CN202903340U - A fiber-grating-sensing-technology-based ambient temperature monitoring system of an oil and gas pipeline in permafrost region - Google Patents

Abstract

The utility model discloses a fiber-grating-sensing-technology-based ambient temperature monitoring system of an oil and gas pipeline in permafrost region. Fiber grating temperature sensor groups are mounted on the surface of and around the oil and gas pipeline in permafrost region. All the sensor groups are connected with an optical cable (12) and are guided to a monitoring station by the optical cable (12). The optical cable (12) is connected with an optical switch (13) which is connected with a fiber grating demodulation instrument (14). The fiber grating demodulation instrument (14) is connected with a slave computer (15). Data preprocessed by the slave computer (15) is transmitted to a low-orbit satellite (17) via a first satellite communication module (16). The low-orbit satellite (17) forwards the data to a second satellite communication module (18). The received data is transmitted to a principal computer (19) by the second satellite communication module (18) to be analyzed and processed. The ambient temperature monitoring system has characteristics of high precision, and high stability, and low cost.

Description

A kind of permafrost region oil and gas pipes environment temperature monitoring system

Technical field

The utility model is a kind of permafrost region oil and gas pipes environment temperature monitoring system based on fiber grating sensing technology, and measurement, other class that relates to measurement of length, temperature do not comprise measurement, general control system and piping system technical field.

Background technology

Frozen soil is a kind of special great soil group, and temperature is subzero temperature or zero temperature, and contains the soil of ice, is called frozen soil.By the length of native frozen state retention time, frozen soil generally can be divided into again in short-term frozen soil (a few hours are to first quarter moon), seasonal frozen ground (first quarter moon is to the several months) and ever frost (more than 2 years).China's frozen soil is grown very much, and the ever frost area is about 2,110,000 square kilometres, accounts for 23% of China's territory total area, accounts for the 3rd in the world, mainly is distributed in Qinghai-Tibet Platean, western high mountain and northeast Xing'anling mountains; The frost zone area is about 5,140,000 square kilometres, accounts for 53.5% of territory total area.Wherein, middle degree of depth seasonal frozen ground (＞1m) account for 1/3 of area, mainly be distributed in the ground such as three provinces in the northeast of China, the Inner Mongol, Gansu, Ningxia, In The North of Xinjiang, Qinghai and Chuan Xi.

Developed country's oil pipeline construction has more than 100 year history, and a lot of Frozen Ground Areas are contained huge hydrocarbon resources, and correspondingly the oil and gas pipes engineering design and construction becomes the up-to-date challenge of these regional petroleum industries.Since the sixties in 20th century, large diameter pipeline begins leading northern North america and Siberia Permafrost Area oil gas field transports market.During the Second World War, gram is exerted (Canol) pipeline and is transported crude oil to the Fairbanks city, Alaska State (Fairbanks) of the U.S. from Canadian Luo Man well; The oil pipe that caliber in 1956 is 203mm is built successfully to the Fei Bankesi city from this city of Alaska State glycolylurea (Haines); 20 century 70s are early stage, and the USSR (Union of Soviet Socialist Republics) Permafrost Area has oil pipeline; 1977, long 1280km, diameter are that the oil pipeline of 1220mm is transported to the natural warm water port Wa Erdisi (Valdez) in south, Alaska continuously with the crude oil of U.S.'s Alaska State north slope low temperature Permafrost Area, then oil tanker with crude oil transportation to the California.20th century the mid-80, economize the environment temperature pipeline of northern our horse (Zama) lake, long 869km, bore 30.5cm from Canadian Luo Man well to Canadian Ahlport (Alberta) and finish laying on time, the Luo Man well conduit is the oil pipeline that Canadian Permafrost Area article one is buried underground fully.These pipelines all are subject to threat even the destruction of permafrost region frozen swell and melt settlement disaster during runing.Wherein, gram is exerted (Canol) pipeline after bringing into operation front 9 months, and pipeline has 700x10 along the line approximately ⁴The L crude oil leakage.12700m on the Mackenzie riverbank ³Storage tank farm break, most of oil storage flows in the river.Behind the Japan surrenders in 1945, this pipeline is removed soon; The Luo Man well conduit is along the line by way of discontinuous ever frost, construction and frost heave and the thaw collapse problem of meeting in service, by reaching the monitoring in 17 years, find that pipeline ever frost along the line continues to melt and sedimentation causes thaw depth to reach 3-5m (gyittja) or 5-7m (coarse particle mineral soil), and significant land subsidence.

