CN101667327A - Method and system for monitoring and warning pipeline landslide depth displacement and method for constructing system - Google Patents
Method and system for monitoring and warning pipeline landslide depth displacement and method for constructing system Download PDFInfo
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Abstract
The invention relates to a method and a system for monitoring and warning pipeline landslide depth displacement and a method for constructing the system. The monitoring is divided into three parts including landslide depth displacement monitoring, monitoring of thrust of landslide on a pipeline and pipeline strain monitoring, and comprises the steps of: inserting an inclinometer pipe (1) pasted with a fiber Bragg grating sensor into the landslide (13), penetrating all potential sliding surfaces (15), extending the inclinometer pipe to a drilling hole 3 to 5m deep under a bedrock surface, and measuring the maximum tension strain born by the inclinometer pipe (1); measuring the front thrust of the landslide (13) on the pipeline by using a packaged earth pressure cell fiber Bragg grating sensor (4) fixed on the pipeline (14); and uniformly arranging pipeline (14) monitoring sections on edges on two sides of the landslide and the pipeline (14) in the center of the landslide (13), and uniformly arranging three pipe strain fiber Bragg grating sensors (3) on each monitoring section to monitor the axial strain of the pipeline (14).
Description
Technical field
The present invention is a kind of based on the monitoring and warning pipeline landslide depth displacement method and system of fiber grating and the construction method of system.Relate to measurement and the piping system technical field of measuring stress, temperature.
Background technology
The rock soil mass that is meant the formation slope that comes down is followed the shear action process on the weak face in its underpart and is produced the mass motion phenomenon under action of gravity.Landslide disaster is one of the principal mode that causes the geologic hazard of human life's property loss.Length can reach thousands of kilometers apart from oil transportation or gas pipe line fed distance, passes through numerous geology and geomorphologies unit, often will pass the geologic condition areas with complicated inevitably, as mountain area, permafrost region etc.Because the insufficient or pipe-line construction of route selection brings out the landslide or reasons such as landslide are brought out in earthquake, the pipeline that lays in the mountain area might pass through in movable sliding mass, and the safe operation of pipeline suffers the serious threat on these movable landslides.These are referred to as pipeline landslide in landslide of threat tube safety possibly.
In the past in the pipeline transportation history in 40 years, once repeatedly caused pipeline accident based on the geologic hazard on landslide.Europe natural gas line casualty data group (EGIG) investigation 1970 in the West Europe pipeline accident of calendar year 2001, the 7%th, cause by geologic hazard; 1984 of DOT statistics show that to 2001 natural gas transport data 8.5% accident is caused by geologic hazard; 12% of the pipeline accident of Canada State Energy Resources Commission investigation demonstration influence Canada operation is that geologic hazard causes.The huge landslide that caused by earthquake in March, 1987 makes traverses the fracture that 40km length takes place Ecuador's pipeline, and stopping transportation fortnight, economic loss reaches 700,000,000 dollars.Nineteen ninety-five and winter in 1996,, cause U.S.'s northwest gas transmission line three place's pipelines to rupture because the landslide is brought out in the extra-heavy rainfall in western part, Washington.
The pipeline industry of China be in flourish among, these pipelines are transported to the western abundant petroleum gas of China the east of China mostly, and the most of mountain regions of China have been concentrated in western part of China, the west and south, and pipeline just will pass through seriously area of geologic hazard inevitably.Loyal military gas pipe line Zhong County-Yichang 409 km segment are in eastern west place in Hubei mountain area, Chongqing, and peaks rising one upon another on the mountain peak, the discrepancy in elevation is remarkable, landform, geologic condition complexity, and growing has the geologic hazard of many groups easily to send out the rock stratum, is the location that takes place frequently of landslide, crag avalanche.The blue Chengdu-Chongqing products pipeline Lanzhou that was constructed and put into operation in 2003 is to the Guangyuan section, structure is active, the lithology fragmentation, and the landform cutting is grown, the back input huge fund of going into operation is used for hazards control, still has more than 530 places but investigation in 2007 shows the geologic hazard of threat tube safety.The West-East National Gas Transmission Project main line always is about 4000 kilometers, suffers various geologic hazard serious threats, and the landslide disaster of wherein finding out reaches more than 39 places.
In the face of numerous pipeline landslide disasters, the pipeline operator of China is often taked positive engineering control measure, but also there is the drawback of some in these measures, it at first is the cost height, next is that prevention and cure project is not " putting things right once and for all " yet, the uncertain factor of design and construction is more, moreover the cycle of administering is long.The monitoring then be a kind of efficiently, prophylactico-therapeutic measures cheaply.Italy SNAM company will monitor the main mode of pipeline as the control landslide disaster, and they have carried out reaching the monitoring in 30 years to pipeline, have successfully avoided a large amount of pipeline accidents.After pipelines such as the transfering natural gas from the west to the east of China, loyal military line are gone into operation the landslide is also effectively monitored.
Main multipoint displacement meter or the clinograph of adopting of traditional landslide depth displacement monitoring, the real-time of this method is all relatively poor, is difficult to satisfy the long-term real-time requirement of landslide monitoring.
When being used to monitor landslide depth displacement, the concentric cable technology all having superiority aspect cost, the monitoring in real time, but the concentric cable external diameter is thin (about 10mm), buy in that cable is difficult to compatible deformation with the soil body after the soil body, cause concentric cable can not reflect really that sliding mass is out of shape.
