CN201266419Y - Distributed fibre-optical Laman photon temperature-sensing fire disaster detector - Google Patents

Distributed fibre-optical Laman photon temperature-sensing fire disaster detector Download PDF

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Publication number
CN201266419Y
CN201266419Y CNU2008201222254U CN200820122225U CN201266419Y CN 201266419 Y CN201266419 Y CN 201266419Y CN U2008201222254 U CNU2008201222254 U CN U2008201222254U CN 200820122225 U CN200820122225 U CN 200820122225U CN 201266419 Y CN201266419 Y CN 201266419Y
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China
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optical fiber
temperature
type optical
sensing
fire disaster
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CNU2008201222254U
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Chinese (zh)
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张在宣
张淑琴
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Hangzhou OE Photoelectric Technology Co., Ltd.
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China Jiliang University
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Abstract

The utility model discloses a distributed optical fiber Raman photon temperature-sensing fire detector which is produced by being based on the integrated optical fiber wavelength division multiplexing technology and utilizing the principle that the optical fiber anti-Stokes Raman photon intensity is modulated by the optical fiber temperature and the optical time-domain reflection principle. The fire detector comprises an optical pulse laser, an integrated optical fiber wavelength division multiplexer, an intrinsic temperature-sensing optical fiber, two photoelectric avalanche diodes, a digital signal processor and a display or an alarm. The intrinsic temperature-sensing optical fiber which is paved on a disaster prevention site is not charged and has anti-electromagnetic interference capability, radiation resistance and corrosion resistance, thereby being not only a transmission medium, but also a sensing medium. The fire detector has low cost, long service life, simple structure, good signal-to-noise ratio and good reliability, thereby being applicable to the temperature-sensing fire detection with medium-range and short-range from 100m to 15km.