The long oil and gas pipeline of article one that China builds in Permafrost Area, i.e. Golmud-Lhasa oil pipeline (be called for short lattice backguy), the lattice backguy was constructed by the Chinese People's Liberation Army in 1972, substantially built up in 1977, and reached 1076km, caliber 159mm, thickness of pipe 6mm, investment 2.3x108 unit.Lattice backguy engineering is built and is safeguarded very difficultly, and completely the spanning of river is 108, road crossing 123 places, and more than 900 kilometer pipeline (highest point height above sea level 5200m) more than height above sea level 4000m, 560km is positioned at Permafrost Area, and freezing period, reach 8 months.The lattice backguy is since operation in 1977, and frost heave, thaw collapse problem have caused repeatedly " revealing pipe " phenomenon.

China-Russia Crude Oil Pipeline reaches the grand celebration terminal in the south North gets boundary line, Sino-Russian Heilungkiang, Mo River initial station, and more than 960 kilometer of total length by way of two provinces, 12 counties and districts in five cities, passed through 440 kilometers virgin forests, 11 big-and-middle-sized rivers, 5 wilderness areas.High south, pipeline physical features along the line north is low, and northern topographic relief is larger, is Daxing'an Mountainrange low mountain, hills and river valley geomorgy along the line, and the south is song-Nen plain, and landform is smooth open; Mo River-about 460km of Jagdaqi section is mountain area, forest zone, Permafrost Area, and the about 314km of ever frost total length wherein ices, ices more ever frost 209km less, full ice, rich ice ever frost 62km, frozen soil marsh 43km.Pipeline is faced with serious frozen swell and melt settlement disaster and threatens.

For the frozen swell and melt settlement problem that pipeline faces, unit of operation has taked positive counter-measure both at home and abroad.After the Luo Man well conduit was gone into operation in 1985, the daily monitoring plan of pipeline is being implemented as the important component part of project operation always, except weekly aircraft aerial surveillance, also a large amount of measuring instruments has been installed with the record service data along the line at pipeline, and in annual September, carry out an on-site land survey when namely pipe sedimentation is maximum with the record of finishing pipeline on-site inspection along the line, instrument data and the work such as site assessment of coming down the location.After 1989, the Luo Man well conduit adopts in-pipeline detector to carry out annual interior detection, to assess the motion of the unstable soil body and otherness thaw collapse to the influence degree of pipeline, along with continuous accumulation and the expansion of detection data, for the assessment of pipe technology performance provides good basis.Norman wells pipeline is the oil and gas pipes that article one is embedded in Canadian northern Permafrost Area, be in charge of and run by adding by Enbridge company, under the requirement of various regulations rules, set up one and planned monitoring system careful, strong operability, comprising the content of seven aspects such as the monitoring of frozen soil thaw collapse, pipeline detection, warpage arch detection, wrinkle detection, slope test, the detection of wood chip stratiform condition and temperature monitoring.The variation of frozen soil is also monitored in lattice trombone slide road by regular line walking, setting pressure, temperature sensor etc.

Although pipeline unit of operation has taked the frozen swell and melt settlement disaster of positive measure reply permafrost region both at home and abroad, but because the formation mechanism of frozen swell and melt settlement disaster is very complicated, and the frozen soil characteristic of different regions is different, at present both at home and abroad and there are no the monitoring technology of maturation, can monitor the frozen swell and melt settlement disaster to the impact of pipeline.

