JP6989291B2 - Flame detector - Google Patents

Description

The present invention relates to a flame detection device.

A flame detection device for detecting a flame has been known (see, for example, Patent Document 1). This flame detection device includes a photodetecting means that outputs an electric signal corresponding to the amount of light of the flame, and is configured to detect the flame based on the electric signal output by the light detecting means.

Japanese Unexamined Patent Publication No. 2010-175562

By the way, in the flame detection device of Patent Document 1, for example, it is often installed and used outdoors such as in a tunnel, and in this case, noise (for example) is generated in the flame detection device due to the installation environment of the flame detection device. , Vibration, radio waves, heat, etc.) is added, and noise is superimposed on the electric signal due to the added noise, and the flame is detected even though the flame is not actually generated. False alarms may occur, and there was room for improvement in terms of preventing the occurrence of false alarms and reliably detecting flames.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a flame detection device capable of reliably detecting a flame.

In order to solve the above-mentioned problems and achieve the object, the flame detection device according to claim 1 is a flame detection device that detects the flame based on the light from the flame, and is a level according to the amount of incident light. The irradiation side signal generation means for outputting the irradiation side electric signal, which is configured to irradiate itself with the light from the flame, and the irradiation side signal generation means having a level corresponding to the amount of incident light. The non-irradiation side signal generation means, which is a non-irradiation side signal generation means for outputting an irradiation side electric signal and is configured so that the light from the flame is not irradiated to itself, and the non-irradiation side signal generation means. A removing means for removing noise superimposed on the irradiation side electric signal output by the irradiation side signal generating means based on the output of the non-irradiating side electric signal, and the irradiation for which noise is removed by the removing means. A flame detecting means for detecting the flame based on the side electric signal is provided, and each of the irradiated side signal generating means and the non-irradiating side signal generating means has a sensor unit housed in a separate sensor case. the amplifier portion has the same configuration as each other and a frequency filter unit.

Further, the flame detection device according to claim 2 is the flame detection device according to claim 1, wherein the removing means subtracts the non-irradiation side electric signal from the irradiation side electric signal to obtain the irradiation side. The noise superimposed on the irradiation side electric signal output by the signal generation means is removed.

Further, the flame detection device according to claim 3 includes a circuit board for mounting the irradiation side signal generation means in the flame detection device according to claim 1 or 2, and the non-irradiation side signal generation means includes the non-irradiation side signal generation means. It is mounted on the circuit board.

According to the flame detecting device according to claim 1, in example embodiment, for detecting the flame, it is possible to remove the influence of noise superimposed on the irradiation side electrical signals, actually has occurred flame It is possible to prevent the occurrence of false alarms that detect flames even though they are not present, and to reliably detect flames .

According to the flame detection device according to claim 2, for example, it is relatively simple by removing the noise superimposed on the irradiation side electric signal by subtracting the non-irradiation side electric signal from the irradiation side electric signal. Since the noise superimposed on the irradiation side electric signal can be removed by various processing, the noise superimposed on the irradiation side electric signal can be quickly removed, and the flame can be detected quickly and reliably. It becomes possible to provide a possible flame detection device. Further, for example, the removing means of the flame detection device can be realized with a relatively simple configuration, and the manufacturing cost of the flame detection device can be reduced by simplifying the manufacturing process of the flame detection device.

According to the flame detecting device according to claim 3, comprising a circuit board for mounting the irradiated side signal generating unit, by the non-irradiation-side signal generating means mounted on the circuit board, for example, irradiation-side signal generating means And since the non-irradiation side signal generation means are mounted on the same circuit board, the same noise is added to both the irradiation side signal generation means and the non-irradiation side signal generation means. , Noise similar to the noise to be removed from the irradiation side electric signal can be superimposed on the non-irradiation side electric signal, and the noise can be reliably removed from the irradiation side electric signal by using this non-irradiation side electric signal. It becomes.

It is a block diagram of the flame detection apparatus which concerns on this embodiment. This is an example of a waveform diagram of an analog signal on the first irradiation side in a state where signal noise is not superimposed. It is a flowchart of a flame detection process.

Hereinafter, embodiments of the flame detection device according to the present invention will be described in detail with reference to the drawings. The present invention is not limited to the embodiments.

[Basic concept of the embodiment]
First, the basic concept of the embodiment will be described. Embodiments generally relate to a flame detecting apparatus comprising at least an irradiation side light detecting means, a non-irradiating side light detecting means, a removing means, and a flame detecting means.

Here, the "flame detection device" is a detection means for detecting a flame based on the light from the flame, specifically, for detecting a flame in a monitoring area, for example, any property of the flame. The flame is detected by using the above, for example, the property that the light of the flame has an intensity peak at a wavelength near 4.4 μm to 4.5 μm (that is, so-called CO2 resonance radiation), and the flame. It is a concept including one that detects a flame by utilizing the property that light flickers at a frequency in the vicinity of 1 Hz to 15 Hz. Further, the "flame detection device" includes, for example, a method of detecting a flame by focusing on only one wavelength band, or a method of detecting a flame by focusing on a plurality of wavelength bands. It is a concept.

Further, the "monitoring area" is an area to be monitored by the flame detection device, specifically, a space having a certain extent, an indoor space or an outdoor space, for example. , Areas inside and outside the tunnel, areas inside and outside the building, and the like.

Further, the "irradiation side light detecting means" is a means for outputting an irradiation side electric signal corresponding to the amount of light radiated to the self, and is configured to irradiate the self with the light from the flame. In particular, it is a means for performing photoelectric conversion, and for example, a pyroelectric element provided so as to be irradiated with light from a flame (hereinafter, "to be irradiated with light from a flame"). The "pyroelectric element provided in the light" is also referred to as "irradiation side pyroelectric element") and the like. The "irradiation side electric signal" is an electrical signal, specifically, a signal output from the irradiation side light detection means (that is, a signal at a level corresponding to the amount of incident light), and is irradiated. It is a signal corresponding to the amount of light emitted to the side light detecting means, and is a concept including, for example, a signal having a voltage value corresponding to the amount of light of light.

Further, the "non-irradiated side light detecting means" is a means for outputting a non-irradiated side electric signal corresponding to the amount of light radiated to the self, and is configured so that the self is not irradiated with the light from the flame. Specifically, it performs photoelectric conversion, for example, a pyroelectric element provided so as not to be irradiated with light from a flame (hereinafter, "so as not to be irradiated with light from a flame". The provided pyroelectric element is also referred to as a “non-irradiation side pyroelectric element”) and the like. The "non-irradiating side electric signal" is an electrical signal, specifically, a signal output from the non-irradiating side light detecting means, and is the light irradiated to the non-irradiating side light detecting means. It is a signal corresponding to the amount of light (that is, a signal of a level corresponding to the amount of incident light), and is a concept including, for example, a signal having a voltage value corresponding to the amount of light of light.

