JP2003106898A - Flame detector - Google Patents

Abstract

PROBLEM TO BE SOLVED: To realize a flame detector that can highly accurately detect flame generated in case of fire by enabling the elimination of a periodical incorrect report source. SOLUTION: The flame detector, which detects the flame generated in case of the fire by detecting the infrared ray of the specific wavelength of the flame, comprises a detecting means for the infrared ray outputting a detection signal corresponding to the wavelength of a detected infrared ray by detecting the infrared ray of the specific wavelength of the flame, an evaluating means for waveform periodicity evaluating the periodicity of the waveform of the detection signal detected by the detecting means for the infrared ray, and a judging means for the flame based on the detection signal detected by the detecting means for the infrared ray and the evaluating means for the waveform periodicity evaluated by evaluating means for waveform periodicity.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flame detection device, and more particularly to a flame detection device that detects infrared rays having a wavelength peculiar to the flame generated during a fire to eliminate false alarm sources and detect the flame. It is a thing.

[0002]

2. Description of the Related Art As a conventional fire alarm of this type, the invention described in Japanese Patent Application Laid-Open No. 47-28898 is known.
The “fire alarm” of the invention described in the above publication measures the time interval of zero-passage of the measurement signal appearing in the flicker frequency range. At least a large number of all the intervals measured during the measurement time have different interval values so that a fire can be determined and reported. And in this "fire alarm" based on such measurement principle,
For example, it is explained that a periodic false alarm source such as a revolving lamp having a constant time interval of zero-pass of a measurement signal can be eliminated.

[0003]

However, in general, the periodic error sources include, for example, a time interval of the first zero passage, a time interval of the second zero passage, and a time interval of the third zero passage. There is also a source of periodic misinformation such that is repeated periodically. As an example, it is a multi-lamp type rotating lamp that is regularly and instantaneously lit several times at regular time intervals, and in this case, the time interval of zero-passage of the measurement signal is not constant.
Therefore, if a flicker signal such as that of a multi-lamp rotating lamp is input to the fire detection element, there is a problem that the fire is erroneously determined. Another source of such periodic misinformation is a motorcycle engine with a small number of cylinders.

The present invention has been made to solve the above-mentioned problems of the conventional "fire alarm", and introduces the concept of "autocorrelation value Sn" for evaluating the periodicity of the waveform of the detection signal. did. Then, when the autocorrelation value Sn is larger than a certain threshold value, it is determined to be a false alarm source having periodicity, and a flame detection device capable of eliminating a periodic false alarm source such as a multi-lamp rotating lamp is realized. It is a thing.

[0005]

DISCLOSURE OF THE INVENTION The present invention is a flame detecting apparatus for detecting an infrared ray having a wavelength peculiar to a flame to detect a flame generated during a fire. Infrared detecting means for outputting a detection signal according to the wavelength of, the waveform periodicity evaluating means for evaluating the periodicity of the waveform of the detection signal detected by the infrared detecting means, the detection signal and the waveform detected by the infrared detecting means A flame detection device having flame determination means for determining flame based on the periodicity of the waveform evaluated by the periodicity evaluation means. Further, in the above, the waveform periodicity evaluation means,
The flame detecting device is configured to evaluate the periodicity of the waveform based on time series data of the interval value obtained by measuring the time interval of passage of the reference potential of the detection signal detected by the infrared detecting means. Further, in the above, the waveform periodicity evaluation means,
The flame detecting device is configured to evaluate the periodicity of the waveform based on time series data of the interval value obtained by measuring the time interval between peaks of the detection signal detected by the infrared detecting means. Further, in the above description, the waveform periodicity evaluation means constitutes a flame detection device that calculates the autocorrelation value of the time-series data and evaluates the periodicity of the waveform based on the calculated autocorrelation value. Further, in the above description, the waveform periodicity evaluation means constitutes a flame detection device that determines a fire when the autocorrelation value is equal to or less than the threshold value. Also, in the above,
The reference potential constitutes a flame detection device set to a value other than near zero potential. Further, in the above description, the peak constitutes a flame detection device that uses peaks other than those near the bias voltage.