The utility model content

The purpose of this utility model is design a kind of high precision, high stability, cheaply based on the permafrost region oil and gas pipes environment temperature monitoring system of fiber grating sensing technology.

The utility model proposes a kind of permafrost region oil and gas pipes environment temperature monitoring system based on fiber grating sensing technology.System adopts fiber grating sensing technology, the oil and gas pipes under frozen soil and the impact thereof is monitored, and made up monitoring system, has realized real-time automatic collecting, remote transmission and the automatic analysis of data.

The permafrost region oil and gas pipes environment temperature monitoring system based on fiber grating sensing technology that the utility model proposes, the permafrost region temperature monitoring adopts the fiber-optical grating temperature sensor real time on-line monitoring.

This permafrost region oil and gas pipes environment temperature monitoring system as shown in Figure 1, this system is divided into on-site data gathering transmission subsystem and data analysis display subsystem, specifically comprises fiber-optical grating temperature sensor group, field monitoring station, remote monitoring center.

The overall formation of permafrost region oil and gas pipes environment temperature monitoring system as shown in Figure 1.On oil and gas pipes 2 surface of permafrost region 1 and a plurality of fiber-optical grating temperature sensor a 3 are installed on every side, fiber-optical grating temperature sensor b4, the sets of temperature sensors that fiber-optical grating temperature sensor c 5 forms, the all the sensors series welding, then guide in the monitoring station by optical cable 12, optical cable 12 is connected with photoswitch 13, photoswitch 13 is connected with fiber Bragg grating (FBG) demodulator 14, fiber Bragg grating (FBG) demodulator 14 is connected with slave computer 15, slave computer 15 pretreated data communication devices are crossed satellite communication module 16 and are transferred to low-orbit satellite 17, low-orbit satellite 17 forwards the data to satellite communication module 18 after receiving data, satellite communication module 18 is analyzed the data transmission that receives and process to host computer 19, thereby realizes the safety monitoring to the permafrost region oil and gas pipes.

Fiber-optical grating temperature sensor a 3, fiber-optical grating temperature sensor b 4, fiber-optical grating temperature sensor c5 pass to photoswitch 13 with the temperature signal of pipeline through optical cable 12 respectively, reach slave computer 15 through fiber Bragg grating (FBG) demodulator 14 demodulation, slave computer 15 calls self-editing program, control photoswitch 13 and fiber Bragg grating (FBG) demodulator 14 are realized data acquisition and data are carried out pre-service; Pretreated data communication device is crossed satellite communication module 16 and is transferred to low-orbit satellite 17, low-orbit satellite 17 forwards the data to satellite communication module 18 after receiving data, satellite communication module 18 is analyzed the data transmission that receives and process to host computer 19, judges the safe condition of permafrost region pipeline.The processing of data is mainly finished by software, and software flow as shown in Figure 3.The pre-service of slave computer data mainly is with the data based temperature data that is converted into of the optical wavelength of fiber Bragg grating (FBG) demodulator collection, host computer is behind receive data, at first with Data classification, draw out the trend map of pipeline temperature, and three Monitoring Data merge the most at last, judge the steady state (SS) of permafrost region and the safety case of pipeline.

The theory diagram of permafrost region oil and gas pipes environment temperature monitoring system as shown in Figure 3, it is divided into on-site data gathering transmission subsystem and data analysis display subsystem.The composition of on-site data gathering transmission subsystem is: the output of fiber-optical grating temperature sensor connects the input of photoswitch, the output of photoswitch connects the input of fiber Bragg grating (FBG) demodulator, fiber Bragg grating (FBG) demodulator output connects the input of slave computer, and slave computer output connects satellite communication module.The on-site data gathering transmission subsystem links by low-orbit satellite and data analysis display subsystem.The composition of data analysis display subsystem is: satellite communication module output connects the input of host computer, and host computer output has the permafrost region temperature field dynamically to show.