The distribution type fiber-optic technology has been applied to landslide monitoring as a kind of new technology, this technology has superiority at aspects such as precision, automatic monitorings, but during this technical monitoring landslide depth displacement, its vertical bearing accuracy poor (about 1m) also has certain limitation aspect landslide monitoring.
Summary of the invention
The objective of the invention is to invent a kind of accurate location, spatial resolution height, cost low based on the monitoring and warning pipeline landslide depth displacement method and system of fiber grating and the construction method of system.
The present invention proposes a kind of monitoring and warning pipeline landslide depth displacement method and system and construction method thereof based on fiber grating sensing technology.This system employing fiber grating sensing technology carries out combined monitoring to the pipeline under landslide and the influence thereof, and the monitoring content comprises the landslide depth displacement monitoring, comes down to the thrust monitoring and the pipeline strain monitoring of pipeline.And made up monitoring system, realized real-time automatic collecting, remote transmission and the analysis automatically of data.
Fiber Bragg Grating (Fiber Bragg Grating, FBG are called for short fiber grating) is the micro optical element that develops rapidly over nearly 20 years, is to utilize the photosensitivity in the optical fiber to make.Photosensitivity in the so-called optical fiber is meant when laser passes through doped fiber, and the refractive index of optical fiber will be with the characteristic of the space distribution generation respective change of light intensity.And the space phase grating that in fibre core, forms, the essence of its effect is exactly (transmission or reflection) wave filter or the catoptron that forms an arrowband in fibre core.
Optical fiber grating sensing is a kind ofly to select reverberator, its back-reflection center wavelength of light λ being scribed the wavelength that forms by optical fiber
BWith grating periods lambda and fiber core refractive index n
EffRelevant, promptly
λ
B=2n
effΛ
The ultimate principle of FBG optical fiber grating sensing is when temperature, strain, stress or other measured physical quantity around the grating change, will cause the variation of grating cycle or fiber core refractive index, thereby make the centre wavelength of fiber grating produce displacement λ
B,, can obtain the situation of change of measured physical quantity by detecting the displacement situation of grating wavelength.Promptly
Δλ
B=K
ε·Δε+K
T·ΔT
K in the formula
εBe strain sensing sensitivity coefficient, K
TBe the fiber grating temperature sensor sensitivity coefficient.
For the FBG fibre core is the situation of pure quartz, K
εBe 1pm/u ε, K
TBe 10pm/ ℃.The optical fiber material, write strain and temperature sensing sensitivity coefficient that technology and encapsulating material all can influence FBG, must demarcate above parameter before using.
Fiber grating can be made into various senser elements, is used widely at sensory field.Compare with traditional electric transducer, fiber-optic grating sensor has own unique advantage: 1. sensing head is simple in structure, volume is little, in light weight, shape variable, be fit to imbed in the various large scale structures, but the stress of measurement structure inside, strain and structural damage etc., stability, good reproducibility; 2. and have natural compatibility between the optical fiber, easily be connected with optical fiber, optical loss is low, spectral characteristic good, reliability is high; 3. have non-conducting, little to measured medium influence, have characteristics anticorrosive, anti-electromagnetic interference (EMI) again, be adapted at working in the rugged surroundings; 4. light and handy soft, can in an optical fiber, write a plurality of gratings, constitute sensor array, combine with wavelength-division multiplex and time division multiplex system, realize distributed sensing; 5. metrical information is with Wavelength-encoding, thereby fiber-optic grating sensor is not subjected to the influence of factors such as light-intensity variation, optical fiber connection and coupling loss, the optical polarization variation of light source, the antijamming capability that tool is stronger; 6. high sensitivity, high degree of resolution.
Compare with widely used Brillouin light domain reflectometer BOTDR, the advantage of fiber-optic grating sensor has: 1. pair measurement point can accurately be located, the resolution height; 2. cost is low; 3. can process, encapsulate transducing part, make it be more suitable for on-the-spot rugged surroundings.
Because these advantages, in the Geotechnical Engineering field, fiber-optic grating sensor is easy to imbed in the rock soil mass strain and the temperature to its inside and carries out high resolving power and large-range measuring, and technical advantage is very obvious, especially is embodied in to obtain long-term, rock soil mass deformation data reliably.The deep displacement that present fiber grating sensing technology also is not used to come down is monitored.
The present invention propose based on the monitoring and warning pipeline landslide depth displacement method of fiber grating sensing technology as shown in Figure 1, be with monitoring be divided into the landslide depth displacement monitoring, three parts are monitored to the thrust monitoring and the pipeline strain of pipeline in the landslide.Landslide depth displacement will produce the thrust to pipeline, and then produces strain on pipeline.
The landslide depth displacement monitoring method as shown in Figure 2, when gliding, sliding mass make deviational survey pipe 1 be subjected to sliding mass thrust and when bending, monitoring is born maximum stretching strain towards deviational survey pipe 1 one sides of sliding mass glide direction, and forward deviational survey pipe 1 one sides of sliding mass glide direction are born maximum compressive strain; Specifically be the deviational survey pipe 1 that to be pasted with deviational survey pipe fiber-optic grating sensor 16 being stained with the direction of fiber-optic grating sensor one side, insert in sliding mass upper edge vertical and pass all potential slipping planes and extend in the boring of 3~5m below the bedrock surface towards the potential slip in landslide; Fibre-optical splice is connected with optical cable, signal is guided to the monitoring station by optical cable 5; In the monitoring station, host computer 8 calls self-editing program, control fiber Bragg grating (FBG) demodulator 7, the real-time automatic collecting of realization data; Just can measure the maximum stretching strain that deviational survey pipe 1 bears.The deviational survey pipe of setting in the basement rock 1 is a fixed constraint, utilizes the double integral algorithm, and the stretching strain by deviational survey pipe 1 distributes and just can solve the sag of deviational survey pipe 1, and this amount of deflection promptly is the landslide depth displacement amount.
