TW200834477A - Multi-band flame detection device and method thereof - Google Patents

Abstract

The invention is related to a multi-band flame detection device and method thereof. The multi-band flame detection device includes a light detection module and a signal processing module. The light detection module can detect multiple radiation light-waves generated from burning of flame. The detected range of light-wave bands relating to this multi-band flame detection device are between 4,000 and 5,000 nanometers in infrared light-wave, between 400 and 1100 nanometers in visible lightwave, and between 100 and 400 nano-meters in ultraviolet light-wave. Therefore, the light detection module can convert the radiation light-wave into corresponding multiple light signals, which are judged whether the fire happens or not by the signal processing module. If the fire really happens, a triggering signal is generated to trigger an alarm system and fire extinguisher system to carry out the fire fighting.

Description

200834477 IX. Description of the invention: [Technical field to which the invention pertains] In particular, a multi-band multi-band invention relates to a flame detecting device and method thereof, a flame detecting device and a method thereof. [Prior Art] According to the tour, send == things =’, ί ΓΙΓ 健康 healthy kindergarten teachers and students to the Liufu Village Wildlife Park to avoid the incident of fire burning, resulting in a teacher, two parents and

The fire burned to death, Lin eight students, - recorded _ heavy _ 妓 riding axis == burned car case caused six people were burned to death, we can report in the newspaper every second 'two accidents' will cause some casualties, How to reduce the incidence of such accidents t '疋大豕 expected I usually fire the vehicle, the engine is often the most prone to fire. If the words __ fire level, set the warning, the automatic fire-fighting measures will be saved, will save many precious lives. When the fire talks about burning, because the fiber has no _f, the spectrum of fire bribes generated by it is also different. If the chlorine gas burns, it will emit & weak ultraviolet light. Need to be high spirit = go _. There are paid infrared spectacles such as thieves and firewood scales. There are secrets in both bands that are rich in radiation. For carbon ydn)earbGn flames) materials, the flames produced by the job, such as wood, paper, gasoline and natural gas, will produce yellow/red visible light flames, and others will affect the material of each spectrum, and the environment will also produce Some interference light sources often cause false alarm signals to occur. Most of the flames burn, in addition to detecting the occurrence of ultraviolet light, of course, there are also the emergence of heat and smoke. Therefore, some people have developed flame detectors, such as the flame detector of the Republic of China Patent Gazette No. 177462. This patent is a flame detector characterized by: an ultraviolet sensor that senses at least the ultraviolet light contained in the flame; a power source battery; and a DC that boosts the voltage of the power source battery to the operating voltage of the ultraviolet sensor. a DC converter circuit; a drive circuit for outputting a pulse signal from the ultraviolet sensor; and a pulse of the signal transmitted from the ultraviolet sensor 200834477. The signal is a flame circuit that is generated by the ultraviolet light of the flame and is caused by the nuclear sensing other material line; The fire 阙 路 _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ The window is exposed to the outside. " ... is also the "Flame Detection System" of the Republic of China Patent Gazette No. 24449, which is a flame detection system suitable for the side-wavelength-infrared ray and located at the first: a difference in radiant intensity between the second infrared rays of the wavelength near the wavelength, and stimulating the alarm device, " the first infrared ray of the first wavelength is generated by resonance radiation of carbon dioxide, the second infrared line is in the wavelength region (d) absorbed by carbon dioxide in the air. The feature is that the detection side of the flame passes through the short period of the segment, and after the first infrared radiation and the second & 'pitch intensity difference, the second infrared Lin bribe cake exceeds a certain value. = The actor is activated by the above alarm device. Although the above-mentioned conventional techniques only use the detection of ultraviolet light or infrared light to determine whether or not a fire has occurred, the environment may also generate some interference light sources, which often leads to the occurrence of a false number, so the ^&&; The present invention is directed to a multi-band flame detecting device and a method thereof, which can detect infrared light waves, visible light waves, and ultraviolet light waves.