Further, the non-irradiation side pyroelectric element here has the same configuration as the irradiation side pyroelectric element except for the configuration regarding the presence or absence of irradiation of light from the flame to the self, that is, non-irradiation side pyroelectric element. For the irradiation side pyroelectric element and the irradiation side pyroelectric element, when the same additional noise is applied, the same signal noise is generated for the non-irradiation side electric signal and the irradiation side electric signal due to the additional noise. It is configured to overlap. The "additional noise" is noise added to the flame detection device, and specifically causes signal noise, and is a concept including, for example, vibration, radio waves, heat, and the like. Further, the "signal noise" is at least noise superimposed on the irradiation side electric signal and the non-irradiation side electric signal, and specifically, is a concept including noise caused by additional noise.

Further, the "removing means" is a means for removing noise superimposed on the irradiation side electric signal output by the irradiation side light detection means based on the non-irradiation side electric signal output by the non-irradiation side light detection means. Yes, specifically, it is a concept that removes signal noise, and includes, for example, one that removes signal noise in an analog manner, one that removes signal noise digitally, and the like. Note that "removing signal noise in an analog manner" means removing signal noise at the level of an electric signal using a predetermined electric circuit, and "removing signal noise digitally". Indicates that the electrical signal is digitized to remove signal noise at the level of arithmetic processing.

Further, the "flame detecting means" is a means for detecting a flame based on an irradiation-side electric signal from which noise has been removed by the removing means.

Then, in the embodiment shown below, the "flame detection device" adopts a method of detecting a flame by focusing on only one wavelength band, the "monitoring area" is an outdoor space, and " A case where the "removing means" removes signal noise in an analog manner will be described.

(composition)
First, the configuration of the flame detection device according to the present embodiment will be described. FIG. 1 is a block diagram of a flame detection device according to the present embodiment.

The flame detection device 100 shown in FIG. 1 detects a flame in a monitoring area, and specifically, is provided on a wall surface or the like on the outdoor side of a building to monitor an outdoor space in the monitoring area. It includes, for example, an irradiation side signal generation unit 11, a non-irradiation side signal generation unit 12, a removal unit 13, a signal conversion unit 14, a communication unit 15, a recording unit 16, and a control unit 17.

(Structure-Irradiation side signal generator)
The irradiation side signal generation unit 11 is a signal generation means for generating and outputting an irradiation side analog signal, and is mounted on, for example, a circuit board for a flame detection device. As an example, the irradiation side sensor unit 111 , The irradiation side frequency filter 112, the irradiation side preamplifier 113, and the irradiation side main amplifier 114.

Here, the "circuit board for a flame detection device" is a mounting means on which an electric circuit or an element is mounted, and specifically, is a circuit board provided in the flame detection device 100, for example, at least. The irradiation side signal generation unit 11 and the non-irradiation side signal generation unit 12 are mounted. Further, the "irradiation side analog signal" is an electrical signal, specifically, a signal on which signal noise can be superimposed due to the above-mentioned additional noise. For example, the first irradiation side analog to be described later. It is a concept including a signal S11, a second irradiation side analog signal S12, a third irradiation side analog signal S13, a fourth irradiation side analog signal S14, and the like.

(Structure-Irradiation side sensor unit)
The irradiation side sensor unit 111 is a conversion means that performs photoelectric conversion, and specifically, is a signal output means that generates and outputs a first irradiation side analog signal S11, which will be described later. For example, a case for an irradiation side sensor unit. It includes 111a, an irradiation-side optical filter 111b, and an irradiation-side light detection unit 111c.

(Structure-Irradiation side sensor unit-Irradiation side sensor unit case)
The irradiation-side sensor unit case 111a is a housing means for accommodating at least the irradiation-side light detection unit 111c, and specifically forms the outer shape of the irradiation-side sensor unit 111. For example, a flame inside itself. An irradiation-side opening (not shown) for introducing external light of the detection device 100 is provided, and the irradiation-side light detection unit 111c housed by the detection device 100 is provided with the irradiation-side opening only through the irradiation-side opening. It can irradiate light.

(Structure-Irradiation side sensor unit-Irradiation side optical filter)
The irradiation-side optical filter 111b is a transmission means that transmits light in a predetermined wavelength band, and specifically, transmits light in a wavelength band related to flame detection, for example, of flame light. It transmits only light in the wavelength band where the intensity peaks, and as an example, it can be configured by using a known optical filter that transmits only light in the wavelength band around 4.4 μm to 4.5 μm. Is. Further, the specific mounting position of the irradiation side optical filter 111b is arbitrary, but for example, the light outside the flame detection device 100 passes through the irradiation side optical filter 111b to the irradiation side sensor unit case 111a. It is provided in an irradiation-side opening (not shown) of the irradiation-side sensor unit case 111a so that the irradiation-side light detection unit 111c inside is irradiated.

(Structure-Irradiation side sensor unit-Irradiation side light detection unit)
The irradiation-side photodetector 111c is a conversion means that performs photoelectric conversion, and specifically, the first irradiation-side analog signal S11 corresponding to the amount of light radiated to itself (that is, the level corresponding to the amount of incident light). It is an irradiation side light detection means that outputs a signal) and is configured to irradiate itself with light from a flame. For example, it is housed in a case 111a for an irradiation side sensor unit. Therefore, the external light of the flame detection device 100 is irradiated to itself through the irradiation side optical filter 111b. For example, the above-mentioned irradiation side pyroelectric element, which is a known pyroelectric element. Can be configured using.

Here, the "first irradiation side analog signal" S11 is an irradiation side electric signal, and specifically, is an electric signal corresponding to the amount of light irradiated to the irradiation side light detection unit 111c. For example, it is an analog signal having a level corresponding to the amount of light irradiated to the irradiation side photodetector 111c, and is a signal on which signal noise caused by additional noise can be superimposed. FIG. 2 is an example of a waveform diagram of the first irradiation side analog signal in a state where signal noise is not superimposed. As shown in FIG. 2, the first irradiation side analog signal S11 in the state where the signal noise is not superimposed is, for example, a signal based on the reference voltage Vr, and in detail, the light of the flame is emitted. When the irradiation side light detection unit 111c is irradiated, an analog waveform is obtained as illustrated in FIG. 2, and when the flame light is not irradiated to the irradiation side light detection unit 111c (that is, when the incident light amount is "0"). In some cases), it is a signal having a constant level waveform shown as the reference voltage Vr in FIG.

(Construction-Irradiation side frequency filter)
The irradiation side frequency filter 112 of FIG. 1 is a filter means for passing a signal in a predetermined frequency band, specifically, for passing a signal in a frequency band related to flame detection, for example, a flame. It passes only the signal in the frequency band where the light flickers, and as an example, it can be configured by using a known signal filter that passes only the signal in the frequency band around 1 Hz to 15 Hz. Further, in the irradiation side frequency filter 112, for example, the first irradiation side analog signal S11 is input, and the predetermined frequency band of the first irradiation side analog signal S11 (for example, around 1 Hz to 15 Hz). The signal is output as the second irradiation side analog signal S12.