Description

A kind of distributed type optical fiber Raman photon temperature sensing fire disaster detector
Technical field
The utility model relates to fire monitoring device, especially distributed type optical fiber Raman photon temperature sensing fire disaster detector.
Background technology
For a long time, mainly use linear temperature sensitive cable as line-type heat detector in fire prevention and engineering field both at home and abroad, temperature sensing cable is the cable of a kind of two cores and employing " ON/OFF " formula principle design.When the default temperature of two built-in core lead whats, be subjected to heat of solution just can form wire short-circuiting and report to the police.The temperature sensing cable relative low price, but can not locate, the change procedure of the scene temperature of taking precautions against natural calamities can not be forecast.
Development in recent years is got up utilizes distributed optical fiber temperature sensor and quasi-distributed fibre optic temperature sensor (mainly containing grating type optical fiber and the Fabry-perot optical fiber type) heat fire detector as line style fire monitoring temperature-sensitive optical fiber, it can online in real time forecast variation of temperature, can alarm temperature be set in very big temperature range, be the line-type heat detector of essential safe type, on power industry, petroleum chemical enterprise and civil engineering work, successfully use.Distributed optical fiber temperature sensor has two kinds: a kind of is the Raman scattering type, and another kind is the Brillouin scattering type.
The Raman scattering of optical fiber is very weak, existing external intermediate range distributed type optical fiber Raman photon temperature sensor, adopt discrete wavelength division multiplexer system and 1064nm fiber laser, discrete wavelength division multiplexer complex structure, loss is big, and isolation is low, the cost height, poor reliability, and the fibre loss of 1064nm wave band is big.
Summary of the invention
The purpose of this utility model provides that a kind of cost is low, simple in structure, signal to noise ratio (S/N ratio) is good, the distributed type optical fiber Raman photon temperature sensing fire disaster detector of good reliability.
The distributed type optical fiber Raman photon temperature sensing fire disaster detector of invention, comprise the light pulse laser instrument, the integrated-type optical fibre wavelength division multiplexer, Intrinsical temperature-sensitive optical fiber, two photoelectricity avalanche diodes, digital signal processor and display or alarm, the integrated-type optical fibre wavelength division multiplexer has four ports, 1550nm port wherein links to each other with the light pulse laser instrument, public port links to each other with Intrinsical temperature-sensitive optical fiber, the 1450nm port links to each other with the first photoelectricity avalanche diode, the 1660nm port links to each other with the second photoelectricity avalanche diode, the other end of the other end of the first photoelectricity avalanche diode and the second photoelectricity avalanche diode links to each other with digital signal processor respectively, and the signal output part of digital signal processor connects display or alarm.
It is 1550nm that light pulse laser instrument in the utility model adopts centre wavelength, and spectral width is 0.1nm, and laser pulse width is 18ns or 8ns, and peak power is 20W, and repetition frequency is the light pulse laser instrument of 4kHz.
Intrinsical temperature-sensitive optical fiber in the utility model is 62.5/125 multimode optical fiber, and the temperature-sensitive fiber lengths is 100m~15km.
Said integrated-type optical fibre wavelength division multiplexer can be integrated by discrete optical fiber bidirectional coupler, optical fiber parallel light path, Stokes and anti-Stokes Raman diffused light broad band pass filter, has 1550nm, common port, four ports of 1450nm and 1660nm.
Intrinsical temperature-sensitive optical fibre installation is at the scene of taking precautions against natural calamities, and this optical fiber is not charged, anti-electromagnetic interference (EMI), radiation hardness, corrosion-resistant, be transmission medium be again sensor information.The light pulse laser instrument sends laser pulse and injects Intrinsical temperature-sensitive optical fiber by the integrated-type optical fibre wavelength division multiplexer, Stokes dorsad that produces on Intrinsical temperature-sensitive optical fiber and anti-Stokes Raman light wavelet are through the beam splitting of integrated-type optical fibre wavelength division multiplexer, convert analog electrical signal and amplification to through two photoelectricity avalanche diodes respectively, by both strength ratios, obtain the temperature information of each section of optical fiber, provide the temperature of each heat detection point on the Intrinsical temperature-sensitive optical fiber, temperature changing speed and direction utilize optical time domain reflection to Raman photon temperature sensing detection point location on the temperature-sensitive optical fiber (optical fibre radar location).By the digital signal processor demodulation, through Temperature Scaling, in 30 seconds, obtain Raman photon temperature sensing detection on the Intrinsical temperature-sensitive optical fiber and put the temperature variation at each place, spatial domain, temperature measurement accuracy ± 1 ℃, in 0 ℃ of-300 ℃ of scope, carry out the forecast of fire on-line monitoring, carry out the telecommunication network transmission by the display demonstration or by communication interface, communications protocol, when spatial domain, the Raman photon temperature sensing detection point place temperature on the temperature-sensitive optical fiber reaches the fire alarm temperature of setting, send fire alarm signal to fire alarm control unit.
The temperature-measurement principle of distributed type optical fiber Raman photon temperature sensing fire disaster detector:
Fiber pulse laser sends laser pulse and injects Intrinsical temperature-sensitive optical fiber by the integrated-type optical fibre wavelength division multiplexer, the nonlinear interaction of laser and optical fiber molecule, incident photon is become another low frequency Stokes photon or high frequency anti-Stokes photon by a molecular scattering, corresponding molecule is finished two transition between the vibrational state, emit a phonon and be called the Stokes Raman scattering photon, absorb a phonon and be called the anti-Stokes Raman scattering photon, the phonon frequency of optical fiber molecule is 13.2THz.Boltzmann (Boltzmann) law is obeyed in population heat distribution on the optical fiber molecular entergy level, the strength ratio R (T) of anti-Stokes Raman diffused light and Stokes Raman diffused light:
R ( T ) = [ v as v s ] 4 e - ( hΔ v r kT ) - - - ( 1 )
ν wherein As, ν sBe respectively the frequency of anti-Stokes Raman scattering photon and Stokes Raman scattering photon, h is Bo Langke (Planck) constant, Δ ν rThe phonon frequency that is an optical fiber molecule is 13.2THz, and k is a Boltzmann constant, T Shi Kay that literary composition (Kelvin) absolute temperature.By both strength ratios, obtain the temperature information of each section of optical fiber.The temperature control of Raman scattering photon is obtained by (1) formula:
1 R ( T ) dR ( T ) dT = hΔ v r k T 2 - - - ( 2 )
At room temperature T=293K, the thermometric degree sensitivity that obtains distributed type optical fiber Raman photon temperature sensing fire disaster detector is about 0.80%/K.
The beneficial effects of the utility model are:
The utility model adopts integrated wavelength division multiplexer, has improved the signal to noise ratio (S/N ratio) of distributed type optical fiber Raman photon temperature sensor system, and reliability and spatial resolution have reduced cost; The utility model is selected the communication band of the low optical fiber loss of 1550nm for use, is different from external intermediate range distributed optical fiber temperature sensor, is better than temperature sensing cable and other temperature-sensitive optic fibre fire detector on cost performance.Be laid on the on-the-spot temperature-sensitive optical fiber of taking precautions against natural calamities and insulate, uncharged, anti-electromagnetic interference (EMI), radiation hardness, corrosion resistant, be essential safe type, optical fiber be transmission medium be again sensor information, be the temperature-sensitive optical fiber of Intrinsical, and have the long-life more than 50 years.During the utility model is applicable to, 100 meters-15 kilometers temperature-sensing fire detectings of short distance.
Description of drawings
Fig. 1 is the synoptic diagram of distributed type optical fiber Raman photon temperature sensing fire disaster detector.
Embodiment
With reference to Fig. 1, distributed type optical fiber Raman photon temperature sensing fire disaster detector comprises light pulse laser instrument 10, integrated-type optical fibre wavelength division multiplexer 11, Intrinsical temperature-sensitive optical fiber 12, two photoelectricity avalanche diodes 13,14, digital signal processor 15 and display or alarm 16, integrated-type optical fibre wavelength division multiplexer 11 has four ports, 1550nm port wherein links to each other with light pulse laser instrument 10, public port links to each other with Intrinsical temperature-sensitive optical fiber 12, the 1450nm port links to each other with the first photoelectricity avalanche diode 13, the 1660nm port links to each other with the second photoelectricity avalanche diode 14, the other end of the other end of the first photoelectricity avalanche diode 13 and the second photoelectricity avalanche diode 14 links to each other with digital signal processor 15 respectively, and the signal output part of digital signal processor 15 connects display or alarm 16.
The Intrinsical temperature-sensitive optical fiber that is laid on the scene of taking precautions against natural calamities is 15 kilometers long 62.5/125 multimode optical fiber, it is 1550nm that the light pulse laser instrument adopts centre wavelength, spectral width is 0.1nm, laser pulse width is 18ns, and peak power is 20W, and repetition frequency is the light pulse laser instrument of 4kHz, at this moment, 15 kilometers long 62.5/125 multimode optical fiber, temperature-sensitive length is 3 meters, has 5000 heat detection points.If it is 1550nm that the light pulse laser instrument adopts centre wavelength, spectral width is 0.1nm, laser pulse width is 8ns, peak power is 20W, repetition frequency is the light pulse laser instrument of 4kHz, 15 kilometers long 62.5/125 multimode optical fiber then, temperature-sensitive length is 1 meter, has 15000 heat detection points.
Digital signal processor Bian is inserted in the computing machine with general signal processing card.Digital signal processor can adopt the binary channels 100MHz bandwidth of America NI company, the NI5911 type signal processing card of 100MS/s Bian collection rate, or adopt Canadian GaGe company binary channels, the CS21GB-1GHz type signal processing card of 500MS/s acquisition rate.