A secondary object of the present invention is to provide a multi-band flame detecting device and a method thereof, which can determine a plurality of face-to-face touch-to-return records according to a predetermined flame flicker frequency and a band ratio range. scale. ^ ^ Another object of the present invention is to provide a multi-band flame detecting device and a method thereof, wherein when a fire alarm is confirmed, the new section fires (4) generates a trigger signal, and the alarm system and the fire extinguishing system are driven according to the trigger signal. To achieve the effects of warnings and disaster relief. Another object of the present invention is to provide a multi-band flame detecting device and a method thereof. The present invention uses a CMOS sensor or a CCD detector to detect visible light signals, and can capture and display the 200834477 flame image. The current state of fire. In order to achieve the above object, the present invention is a multi-band flame detecting device and a method thereof, and the present invention relates to a light-band gamma device comprising a light gamma module and a signal processing module, A plurality of radiated light waves generated by a flame burning on the side of the light-sampling module, the light-emitting optical wave systems are respectively (four) wavelength bands, and some of the light waves are subdivided into the fine elements of the band, and corresponding to the leveling The plurality of optical pros are then processed by the signal processing method, and the fire is generated by the hybrid nucleus. When the fire occurs, a trigger signal is generated. The multi-band flame gamma device of the present invention includes a driving module, and the signal processing group receives the trigger signal, and the driving module drives an alarm system and a fire extinguishing system according to the trigger signal. Warning and disaster relief. . ^ [Implementation] In order to enable your review committee to have a better understanding and understanding of the structural features and effects achieved by the reviewer, I would like to discuss the actual side and the detailed system, as follows: "Month" The first figure is a schematic diagram of the basic device of the present invention. As shown in the figure, the multi-wave, flame thin device of the present invention comprises a light detecting module 1 and a signal processing module 12, and the light is similar. The 1G side of the 1G side is full of the I-level of the reduced-valve I, and the radiation is replaced by a corresponding plurality of optical signals, and the auxiliary numbers are transmitted to the signal processing module 1 for processing according to the light. The processing result of ## confirms whether a fire alarm occurs. If the fire alarm is generated, the domain processing module 12 generates a trigger signal to drive an alarm system 16 and a 屮 屮 amp Q Q Q Q Q Q Q , , , , , , , , , The device is a schematic diagram of a device according to a preferred embodiment of the present invention. As shown in the figure, the flame side device 1a of the present embodiment includes a light side module gamma, a signal processing module = and - drive. The module 14a, the optical copper module 1Ga includes a first detecting unit, and a ^ The second detection unit 1 () 2a and - the third detection unit is achieving, the first detection unit is a system containing a - filter single (four) la, the first - light single unit is - filter, mirror, with a transitional flame Burning a plurality of radiated light waves generated by 200834477, so that the optical band of the range of between 4000 nm and 5 nanometers passes through the -first-radiation light wave, and the first radiation light wave system is touched according to the optical band range The infrared level is transmitted to the first detecting unit, and the first detecting unit 101a detects the infrared light wave of the optical band fc between 働0 nm and the bay nanometer, and the first detecting unit detects the infrared light wave The first-radiation light wave generates a first optical signal and transmits the signal to the signal processing module. The second detecting unit transmits a second filter unit, and the second filter unit and the second detecting unit _Additional _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ a second illuminating light wave passes through, the second radiant light wave is transmitted to the knife light unit, the first The second radiant light wave of the radiant light wave in the range of 4Q 〇 nanometer and 11 (9) nanometer directly penetrates the light splitting unit to the second detecting unit 102a, according to the optical band range of the third radiated light wave The third radiant light wave is a visible light wave/near-infrared light wave, and the second detecting unit 103a detects a visible light wave/near-infrared light wave with a light band ranging between 400 nm and 1100 nm, and can be a CM0S a sensor or a CCD sensor, a face 敎 m m step-display, the display unit displays the image, and finally the second detecting unit 10 〇 3a detects the third radiant light, generating a a second optical signal: 1 φ and the beam splitting unit 105a reflects a fourth radiation light wave in the second radiation light wave having a wavelength band ranging from 1 nanometer to 400 nanometer to the third detecting unit 1 4a, according to the fourth Hanxian wave light band, the third radiation level ultraviolet light wave, and the third detection 'unit 104a detecting light band range between 100 nm and 4 nanometers The ultraviolet light wave is detected by the third detecting unit l〇4a The fourth radiant light wave is measured to generate a third optical signal. The first optical signal, the second optical signal, and the third optical signal are transmitted to the signal processing module. The signal processing module 12a includes a filtering unit 120a, a detecting unit 12, and a triggering unit 124a. The signal processing module 12a receives the first optical signal, the second optical signal, and the third optical signal, and the filtering unit 12A filters the plurality of flame flicker frequencies corresponding to the optical signals to determine the flames. Whether the flashing frequency falls within a range of flame flickering frequency. If the 200834477 falls within the flame flashing frequency range, even if the optical signals pass the next signal processing, the flame flashing frequency range is between 2 Hz and 50 Hz. between. The filtered optical signals are transmitted to the detecting unit 122a. In this embodiment, a threshold voltage value is preset to determine whether the voltage values of the optical signals exceed the threshold voltage value, and the optical signals are used. When the voltage value exceeds the threshold voltage value, it is confirmed that a fire alarm has occurred, and a trigger signal is generated by the trigger unit 124a.