The electric principle of this system as shown in Figure 4, the FC joint of fiber-optical grating temperature sensor group respectively with the FC input port 1 of photoswitch, FC input port 2, FC input port 3 connects, the R232 port of photoswitch connects the R232 port one of slave computer, the FC output port of photoswitch connects the FC input port of fiber Bragg grating (FBG) demodulator, the LAN port of fiber Bragg grating (FBG) demodulator connects the LAN port of slave computer, the VGA of slave computer is connected with the VGA of display, the R232 port 2 of slave computer connects the R232 port of satellite communication module, satellite communication module transfers data to low-orbit satellite, low-orbit satellite forwards the data to another satellite communication module in real time, by the R232 port of R232 port transmission to host computer, host computer exports display to by the VGA port after data analysis is processed to this satellite communication module with receive data.

Fiber grating pass the temperature sensor signal through photoswitch 13 one by one conducting transfer to fiber Bragg grating (FBG) demodulator 14, the centre wavelength that fiber Bragg grating (FBG) demodulator 14 demodulates each fiber-optic grating sensor transfers to slave computer 15, and the cycle of photoswitch 13 Continuity signals is by slave computer 15 controls.15 pairs of data of slave computer are carried out pre-service, and the data after will processing are defeated by satellite communication module 16, satellite communication module 16 transfers data to low-orbit satellite 17, low-orbit satellite 17 forwards the data to satellite communication module 18 in real time, satellite communication module 18 transfers to host computer with receive data, host computer carries out analyzing and processing by self-programmed software to data, is shown by display.

Fiber-optical grating temperature sensor is for developing voluntarily sensor.Fiber-optical grating temperature sensor adopts the structure of double-layer pipe, has not only improved the sensitivity of sensor, and has played protective effect.

Except the foregoing circuit part, the formation of the fiber-optical grating temperature sensor group of permafrost region oil and gas pipes environment temperature monitoring system is:

The formation of permafrost region fiber-optical grating temperature sensor group is as shown in Figure 3: at pipeline c28 up and down, and respectively installing optical fibres grating temperature sensor group a 29, fiber-optical grating temperature sensor group b 30, fiber-optical grating temperature sensor group c 31, fiber-optical grating temperature sensor group d 32.Sets of temperature sensors 29 is comprised of several fiber-optical grating temperature sensors 33, and the quantity of fiber-optical grating temperature sensor 33 and interval can arrange according to demand.Connect by single core armored optical cable 34 between sets of temperature sensors 30 and the sets of temperature sensors 32.Fiber-optical grating temperature sensor group a 29, fiber-optical grating temperature sensor group b 30, fiber-optical grating temperature sensor group c 31, fiber-optical grating temperature sensor group d 32 are connected with data collector by cable junction box 35, realize the monitoring of pipeline temperature.

The advantage of native system shows:

(1) proposes to descend oil and gas pipes to carry out the system of combined monitoring on permafrost region and impact thereof, disclosed frozen soil effect lower tube body stress characteristic and body and the interactional feature of frozen soil; Carry out the safe early warning of the lower oil and gas pipes of frozen soil impact with many indexs;

(2) fiber grating sensing technology is applied to permafrost region pipeline monitoring, this technology is anti-interference, corrosion-resistant, it is with the obvious advantage to be easy to networking etc.; This technology is easy to realize automatic real time on-line monitoring, and cost is lower;

(3) permafrost region temperature monitoring, adopt fiber-optical grating temperature sensor monitoring permafrost region temperature, because fiber grating sensing technology has the advantage of wavelength-division multiplex, an optical fiber a plurality of fiber-optical grating temperature sensors of can connecting, avoid complicated cabling, also saved cost simultaneously.