Claims (4)

1. distributed type optical fiber Raman photon temperature sensing fire disaster detector, it is characterized in that comprising light pulse laser instrument (10), integrated-type optical fibre wavelength division multiplexer (11), Intrinsical temperature-sensitive optical fiber (12), two photoelectricity avalanche diodes (13), (14), digital signal processor (15) and display or alarm (16), integrated-type optical fibre wavelength division multiplexer (11) has four ports, 1550nm port wherein links to each other with light pulse laser instrument (10), public port links to each other with Intrinsical temperature-sensitive optical fiber (12), the 1450nm port links to each other with the first photoelectricity avalanche diode (13), the 1660nm port links to each other with the second photoelectricity avalanche diode (14), the other end of the other end of the first photoelectricity avalanche diode (13) and the second photoelectricity avalanche diode (14) links to each other with digital signal processor (15) respectively, and the signal output part of digital signal processor (15) connects display or alarm (16).
2. distributed type optical fiber Raman photon temperature sensing fire disaster detector according to claim 1, the centre wavelength that it is characterized in that light pulse laser instrument (10) is 1550nm, and spectral width is 0.1nm, and laser pulse width is 18ns or 8ns, peak power is 20W, and repetition frequency is 4kHz.
3. distributed type optical fiber Raman photon temperature sensing fire disaster detector according to claim 1 is characterized in that Intrinsical temperature-sensitive optical fiber (12) is 62.5/125 multimode optical fiber, and temperature-sensitive optical fiber (12) length is 100m~15km.
4. distributed type optical fiber Raman photon temperature sensing fire disaster detector according to claim 1, it is characterized in that integrated-type optical fibre wavelength division multiplexer (11), integrated by discrete optical fiber bidirectional coupler, optical fiber parallel light path, Stokes and anti-Stokes Raman diffused light broad band pass filter.
CNU2008201222254U 2008-07-25 2008-07-25 Distributed fibre-optical Laman photon temperature-sensing fire disaster detector Expired - Lifetime CN201266419Y (en)