The triggering signal is further transmitted to the driving module 14a. The driving module i4a receives the triggering signal. The driving module 14a drives an alarm system 16a to issue an alarm, and drives a fire extinguishing system 18a to perform fire fighting and disaster relief. To prevent power failure due to fire alarm, an automatic power supply system 20a can be driven to maintain the power of the multi-band flame detecting device 1& Please refer to the third figure, which is a schematic diagram of a device according to another preferred embodiment of the present invention. As shown in the figure, in this embodiment, an amplifying unit and a comparing unit 123a are added to the signal processing module 12a. The amplifying unit 121a is disposed in front of the detecting unit 122a, and the amplifying unit 121a is Amplifying the voltage values corresponding to the optical signals, and the comparing unit is finely preset-band ratio, and the ratio of the bands is between 〇·5 and I 5, when the optical signals of the optical signals are When the ratio is in the range of the band ratio, it is more certain that a fire invitation has occurred. Please refer to the fourth figure, a schematic diagram of another embodiment of the present invention. As shown in the figure: this embodiment provides - the flame side green, the recording step S1Q, the light fine mold _ measured the flame spread of the Wei spread level 'and the gallop wire turns the thread of the light The signals 'the optical signals include infrared light signals with a fine segment between the side nanometer and the rice, and a visible light signal with a light band between the mother and the nanometer. The ultraviolet light signal between 1GG nanometer and 4G0 nanometer enters the step of committing crimes, and uses the letter to deal with the ship's single-simplification _ some light money on the red button fires off the fire 1 in the preset fire Guande _, When the approximate frequency of the recorded silk is within the range of the flame flicker frequency, the step su is performed, and then the «_unit_the plurality of voltage values of the optical signals are used, and the critical voltage value is used. When the electrical noise is greater than the threshold voltage, the step training is performed, and the triggering unit of the 200834477 module confirms that a fire has occurred, that is, a trigger signal is generated. If it is determined in step S12 that the plurality of flame flash frequencies corresponding to the light signals are not within the flame flicker frequency range, then returning to step S10, if it is determined in step S14 that the voltage values are less than the threshold voltage value, Then, it returns to step S10. Please refer to the fifth figure for a schematic flow chart of another embodiment of the present invention. As shown in the figure, this embodiment adds a step S13 to the step S14 before the step S14, and determines whether the band ratio of the optical signals is within a range ratio, and the band ratio range is between 〇·5 and Between 丨·5, if the ratio of the band of the optical signals falls within the ratio of the band, that is, it is determined that a fire has occurred, then steps S14 and S16 are performed, and the trigger signal is generated and transmitted to a driving module, by using the The driving module drives the alarm system and the fire extinguishing system to achieve the effects of warning and disaster relief. It can be seen from the above that the multi-band flame detecting device and the method thereof of the present invention have sensors of various wavelength bands, such as infrared detecting light band range between 4 00 nm and 5 〇〇〇 nanometer. Photodetector, visible light sensor with a range of between 400 nm and n (10) nm, and a thin-light band between the (10) Nai shed nanometer. / then radiating light waves of different bands, and then generating corresponding plurality of optical signals, the optical signals are processed by L-number, and the optical signals are judged by the pre-twisted flame flashing frequency and the band ratio to confirm whether the real fire occurs. The false alarm rate of the multi-band flame detecting device is reduced by the above method. In summary, the present invention is a novelty, progressive and available for industrial use, and should conform to the patent application provisions stipulated in the Patent Law of China, and the application for the invention patent is filed, and the prayer bureau is early. Granting a patent, it is a prayer. Each of the above is only the preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and is equally uniform in shape, structure, features, and spirit as described in the scope of the present application. Variations and modifications are intended to be included within the scope of the invention. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a basic device of the present invention; FIG. 2 is a schematic view of a device according to a preferred embodiment of the present invention; 200834477 FIG. 3 is a schematic view of a device according to another preferred embodiment of the present invention; Figure 4 is a flow chart showing another embodiment of the present invention; and Figure 5 is a flow chart showing another embodiment of the present invention. [Main component symbol description]