Description of drawings

Fig. 1 adopts permafrost region oil and gas pipes monitoring principle figure

Fig. 2 permafrost region pipe temperature monitoring device figure

Fig. 3 permafrost region oil and gas pipes Fundamentals of Supervisory Systems block diagram

Fig. 4 permafrost region oil and gas pipes monitoring system electrical schematic diagram

1-permafrost region 2-pipeline a wherein

3-fiber-optical grating temperature sensor a 4-fiber-optical grating temperature sensor b

5-fiber-optical grating temperature sensor c 12-optical cable

13-photoswitch 14-fiber Bragg grating (FBG) demodulator

15-slave computer 16-satellite communication module a

17-low-orbit satellite 18-satellite communication module b

19-host computer 28-pipeline c

29-fiber-optical grating temperature sensor group a 30-fiber-optical grating temperature sensor group b

31-fiber-optical grating temperature sensor group c 32-fiber-optical grating temperature sensor group d

The single core armored optical cable of 33-fiber-optical grating temperature sensor d 34-a

35-cable junction box b

Embodiment

Embodiment. this example is a kind of pilot system, and tests for the permafrost region of the full ice of rich ice at frost zone thickness 2m, frozen soil type, buried depth of pipeline 2m wherein, pipe diameter is that 813mm, wall thickness are 10mm, grade of steel X65.

The overall formation of permafrost region oil and gas pipes environment temperature monitoring system as shown in Figure 1, theory diagram is as shown in Figure 3.Installing optical fibres grating temperature sensor 3 on oil and gas pipes 2 surface of permafrost region 1 and on every side, 4,5 sets of temperature sensors that form, the all the sensors series welding, then guide in the monitoring station by optical cable 12, optical cable 12 is connected with photoswitch 13, photoswitch 13 is connected with fiber Bragg grating (FBG) demodulator 14, fiber Bragg grating (FBG) demodulator 14 is connected with slave computer 15, slave computer 15 pretreated data communication devices are crossed satellite communication module 16 and are transferred to low-orbit satellite 17, low-orbit satellite 17 forwards the data to satellite communication module 18 after receiving data, satellite communication module 18 is analyzed the data transmission that receives and process to host computer 19, thereby realizes the safety monitoring to the permafrost region oil and gas pipes.

The electric principle of this example as shown in Figure 4, the FC joint of fiber-optical grating temperature sensor group respectively with the FC input port 1 of photoswitch, FC input port 2, FC input port 3 connects, the R232 port of photoswitch connects the R232 port one of slave computer, the FC output port of photoswitch connects the FC input port of fiber Bragg grating (FBG) demodulator, the LAN port of fiber Bragg grating (FBG) demodulator connects the LAN port of slave computer, the VGA of slave computer is connected with the VGA of display, the R232 port 2 of slave computer connects the R232 port of satellite communication module, satellite communication module transfers data to low-orbit satellite, low-orbit satellite forwards the data to another satellite communication module in real time, by the R232 port of R232 port transmission to host computer, host computer exports display to by the VGA port after data analysis is processed to this satellite communication module with receive data.

The fiber-optical grating temperature sensor signal through photoswitch 13 one by one conducting transfer to fiber Bragg grating (FBG) demodulator 14, the centre wavelength that fiber Bragg grating (FBG) demodulator 14 demodulates each fiber-optic grating sensor transfers to slave computer 15, and the cycle of photoswitch 13 Continuity signals is by slave computer 15 controls.15 pairs of data of slave computer are carried out pre-service, and the data after will processing are defeated by satellite communication module 16, satellite communication module 16 transfers data to low-orbit satellite 17, low-orbit satellite 17 forwards the data to satellite communication module 18 in real time, satellite communication module 18 transfers to host computer with receive data, host computer carries out analyzing and processing by self-programmed software to data, is shown by display.