[0006]

1 is a block diagram of an embodiment of the present invention, (a) is a block diagram, (b) and (c) are (a).
3 is a circuit diagram of the detection circuit and the integrator of FIG. In FIG. 1A, 1 is a flame detection device. 2 is a detection unit, 3 is an amplifier for amplifying the output of the detection unit 2, 4 is a detection circuit, 5 and 6 are rectification units and integrators, 7 is a determination unit, and 8 is a fire signal generation circuit. The detection unit 2 is an example of infrared detection means that detects infrared rays having a wavelength peculiar to the flame and outputs a detection signal corresponding to the wavelength of the detected infrared rays. The detection circuit 4 and the determination unit 7 are
It is an example of the waveform periodicity evaluation means for evaluating the periodicity of the waveform of the detection signal detected by the infrared detection means. Judgment part 7
Is an example of flame determining means for determining flame based on the detection signal detected by the infrared detecting means and the periodicity of the waveform evaluated by the waveform periodicity evaluating means.

The detecting section 2 is an example of infrared detecting means for detecting infrared rays having a wavelength peculiar to the flame and outputting a detection signal corresponding to the wavelength of the detected infrared rays. The detection circuit 4 and the determination unit 7 are examples of waveform periodicity evaluation means for evaluating the periodicity of the waveform of the detection signal detected by the infrared detection means.
The determination unit 7 is an example of a flame determination unit that determines a flame based on the detection signal detected by the infrared detection unit and the periodicity of the waveform evaluated by the waveform periodicity evaluation unit. A flame sensing element such as a pyroelectric element is used in the detection unit 2 to detect infrared rays near the 4.4 μm band, which is peculiar to the flame generated during a fire. The amplifier 3 has an electrical flicker frequency band of the signal of the detector 2 which is 4 to 30H.
A signal component of z is selected and amplified. It should be noted that if a narrow band filter that passes only the signal component of 4 to 30 Hz, which is an electrical flame flicker frequency band, of the signal of the detection unit 2 is provided in the subsequent stage of the detection unit 2, noise components other than 4 to 30 Hz are provided. Will be more reliable.

The rectifying section 5 takes out the plus side signal from the signals amplified by the amplifier 3. The integrator 6 is shown in FIG.
It is configured as shown in (c). 61 is a diode, 6
Reference numerals 2 and 63 are resistors for charging and discharging, and 64 is a capacitor. Further, reference numeral 65 is a set power source, and 66 is a comparator, which is a part of the determination unit 7 described later. The plus-side signal extracted by the rectifying unit 5 is charged in the capacitor 64 via the backflow prevention diode 61 and the resistor 62 and smoothed. The resistor 63 is a discharge resistor that discharges this signal, and is slowly discharged so that the signal remains stable. Then, a constant voltage as a flame determination reference value is set by the set power supply 65, the smoothed signal is compared with this constant voltage by the comparator 66, and if the smoothed signal is equal to or higher than the constant voltage, the detector 2 causes the flame. Assuming that a possible infrared radiation source is detected, the output signal is changed from a normal zero output to a positive output.

The detection circuit 4 is constructed as shown in FIG. Reference numerals 42 and 43 are voltage dividing resistors, and 44 is a comparator. Further, 41 is an amplifier as the amplifier 3. The reference potential of the comparator 44 is set by the voltage dividing resistors 42 and 43 connected to a constant voltage power source (not shown). The comparator 44 compares the signal amplified by the amplifier 41, which is the amplifier 3, with the reference potential. The comparator 44 outputs a plus-side signal when the amplified signal is equal to or higher than the reference potential, and outputs a zero-side signal when the amplified signal is less than the reference potential, thereby forming a rectangular wave and a plus-side signal of the rectangular wave. Based on the output continuation time of or the output continuation time of the zero-side signal, an interval value (time data) that is a time interval of passage of the reference potential is formed and output to the determination unit 7.

The judgment unit 7 confirms whether or not an infrared radiation source having a possibility of flame is detected by the detection unit 2 described above, a set power source 65, a comparator 66, an output signal from the integrator 6, and the detection circuit 4. It has a RAM (not shown) for temporarily storing the interval value formed by the above, and a ROM (not shown) for storing a program and a threshold value as a periodic false alarm source reference value to be compared with an autocorrelation value Sn described later. The judgment unit 7 stores a predetermined number of interval values formed by the detection circuit 4 in the RAM as time series data, calculates an autocorrelation value Sn from the time series data, and calculates the autocorrelation value S
The flame is judged based on n and the output signal from the integrator 6. The fire signal generation circuit 8 outputs a fire signal based on the result of the flame determination by the determination unit 7.