(Configuration-Irradiation side preamplifier)
The irradiation side preamplifier 113 is a pre-stage amplification means that amplifies a signal at a predetermined amplification factor, and specifically, amplifies the signal to a level suitable as an input level of the irradiation side main amplifier 114. It can be configured by using a known amplification circuit that amplifies at an amplification factor of several tens of times. For example, the irradiation side preamplifier 113 receives the second irradiation side analog signal S12 and amplifies the second irradiation side analog signal S12 at a predetermined amplification factor (for example, several times to several tens of times). The amplified signal is output as the third irradiation side analog signal S13.

(Configuration-Irradiation side main amplifier)
The irradiation side main amplifier 114 is a main amplification means that amplifies a signal at a predetermined amplification factor, and specifically, amplifies the signal to a level suitable as an input level of the removal unit 13 or the signal conversion unit 14, for example. , It can be configured by using a known amplification circuit that amplifies at an amplification factor of several hundred times to several thousand times. For example, the irradiation side main amplifier 114 receives the third irradiation side analog signal S13 and amplifies the third irradiation side analog signal S13 at a predetermined amplification factor (for example, several hundred times to several thousand times). Then, the amplified signal is output as the fourth irradiation side analog signal S14.

(Structure-Non-irradiation side signal generator)
The non-irradiation side signal generation unit 12 is a signal generation means for generating and outputting a non-irradiation side analog signal, and is mounted on, for example, the above-mentioned circuit board for a flame detection device on which the irradiation side signal generation unit 11 is mounted. As an example, the non-irradiated side sensor unit 121, the non-irradiated side frequency filter 122, the non-irradiated side preamplifier 123, and the non-irradiated side main amplifier 124 are provided.

Here, the "non-irradiation side analog signal" is an electrical signal, specifically, a signal to which signal noise can be superimposed due to the above-mentioned additional noise, for example, the first non-existence described later. It is a concept including an irradiation side analog signal S21, a second non-irradiation side analog signal S22, a third non-irradiation side analog signal S23, a fourth non-irradiation side analog signal S24, and the like.

(Structure-non-irradiation side sensor unit)
The non-irradiation side sensor unit 121 is a conversion means for performing photoelectric conversion, and specifically, is a signal output means for generating and outputting a first non-irradiation side analog signal S21 described later, for example, a non-irradiation side sensor. The unit case 121a, the non-irradiation side light-shielding material 121b, and the non-irradiation side light detection unit 121c are provided. Further, the non-irradiation side sensor unit 121 has the same configuration as the irradiation side sensor unit 111, except that its own non-irradiation side light-shielding material 121b is different from the irradiation side optical filter 111b of the irradiation side sensor unit 111. It is what has been done.

(Structure-Non-irradiation side sensor unit-Non-irradiation side sensor unit case)
The case 121a for the non-irradiation side sensor unit is a housing means for accommodating at least the non-irradiation side light detection unit 121c, and specifically forms the outer shape of the non-irradiation side sensor unit 121. Except for the matter, it is configured in the same manner as the case 111a for the irradiation side sensor unit, and has an opening on the non-irradiation side (not shown) for introducing external light of the flame detection device 100 inside itself. It is provided, and can irradiate the non-irradiation side light detection unit 121c housed by itself with light only through the non-irradiation side opening.

(Structure-Non-irradiated side sensor unit-Non-irradiated side light-shielding material)
The non-irradiated side light-shielding material 121b is a light-shielding means that blocks light in all bands, and is formed of, for example, a known light-shielding material. As an example, external light of the flame detection device 100 is used. However, the non-irradiated side sensor unit is prevented from being irradiated to the non-irradiated side light detection unit 121c in the non-irradiated side sensor unit case 121a through the non-irradiated side opening (not shown) of the non-irradiated side sensor unit case 121a. It is provided in a non-irradiated side opening (not shown) of the case 121a.

(Structure-Non-irradiation side sensor unit-Non-irradiation side light detection unit)
The non-irradiation side light detection unit 121c is a conversion means for performing photoelectric conversion, and specifically, the first non-irradiation side analog signal S21 corresponding to the amount of light irradiated to itself (that is, according to the amount of incident light). It is a non-irradiation side light detection means that outputs a level signal) and is configured so that the light from the flame is not irradiated to itself. For example, it is separate from the irradiation side light detection unit 111c. It is configured in the same manner as the irradiation side light detection unit 111c except for special matters, and is housed in the non-irradiation side sensor unit case 121a, and is the flame detection device 100. External light is shielded by the non-irradiation side light-shielding material 121b and is not irradiated to itself. As an example, the above-mentioned non-irradiation-side pyroelectric element, which can be configured by using a known pyroelectric element. Is.

Here, the "first non-irradiation side analog signal" S21 is a non-irradiation side electric signal, and specifically, an electric signal corresponding to the amount of light irradiated to the non-irradiation side light detection unit 121c. This is, for example, an analog signal having a level corresponding to the amount of light irradiated to the non-irradiated side light detection unit 121c, and is a signal on which signal noise due to additional noise can be superimposed. Further, the first non-irradiation side analog signal S21 in a state where signal noise is not superimposed is, for example, a signal having the same waveform as the above-mentioned first irradiation side analog signal S11, but the non-irradiation side light detection unit 121c. This is a signal having a constant level waveform of the reference voltage Vr in FIG. 2 because it is configured so that the light is not irradiated to the signal.

(Construction-Frequency filter on non-irradiation side)
The non-irradiated side frequency filter 122 is a filter means that passes a signal in a predetermined frequency band, and specifically, passes a signal in a frequency band related to flame detection. Except for this, it is configured in the same manner as the irradiation side frequency filter 112, and the first non-irradiation side analog signal S21 is input to a predetermined frequency band of the first non-irradiation side analog signal S21. As an example, a signal (near 1 Hz to 15 Hz) is output as the second non-irradiated side analog signal S22.

(Configuration-Non-irradiation side preamplifier)
The non-irradiation side preamplifier 123 is a pre-stage amplification means that amplifies a signal at a predetermined amplification factor, and specifically, amplifies to a level suitable as an input level of the non-irradiation side main amplifier 124. It is configured in the same manner as the irradiation side preamplifier 113 except for the matters to be performed, and the second non-irradiation side analog signal S22 is input, and the second non-irradiation side analog signal S22 is subjected to a predetermined amplification factor ( As an example, the signal is amplified by several times to several tens of times), and the amplified signal is output as the third non-irradiation side analog signal S23.