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Cited By (7)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN102161429A (en) * 2010-12-31 2011-08-24 聚光科技(杭州)股份有限公司 On-line monitoring device and method of belt conveyor fault based on optical fiber technology
CN102280004A (en) * 2011-05-26 2011-12-14 无锡圣敏传感科技有限公司 Heat fire detector of high-sensitivity Raman sensing optical fiber
CN103180702A (en) * 2010-08-05 2013-06-26 韩国标准科学研究院 Optic fiber distributed temperature sensor system with self- correction function and temperature measuring method using thereof
CN104361707A (en) * 2014-09-09 2015-02-18 杭州东环电气有限公司 Fiber-optic temperature-sensing fire detector system
CN106353003A (en) * 2016-08-10 2017-01-25 深圳艾瑞斯通技术有限公司 Distributed optical fiber temperature measuring method and system
CN109520636A (en) * 2018-11-13 2019-03-26 上海隽富机电科技有限公司 A kind of high pressure enclosed busbar on-line monitoring management system based on optical fiber
CN111982189A (en) * 2020-07-29 2020-11-24 电子科技大学 High-precision sensing method for simultaneously realizing temperature and strain based on photon detection technology

Cited By (11)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN103180702A (en) * 2010-08-05 2013-06-26 韩国标准科学研究院 Optic fiber distributed temperature sensor system with self- correction function and temperature measuring method using thereof
CN103180702B (en) * 2010-08-05 2014-12-10 韩国标准科学研究院 Optic fiber distributed temperature sensor system with self-correction function and temperature measuring method using thereof
CN102161429A (en) * 2010-12-31 2011-08-24 聚光科技(杭州)股份有限公司 On-line monitoring device and method of belt conveyor fault based on optical fiber technology
CN102280004A (en) * 2011-05-26 2011-12-14 无锡圣敏传感科技有限公司 Heat fire detector of high-sensitivity Raman sensing optical fiber
CN102280004B (en) * 2011-05-26 2015-03-25 无锡圣敏传感科技有限公司 Heat fire detector of high-sensitivity Raman sensing optical fiber
CN104361707A (en) * 2014-09-09 2015-02-18 杭州东环电气有限公司 Fiber-optic temperature-sensing fire detector system
CN106353003A (en) * 2016-08-10 2017-01-25 深圳艾瑞斯通技术有限公司 Distributed optical fiber temperature measuring method and system
CN106353003B (en) * 2016-08-10 2019-03-01 深圳艾瑞斯通技术有限公司 A kind of distributed optical fiber temperature measuring method and system
CN109520636A (en) * 2018-11-13 2019-03-26 上海隽富机电科技有限公司 A kind of high pressure enclosed busbar on-line monitoring management system based on optical fiber
CN111982189A (en) * 2020-07-29 2020-11-24 电子科技大学 High-precision sensing method for simultaneously realizing temperature and strain based on photon detection technology
CN111982189B (en) * 2020-07-29 2022-04-29 电子科技大学 High-precision sensing method for simultaneously realizing temperature and strain based on photon detection technology

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Owner name: HANGZHOU OUYI OPTOELECTRONICS CO., LTD.

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Effective date: 20100325

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Free format text: CORRECT: ADDRESS; FROM: 310018 XUEYUAN STREET, XIASHA HIGHER EDUCATION PARK ZONE, HANGZHOU CITY, ZHEJIANG PROVINCE TO: 310018 NO.258, XUEYUAN STREET, XIASHA HIGHER EDUCATION PARK ZONE, HANGZHOU CITY, ZHEJIANG PROVINCE

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Address after: Hangzhou City, Zhejiang province 310018 Xiasha Higher Education Park source Street No. 258

Patentee after: Hangzhou OE Photoelectric Technology Co., Ltd.

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Patentee before: China Jiliang University

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Granted publication date: 20090701

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