1 Multi-band flame detection device 10 Light detection module 12 Signal processing module 16 Alarm system 18 Fire suppression system la Multi-band flame detection device 10 a Light detection module 100a First detection unit 101a First filter unit 102a Second detecting unit 103a Second filtering unit 104a Third detecting unit 105a Light splitting unit 106a Display unit 12a Signal processing module 120a Filter unit 121a Amplifying unit 122a Detection unit 123a Comparison unit 124a Trigger unit 14a Drive module 16a Alarm system 18a Fire extinguishing system 11 200834477 2〇a Automatic power supply system

Claims (1)

200834477 X. Patent application scope: L A multi-band flame detecting device, comprising: a light detecting module, detecting a flame, converting a plurality of radiated light waves generated by burning the flame into corresponding plurality of The optical signal; and 2 a signal processing module receives the optical signals for signal processing to generate a trigger signal. The multi-band flame measuring device according to claim 1, wherein the optical module comprises a first filter unit for filtering a plurality of radiated light waves generated by the flame combustion. Passing a first radiation light wave; and a first detecting unit receiving the first radiation light wave to generate a first light signal. • The multi-band flame detecting device described in claim 2, wherein the first filter unit is a filter. 4·=Please refer to the multiple-in-one flame device described in item 2 of the patent scope, wherein the wavelength band of the radiation light received by the first filter unit is between 4〇(10) nanometers and 5〇〇〇米米The multi-band flame detecting device described in claim 2, wherein the optical band of the radiant light detected by the first detecting unit is between 4000 nm and 5000 nm. . 6. The multi-band flame detecting device of claim 2, wherein the first radiant wave has an optical band ranging between 4 nanometers and 5 nanometers. The multi-band multi-band flame side device according to claim 1, wherein the light detecting module comprises: a second filtering and light unit, which is a plurality of filtering light waves generated by filtering the fiber. Passing a second radiation light wave; and a second detecting unit receiving the second radiation light wave to generate a second light signal. 8·=Application of the multi-band flame device described in the scope of claim 7, wherein the second filter unit is a filter. 13 200834477 9·=The multi-band flame detecting device described in claim 7 wherein the second light-receiving unit receives a range of light wavelengths of 100 nm & n3〇奈厶1〇. t Apply for the multi-band flame steel skirt described in item 7 of the patent scope, wherein the range of the optical wavelength of the radiant light detected by the second detecting unit is between _ nanometer and rice 11. 12· ^ The special section of the 7th handle is described as the fire section __, and the second detection unit is a sensor, which is the image of the flame. The multi-band flame detection as described in the scope of the patent application is a CMOS sensor or a CCD sensor. Set, where the sensor system 13. 14· 15· 16· 17· The multi-band flame copper device according to the scope of the patent application, wherein the sensor is connected to the unit, and the image of the second inspector is taken. For example, the multi-band flame detection device described in claim 7 wherein the first light-emitting wave has a light band range between 100 nm and 1100 nm. Μ Ida, for example, applies for the multi-band fire-test device described in item 7 of the full-time, wherein the second filter unit 7G and the second system add a light splitting unit, and the light splitting unit is a second light-emitting light wave. Dividing into a third radiant wave and a illuminating wave, the third illuminating wave is transmitted to the second