JPH11185177A - Fire sensor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fire sensor of a simple constitution capable of sensing a fire in a large space, sensing a fire with little smoke by heat and sensing a fire by the detection of smoke or the like. SOLUTION: This fire sensor is provided with a light emitting part 10 for outputting the light of a single wavelength, a mirror part 11 for allowing light outputted from the light emitting part 10 and light outputted from the light emitting part 10 and passed through the monitoring section of the fire interfere to be interferred and outputting them, a light receiving part 13 for receiving interference light made to interfere in the mirror part 11 and outputting electric signals corresponding to the luminance of the received interference light and an arithmetic part 14 for monitoring the fluctuation of the output signals of the light receiving part 13 and sensing the generation of a hot air flow by the fire and the generation of smoke by the fire in the monitoring section based on the fluctuation state of the output signals of the light receiving part 13.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a fire detector for detecting a fire in a large space or the like.

[0002]

2. Description of the Related Art Conventionally, as a fire detector for detecting a fire in a large space, an atrium or the like, there has been a photoelectric separation type fire detector for detecting smoke generated by a fire and detecting the occurrence of the fire. In this method, dust such as soot passes between the light emitting device and the light receiving device, and the occurrence of a fire is detected by dimming light between the light emitting device and the light receiving device.

[0003]

However, in the conventional photoelectric separation type fire detector, the light between the light emitting device and the light receiving device must be dimmed. There were problems such as a delay in the sensing time. Therefore, an ultrasonic fire detecting device for detecting heat at the time of a fire by using an ultrasonic wave as described in JP-A-6-36158 has been proposed. Because of the use of ultrasonic waves, only heat from a fire can be detected, and the detection of smoke due to a fire requires the use of another fire detector.

[0004] Conventionally, coherent radiation of monochromatic light, as described in Japanese Utility Model Publication No. 55-13732, is simultaneously transmitted through a measurement radiation path and a reference radiation path, and both radiation rays are transmitted. Receive the radiation from the path with the same photoelectric device,
Normally, a dimming sensor was proposed in which the radiations from both radiation paths were canceled by interference, but this dimming sensor is used as a fire detector as a measurement radiation path. It detects smoke by detecting smoke and the like generated when a fire enters the building.The detection of heat due to the fire uses the deformation of the housing of the measurement room, which forms the measurement radiation path, due to heat. In order to detect a fire in a space or the like, there is a problem that a large-scale measurement room is required, and its installation becomes difficult, and its installation cost increases.

Therefore, conventionally, a fire in a large space can be detected with a simple structure, a fire can be detected by heat even in a fire with little smoke, and a fire can be detected by detecting smoke or the like at the time of fire. The advent of a fire detector that could be performed was desired.

[0006]

According to the present invention, there is provided a fire detector which emits light of a single wavelength, and outputs light emitted from the light emitting means and a fire monitoring section output from the light emitting means. Interfering means for interfering with the received light, receiving the interfering light interfered by the interfering means, and outputting an electric signal corresponding to the brightness of the received interfering light, and fluctuation of the output signal of the light receiving means Computing means for monitoring the occurrence of hot air flow and the generation of smoke due to a fire in the monitoring section based on the fluctuation state of the output signal of the light receiving means.

[0007]

FIG. 1 is a configuration diagram showing a configuration of a fire detector according to an embodiment of the present invention. In the figure,
Reference numeral 10 denotes a laser emitting unit that outputs a laser beam, 11 denotes a mirror unit that includes a mirror 11a and a half mirror 11b, and transmits and reflects the laser light output from the laser emitting unit 10, and 12 denotes a laser that passes through the mirror unit 11. The reflecting portion 12 reflects light without reflection of energy using a metal mirror (a glass surface on which aluminum is vapor-deposited). Note that a corner mirror may be used instead of the metal mirror for the reflection unit 12. Reference numeral 13 denotes a light receiving unit that receives laser light from the mirror unit 11 and converts the luminance of the input laser light into an electric signal. Reference numeral 14 denotes an arithmetic unit that detects a fire based on the electric signal output from the light receiving unit 13. It is.

