor output value input within a predetermined time is extracted and stored, and this lowest output value is compared with the low stain level (03). Not all smoke detectors that were input within the specified time 1
It is also possible to store the output values of the above and determine whether or not all the output values within the predetermined time are below the low stain level (03).

[0087]

According to the fire alarm system of the first aspect of the present invention, if the predetermined number is sufficiently large,
It is unlikely that the predetermined output value will continuously exceed either the upper limit value or the lower limit value for a predetermined number of times due to transient noise. It is possible to prevent a change in the output value of the smoke detector from being determined to be a smoke sensor stain.

According to the fire alarm system of the second aspect of the present invention, the lowest output value among the output values input within the predetermined time is used as the predetermined output value to be compared with the lower limit value. Therefore, for example, when noise that increases the output value is mixed within a predetermined time, it is possible to select the output value that was not affected by noise as the predetermined output value instead of the output value that was increased by the noise. Is high, the influence of noise that raises the output value can be eliminated.

According to the fire alarm system of the third aspect of the present invention, the highest output value of the output values input within the predetermined time is used as the predetermined output value to be compared with the upper limit value. Therefore, for example, when noise that decreases the output value is mixed within a predetermined time, it is possible to select the output value that was not affected by noise as the predetermined output value instead of the output value that was decreased by the noise. Is high, the influence of noise that lowers the output value can be eliminated.

According to the fire alarm system of the fourth aspect of the present invention, all the output values input within the predetermined time are selected as the predetermined output values to be compared with the upper limit value, and all of these output values are selected. Since the output value is compared with the upper limit value to determine whether all the output values have exceeded the upper limit value, for example, noise that raises the output value within a predetermined time is mixed, Even if some output values increase, the influence of noise can be eliminated as long as all output values within a predetermined time have not increased due to noise.

According to the fire alarm system of the fifth aspect of the present invention, as the predetermined output value to be compared with the lower limit value, all output values input within the predetermined time are selected, and all of these output values are selected. Since the output value is compared with the lower limit value to determine whether all output values have exceeded the lower limit value, for example, noise that lowers the output value within a predetermined time is mixed, and Even if some output values decrease, the influence of noise can be eliminated as long as all output values within a predetermined time have not decreased due to noise.

According to the fire alarm system of the sixth aspect of the present invention, the stain whose output value exceeds the upper limit value, that is, the above-mentioned white stain, and the stain whose output value exceeds the lower limit value, that is, Since different notifications will be made depending on the case where the black stains occur, it is possible to deal more urgently when the notice that the black stains have occurred than when the notice that the white stains have occurred. Becomes

[Brief description of drawings]

FIG. 1 is a block diagram for explaining a fire alarm system according to an example of an embodiment of the present invention.

FIG. 2 is a diagram for explaining a level of an output value of a smoke detector in the fire alarm system of the above example.

FIG. 3 is a flow chart for explaining a method of discriminating whether or not a smoke sensor is dirty in the fire alarm system of the above example.

FIG. 4 is a flow chart for explaining a method of discriminating whether or not the smoke sensor is dirty in the fire alarm system of the above example.

[Explanation of symbols]

 1 Smoke Detector 6 High Contamination Discrimination Section 6c High Level Side Comparison Section (Output Value Comparison Means) 6d Counter (Counting Means) 6e Count Value Comparison Section (Count Value Comparison Means) 6f High Contamination Warning Section (Alarm Means) 7 Low Contamination Discrimination unit 7c Low-level side comparison unit (output value comparison unit) 7d Counter (counting unit) 7e Count value comparison unit (count value comparison unit) 7f Low pollution alarm unit (warning unit)

Claims (6)

[Claims] 1. A fire alarm system having a smoke detector for outputting a value according to smoke concentration, and having means for detecting dirt on the smoke detector, wherein the smoke is detected within a preset time. A predetermined output value of the output values input from the sensor is repeatedly compared with a preset lower limit value and upper limit value at each of the predetermined times, and the predetermined output value is equal to the lower limit value and the upper limit value. Output value comparing means for repeatedly determining whether or not one of the values exceeds one of the ranges, and the output value comparing means determines whether the predetermined output value is one of the upper limit value and the lower limit value. When it is determined that the range has been continuously exceeded, the number of determinations is counted and
Counting means for clearing the counted number of times when the predetermined output value is not judged by the output value comparison means to continuously exceed one of the upper limit value and the lower limit value; Count value comparing means for determining whether or not the number of determinations counted by the counting means exceeds a predetermined number set in advance, and when the count value comparing means determines that the number of determinations exceeds the predetermined number. A fire alarm system comprising: an alarm means for informing that the smoke detector is dirty. 2. The output value comparing means selects the lowest output value of the output values input within the predetermined time as the predetermined output value to be compared with the lower limit value, and selects the lowest selected output value. The fire alarm system according to claim 1, wherein the output value of the fire alarm is compared with the lower limit value. 3. The output value comparing means selects, as the predetermined output value to be compared with the upper limit value, the highest output value among the output values input within the predetermined time, and selects the highest output value. The fire alarm system according to claim 1, wherein an output value of the fire alarm is compared with the upper limit value. 4. The output value comparing means selects, as the predetermined output value to be compared with the upper limit value, all output values input within the predetermined time, and outputs all of these output values as the upper limit value. The fire alarm system according to claim 1 or 2, characterized in that it is determined whether or not all output values exceed the upper limit value by comparing with. 5. The output value comparing means selects, as the predetermined output value to be compared with the lower limit value, all output values input within the predetermined time, and sets all of these output values to the lower limit value. The fire alarm system according to claim 1, 3 or 4, wherein all the output values are compared with each other to determine whether or not all the output values have exceeded the lower limit value. 6. The alarm means outputs the predetermined output value when the predetermined output value continuously exceeds the upper limit value and the determination count counted by the counting means exceeds a predetermined number. The fire alarm according to any one of claims 1 to 5, wherein different alarms are issued when the number of determinations counted by the counting means exceeds the lower limit and the number of determinations exceeds a predetermined number continuously. system.