Before describing the operation using the flow chart of FIG. 3, the autocorrelation value Sn introduced in the present application will be described with reference to FIG. FIG. 2A shows a periodicity false alarm that is periodically repeated with a combination of different periods, that is, a period S1 having a first zero-pass time interval and a period S2 having a second zero-pass time interval. FIG. 4 is a waveform diagram of a source, that is, a periodic false alarm source in which a time interval of zero-pass of a measurement signal is not constant,
The horizontal axis and the vertical axis are the time (t) and the waveform signal (v). Here, the reference potential of the comparator 44 is v1, and the time data that is the interval value between the time tn at the intersection of the input waveform and the reference potential and the time tn-1 at the intersection of the previous reference potential is Dn. This periodic error source is time data Dn, Dn-
This cycle is periodically repeated with 1, Dn-2, and Dn-3 as one cycle. FIG. 2B shows a state in which the time data is temporarily stored in the RAM of the determination unit 7 to be time-series data. Here, for example, the time data Dn, Dn-1, ..., Dn-7 of the waveform of the two cycles is time data Dn- obtained by shifting the leading time data by one in the past.
, Dn-2, ..., Dn-8, time data Dn-2, Dn-3 ,.
When sequentially compared with n-9, ..., Time data Dn-4, Dn-5 ,.
Since it is similar to 1, the waveform can be judged to be the waveform of the periodic false alarm source. For this determination, the autocorrelation value S of the following equation
Evaluate the periodicity of the input waveform using n.

[0012]

[Equation 1] However, x is the number of data j The number of data to shift

The autocorrelation value Sn is an interval value (time data) obtained by measuring the time interval of passage of the reference potential of the detection signal detected by the infrared detecting means, and a predetermined number of x + j interval values are set as the time value. The time-series data is stored as a series of data in the RAM of the determination unit 7 and is calculated from the stored time-series data.
The autocorrelation value Sn is set to j by substituting 1 to 10, for example, and the current input waveform from time data Dn to Dn-x and time data obtained by shifting j times of the time data from the current input waveform in the past. The waveforms of the past input waveforms Dn-j to Dn-x-j are sequentially compared with each other, and when the waveforms are the most similar, the maximum value is shown and the maximum value is taken. The autocorrelation value Sn shows a large value if the waveform has periodicity, and shows a small value if the waveform has no periodicity. This value is larger than the threshold value stored in the ROM as the periodicity false alarm source reference value. If it is also large, the determination unit 7 determines that it is a periodic error source.

Therefore, as shown in FIG. 2A, even in the case of a periodic error source which is periodically repeated with a combination of different periods such as the period S1 and the period S2, a stable waveform is obtained. It can be judged that there is periodicity. Of course, even in the case of a periodic error source in which a single cycle is periodically repeated, that is, a periodic error source in which the time interval of zero-pass of the measurement signal in the conventional example is constant, a stable periodicity determination can be made. It can be performed. The reference potential of the comparator 44 may be a positive potential or a negative potential, and if it is set to a potential other than near zero potential, it will be affected by a noise source such as power noise superimposed on the signal component of the input waveform. The time interval of passage of the reference potential of the detection signal detected by the infrared detecting means does not become unstable.

Subsequently, referring to the flow chart of FIG.
The operation of the embodiment will be described in itemized form as follows. (S1) The value of the fire counter, which is a function of the determination unit 7, is reset to "0". (S2) The amount of infrared rays in a predetermined wavelength band is converted into an electric signal from the flame sensing element of the detection unit 2 and input. The wavelength band to be detected is, for example, 4.4 μm.

From the signals obtained in (S1) and (S2), the frequency band of the flicker of the flame electrically caused by the amplifier 3 is 4
A signal component of -30 Hz is selected and amplified. (S4) The amplified signal obtained in (S3) is formed into a rectangular wave by the detection circuit 4, and the signal output is output to the RAM of the determination unit 7.
Sequentially store in. An intersection is detected when the square wave switches from the plus side signal to the zero side signal or the opposite zero side signal to the plus side signal. When this intersection is detected, the time when the signal output is stored this time is set as the time of the intersection and is stored in the RAM. If an intersection is detected, the process proceeds to (S5), and if not detected, the process proceeds to (S6).