The laser light emitting unit 10, the mirror unit 11, and the light receiving unit 13 are affected by the laser light from the laser light emitting unit 10 to the mirror unit 11 and the laser light from the mirror unit 11 to the light receiving unit 13 due to fire or the like. The mirror unit 11 is arranged so as not to receive the light beam.
The section up to is the fire monitoring section. The laser beam input from the laser emitting unit 10 to the light receiving unit 13 via the mirror unit 11 becomes the reference light, passes through the monitoring section from the laser emitting unit 10 and is input to the light receiving unit 13 via the mirror unit 11. The monitored laser light is the monitoring light, and the laser light that interferes with the reference light and the monitoring light is input to the light receiving unit.

Next, the principle of fire detection according to this embodiment will be described. FIG. 2 is an explanatory view for explaining the relationship between the reference light and the monitoring light in the normal state, FIG. 3 is an explanatory view for explaining the state of the fire detector in the event of a fire, and FIG. FIG. 5 is an explanatory diagram for explaining the relationship between the interference light and the monitoring light, and FIG.

FIGS. 2 and 4 show the reference light, and the laser light emitting section 10 → the half mirror 11 b of the mirror section 11 → the mirror 11 a of the mirror section 11 → the mirror section 11.
Is the laser beam that has passed through the path from the half mirror 11b to the light receiving section 13, and indicates the monitoring light 1 and 2. The laser light emitting section 10 → the half mirror 1 of the mirror section 11
1b → reflection part 12 → half mirror 11b of mirror part 11
→ It is a laser beam that has passed through the path of the light receiving unit 13. Further, the difference from the above is caused by the fluctuation of air in the space of the monitoring section, and the amplitude of the actual monitoring light −
The time curve passes between the amplitude-time curves of the monitoring light 1 and the monitoring light 2.

The interference light 1 caused by the reference light and the monitoring light 1 is the interference light 2 caused by the reference light and the monitoring light 2. Further, due to the fluctuation of air in the space of the monitoring section, the amplitude-time curve of the actual interference light passes between the amplitude-time curves of the interference light 1 and the interference light 2 similarly to the monitoring light. .

First, as shown in FIG. 1, when there is no hot air flow due to a fire in the monitoring section during normal times and there is no rapid change in air density due to the hot air flow in the air in the monitoring section, FIG. Thus, the fluctuation of the phase of the monitoring light passing through the monitoring section is small, and the fluctuation of the amplitude of the interference light between the reference light and the monitoring light is small. Therefore, the fluctuation of the luminance detected by the light receiving unit 13 is small.

As shown in FIG. 3, when a fire occurs and a hot air flow due to the fire exists in the monitoring section, and a sudden change in air density occurs due to the hot air flow in the air in the monitoring section, As shown in FIG. 4, the fluctuation of the phase of the monitoring light passing through the monitoring section is large, and the fluctuation of the amplitude of the interference light between the reference light and the monitoring light is large. Therefore, the fluctuation of the luminance detected by the light receiving unit 13 increases.

Therefore, the arithmetic unit 14 includes the light receiving unit 13
The change rate of the brightness of the interference light input to the light receiving unit 13 is compared with a preset threshold value based on the electric signal of the brightness of the interference light received by When a threshold value is exceeded, it is determined that a fire has occurred. Further, in the case of a smoke fire, for example, a smoldering fire in which little heat is generated, as shown in FIG. 5A and FIG. 5B, the phase change of the monitoring light is small, so the change rate of the amplitude of the interference light is small. Is small, but the amplitude tends to decrease or increase in proportion to time.

This is because, when the monitor light and the reference light interfere with each other in a mutually reinforcing manner, for example, when the monitor light and the reference light are in phase, as the amplitude of the monitor light decreases due to the smoke from the smoldering fire. This is because the amplitude of the interference light gradually decreases. In addition, when the monitoring light and the reference light interfere with each other so as to weaken each other, for example, in a case where the monitoring light and the reference light are out of phase with each other, as the amplitude of the monitoring light decreases due to smoke from the smoldering fire, the interference light is This is because the amplitude also increases gradually. Therefore, the arithmetic unit 14 determines that a fire has occurred by detecting that the tendency of the amplitude with respect to time is decreasing or increasing as compared with the normal time.