(Configuration-Non-irradiation side main amplifier)
The non-irradiation side main amplifier 124 is a main amplification means that amplifies a signal at a predetermined amplification factor, and specifically, amplifies the signal to a level suitable as an input level of the removal unit 13 or the signal conversion unit 14. For example, it is configured in the same manner as the irradiation side main amplifier 114 except for special matters, and a third non-irradiation side analog signal S23 is input to specify the third non-irradiation side analog signal S23. The amplification factor (for example, several hundred times to several thousand times) is amplified, and the amplified signal is output as the fourth non-irradiation side analog signal S24.

(Structure-removal part)
The removing unit 13 is a removing means for removing noise superimposed on the irradiation side analog signal output by the irradiation side signal generation unit 11 based on the non-irradiation side analog signal output by the non-irradiation side signal generation unit 12. Specifically, the first output by the irradiation side light detection unit 111c is based on the fourth non-irradiation side analog signal S24 corresponding to the first non-irradiation side analog signal S21 output by the non-irradiation side light detection unit 121c. It removes the signal noise superimposed on the fourth irradiation side analog signal S14 corresponding to the irradiation side analog signal S11, that is, the first non-irradiation side analog signal S21 output by the non-irradiation side light detection unit 121c. Based on this, the signal noise superimposed on the first irradiation side analog signal S11 output by the irradiation side light detection unit 111c is removed. Further, the removing unit 13 subtracts, for example, the fourth non-irradiation side analog signal S24 corresponding to the first non-irradiation side analog signal S21 from the fourth irradiation side analog signal S14 corresponding to the first irradiation side analog signal S11. Therefore, the signal noise superimposed on the fourth irradiation side analog signal S14 corresponding to the first irradiation side analog signal S11 is removed, that is, the first irradiation side analog signal S11 to the first non-irradiation side analog signal. By subtracting S21, the signal noise superimposed on the first irradiation side analog signal S11 is removed, and as an example, it can be configured by using a known subtraction circuit. Further, in the removing unit 13, for example, the fourth irradiation side analog signal S14 and the fourth non-irradiation side analog signal S24 are input, and the fourth non-irradiation unit 13 is input from the level of the input fourth irradiation side analog signal S14. By subtracting the level of the side analog signal S24, the signal noise superimposed on the input fourth irradiation side analog signal S14 is removed, and the fourth irradiation side analog signal S14 from which the signal noise is removed is the fifth. It is output as an irradiation side analog signal S15.

(Configuration-Signal converter)
The signal conversion unit 14 is a conversion means for converting the signal format, specifically, it converts an analog signal into a digital signal. For example, the fifth irradiation side analog signal S15 is input and input. The fifth irradiation side analog signal S15 is converted into a fifth irradiation side digital signal S16, which is a digital electric signal corresponding to the fifth irradiation side analog signal S15, and is output. For example, a known analog digital signal. It can be configured using a conversion circuit.

(Configuration-Communication unit)
The communication unit 15 is a communication means for communicating, for example, for communicating with a disaster prevention receiver (not shown), and can be configured by using a known wired or wireless communication circuit or the like. ..

(Structure-Recording unit)
The recording unit 16 is a recording means for recording a program and various data necessary for the operation of the flame detection device 100, and is configured by using, for example, an EEPROM, a Flash memory, or the like. However, instead of or together with EEPROM or Flash memory, an external recording device such as a hard disk, a magnetic recording medium such as a magnetic disk, an optical recording medium such as a DVD or Blu-ray disk, or a ROM, USB memory, SD. Any other recording medium, including an electrical recording medium such as a card, can be used.

(Configuration-Control unit)
The control unit 17 is a control means for controlling the flame detection device 100, and specifically, the CPU, various programs interpreted and executed on the CPU (basic control programs such as an OS, and specific programs started and specified on the OS). It is a computer configured with an internal memory such as a RAM (including an application program that realizes a function) and a RAM for storing the program and various data. In particular, the control program according to the embodiment is installed in the flame detection device 100 via an arbitrary recording medium or network to substantially configure each part of the control unit 17.

The control unit 17 is functionally conceptually provided with a flame detection unit 171. The flame detection unit 171 is a flame detection means for detecting a flame based on an irradiation side analog signal from which noise has been removed by the removal unit 13, and for example, a fifth irradiation side digital signal S16 is input and input. The flame is detected based on the fifth irradiation side digital signal S16. The processing performed by each unit of the control unit 17 will be described later.

(motion)
Next, the signal processing operation of the flame detection device 100 configured as described above will be described. The "signal processing operation" is an operation for processing an electric signal performed by the flame detection device 100, and here, when additional noise such as vibration, radio wave, or heat is added to the flame detection device 100. Each signal and each signal when additional noise is not applied to the flame detection device 100 will be described. In particular, when the additional noise is added to the flame detection device 100, the light of the flame is the flame detection device 100 when the irradiation side light detection unit 111c and the non-irradiation side light detection unit 121c are affected by the additional noise. The case of being irradiated with light will be described as an example. Further, the timing for executing this "signal processing operation" is arbitrary, but for example, it will be described from the point where the signal processing operation is started, assuming that the flame detection device 100 is started and executed after the power is turned on. ..

(Operation-when additional noise is added)
When the additional noise is applied to the flame detection device 100 and the light of the flame is irradiated to the flame detection device 100, the irradiation side light detection unit 111c is the irradiation side (not shown) of the irradiation side sensor unit case 111a. The light of the flame is irradiated through the irradiation side optical filter 111b of the opening. Then, the irradiation side light detection unit 111c is added as described above to the signal corresponding to the light amount of the irradiated light (for example, the signal of the AC waveform based on the reference voltage Vr exemplified in FIG. 2). The first irradiation side analog signal S11 on which the signal noise (for example, a relatively low frequency signal noise) caused by the additional noise is superimposed is output. The signal noise superimposed on the first irradiation side analog signal S11 will be referred to as "first irradiation side analog signal superimposed noise" and will be described below.

Next, the irradiation side frequency filter 112 is in a predetermined frequency band (for example, around 1 Hz to 15 Hz) of the first irradiation side analog signal S11 on which the “first irradiation side analog signal superimposition noise” is superimposed. The signal is output as the second irradiation side analog signal S12, and then the irradiation side preamplifier 113 amplifies the second irradiation side analog signal S12 at a predetermined amplification factor (for example, several times to several tens of times). Then, the amplified signal is output as the third irradiation side analog signal S13, and then the irradiation side main amplifier 114 outputs the third irradiation side analog signal S13 with a predetermined amplification factor (for example, several hundred times). It is amplified by ~ several thousand times), and the amplified signal is output to the removal unit 13 as the fourth irradiation side analog signal S14. In this case, the fourth irradiation side analog signal S14 output by the irradiation side main amplifier 114 has signal noise corresponding to the "first irradiation side analog signal superimposition noise" superimposed on the first irradiation side analog signal S11 described above. It will be in a superimposed state. The signal noise superimposed on the fourth irradiation side analog signal S14 will be referred to as "fourth irradiation side analog signal superimposed noise" and will be described below.