(S5) When an intersection is detected in (S4), an interval value (time data Dn), which is a time interval of passage of the reference potential, is determined by the interval value between the time of the intersection and the time of the previous intersection. Is stored in the RAM of the determination unit 7 as time series data. The time data Dn moves to the subsequent stage of the time data Dn-1, time data Dn-2, ... And time series data every time new time data is stored in the RAM. Further, the time data is stored in a predetermined number of RAMs, and when the time data exceeds a predetermined number, the past data are sequentially discarded. (S6) The amplified signal obtained in (S3) is smoothed by the integrator 6 via the rectifying unit 5. (S7) When the smoothed signal obtained in (S6) is equal to or higher than the constant voltage which is the flame determination reference value, a positive output is output to the determination unit 7 and the process proceeds to (S8). If the voltage is lower than the constant voltage, zero output is output to the determination unit 7, and then the process returns to (S1) and repeats the procedure.

(S8) The autocorrelation value Sn is calculated using the time-series data stored in the RAM of the judgment unit 7. The autocorrelation value Sn is obtained by the equation [Equation 1], and is the most calculated value when the time series data is shifted by one data in the past to the time when it is shifted by a predetermined data (for example, 10 data). It will be a large value. (S9) The autocorrelation value Sn is compared with a threshold value as a periodicity error source determination reference value stored in the ROM of the determination unit 7, and if it is equal to or less than the threshold value, it is determined to be a flame, and the process proceeds to (S10).
If it is larger than the threshold value, it is determined to be a periodic error source,
Return to (S1) and repeat the procedure.

(S10) The fire counter is incremented by "1". (S11) If the value of the fire counter has not reached the predetermined value, eg, 3, then return to (S2) and repeat the procedure. When the value of the fire counter reaches a predetermined value, for example 3, (S1
Proceed to 2). (S12) Assuming that a fire is detected, the fire occurrence signal circuit 8 transmits a fire signal to a fire receiver (not shown). The value of this fire counter counts the number of times that it is judged that a flame has occurred, and in order to reliably detect only a fire, when it is judged three times in succession that a flame has occurred. It is assumed that a fire has been detected. Of course, the value of the fire counter as a condition for transmitting the fire signal to the fire receiver may be set to a value other than 3.

FIG. 4 is a block diagram showing the structure of another embodiment. The same members as those of the flame detection device 1 of FIG. 1 are designated by the same reference numerals, and the description thereof will be omitted. Different parts will be described below. In FIG. 4, an A / D converter 10 is provided instead of the detection circuit 4, the rectifying unit 5 and the integrator 6 of FIG. Further, in place of the determination unit 7, a calculation unit 11 that can calculate at higher speed is arranged. The A / D converter 10 and the arithmetic unit 11 are examples of waveform periodicity evaluation means for evaluating the periodicity of the waveform of the detection signal detected by the infrared detection means. The calculation unit 11 is an example of a flame determination unit that determines a flame based on the detection signal detected by the infrared detection unit and the periodicity of the waveform evaluated by the waveform periodicity evaluation unit.

Then, the A / D converter 10 converts the signal amplified by the amplifier 3 into a digital signal. The fire signal generation circuit 8 outputs a fire signal based on the result of the flame judgment by the calculation unit 11. Although not shown, the calculation unit 11 stores a RAM for temporarily storing various signals and interval values described later, a program, and a reference potential described later, a flame determination reference value level, and a threshold value as a periodic false alarm source determination reference value. Has a ROM. The calculation unit 11 stores the digital signal from the A / D converter 10 in the RAM,
By performing a weighted averaging process or the like on a fixed number of digital signals stored in M, the signals are smoothed and stored in the RAM as a smoothed signal. Also, the smoothed signal and RO
The flame judgment value reference value level as the flame judgment value reference value stored in M is compared, and if the smoothing signal is equal to or higher than the flame judgment value reference value level, the detection unit 2 detects infrared rays with a possibility of flame. Judge as detected.

The arithmetic unit 11 also compares the digital signals sequentially stored in the RAM with the reference potential stored in the ROM. The digital signal stored last time has a value smaller than the reference potential, and the digital signal stored this time has a value greater than the reference potential or vice versa. When the signal crosses the reference potential, it is detected as a crossing point. When the intersection is detected, the time when the digital signal is stored this time is set as the time of the intersection for convenience. Then, an interval value (time data), which is a time interval of passage of the reference potential, is formed by the interval value between the time of the intersection and the time of the previous intersection and is stored in the RAM. Although the time of the intersection is set to the time when the digital signal is stored this time for convenience, it may be set to the time when the digital signal is stored the previous time. Further, the arithmetic unit 11 stores a predetermined number of sequentially output interval values in the RAM as time series data, calculates the autocorrelation value Sn from the time series data, and calculates the autocorrelation value Sn and the smoothed signal described above. Flame judgment value A flame is judged based on comparison with the reference value level.