Utilize the double integral algorithm to ask the formula of deviational survey canal curvature amount of deflection (landslide depth displacement amount) as follows:
In the formula:
ε---the FBG sensor is measured the bending strain of deviational survey pipe;
Y---the amount of deflection (landslide depth displacement) of depth location x place (counting) deviational survey pipe from the basement rock end face;
R---deviational survey external diameter of pipe;
ε (x)---the bending strain of x place deviational survey pipe, x=L place strain tube does not have constraint, ε=0;
C---integration constant, x=0 place deviational survey pipe is fixed, so c=0.
Fiber-optic grating sensor is point type along the strain tube depth direction and distributes, and employing cubic spline function difference or approach based on linear interpolation are tried to achieve the strain stress (x) between the measurement point.ε between the each point (x) may have nothing in common with each other, and deep displacement y essence is a subsection integral function.
The landslide to the thrust monitoring method of pipeline as shown in Figure 6, with encapsulation soil pressure cell fiber-optic grating sensor 4 measuring pressures that are fixed on the pipeline; Soil pressure cell fiber-optic grating sensor 4 is fixed on the pipeline 14 by soil pressure cell support 21, and soil pressure cell fiber-optic grating sensor 4 is experienced the glide direction of the sensitive area of pressure towards landslide 13.The pressure of soil pressure cell fiber-optic grating sensor 4 measurements is exactly the positive thrust of the 13 pairs of pipelines 14 in landslide like this.
The pipeline strain monitoring method on the pipeline 14 of the center on 13 both sides of the edge, landslide and landslide, evenly arrange pipeline monitoring cross section, and the spacing in monitoring cross section should not surpass 60m as shown in Figure 7 and Figure 8; On each monitoring cross section of pipeline 14, evenly arrange 3 body fiber Bragg grating strain sensors 3, the strain that monitoring pipeline 14 is axial.
A large amount of studies show that, the crucial performance of 13 pairs of pipeline 14 imposed stresses that come down just can be judged the acceptable stress state of pipeline 14 in the axial direction preferably to the measurement of pipeline 14 axial stresses.Therefore the only axial strain of measuring channel of body fiber Bragg grating strain sensor 3, based on the steel theory of elasticity, known strained just can be obtained stress.
Because the complicacy of landslide 13 distortion self and the complicacy that pipeline 14 is acted on thereof adopt the mode of many indexs early warning that the safety of pipeline landslide 13 is carried out early warning.These indexs comprise: sliding surface formation, the table portion deflection on landslide 13, the additional strain of pipeline 14.Wherein " sliding surface formation " is to qualitatively judge index, and all the other 2 indexs are quantitative judge index.Only work as 3 indexs and all reach the early warning threshold values, then pipeline landslide is sent safe early warning.The basis for estimation whether sliding surface 15 forms is on 13 the deep displacement distribution curve of landslide whether catastrophe point to be arranged." sliding surface formation " has that two comments " form ", " form ", will " form " as the early warning threshold values.The influence of the strain that the additional axial strain threshold values of pipeline 14 is subjected to landslide before tubing, operating pressure, construction temperature, the monitoring to give pipeline 14 to have caused, defect of pipeline etc.For the unconspicuous X60 pipeline of defective, the additional axial strain threshold values of the tension of pipeline 14 is decided to be 380u ε, the additional axial strain threshold values of pressurized is decided to be-300u ε.
The monitoring and warning pipeline landslide depth displacement system that makes up according to above-mentioned method is made up of the receiving terminal of the thrust monitoring device of pipeline, pipeline strain monitoring device, field monitoring station, office landslide depth displacement monitoring device, landslide as shown in Figure 3.The automatic light switch 6 that connects the field monitoring station is exported to the soil pressure cell strain fiber-optic grating sensor 4 of the thrust monitoring device of pipeline and the body strain fiber-optic grating sensor 3 of pipeline strain monitoring device in the deviational survey pipe strain fiber-optic grating sensor 16, the landslide that are installed in the on-the-spot landslide depth displacement monitoring device in the landslide with certain version, automatically 6 outputs of light switch connect the input of fiber Bragg grating (FBG) demodulator 7, and the output of an end of host computer 8 connects the end input of automatic light switch 6 in addition; The output of fiber Bragg grating (FBG) demodulator 7 also connects the input of bit machine 8; The output of host computer 8 connects GPRS transport module 9, connects the input of next bit computer 11, the output of next bit computer 11 device 12 taking alarm and display by the receiving terminal GPRS receiver module 10 of office.
The electric principle of this system as shown in Figure 4, monitor landslide depth displacement respectively, the landslide is to three fiber-optic grating sensors--the deviational survey pipe fiber-optic grating sensor 16 of the thrust and the pipeline strain of pipeline, soil pressure cell fiber-optic grating sensor 4, the PC joint of body fiber-optic grating sensor 3 is connected with the PC joint of light switch 6 with optical fiber, the R232 of light switch 6 directly connects the R232 of bit machine 8, the PC joint of light switch 6 connects the CH1 end of fiber Bragg grating (FBG) demodulator 7SM125, the LAN port of fiber Bragg grating (FBG) demodulator 7SM125 connects the LAN port of bit machine 8, the R232 port of host computer 8 connects the R232 port of GPRS transport module 9 Siemens MC 35i, GPRS transport module 9 is through antenna GSM, GPRS network, received next bit computer 11 is received in the back by R232 R232 by GPRS receiver module 10 antenna GSM, the output of next bit computer 11 is by the R232 of R232 device 12DS-7400 taking alarm, and the output of next bit computer 11 is by the VGA end of VGA termination display.