On the other hand, when the additional noise is applied to the flame detection device 100 and the light of the flame is irradiated to the flame detection device 100, the non-irradiation side light detection unit 121c is not the case 121a for the non-irradiation side sensor unit. Since the non-irradiated side light-shielding material 121b is provided in the non-irradiated side opening in the figure, the light of the flame is shielded by the non-irradiated side light-shielding material 121b, and the light of the flame is not irradiated. Then, the non-irradiated side light detection unit 121c is caused by the above-mentioned added noise with respect to the signal in the state where the light is not irradiated (for example, the signal of the reference voltage Vr exemplified in FIG. 2). The first non-irradiation side analog signal S21 on which the signal noise is superimposed is output. The signal noise superimposed on the first non-irradiated analog signal S21 will be referred to as "first non-irradiated analog signal superimposed noise" and will be described below. Further, regarding this "first non-irradiation side analog signal superimposition noise", the non-irradiation side light detection unit 121c and the irradiation side light detection unit 111c are mounted on the same circuit board for the flame detection device. Since it is configured in the same manner as the irradiation side light detection unit 111c, the noise is the same as the “first irradiation side analog signal superimposition noise” in the irradiation side light detection unit 111c.

Next, the non-irradiation side frequency filter 122 uses a predetermined frequency band (for example, 1 Hz to 15 Hz) of the first non-irradiation side analog signal S21 on which the “first non-irradiation side analog signal superimposition noise” is superimposed. The signal of (near) is output as the second non-irradiated side analog signal S22, and then the non-irradiated side preamplifier 123 outputs the second non-irradiated side analog signal S22 with a predetermined amplification factor (for example, several times to several times). It is amplified by several tens of times), and the amplified signal is output as the third non-irradiated side analog signal S23. Next, the non-irradiated side main amplifier 124 appoints the third non-irradiated side analog signal S23. It is amplified at a rate (for example, several hundred times to several thousand times), and the amplified signal is output to the removal unit 13 as the fourth non-irradiated side analog signal S24. In this case, the fourth non-irradiation side analog signal S24 output by the non-irradiation side main amplifier 124 responds to the "first non-irradiation side analog signal superimposition noise" superimposed on the first non-irradiation side analog signal S21 described above. The signal noise is superimposed. The signal noise superimposed on the fourth non-irradiation side analog signal S24 is referred to as "fourth non-irradiation side analog signal superimposed noise" and will be described below. Regarding this "fourth non-irradiation side analog signal superimposition noise", the non-irradiation side frequency filter 122, the non-irradiation side preamplifier 123, and the non-irradiation side main amplifier 124 are the irradiation side frequency filter 112, the irradiation side preamplifier 113, Since it is configured in the same manner as the irradiation side main amplifier 114, it has the same noise as the “fourth irradiation side analog signal superimposition noise” in the irradiation side main amplifier 114.

Next, the removing unit 13 superimposes the fourth irradiation side analog signal S14 on which the "fourth irradiation side analog signal superimposition noise" is superimposed and the fourth irradiation side analog signal superimposition noise on which the "fourth non-irradiation side analog signal superimposition noise" is superimposed. The non-irradiation side analog signal S24 is input, and the level of the input fourth non-irradiation side analog signal S24 is subtracted from the level of the input fourth irradiation side analog signal S14. The irradiation side analog signal S15 (that is, a signal from which the "fourth irradiation side analog signal superimposition noise" is removed from the input fourth irradiation side analog signal S14) is generated and output to the signal conversion unit 14. Here, as described above, the “fourth irradiation side analog signal superimposition noise” and the “fourth non-irradiation side analog signal superimposition noise” are similar noises to each other, and the irradiation side light detection unit 111c However, the "first irradiation side analog signal superimposition noise" is superimposed on the signal corresponding to the amount of the irradiated light (for example, the signal of the AC waveform based on the reference voltage Vr exemplified in FIG. 2). The first irradiation side analog signal S11 is output, and the non-irradiation side light detection unit 121c is used as a signal in a state where no light is irradiated (for example, a signal having a reference voltage Vr exemplified in FIG. 2). On the other hand, since the first non-irradiation side analog signal S21 on which the "first non-irradiation side analog signal superimposition noise" is superimposed is output, for example, the signal corresponding to the AC component in FIG. 2 is the signal of the subtraction result. It is generated and output as the fifth irradiation side analog signal S15.

Next, the signal conversion unit 14 is input with the fifth irradiation side analog signal S15, and the input fifth irradiation side analog signal S15 is a digital electric signal corresponding to the fifth irradiation side analog signal S15. It is converted into a certain fifth irradiation side digital signal S16 and output to the control unit 17.

Next, the control unit 17 receives the input of the fifth irradiation side digital signal S16, and performs each process based on the input fifth irradiation side digital signal S16.

(Operation-when no additional noise is added)
When the flame light is irradiated to the flame detection device 100 when the additional noise is not applied to the flame detection device 100, the irradiation side light detection unit 111c is irradiated with the flame light as described above. It will be. Then, the irradiation side light detection unit 111c uses a signal corresponding to the amount of irradiated light (for example, an AC waveform signal based on the reference voltage Vr exemplified in FIG. 2) as a first irradiation side analog signal S11. Is output as.

Next, the irradiation side frequency filter 112 outputs a signal in a predetermined frequency band of the first irradiation side analog signal S11 as the second irradiation side analog signal S12, and then the irradiation side preamplifier 113 outputs the signal in the predetermined frequency band. The second irradiation side analog signal S12 is amplified at a predetermined amplification factor, and the amplified signal is output as the third irradiation side analog signal S13. Next, the irradiation side main amplifier 114 uses the third irradiation side analog signal. S13 is amplified at a predetermined amplification factor, and the amplified signal is output to the removal unit 13 as the fourth irradiation side analog signal S14.

On the other hand, when the additional noise is not applied to the flame detection device 100 and the light of the flame is irradiated to the flame detection device 100, the non-irradiation side light detection unit 121c is the non-irradiation side sensor as described above. Since the non-irradiated side light-shielding material 121b is provided in the non-irradiated side opening of the part case 121a (not shown), the light of the flame is shielded by the non-irradiated side light-shielding material 121b and the flame light is not irradiated. become. Then, the non-irradiated side light detection unit 121c outputs a signal in a state where the light is not irradiated (for example, a signal of the reference voltage Vr illustrated in FIG. 2) as the first non-irradiated side analog signal S21.

Next, the non-irradiation side frequency filter 122 outputs a signal in a predetermined frequency band of the first non-irradiation side analog signal S21 as a second non-irradiation side analog signal S22, and then outputs the non-irradiation side analog signal S22. The 123 amplifies the second non-irradiating side analog signal S22 at a predetermined amplification factor, outputs the amplified signal as the third non-irradiating side analog signal S23, and then the non-irradiating side main amplifier 124 receives the amplified signal. The third non-irradiation side analog signal S23 is amplified at a predetermined amplification factor, and the amplified signal is output to the removal unit 13 as the fourth non-irradiation side analog signal S24.