Subsequently, referring to the flow chart of FIG.
The operation of another embodiment will be described in itemized form as follows. (S21) The value of the fire counter, which is a function of the calculation unit 11, is reset to "0". (S22) The amount of infrared rays in a predetermined wavelength band is converted into an electric signal from the flame sensing element of the detection unit 2 and input. The wavelength band to be detected is, for example, 4.4 μm. (S23) From the signal obtained in (S22), the amplifier 3
4 to 30H, which is the frequency band of electrical flicker of flame due to
A signal component of z is selected and amplified. (S24) The amplified signal obtained in (S23) is converted into a digital signal by the A / D converter 10, and R
Store in AM. (S25) Digital signal and RO stored in RAM
Compare with the reference potential stored in M. The digital signal stored last time has a value smaller than the reference potential, and the digital signal stored this time has a value greater than the reference potential or vice versa. When the signal crosses the reference potential, it is detected as a crossing point. When this intersection is detected, the time at which the digital signal is stored this time is set as the time at the intersection and is stored in the RAM. If an intersection is detected, the process proceeds to (S26), and if not detected, the process proceeds to (S27).

(S26) When an intersection is detected in (S25), an interval value (time data Dn), which is a time interval of passage of the reference potential, is determined by the interval value between the time of the intersection and the time of the previous intersection. Is formed and stored in the RAM of the determination unit 7 as time series data. The time data Dn moves to the subsequent stage of the time data Dn-1, time data Dn-2, ... And time series data every time new time data is stored in the RAM. Further, the time data is stored in a predetermined number of RAMs, and when the time data exceeds a predetermined number, the past data are sequentially discarded. (S27) By performing a weighted averaging process or the like on a fixed number of digital signals stored in the RAM, the signals are smoothed and stored in the RAM as a smoothed signal. (S28) If the smoothed signal stored in the RAM is equal to or higher than the flame judgment reference value level stored in the ROM (S29).
Go to. If it is smaller than the flame judgment reference value level, (S
Return to 21) and repeat the procedure.

(S29) The autocorrelation value Sn is calculated using the time series data stored in the RAM of the arithmetic unit 11. The autocorrelation value Sn is obtained by the equation [Equation 1], and is the most calculated value when the time-series data is shifted by one data in the past to the predetermined data (for example, 10 data). It will be a large value. (S30) The autocorrelation value Sn is compared with a threshold value as a periodic error source determination reference value stored in the ROM of the calculation unit 11, and if it is equal to or less than the threshold value, it is determined to be flame, and the process proceeds to (S31). If it is larger than the threshold value, it is determined to be a periodic error information source, and the procedure returns to (S21) to repeat the procedure. (S31) The fire counter is incremented by "1". (S32) If the value of the fire counter has not reached the predetermined value, eg, 3, then return to (S22) and repeat the procedure.
When the value of the fire counter reaches a predetermined value, for example 3, (S
Go to 33). (S33) Assuming that a fire has been detected, the fire occurrence signal circuit 8 transmits a fire signal to a fire receiver (not shown).

In this embodiment, the interval value (time data) used as the time series data is the time interval of passage of the reference potential of the detection signal detected by the infrared detecting means. It may be the time interval between the peaks of the detection signal detected by. In this case, in the amplifier 3, the minimum peak of the detection signal is the A / D converter 1
It is assumed that the signal is biased so that digital conversion is possible at 0, and the arithmetic unit 11 determines that the digital signals stored in the RAM two times before and this time are larger than the digital signals stored in the RAM last time, or vice versa. If the peak is detected as a small value, the interval value (time data) that is the time interval between the peak and the previous peak
Is stored in RAM. Further, if only peaks other than the vicinity of the bias voltage are used as the peaks used for the interval value, it is possible to detect the peaks near the bias voltage due to the influence of noise sources such as power supply noise among the peaks of the detection signal. And a more accurate interval value can be obtained.