Monitoring landslide depth displacement, landslide are given fiber Bragg grating (FBG) demodulator 7 to the output signal of three kinds of fiber-optic grating sensors of the thrust of pipeline and pipeline strain through conducting one by one, fiber Bragg grating (FBG) demodulator 7 demodulates the centre wavelength displacement of each fiber-optic grating sensor and is defeated by host computer 8, and light switch 6 gives the cycle of fiber Bragg grating (FBG) demodulator 7 Continuity signals by host computer 8 controls.Host computer 8 calculates the signal that each monitoring variable is defeated by GPRS transport module 9 and accepts GPRS transport module 9 automatically and controls, GPRS transport module 9 is transferred to the receiving terminal GPRS receiver module 10 that is positioned at office with each monitoring variable that host computer 8 calculates by public's cordless communication network, also can accept the signal of receiving terminal, after sending to next bit computer 11 processing, report to the police by the display demonstration and by alarm 12.
The formation of landslide depth displacement monitoring device as depicted in figs. 1 and 2, deviational survey pipe fiber-optic grating sensor 16 outputs that are deviational survey pipe 1 connect 6 inputs of light switch, 6 outputs of light switch connect fiber Bragg grating (FBG) demodulator 7 inputs, and the output of fiber Bragg grating (FBG) demodulator 7 connects on-the-spot host computer 8.And the deviational survey pipe fiber-optic grating sensor 16 on the deviational survey pipe 1 be will series connection fiber-optic grating sensor form sensor groups and directly be pasted on the axial outside of deviational survey pipe 1, each deviational survey pipe fiber-optic grating sensor 16 draw fine welding after be connected to connection optical fiber.Put into the deviational survey pipe 1 that is pasted with fiber-optic grating sensor in the boring on landslide 13, a side that when transferring deviational survey pipe 1 is stained with deviational survey pipe fiber-optic grating sensor 16 is towards the potential glide direction in landslide.Fibre-optical splice is connected with optical cable 5, signal is guided to the monitoring station by optical cable 5; In the monitoring station, host computer 8 calls self-editing program, control fiber Bragg grating (FBG) demodulator 7, the real-time automatic collecting of realization data.
The principle of work of this device be such, when landslide 13 when slipping plane 15 glides, deviational survey pipe 1 is subjected to coming down 13 thrusts and bends, then bear maximum stretching strain towards deviational survey pipe 1 one sides of landslide 13 glide directions, deviational survey pipe 1 one sides of 13 glide directions that forward come down are born maximum compressive strain.Place on the deviational survey pipe 1 and just can measure the maximum stretching strain that the deviational survey pipe bears for 16 groups towards the deviational survey pipe fiber-optic grating sensor of landslide 13 glide directions, one side.The deviational survey pipe of setting in the basement rock 1 is a fixed constraint, utilizes the double integral algorithm, and the stretching strain by deviational survey pipe 1 distributes and just can solve the sag of deviational survey pipe 1, and this amount of deflection promptly is the landslide depth displacement amount.
Wherein:
Deviational survey pipe fiber-optic grating sensor 16 is divided into surveys two kinds of axial strain and thermometric degree; The deviational survey pipe fiber-optic grating sensor 16 of surveying axial strain adopts Instant cements to be pasted on deviational survey pipe 1 outer wall, then with foam seal glue sealing deviational survey pipe fiber-optic grating sensor 16, avoids deviational survey pipe fiber-optic grating sensor 16 directly to contact with rock soil mass on every side; Freely place deviational survey pipe fiber-optic grating sensor 16 a distance on deviational survey pipe 1 of thermometric degree, this fiber-optic grating sensor of not pasting is only to responsive to temperature, be that deviational survey pipe fiber Bragg grating strain sensor is carried out temperature compensation for 16 groups, and the influence of not tested inclined tube distortion;
Deviational survey pipe fiber-optic grating sensor 16 is equidistantly pasted, and pastes spacing and dwindle near potential slipping plane;
The connection fiber arrangement of deviational survey pipe fiber-optic grating sensor 16 in the groove that deviational survey pipe 1 outer wall is carved, in case in the process of transferring the deviational survey pipe, borehole wall scratch optical fiber.