Next, the removal unit 13 subtracts the level of the input fourth non-irradiation side analog signal S24 from the level of the input fourth irradiation side analog signal S14, and as a signal of the subtraction result described above. A fifth irradiation side analog signal S15 similar to the fifth irradiation side analog signal S15 described in "(Operation-when additional noise is added)" is generated and output to the signal conversion unit 14. After that, the signal conversion unit 14 and the control unit 17 perform the same operation as that described in the above-mentioned "(operation-when additional noise is added)". This ends the signal processing operation.

As described above, since the signal noise can be removed by the removing unit 13, at least the fifth irradiation side digital output to the control unit 17 is performed regardless of whether or not additional noise is added to the flame detection device 100. It is possible to eliminate the influence of signal noise in the signal S16.

(process)
Next, the flame detection process executed by the flame detection device 100 configured as described above will be described. FIG. 3 is a flowchart of the flame detection process (steps are abbreviated as “S” in the following description of each process). The "flame detection process" is a process for disaster prevention, specifically, a process of detecting a flame and notifying it via a disaster prevention receiver (not shown), for example, a power source of the flame detection device 100. After turning on, the flame detection process will be described from the point where the flame detection process is started, assuming that the flame detection process is repeatedly started and executed every predetermined time (for example, 10 to 20 seconds).

First, as shown in FIG. 3, the flame detection unit 171 in SA1 determines whether or not a flame has occurred. Specifically, any method including a known method can be used. For example, it is assumed that the flame determination threshold value, which is the threshold value for determining the flame, is recorded in the recording unit 16 of FIG. 1, and this flame is recorded. The determination threshold is compared with the integral value of the information indicated by the fifth irradiation side digital signal S16 (that is, the information corresponding to the amount of light emitted to the irradiation side light detection unit 111c), and the determination is made based on the comparison result. And. Then, when the above-mentioned integral value is less than the flame determination threshold value, it is determined that no flame has occurred (NO of SA1) without detecting the flame, and SA1 is repeated until it is determined that the flame has occurred. To execute. Further, when the above-mentioned integrated value becomes equal to or higher than the flame determination threshold value, the flame is detected, it is determined that the flame is generated (YES of SA1), and the process proceeds to SA2. Here, for example, when a flame is generated and the light of the flame is irradiated to the irradiation side light detection unit 111c of the flame detection device 100, it is determined that the integrated value is equal to or higher than the flame determination threshold value, and the flame is generated. judge.

Returning to FIG. 3, in SA2, the control unit 17 notifies the fire via a disaster prevention receiver (not shown). Specifically, any method including a known method can be used, but for example, a fire detection signal which is a signal indicating that a flame is detected and a fire is detected via the communication unit 15 of FIG. 1 is not used. By transmitting to the disaster prevention receiver shown in the figure, the fire occurrence is notified via the disaster prevention receiver. Here, for example, a fire detection signal is transmitted to a disaster prevention receiver (not shown) via the communication unit 15, and a message such as "a fire has been detected" is transmitted from the speaker of the disaster prevention receiver that has received the fire detection signal. The voice is output, or the indicator light of the disaster prevention receiver is made to emit light. After that, recovery is performed or a fire is determined on the disaster prevention receiver side (not shown), but since known processes can be applied to these processes, the description thereof will be omitted. This ends the flame detection process.

(Effect of embodiment)
As described above, according to the present embodiment, the irradiation side light detection unit 111c is based on the fourth non-irradiation side analog signal S24 corresponding to the first non-irradiation side analog signal S21 output by the non-irradiation side light detection unit 121c. By removing the signal noise superimposed on the fourth irradiation side analog signal S14 corresponding to the first irradiation side analog signal S11 output by, for example, to the first irradiation side analog signal S11 for detecting a flame. Since the influence of the signal noise superimposed on the corresponding fourth irradiation side analog signal S14 can be removed, it is possible to prevent the occurrence of false alarms that detect the flame even though the flame is not actually generated. It is possible to reliably detect the flame. Further, for example, the irradiation side light detection unit 111c and the non-irradiation side light detection unit 121c having similar configurations are superimposed on the fourth irradiation side analog signal S14 corresponding to the first irradiation side analog signal S11. Since signal noise can be removed, it has a different configuration from the components (that is, the irradiation side light detection unit 111c and the non-irradiation side light detection unit 121c) that perform an operation of outputting an electric signal corresponding to the amount of light. Since it is not necessary to provide an element (for example, an acceleration sensor), the types of components used in the flame detection device 100 can be reduced, and the assembly procedure of the flame detection device 100 can be simplified.

Further, by subtracting the fourth non-irradiation side analog signal S24 corresponding to the first non-irradiation side analog signal S21 from the fourth irradiation side analog signal S14 corresponding to the first irradiation side analog signal S11, the first irradiation side analog By removing the signal noise superimposed on the fourth irradiation side analog signal S14 corresponding to the signal S11, for example, the fourth irradiation side analog signal S14 corresponding to the first irradiation side analog signal S11 by a relatively simple process. Since the signal noise superimposed on the first irradiation side analog signal S11 can be removed, the signal noise superimposed on the fourth irradiation side analog signal S14 corresponding to the first irradiation side analog signal S11 can be quickly removed, and the flame can be reduced. It becomes possible to provide a flame detection device 100 capable of promptly and surely detecting. Further, for example, the removing unit 13 of the flame detection device 100 can be realized with a relatively simple configuration, and the manufacturing cost of the flame detection device 100 can be reduced by simplifying the manufacturing process of the flame detection device 100. can.

Further, a circuit board for a flame detection device (not shown) on which the irradiation side light detection unit 111c is mounted is provided, and the non-irradiation side light detection unit 121c is mounted on the flame detection device circuit board, so that, for example, the irradiation side light Since the detection unit 111c and the non-irradiation side light detection unit 121c are mounted on the flame detection device circuit board which is the same circuit board as each other, both the irradiation side light detection unit 111c and the non-irradiation side light detection unit 121c have the detection unit 111c and the non-irradiation side light detection unit 121c. On the other hand, similar additional noise is added to each other, and signal noise similar to the signal noise to be removed from the first irradiation side analog signal S11 can be superimposed on the first non-irradiation side analog signal S21. The signal noise can be reliably removed from the first irradiation side analog signal S11 by using the first non-irradiation side analog signal S21.

[Variation example with respect to the embodiment]
Although the embodiments according to the present invention have been described above, the specific configuration and means of the present invention shall be arbitrarily modified and improved within the scope of the technical idea of each invention described in the claims. Can be done. Hereinafter, such a modification will be described.