detecting unit, and the fourth radiant wave is transmitted to a third detecting unit. The multi-band flame detecting device of claim 15, wherein the third radiating wave has an optical band ranging between 400 nm and 1100 nm. " As in the patented fine item 15 of the new section of the flame device, the band of the fourth ray of the light wave is between 1 nanometer and 4 nanometer. [18] The multi-band flame_device according to claim 1, wherein the signal processing module comprises: a filtering unit that receives a plurality of optical signals and determines a plurality of flame flickers corresponding to the optical signals Whether the frequency is within a flame flashing frequency range; a detecting unit receives the optical signals processed by the filtering unit, and detects whether the voltage values of the 200834477 optical signals reach a threshold voltage value; and triggers The single 7G receives the optical signals processed by the detecting unit to generate a trigger signal. • A multi-band flame detection device as described in Section 18 of the patent application, wherein the flame flicker frequency range is between 2 Hz and 50 Hz. 20. The multi-band flame detecting device of claim 18, wherein the threshold voltage value exceeds 〇·8 volts. The multi-band flame detecting device according to claim 18, wherein the signal processing pull group further comprises: a comparing unit, determining whether the band ratio of the optical signals is in a range of ratios Inside. 22. The multi-band flame detecting device of claim 21, wherein the optical signal has a band ratio ranging between 〇·5 and 1.5. The multi-band flame detecting device of claim 18, wherein the signal processing module further comprises: an amplifying unit disposed in front of the detecting unit to amplify the optical signals. The multi-band flame detecting device of claim 2, further comprising: a driving module that receives the trigger signal to drive an alarm system and a fire extinguishing system. The multi-band flame detecting device of claim 24, wherein the driving module further drives an automatic power supply system that supplies power to the multi-band flame detecting device. 2δ· a multi-band flame detection method, comprising: detecting a plurality of radiation light waves generated by flame combustion, and converting into corresponding plurality of light signals; determining a plurality of flame flicker frequencies corresponding to the light signals in a flame a flashing frequency range; determining that the plurality of voltage values corresponding to the filtered optical signals are greater than a threshold voltage value; and 15 200834477 confirming that a fire alarm has occurred, that is, generating a trigger signal. The multi-band flame detecting method of claim 26, wherein the flame flash frequency range is between 2 Hz and 50 Hz. ^ ^ ua Shen. For example, please refer to the multi-band flame method described in Patent Item 26, in which it is judged that the pair of optical signals are connected to the plural The band ratio is in the range of one band ratio.多 The multi-band flame detection method described in claim 28, the range is between 0.5 and 1.5. ^ ^ 30 · As described in the multi-band flame detection method described in claim 28, the complex flame signal corresponding to the plurality of flames _ frequency is not in the fire __ rate range: "It is said that the ceremony is as claimed in the 26th item of the patent scope. The 兮 signal corresponds to a plurality of fires. ·If the ratio of the band of the multi-band flame as described in the application for patent scope 帛28 is not within the ratio of the band, then the re-execution level is as described in the 26th paragraph of the patent application scope. The light signals after the flame detection! The scaly plural value of the thief critical = + touch the step of detecting the flame after the evasive.