The construction method (see figure 2) of landslide depth displacement monitoring device is as follows:
1) hole with the geology drilling process on the landslide 13 of intending monitoring, boring need be passed all potential slipping planes 15, and extends to the following 3~5m of bedrock surface; Requiring the whole bore open of boring is Φ 110mm, and hole deviation is less than requiring a complete set to manage and protect wall except that bedrock hole in 1 ° of drilling process;
2) be ready to the conventional deviational survey pipe 1 of a joint ABS or PVC; By drilling depth deviational survey pipe 1 is carried out pre-connection by joint, and make alignment mark and numbering, remove connection then at joint;
3) transfer deviational survey pipe 1 before, in boring, carry out hole operation clearly, till slime water became cleaning muddy water, it was unobstructed to guarantee to hole, and guaranteed transferring smoothly of deviational survey pipe 1; Transfer the deviational survey pipe 1 that is pasted with sensor immediately after carrying brill;
4) on first deviational survey pipe 1 outer wall, paste the fiber grating strain sheet, and cutting on deviational survey pipe 1 outer wall, will connect optical fiber and use immobilization with adhesive tape in groove; For the monitoring result to this device is verified, the fiber-optic grating sensor group is sticked in the residing a certain plane of deviational survey pipe 1 inwall cross guide groove, the distortion of fiber grating monitoring is just consistent with the distortion that tiltmeter is measured like this;
5) transfer first segment deviational survey pipe 1 to the aperture certain altitude, the alignment mark of pressing deviational survey pipe 1 is connected second deviational survey pipe 1 with numbering, and after pasting deviational survey pipe fiber Bragg grating strain sensor 16, cutting, fixedly connected optical fiber on the second joint deviational survey pipe, 1 outer wall, transfer the second joint deviational survey pipe 1; Using such method is transferred all deviational survey pipes 1 to the hole; When buoyancy of water in the boring causes deviational survey pipe 1 come-up, can inject proper amount of clear water to reduce to transfer resistance at deviational survey pipe 1;
6) treat that all deviational survey pipes 1 are transferred to the hole after, adjust the guide groove direction, make the sense of displacement of the direction of 16 groups of guide groove direction and deviational survey pipe fiber Bragg grating strain sensors towards sliding mass;
7) inject M5 fine sand sand-cement slurry in basement rock and deviational survey pipe 1 gap, mortar guides with Grouting Pipe, when Grouting Pipe down to from beginning slip casting behind the 1m place at the bottom of the hole; Backfill fine sand in the soil body and deviational survey pipe 1 gap;
8) do concrete pier in the aperture, in pier, bury steel bushing underground, with the Signal connector of 16 groups of protection deviational survey pipe fiber Bragg grating strain sensors; The fiber-optic signal joint is connected with optical cable 5, signal is guided to the monitoring station by optical cable 5.
The landslide to the formation of the thrust monitoring device of pipeline as shown in Figure 6, soil pressure cell fiber-optic grating sensor 4 outputs that are the 13 pairs of pipeline 14 thrusts monitorings in landslide connect 6 inputs of light switch, 6 outputs of light switch connect 7 inputs of grating demodulation instrument, and the output of grating demodulation instrument connects on-the-spot host computer 8.And the fiber-optic grating sensor of the 13 pairs of pipeline 14 thrusts monitorings of coming down adopts fiber grating encapsulation soil pressure cell fiber-optic grating sensor 4; Soil pressure cell fiber-optic grating sensor 4 is fixed on the pipeline 14 by soil pressure cell support 21, and soil pressure cell fiber-optic grating sensor 4 is experienced the glide direction of the sensitive area of pressure towards landslide 13.The pressure of soil pressure cell fiber-optic grating sensor 3 measurements is exactly the positive thrust of the 13 pairs of pipelines 14 in landslide like this.
The landslide to the construction method of the thrust monitoring device of pipeline as shown in Figure 6, soil pressure cell fiber-optic grating sensor 4 is fixed on the pipeline 14 by soil pressure cell support 21, and soil pressure cell fiber-optic grating sensor 4 is experienced the glide direction of the sensitive area of pressure towards landslide 13.The pressure of soil pressure cell fiber-optic grating sensor 4 measurements is exactly the positive thrust of the 13 pairs of pipelines 14 in landslide like this.Soil pressure cell support 21 is made up of two circular arc steel plate clips, wherein is welded with base on one section circular arc steel plate, and soil pressure cell fiber-optic grating sensor 4 embeds in the base, and keeps certain allowance, makes soil pressure cell energy Free Transform.The clamp connection part 23 at soil pressure cell support 21 two ends connects by nut.When slide in landslide 13, the thrust of the 13 pairs of soil pressure cells in landslide can be measured by soil pressure cell fiber-optic grating sensor 4, and this measured value deducts the soil body gravity pressure that soil pressure cell fiber-optic grating sensor 4 bears, and is the thrust that landslide 13 distortion produce pipeline 14.
The formation of the monitoring device of body stress such as Fig. 7, shown in Figure 8, be respectively to arrange pipeline monitoring cross section, arrange evenly that in the periphery in each monitoring cross section of pipeline 14 3 body fiber- optic grating sensors 3 and 3 body fiber-optic grating sensors 3 are arranged on the plane with pipeline 14 axis normal in the both sides of the edge and the center on landslide on landslide.3 outputs of body fiber-optic grating sensor connect 6 inputs of light switch, and 6 outputs of light switch connect fiber Bragg grating (FBG) demodulator 7 inputs, and the output of fiber Bragg grating (FBG) demodulator 7 connects on-the-spot host computer 8.
The construction method of the monitoring device of body stress such as Fig. 7, shown in Figure 8 respectively arrange pipeline monitoring cross section in the both sides of the edge on landslide and the center on landslide, and the spacing in monitoring cross section should not surpass 60m.Evenly arrange that in the periphery in each monitoring cross section of pipeline 14 3 body fiber- optic grating sensors 3 and 3 body fiber-optic grating sensors 3 are arranged on the plane with pipeline 14 axis normal.When body fiber-optic grating sensor 3 is installed, scrape pipeline 14 anticorrosive coats fully off, and polishing pipeline 14 surfaces are pasted the body fiber-optic grating sensor with Instant cement 3 and are encapsulated 24 packaged body fiber-optic grating sensors 3 to smooth.After treating that three body fiber-optic grating sensor 3 paste Lists are good, the fibre that draws of body fiber-optic grating sensor 3 is caused ground in the lump, and protect.