(About the problem to be solved and the effect of the invention)
First, the problem to be solved by the invention and the effect of the invention are not limited to the above-mentioned contents, and may differ depending on the implementation environment and the details of the configuration of the invention, and only a part of the above-mentioned problems. May be resolved or only some of the above effects may be achieved.

(About distribution and integration)
Further, the above-mentioned configuration is a functional concept, and does not necessarily have to be physically configured as shown in the figure. That is, the specific form of dispersion or integration of each part is not limited to the one shown in the figure, and all or a part thereof can be functionally or physically dispersed or integrated in any unit.

(About other removal parts (analog processing))
Further, a removal unit (hereinafter, another removal unit) such as the removal unit 13 described in the above embodiment is electrically connected to an arbitrary position instead of the removal unit 13, and flame detection is performed according to the connected position. The configuration of the device 100 may be arbitrarily rearranged. For example, another removing unit may be provided immediately after the irradiation side signal generation unit 11 and the non-irradiation side signal generation unit 12. Specifically, for this case, for example, for the other removal unit, the first irradiation side analog signal S11 and the first non-irradiation side analog signal S21 are input, and the input first irradiation side analog signal S11 to the first By subtracting the non-irradiation side analog signal S21, the signal noise superimposed on the first irradiation side analog signal S11 may be removed, and the signal from which the signal noise has been removed may be output. In the case of such a configuration, it is not necessary to have duplicated components for each component in the subsequent stage of the other removal unit. Therefore, for example, the duplicated components may be omitted. Specifically, for example, after omitting the non-irradiation side frequency filter 122, the non-irradiation side preamplifier 123, and the non-irradiation side main amplifier 124, the signal noise was removed by the irradiation side frequency filter 112 by another removing unit. Even if the above-mentioned signal is output and the signal is output to the control unit 17 via the irradiation side frequency filter 112, the irradiation side preamplifier 113, the irradiation side main amplifier 114, and the signal conversion unit 14. good.

Further, for example, another removing portion may be provided immediately after the irradiation side frequency filter 112 and the non-irradiation side frequency filter 122, or may be provided immediately after the irradiation side preamplifier 113 and the non-irradiation side preamplifier 123. In this case, as in the case where the other removal unit is provided immediately after the irradiation side signal generation unit 11 and the non-irradiation side signal generation unit 12, it is unnecessary that each component in the subsequent stage of the other removal unit is duplicated. Therefore, for example, duplicated ones may be omitted.

(About other removal parts (digital processing))
Further, after omitting the removal unit 13 described in the above embodiment, two signal conversion units such as the signal conversion unit 14 (hereinafter, the first other signal conversion unit and the second other signal conversion unit) are provided. For the first other signal conversion unit, the fourth irradiation side analog signal S14 is input, the input signal is converted into a digital signal, and then output to the control unit 17 to be output to the second unit. Regarding the other signal conversion units, the fourth non-irradiation side analog signal S24 is input, the input signal is converted into a digital signal, and then output to the control unit 17, and the control unit 17 is configured to output the signal. A noise removing unit which is a removing means may be provided. Then, for example, this noise removing unit superimposes on the irradiation side analog signal output by the irradiation side signal generation unit 11 based on the digital signals from the first other signal conversion unit and the second other signal conversion unit. The operation for removing the signal noise may be performed, and the flame detection unit 171 may be configured to detect the flame by using at least the calculation result of the noise removal unit.

Further, except that the control unit 17 is provided with a noise removing unit as a removing means, the flame detecting unit 171 is configured as described in "(About other removing units (digital processing))". , The presence or absence of superimposition of signal noise is determined based on the digital signal from the second other signal conversion unit, and when it is determined that there is superimposition of signal noise, the digital from the first other signal conversion unit is determined. Even if it is configured to determine whether or not a flame is generated when it is determined that there is no superimposition of signal noise without determining whether or not a flame is generated based on the signal. good.

(About the circuit board for the flame detection device)
Further, the case where the irradiation side signal generation unit 11 and the non-irradiation side signal generation unit 12 of the above embodiment are mounted on a circuit board for a flame detection device, which is the same circuit board as each other, has been described. Not exclusively. For example, as long as the irradiation side signal generation unit 11 and the non-irradiation side signal generation unit 12 are in an environment in which additional noise is added in the same manner, the irradiation side signal generation unit 11 and the non-irradiation side signal generation unit 12 may be used. , They may be mounted on different circuit boards, that is, they may be mounted on a circuit board other than the circuit board for the flame detection device. Further, when it is possible to identify a component included in the irradiation side signal generation unit 11 and the non-irradiation side signal generation unit 12 in which signal noise is likely to be superimposed on the signal output by itself based on the added noise. , Only the specified components may be provided in an environment in which additional noise is added in the same manner.

(Irradiated side electric signal and non-irradiated side electric signal)
Further, in the above embodiment, it has been described that the first irradiation side analog signal S11 is the irradiation side electric signal and the first non-irradiation side analog signal S21 is the non-irradiation side electric signal. You may. Specifically, all or only a part of the first irradiation side analog signal S11, the second irradiation side analog signal S12, the third irradiation side analog signal S13, and the fourth irradiation side analog signal S14. The signal may be interpreted as an irradiation side electric signal. Further, all or only a part of the first non-irradiation side analog signal S21, the second non-irradiation side analog signal S22, the third non-irradiation side analog signal S23, and the fourth non-irradiation side analog signal S24. The signal of may be interpreted as an electric signal on the non-irradiating side.

(About components)
Further, the components of the flame detection device 100 of the above embodiment may be arbitrarily rearranged as long as the characteristics of the present application are reflected. For example, the irradiation side preamplifier 113 and the irradiation side main amplifier 114 may be combined into one amplifier, or the non-irradiation side preamplifier 123 and the non-irradiation side main amplifier 124 may be combined into one amplifier. Further, for example, the function of the signal conversion unit 14 may be incorporated into the flame detection unit 171 so that the flame detection unit 171 directly receives the fifth irradiation side analog signal S15 to detect the flame.

(About the calculation of the integrated value)
Further, in the above embodiment, the integral value used when detecting the flame is subtracted by the removing unit 13, so that the offset of the reference voltage Vr in FIG. 2 is reduced at least for the signal of the subtraction result. May be calculated in consideration of.

(About the notification unit)
Further, the flame detection device 100 of FIG. 1 may be provided with a notification unit such as a speaker or an indicator lamp, and the notification unit of the flame detection device 100 may notify the fire with SA2 of FIG.