Wherein:

Fiber-optical grating temperature sensor: the temperature sensor of selecting the designed, designed encapsulation;

Optical cable: select middle day scientific and technological GYTA-12B1;

Photoswitch: select light to swell scientific and technological SUM-FSW;

Fiber Bragg grating (FBG) demodulator: select SM130;

Slave computer and program: select and grind magnificent IPC-610, program is self-editing;

Telstar module: the ST2500 of STELLAR company;

Host computer and program: select and grind magnificent IPC-610, program is self-editing;

Wherein:

The formation of permafrost region fiber-optical grating temperature sensor group as shown in Figure 3.At pipeline 28 up and down, difference installing optical fibres grating temperature sensor group a 29, fiber-optical grating temperature sensor group b 30, fiber-optical grating temperature sensor group c 31, fiber-optical grating temperature sensor group d 32.Sets of temperature sensors 29 is comprised of several fiber-optical grating temperature sensors 33, and the quantity of fiber-optical grating temperature sensor 33 and interval can arrange according to demand.Connect by single core armored optical cable 34 between sets of temperature sensors 30 and the sets of temperature sensors 32.Fiber-optical grating temperature sensor group a 29, fiber-optical grating temperature sensor group b 30, fiber-optical grating temperature sensor group c 31, fiber-optical grating temperature sensor group d 32 are connected with data collector by cable junction box 35, realize the monitoring of pipeline temperature.

Native system is when monitoring, and temperature needs long term monitoring, and according to the analysis to long term monitoring data, total junction temperature and moisture variable condition and trend are used for pipe and soil interaction analysis-by-synthesis and pipeline potential risk and judge.

Through for a long time monitoring, this example is easy to make up monitoring system, is easy to realize real-time automatic collecting analysis and the long-range issue of permafrost region and pipeline combined monitoring data, long-range real-time automatic alarm.Avoided loaded down with trivial details artificial image data, improved the precision of early warning, reduced time of fire alarming, can also accurately locate place of alarm simultaneously, this to the pipeline emergency measure take most important.

Claims (5)

1. a permafrost region oil and gas pipes environment temperature monitoring system is characterized in that this system is divided into on-site data gathering transmission subsystem and data analysis display subsystem, specifically comprises fiber-optical grating temperature sensor group, field monitoring station, remote monitoring center;

Totally constituting of permafrost region oil and gas pipes environment temperature monitoring system: on the oil and gas pipes (2) of permafrost region (1) surface and a plurality of fiber-optical grating temperature sensor a (3) are installed on every side, fiber-optical grating temperature sensor b (4), the sets of temperature sensors that fiber-optical grating temperature sensor c (5) forms, the all the sensors group is connected with optical cable (12) respectively, then guide in the monitoring station by optical cable (12), optical cable (12) is connected with photoswitch (13), photoswitch (13) is connected with fiber Bragg grating (FBG) demodulator (14), fiber Bragg grating (FBG) demodulator (14) is connected with slave computer (15), the pretreated data communication device of slave computer (15) is crossed the first satellite communication module (16) and is transferred to low-orbit satellite (17), low-orbit satellite (17) forwards the data to the second satellite communication module (18) after receiving data, the second satellite communication module (18) is analyzed the data transmission that receives and process to host computer (19), thereby realizes the safety monitoring to the permafrost region oil and gas pipes;

A plurality of fiber-optical grating temperature sensor a (3), fiber-optical grating temperature sensor b (4), fiber-optical grating temperature sensor c (5) pass to photoswitch (13) with the temperature signal of pipeline through optical cable (12), reach slave computer (15) through fiber Bragg grating (FBG) demodulator (14) demodulation, slave computer (15) calls self-editing program, control photoswitch (13) and fiber Bragg grating (FBG) demodulator (14) are realized data acquisition and data are carried out pre-service; Pretreated data communication device is crossed the first satellite communication module (16) and is transferred to low-orbit satellite (17), low-orbit satellite (17) forwards the data to the second satellite communication module (18) after receiving data, the second satellite communication module (18) is analyzed the data transmission that receives and process to host computer (19), judges the safe condition of permafrost region pipeline.