Draw when pipeline 14 axially bears/during compressive stress, three body fiber-optic grating sensors 3 bear and draw/compressive strain; According to certain algorithm,, can obtain the size and the position of maximum strain on these pipeline 14 cross sections by this cross section three places strain.Based on the steel theory of elasticity, can obtain the size of maximum drawing/compressive stress on pipeline 14 cross sections.The selection in monitoring cross section is very important to monitoring effect.
A large amount of studies show that, the crucial performance of 13 pairs of pipeline 14 imposed stresses that come down just can be judged the acceptable stress state of pipeline 14 in the axial direction preferably to the measurement of pipeline 14 axial stresses.Therefore, the only axial strain of measuring channel 14 of body fiber-optic grating sensor 3.
It is on-the-spot that the field monitoring station is arranged on the landslide, comprises optical Fiber Closure, connects optical cable 5, light switch 6, fiber Bragg grating (FBG) demodulator 7, host computer 8, GPRS transport module 9; By the optical Fiber Closure of each fiber-optic grating sensor be connected optical cable 5 fiber-optic grating sensor of each position that will come down on 13 and receive the light switch 6 of monitoring station, 6 outputs of light switch connect fiber Bragg grating (FBG) demodulator 7, fiber Bragg grating (FBG) demodulator 7 outputs connect bit machine 8, and host computer 8 outputs connect GPRS transport module 9.The optical Fiber Closure of each fiber-optic grating sensor be connected optical cable 5 and will come down and be transferred to the light switch 6 of monitoring station in the fiber-optic grating sensor set of signals of each position on 13, light switch 6 changes each channel signal successively to fiber Bragg grating (FBG) demodulator 7, fiber Bragg grating (FBG) demodulator 7 demodulates the centre wavelength displacement of each fiber-optic grating sensor and gives host computer 8, host computer 8 calculates the signal that each monitoring variable is defeated by GPRS transport module 9 and accepts GPRS transport module 9 automatically and controls, GPRS transport module 9 is transferred to the receiving terminal that is positioned at office with each monitoring variable that host computer 8 calculates by public's cordless communication network, also can accept the signal of receiving terminal, send to next bit computer 11.
Wherein:
Light switch 6: because the fiber-optic grating sensor of monitoring landslide and pipeline is a lot, signalling channel is numerous, can't once be connected on the fiber Bragg grating (FBG) demodulator 7, with light switch 6 each channel signal is changed successively to fiber Bragg grating (FBG) demodulator 7 and is analyzed; This light switch 6 is selected city's pin product for use;
Fiber Bragg grating (FBG) demodulator 7: the centre wavelength displacement that is used to demodulate each fiber-optic grating sensor; Select city's pin product for use;
GPRS transport module 9: be used for each monitoring variable that host computer 8 calculates is transferred to the receiving terminal that is positioned at office by public's cordless communication network, also can accept the signal of receiving terminal, send to next bit computer 11.
The receiving terminal that is positioned at office comprises following 2 parts:
1) the GPRS receiver module 10, are used to receive the monitoring variable that field monitoring station GPRS transport module 9 sends, and are transferred to terminal next bit computer 11, send feedback command also can for on-the-spot GPRS transport module 9;
2) next bit computer 11 and program are used for the signal of download terminal GPRS receiver module 10, and calling program analyzes automatically, and analysis result and alarming threshold value are compared, and implement in the time of necessary to report to the police;
3) alarm 12, are used for when analysis result surpasses alarming threshold value the sound alarm signal taking place; Alarm 12 is by next bit computer 11 and programmed control.
The principle of work of this system is such, when slide in landslide 13, the deviational survey pipe 1 that is embedded in 13 deeps, landslide come down 13 soil body thrusts and the strain that bends, deviational survey pipe fiber-optic grating sensor 16 on the deviational survey pipe 1 is experienced stretching strain, by calculating the horizontal shift that can draw on the deviational survey pipe, the horizontal shift in 13 deeps of promptly coming down.Come down simultaneously 13 slip, the thrust that pipeline is produced is measured by soil pressure fiber-optic grating sensor 4, and the body strain that finally causes is measured by body fiber-optic grating sensor 3.By connecting optical cable 5, each sensor signal on the landslide is transferred to light switch 6, light switch 6 is given fiber Bragg grating (FBG) demodulator 7 with conversion of signals, fiber Bragg grating (FBG) demodulator 7 demodulates each sensor wavelength centre wavelength displacement and passes to host computer 8, host computer 8 is calculated as monitoring variable automatically with each centre wavelength displacement that (FBG) demodulator demodulates, and each monitoring variable sent to on-the-spot GPRS transport module 9, GPRS transport module 9 is transferred to terminal GPRS receiver module 10 by public's cordless communication network with signal, terminal GPRS receiver module 10 sends to terminal next bit computer 11, terminal next bit computer 11 provides warning with monitoring variable and alarming threshold value contrast in the time of necessary.