As shown in FIG. 6, the reflection section 12 is composed of a half mirror 11c, and the laser beam transmitted through the half mirror 11c is received by a light receiving device 13a to detect a smoked fire. By detecting the extinction ratio of the laser light passing through the sensor, it is possible to use the same calculation method as that of the conventional photoelectric separation type fire detector.

Next, the fire detecting operation of this embodiment will be described. FIG. 7 is a flowchart showing the fire detection operation of this embodiment. The laser light emitting section 10 emits light at a preset constant interval, and the arithmetic section 14 synchronizes with the preset constant interval to form the light receiving section 13.
An output signal from the computer is input, and a fire is detected by comparing the input data. Also,
As counters, counters C1 and C1a for judging a fire due to smoking and C2 for judging a fire due to hot air flow are used. The counter C1 is a counter for judging a fire when the amplitude of the interference light in the case of a smoldering fire tends to decrease, and the counter C1a is a fire judgment when the amplitude of the interference light in the case of a smoldering fire tends to increase. It is a counter for use.

First, data X _n from the light receiving section 13 is input (S100), and the previous data X _{n- 1} and the data X _{n - 1} are input.
Is calculated (S101). It is assumed that the previous data X _n-1 used at this time is stored in a storage unit such as a memory.

Then, the sign of the differential data ΔX calculated in S101 is determined (S102). If the sign of ΔX is determined to be negative in S102, the count value of the counter C1a is reset (S103), and the counter C1 is reset. Is incremented by 1, and the value of C1 is compared with a preset number of times (for example, 3) (S104). And S1
If it is determined in step 04 that the count value of the counter C1 is greater than the preset number of times, the data from the light receiving unit 13 tends to decrease beyond the preset number of times, and the It is determined that there is, and a fire alarm is issued (S105).

If it is determined in step S104 that the count value of the counter C1 is equal to or less than a preset number of times, the absolute value of ΔX is calculated (S106). Also,
When the sign of ΔX is determined to be + in S102, the counter C
The count value of 1 is reset (S107), and the counter C is reset.
The count value of 1a is incremented by 1 and compared with a preset number of times (for example, 3) (S108). And S
If it is determined at 108 that the count value of the counter C1a is greater than the preset number of times, the data from the light receiving unit 13 tends to increase beyond the preset number of times, and Judge that there is,
A fire alarm is issued (S105). If it is determined in S108 that the count value of the counter C1a is equal to or smaller than the preset number of times, the absolute value of ΔX is calculated (S106).

Then, it is determined whether or not the absolute value of ΔX calculated in S106 is larger than a preset threshold value (S109), and it is determined in S109 that the absolute value of ΔX is larger than the preset threshold value. Then, the count value of the counter C2 is incremented by 1, and the value of C2 is compared with a preset number of times (for example, 3) (S1).
10).

If it is determined in step S110 that the count value of the counter C2 is larger than the preset number of times, the absolute value of the difference data ΔX from the light receiving unit 13 exceeds the preset number of times. Since the threshold value is exceeded, it is determined that the fire is caused by a hot air flow, and a fire is issued (S105). If it is determined in step S110 that the count value of the counter C2 is equal to or less than the preset number of times, the process returns to step S100 to input the next data.

If it is determined in S109 that the absolute value of .DELTA.X is equal to or smaller than the preset threshold value, the count value of the counter C2 is reset (S111).
Return to 00 and input the next data.

[0024] In the operation described above, the data X _n from the light receiving portion 13, but is adapted to sense a fire by comparison with the previous data X _n-1, the data X _n from the light receiving portion 13 A predetermined number of pieces of data are stored in a storage means such as a memory, a difference for each adjacent data is calculated, and the calculated differences are stored in a plurality of storage means such as a memory. An average value may be calculated, and a fire may be detected based on the average value of the difference data.

In this embodiment, the reference light from the laser light emitting section 10 and the monitoring light from which the laser light output from the laser light emitting section 10 has passed through the monitoring section interfere with each other, and the interference light is received by the light receiving section 13. The monitor detects fluctuations in the brightness of the interference light and detects both the generation of hot airflow due to a fire and the generation of smoke due to a fire. It is possible to detect a fire in the space, to detect the fire by heat even in the case of a fire with little smoke, and to detect the fire by detecting smoke or the like at the time of the fire.