(About shading)
Further, in the above embodiment, the case where the non-irradiated side light-shielding material 121b of FIG. 1 is used to block the light to the non-irradiated side light detection unit 121c has been described, but the present invention is not limited to this, and any method can be used. It may be shielded from light. For example, the case for the non-irradiated side sensor portion is configured so that the “non-irradiated side opening not shown) of the non-irradiated side sensor portion case 121a described in the embodiment is not provided (that is, closed). The case itself for the non-irradiation side sensor unit having such a configuration may block the light to the non-irradiation side light detection unit 121c. Further, for example, the non-irradiation side sensor unit 121 described in the embodiment is provided at a position inside the case of the flame detection device 100 so as not to be irradiated with light, and the non-irradiation side sensor is provided in the case of the flame detection device 100. The light to the unit 121 (that is, the non-irradiated side light detection unit 121c) may be shielded. Further, for example, an external light-shielding member having the same function (that is, a light-shielding function) as that of the non-irradiation-side light-shielding material 121b in FIG. 1 is provided outside the non-irradiation-side sensor unit case 121a, and the external light-shielding member is used. The light to the non-irradiated side light detection unit 121c may be blocked.

(Characteristics and application)
Further, the features of the above-described embodiment and the features of the modified examples may be arbitrarily combined. Further, these features may be applied to a flame detection device of a method of detecting a flame by focusing on a plurality of wavelength bands.

(Additional note)
The flame detecting device of Appendix 1 is a flame detecting device that detects the flame based on the light from the flame, and is an irradiation side light detecting means that outputs an irradiation side electric signal at a level corresponding to the amount of incident light. The irradiation side light detecting means configured to irradiate itself with the light from the flame, and the non-irradiating side light detecting means for outputting a non-irradiating side electric signal at a level corresponding to the amount of incident light. The irradiation side light detection is based on the non-irradiation side light detecting means configured so that the light from the flame is not irradiated to itself and the non-irradiation side electric signal output by the non-irradiation side light detection means. A removing means for removing noise superimposed on the irradiation-side electric signal output by the means, a flame detecting means for detecting the flame based on the irradiation-side electric signal from which noise has been removed by the removing means, and a flame detecting means. To prepare for.

The flame detection device according to the appendix 2 is the flame detection device according to the appendix 1. The removing means outputs the non-irradiation side electric signal by subtracting the non-irradiation side electric signal from the irradiation side electric signal. The noise superimposed on the irradiation side electric signal is removed.

The flame detecting device of the appendix 3 includes a circuit board for mounting the irradiation side light detecting means in the flame detecting device according to the appendix 1 or 2, and the non-irradiating side light detecting means is mounted on the circuit board. ing.

(Effect of appendix)
According to the flame detection device described in Appendix 1, noise superimposed on the irradiation side electric signal output by the irradiation side light detection means is removed based on the non-irradiation side electric signal output by the non-irradiation side light detection means. By doing so, for example, the influence of the noise superimposed on the irradiation side electric signal on the detection of the flame can be removed, so that the flame is detected even though the flame is not actually generated. It is possible to prevent the occurrence of false alarms and reliably detect flames. Further, for example, the noise superimposed on the irradiation side electric signal can be removed by using the irradiation side light detection means and the non-irradiation side light detection means having similar configurations to each other, so that it corresponds to the amount of light. Since it is not necessary to provide another component (for example, an acceleration sensor) different from the component (that is, the irradiation side light detection means and the non-irradiation side light detection means) that performs the operation of outputting the electric signal, the flame detection is performed. The types of components used in the device can be reduced, and the procedure for assembling the flame detection device can be simplified.

According to the flame detection device described in Appendix 2, the noise superimposed on the irradiation side electric signal is removed by subtracting the non-irradiation side electric signal from the irradiation side electric signal, for example, which is relatively simple. Since the noise superimposed on the irradiation side electric signal can be removed by the processing, the noise superimposed on the irradiation side electric signal can be quickly removed, and the flame can be detected quickly and reliably. It becomes possible to provide a flame detection device. Further, for example, the removing means of the flame detection device can be realized with a relatively simple configuration, and the manufacturing cost of the flame detection device can be reduced by simplifying the manufacturing process of the flame detection device.

According to the flame detection device described in Appendix 3, a circuit board for mounting the irradiation side light detection means is provided, and the non-irradiation side light detection means is mounted on the circuit board, so that, for example, the irradiation side light detection means and the irradiation side light detection means and Since the non-irradiating side photodetecting means are mounted on the same circuit board, the same noise is added to both the illuminated side light detecting means and the non-irradiating side light detecting means. Noise similar to the noise to be removed from the irradiation side electric signal can be superimposed on the non-irradiation side electric signal, and it is possible to reliably remove the noise from the irradiation side electric signal using this non-irradiation side electric signal. Become.

11 Irradiation side signal generation unit 12 Non-irradiation side signal generation unit 13 Removal unit 14 Signal conversion unit 15 Communication unit 16 Recording unit 17 Control unit 100 Flame detection device 111 Irradiation side sensor unit 111a Irradiation side sensor unit case 111b Irradiation side optical type Filter 111c Irradiation side light detection unit 112 Irradiation side frequency filter 113 Irradiation side preamplifier 114 Irradiation side main amplifier 121 Non-irradiation side sensor part 121a Non-irradiation side sensor part case 121b Non-irradiation side shading material 121c Non-irradiation side light detection part 122 Non Irradiation side frequency filter 123 Non-irradiation side preamplifier 124 Non-irradiation side main amplifier 171 Flame detector S11 1st irradiation side analog signal S12 2nd irradiation side analog signal S13 3rd irradiation side analog signal S14 4th irradiation side analog signal S15 5th Irradiation side analog signal S16 5th irradiation side digital signal S21 1st non-irradiation side analog signal S22 2nd non-irradiation side analog signal S23 3rd non-irradiation side analog signal S24 4th non-irradiation side analog signal Vr reference voltage

Claims (3)

A flame detection device that detects the flame based on the light from the flame.
An irradiation-side signal generation means that outputs an irradiation-side electric signal at a level corresponding to the amount of incident light, and is configured to irradiate itself with light from the flame.
The non-irradiated side signal generating means for outputting a non-irradiated side electric signal at a level corresponding to the amount of incident light, and the non-irradiated side signal generating means configured so as not to irradiate the self with the light from the flame.
A removing means for removing noise superimposed on the irradiation side electric signal output by the irradiation side signal generation means based on the non-irradiation side electric signal output by the non-irradiation side signal generation means.
A flame detecting means for detecting the flame based on the irradiation side electric signal from which noise has been removed by the removing means is provided.
Each of the irradiation-side signal generating means and the non-irradiation-side signal generating unit is configured similarly to one another includes a sensor portion accommodated in the case for a separate sensor, and amplifier unit, and a frequency filter unit ,
Flame detector. The removing means removes the noise superimposed on the irradiation side electric signal output by the irradiation side signal generation means by subtracting the non-irradiation side electric signal from the irradiation side electric signal.
The flame detection device according to claim 1. A circuit board on which the irradiation side signal generation means is mounted is provided.
The non-irradiation side signal generation means is mounted on the circuit board.
The flame detection device according to claim 1 or 2.

Images