The advantage of the construction method of this method and system and system shows:
1) fiber grating sensing technology is applied to the deep displacement monitoring of pipeline landslide 13 and to the influence of pipeline 14, this technology is anti-interference, corrosion-resistant, it is obvious sometimes to be easy to networking etc.; By constructing specific carrier, realized monitoring landslide depth displacement with fiber grating sensing technology, to compare with the technological means of traditional monitoring landslide depth displacement, fiber grating sensing technology is easy to realize auto-real-time monitoring, and cost is lower;
2) location is accurate, spatial resolution is high;
3) monitoring variable is realized by fiber grating sensing technology, is easy to make up monitoring system, is easy to realize the real-time automatic collecting analysis and the long-range issue of pipeline landslide depth displacement Monitoring Data, and remote live is reported to the police automatically; Avoided loaded down with trivial details artificial image data, reduced time of fire alarming, this to the pipeline emergency measure take most important.
Description of drawings
Fig. 1 monitoring and warning pipeline landslide depth displacement system constitutes synoptic diagram
Fig. 2 monitoring and warning pipeline landslide depth displacement system fiber-optic grating sensor installation diagram
Fig. 3 pipeline landslide depth displacement Fundamentals of Supervisory Systems block diagram
Fig. 4 pipeline landslide depth displacement monitoring system electrical schematic diagram
The effect contrast figure of Fig. 5 landslide depth displacement monitoring result and movable clinograph monitoring result
Fig. 6 soil pressure fiber-optic grating sensor mounting structure figure
Fig. 7 body fiber-optic grating sensor mounting structure figure (cross-sectional view)
Fig. 8 body fiber-optic grating sensor mounting structure figure
1-deviational survey pipe wherein
3-body fiber-optic grating sensor 4-soil pressure cell fiber-optic grating sensor
5-optical cable 6-light switch
7-fiber Bragg grating (FBG) demodulator 8-host computer
9-GPRS transport module 10-GPRS receiver module
11-next bit computer 12-alarm
13-landslide 14-pipeline
15-slipping plane 16-deviational survey pipe fiber-optic grating sensor
The 18-side slope
21-soil pressure cell support 22-support clip
The encapsulation of 23-clamp connection part 24-body fiber-optic grating sensor
Embodiment
Embodiment. this example is a test method and system, and covers the overlayer that the cross section is sliding surface at a wide 300m, the thick 29m that comes down, base and test on the sliding mass at a slow speed.This monitoring and warning pipeline landslide depth displacement system constitutes as shown in Figure 1, and electric theory diagram as shown in Figure 3.By landslide depth displacement monitoring device, landslide the receiving terminal of the thrust monitoring device of pipeline, pipeline strain monitoring device, field monitoring station, office is formed.The automatic light switch 6 that connects the field monitoring station is exported to the soil pressure cell strain fiber-optic grating sensor 4 of the thrust monitoring device of pipeline and the body strain fiber-optic grating sensor 3 of pipeline strain monitoring device in the deviational survey pipe strain fiber-optic grating sensor 16, the landslide that are installed in the on-the-spot landslide depth displacement monitoring device in the landslide with certain version, automatically 6 outputs of light switch connect the input of fiber Bragg grating (FBG) demodulator 7, and the output of an end of host computer 8 connects the end input of automatic light switch 6 in addition; The output of fiber Bragg grating (FBG) demodulator 7 also connects the input of bit machine 8; The output of host computer 8 connects GPRS transport module 9, connects the input of next bit computer 11, the output of next bit computer 11 device 12 taking alarm and display by the receiving terminal GPRS receiver module 10 of office.
The electric principle of this system as shown in Figure 4, monitor landslide depth displacement respectively, the landslide is to three fiber-optic grating sensors--the deviational survey pipe fiber-optic grating sensor 16 of the thrust and the pipeline strain of pipeline, soil pressure cell fiber-optic grating sensor 4, the PC joint of body fiber-optic grating sensor 3 is connected with the PC joint of light switch 6 with optical fiber, the R232 of light switch 6 directly connects the R232 of bit machine 8, the PC joint of light switch 6 connects the CH1 end of fiber Bragg grating (FBG) demodulator 7SM125, the LAN port of fiber Bragg grating (FBG) demodulator 7SM125 connects the LAN port of bit machine 8, the R232 port of host computer 8 connects the R232 port of GPRS transport module 9 Siemens MC 35i, GPRS transport module 9 is through antenna GSM, GPRS network, received next bit computer 11 is received in the back by R232 R232 by GPRS receiver module 10 antenna GSM, the output of next bit computer 11 is by the R232 of R232 device 12DS-7400 taking alarm, and the output of next bit computer 11 is by the VGA end of VGA termination display.
Monitoring landslide depth displacement, landslide are given fiber Bragg grating (FBG) demodulator 7 to the output signal of three kinds of fiber-optic grating sensors of the thrust of pipeline and pipeline strain through conducting one by one, fiber Bragg grating (FBG) demodulator 7 demodulates the centre wavelength displacement of each fiber-optic grating sensor and is defeated by host computer 8, and light switch 6 gives the cycle of fiber Bragg grating (FBG) demodulator 7 Continuity signals by host computer 8 controls.Host computer 8 calculates the signal that each monitoring variable is defeated by GPRS transport module 9 and accepts GPRS transport module 9 automatically and controls, GPRS transport module 9 is transferred to the receiving terminal GPRS receiver module 10 that is positioned at office with each monitoring variable that host computer 8 calculates by public's cordless communication network, also can accept the signal of receiving terminal, after sending to next bit computer 11 processing, report to the police by the display demonstration and by alarm 12.