2. a kind of permafrost region oil and gas pipes environment temperature monitoring system according to claim 1, it is characterized in that its theory diagram is: it is divided into on-site data gathering transmission subsystem and data analysis display subsystem; The composition of on-site data gathering transmission subsystem is: the output of fiber-optical grating temperature sensor connects the input of photoswitch, the output of photoswitch connects the input of fiber Bragg grating (FBG) demodulator, fiber Bragg grating (FBG) demodulator output connects the input of slave computer, slave computer output connects the first satellite communication module, and the output of the second satellite communication module connects the input of host computer; The on-site data gathering transmission subsystem links by low-orbit satellite and data analysis display subsystem; The composition of data analysis display subsystem is: the output of the second satellite communication module connects the input of host computer, and host computer output has the permafrost region temperature field dynamically to show.

3. a kind of permafrost region oil and gas pipes environment temperature monitoring system according to claim 1 and 2, the electric principle that it is characterized in that this system is: the FC joint of fiber-optical grating temperature sensor group respectively with the FC input port 1 of photoswitch, FC input port 2, FC input port 3 connects, the R232 port of photoswitch connects the R232 port one of slave computer, the FC output port of photoswitch connects the FC input port of fiber Bragg grating (FBG) demodulator, the LAN port of fiber Bragg grating (FBG) demodulator connects the LAN port of slave computer, the VGA of slave computer is connected with the VGA of display, the R232 port 2 of slave computer connects the R232 port of the first satellite communication module, the first satellite communication module transfers data to low-orbit satellite, low-orbit satellite forwards the data to the second satellite communication module in real time, by the R232 port of R232 port transmission to host computer, host computer exports display to by the VGA port after data analysis is processed to the second satellite communication module with receive data;

The fiber-optical grating temperature sensor signal through photoswitch (13) one by one conducting transfer to fiber Bragg grating (FBG) demodulator (14), the centre wavelength that fiber Bragg grating (FBG) demodulator (14) demodulates each fiber-optic grating sensor transfers to slave computer (15), and the cycle of photoswitch (13) Continuity signal is controlled by slave computer (15); Slave computer (15) carries out pre-service to data, and the data after will processing are defeated by the first satellite communication module (16), the first satellite communication module (16) transfers data to low-orbit satellite (17), low-orbit satellite (17) forwards the data to the second satellite communication module (18) in real time, the second satellite communication module (18) transfers to host computer (19) with receive data, host computer (19) carries out analyzing and processing by self-programmed software to data, is shown by display.

4. a kind of permafrost region oil and gas pipes environment temperature monitoring system according to claim 1 and 2 is characterized in that described fiber-optical grating temperature sensor adopts the structure of double-layer pipe.

5. a kind of permafrost region oil and gas pipes monitoring system according to claim 1, the construction method that it is characterized in that described permafrost region fiber-optical grating temperature sensor group is: at oil and gas pipes (2) up and down, the fiber-optical grating temperature sensor group of a plurality of fiber-optical grating temperature sensor a (3), fiber-optical grating temperature sensor b (4), fiber-optical grating temperature sensor c (5) composition is installed respectively; Quantity and the interval of a plurality of fiber-optical grating temperature sensor a (3), fiber-optical grating temperature sensor b (4), fiber-optical grating temperature sensor c (5) arrange according to demand; Connect by single core armored optical cable (34) between the fiber-optical grating temperature sensor group that a plurality of fiber-optical grating temperature sensor a (3), fiber-optical grating temperature sensor b (4), fiber-optical grating temperature sensor c (5) form; The fiber-optical grating temperature sensor group that a plurality of fiber-optical grating temperature sensor a (3), fiber-optical grating temperature sensor b (4), fiber-optical grating temperature sensor c (5) form is connected with data collector by cable junction box (35).

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