In this embodiment, laser light is used. However, light of a single wavelength is output, interference occurs between the reference light and the monitoring light, and the phase difference changes the luminance of the interference light. Such a light source may be used as long as the light source is generated. In this embodiment, the interference light of the reference light and the monitoring light is input to the light receiving unit 13 by using the half mirror 11b and the mirror 11a in the mirror unit 11.
The laser light output from the laser light emitting unit 10 is separated into reference light not affected by a fire or the like and monitoring light affected by a fire or the like passing through a monitoring section, and interferes with the reference light and the monitoring light. Any configuration may be used as long as light is input to the light receiving unit 13. Further, in this embodiment, the laser beam is linearly reflected by one reflecting portion 12, but a plurality of reflecting portions 12 are provided, the installation angle is adjusted, and the laser light is The reflected light may be reflected in the direction, and finally the monitoring light may be input to the mirror unit 11. In this case, a wider range of fire detection is possible.

[0027]

As described above, according to the present invention, light of a single wavelength is output by the light emitting means, and the light output from the light emitting means and the fire monitoring section output from the light emitting means are output by the interference means. Interfering the transmitted light with the received light, outputting the received light, receiving the interference light interfered by the interference means, outputting an electric signal corresponding to the brightness of the received interference light by the light receiving means, The output signal is monitored for fluctuations, and based on the fluctuation state of the output signal of the light receiving means, it is possible to detect the occurrence of hot airflow due to a fire in the monitoring section and the occurrence of smoking due to the fire. This has the effect that the fire can be detected by heat even in the case of a fire with little smoke, and the fire can also be detected by detecting smoke or the like at the time of fire.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing a configuration of a fire detector according to an embodiment of the present invention.

FIG. 2 is an explanatory diagram for explaining a relationship between reference light and monitoring light in a normal state.

FIG. 3 is an explanatory diagram for explaining a state of a fire detector when a fire occurs.

FIG. 4 is an explanatory diagram for explaining a relationship between reference light and monitoring light when a fire occurs.

FIG. 5 is an explanatory diagram for explaining a change in interference light at the time of a smoldering fire.

FIG. 6 is a configuration diagram showing a configuration of a reflection unit 12 for detecting a smoking fire.

FIG. 7 is a flowchart illustrating a fire detection operation according to the embodiment.

[Explanation of symbols]

 Reference Signs List 10 laser light emitting part 11 mirror part (interference means) 12 reflecting part 13 light receiving part 14 arithmetic part

Claims (3)

[Claims] 1. A light emitting means for outputting light of a single wavelength, and an interference means for causing light output from the light emitting means to interfere with light output from the light emitting means and passing through a fire monitoring section to output the light. And a light receiving means for receiving the interference light interfered by the interference means and outputting an electric signal corresponding to the brightness of the received interference light; and monitoring a fluctuation of an output signal of the light receiving means, and outputting the output of the light receiving means. A fire detector, comprising: a calculating means for detecting generation of hot air flow by a fire and generation of smoke by a fire in the monitoring section based on a fluctuation state of a signal. 2. A light emitting means for outputting light of a single wavelength, and an interference means for causing light output from the light emitting means and light output from the light emitting means to pass through a fire monitoring zone to output the light. And light receiving means for receiving the interference light interfered by the interference means and outputting an electric signal corresponding to the luminance of the received interference light; monitoring the output signal of the light receiving means at predetermined intervals; Calculating a difference from a previous output signal of the light receiving means, and when the difference exceeds a threshold value a predetermined number of times in succession, senses the occurrence of a hot air flow due to a fire in the monitoring section; And a calculating means for detecting the occurrence of smoke due to the fire in the monitoring section when the number of times of the monitoring section decreases or increases continuously for a predetermined number of times. 3. The arithmetic means stores a plurality of calculated differences, calculates an average of the plurality of differences, and generates a hot air flow and a fire due to a fire in the monitoring section based on an average value of the calculated differences. 3. The fire detector according to claim 2, wherein the detector detects smoke generated by the fire.