[0027]

INDUSTRIAL APPLICABILITY The present invention is a flame detecting device for detecting an infrared ray having a wavelength peculiar to a flame to detect a flame generated at the time of a fire. Infrared detecting means for outputting the detected signal, waveform periodicity evaluating means for evaluating the periodicity of the waveform of the detection signal detected by the infrared detecting means, detection signal detected by the infrared detecting means and waveform periodicity evaluating means And a flame determination means for determining the flame based on the periodicity of the waveform evaluated by the flame detection device. Further, in the above, the waveform periodicity evaluation means is flame detection for evaluating the periodicity of the waveform based on the time series data of the interval value obtained by measuring the time interval of passage of the reference potential of the detection signal detected by the infrared detection means. Configured the device. Further, in the above, the waveform periodicity evaluation means, a flame detection device for evaluating the periodicity of the waveform based on the time-series data of the interval value measured time interval between peaks of the detection signal detected by the infrared detection means, Configured. Further, in the above, the waveform periodicity evaluation means,
A flame detection device was constructed that calculates the autocorrelation value of time-series data and evaluates the periodicity of the waveform based on the calculated autocorrelation value. Further, in the above, the waveform periodicity evaluation means,
We constructed a flame detection device that judges a fire when the autocorrelation value is below a certain threshold. In the above, the reference potential is
A flame detection device was set up except for near zero potential. Further, in the above, the peak constitutes a flame detection device that uses peaks other than those near the bias voltage.

As described above, according to the present invention, the interval value obtained by measuring the time interval of passage of the reference potential of the detection signal detected by the infrared detecting means, or the peak value of the detection signal detected by the infrared detecting means. The autocorrelation value Sn of the time series data of the interval value obtained by measuring the time interval is calculated. The autocorrelation value Sn is used to evaluate the periodicity of the waveform of the detection signal. The similarities between the waveforms are investigated. If both waveforms have a periodicity, the autocorrelation value Sn is large, and if the waveforms do not have a periodicity, the autocorrelation value Sn is small. It can be identified as a source of false information. For this reason, it is possible to prevent erroneous determination of a periodic error source such as a multi-lamp type rotating lamp in which the time interval of the zero passage of the measurement signal is not constant.

Therefore, according to the present invention, it is possible to provide a flame detection device capable of eliminating the periodic false alarm source and detecting the flame generated at the time of fire with high accuracy.

[Brief description of drawings]

FIG. 1 is a configuration explanatory diagram of an embodiment of the present invention.

FIG. 2 is a waveform diagram for explaining an autocorrelation value.

FIG. 3 is a flowchart showing the operation of the embodiment.

FIG. 4 is a block diagram showing a configuration of another embodiment.

FIG. 5 is a flowchart showing the operation of another embodiment.

[Explanation of symbols]

1 Flame detector 2 detector 3 amplifier 4 Detection circuit 5 Rectifier 6 integrator 7 Judgment section 8 Fire signal generation circuit

Claims (7)

[Claims] 1. A flame detection device for detecting a flame generated during a fire by detecting an infrared ray having a wavelength characteristic of a flame, wherein the infrared ray having a wavelength characteristic of the flame is detected to detect the infrared ray having a wavelength corresponding to the detected infrared ray. Infrared detection means for outputting a signal, waveform periodicity evaluation means for evaluating the periodicity of the waveform of the detection signal detected by the infrared detection means, detection signal detected by the infrared detection means and the waveform periodicity evaluation And a flame determining unit that determines a flame based on the periodicity of the waveform evaluated by the unit. 2. The waveform periodicity evaluation means evaluates the periodicity of the waveform based on time series data of interval values obtained by measuring the time interval of passage of the reference potential of the detection signal detected by the infrared detection means. The flame detection device according to claim 1, wherein 3. The waveform periodicity evaluating means evaluates the periodicity of the waveform based on time-series data of an interval value obtained by measuring a time interval between peaks of a detection signal detected by the infrared detecting means. The flame detection device according to claim 1, which is characterized in that. 4. The waveform periodicity evaluation means calculates an autocorrelation value of the time-series data, and evaluates the periodicity of the waveform based on the calculated autocorrelation value. The flame detection device according to item 3. 5. The flame detection device according to claim 1, wherein the waveform periodicity evaluation means determines that there is a fire when the autocorrelation value is equal to or less than a certain threshold value. 6. The flame detection device according to claim 2, wherein the reference potential is set to a value other than near zero potential. 7. The flame detection device according to claim 2, wherein a peak other than a bias voltage is used as the peak.