The formation of landslide depth displacement monitoring device as shown in Figure 3, deviational survey pipe fiber-optic grating sensor 16 outputs that are deviational survey pipe 1 connect 6 inputs of light switch, 6 outputs of light switch connect fiber Bragg grating (FBG) demodulator 7 inputs, and the output of fiber Bragg grating (FBG) demodulator 7 connects on-the-spot host computer 8.And the deviational survey pipe fiber-optic grating sensor 16 on the deviational survey pipe 1 be will series connection fiber-optic grating sensor form sensor groups and directly be pasted on the axial outside of deviational survey pipe 1, each deviational survey pipe fiber-optic grating sensor 16 draw fine welding after be connected to connection optical fiber.Put into the deviational survey pipe 1 that is pasted with fiber-optic grating sensor in the boring on landslide 13, a side that when transferring deviational survey pipe 1 is stained with deviational survey pipe fiber-optic grating sensor 16 is towards the potential glide direction in landslide.Fibre-optical splice is connected with optical cable 5, signal is guided to the monitoring station by optical cable 5; In the monitoring station, host computer 8 calls self-editing program, control fiber Bragg grating (FBG) demodulator 7, the real-time automatic collecting of realization data.
Wherein:
Deviational survey pipe fiber-optic grating sensor 16 is divided into surveys two kinds of axial strain and thermometric degree; The deviational survey pipe fiber-optic grating sensor 16 of surveying axial strain adopts Instant cements to be pasted on deviational survey pipe 1 outer wall, then with foam seal glue sealing deviational survey pipe fiber-optic grating sensor 16, avoids deviational survey pipe fiber-optic grating sensor 16 directly to contact with rock soil mass on every side; Freely place deviational survey pipe fiber-optic grating sensor 16 a distance on deviational survey pipe 1 of thermometric degree, this fiber-optic grating sensor of not pasting is only to responsive to temperature, be that deviational survey pipe fiber Bragg grating strain sensor is carried out temperature compensation for 16 groups, and the influence of not tested inclined tube distortion;
Deviational survey pipe fiber-optic grating sensor 16 is equidistantly pasted, and pastes spacing and dwindle near potential slipping plane;
The connection fiber arrangement of deviational survey pipe fiber-optic grating sensor 16 in the groove that deviational survey pipe 1 outer wall is carved, in case in the process of transferring the deviational survey pipe, borehole wall scratch optical fiber.
This installs single pass electric principle as shown in Figure 4, the PC joint of the deviational survey pipe fiber-optic grating sensor 16 of monitoring landslide depth displacement is connected with the PC joint of light switch 6 with optical fiber, the R232 of light switch 6 directly connects the R232 of bit machine 8, the PC joint of light switch 6 connects the CH1 end of fiber Bragg grating (FBG) demodulator 7SM125, and the LAN port of fiber Bragg grating (FBG) demodulator 7SM125 connects the LAN port of bit machine 8.
Wherein:
Fiber-optic grating sensor: select the fiber-optic grating sensor of design encapsulation voluntarily for use.
The light switch selects for use light to swell SUM-FSW;
The grating demodulation instrument is selected SM125 for use.
Specifically be will series connection fiber-optic grating sensor form sensor groups and directly be pasted on the axial outside of deviational survey pipe 1, equidistantly paste by surveying axial strain and two kinds of intervals of thermometric degree, near potential slipping plane, paste spacing and narrow down to 0.8 meter; Each fiber-optic grating sensor draw fine welding after be connected to connection optical fiber; Put into the deviational survey pipe 1 that is pasted with fiber-optic grating sensor then in the boring on the sliding mass, a side that when transferring deviational survey pipe 1 is stained with fiber-optic grating sensor is towards the potential glide direction in landslide; Fibre-optical splice is connected with optical cable, signal is guided to the monitoring station by optical cable.
The principle of work of this device be such, when landslide 13 when slipping plane 15 glides, deviational survey pipe 1 is subjected to coming down 13 thrusts and bends, then bear maximum stretching strain towards deviational survey pipe 1 one sides of landslide 13 glide directions, deviational survey pipe 1 one sides of 13 glide directions that forward come down are born maximum compressive strain.Place on the deviational survey pipe 1 and just can measure the maximum stretching strain that the deviational survey pipe bears for 16 groups towards the deviational survey pipe fiber-optic grating sensor of landslide 13 glide directions, one side.The deviational survey pipe of setting in the basement rock 1 is a fixed constraint, utilizes the double integral algorithm, and the stretching strain by deviational survey pipe 1 distributes and just can solve the sag of deviational survey pipe 1, and this amount of deflection promptly is the landslide depth displacement amount.
Its constructive method is as follows:
1) hole with the geology drilling process on the landslide 13 of intending monitoring, boring need be passed all potential slipping planes 15, and extends to the following 3~5m of bedrock surface; Requiring the whole bore open of boring is Φ 110mm, and hole deviation is less than requiring a complete set to manage and protect wall except that bedrock hole in 1 ° of drilling process;
2) be ready to the conventional deviational survey pipe 1 of a joint ABS or PVC; By drilling depth deviational survey pipe 1 is carried out pre-connection by joint, and make alignment mark and numbering, remove connection then at joint;
3) transfer deviational survey pipe 1 before, in boring, carry out hole operation clearly, till slime water became cleaning muddy water, it was unobstructed to guarantee to hole, and guaranteed transferring smoothly of deviational survey pipe 1; Transfer the deviational survey pipe 1 that is pasted with sensor immediately after carrying brill;
4) on first deviational survey pipe 1 outer wall, paste the fiber grating strain sheet, and cutting on deviational survey pipe 1 outer wall, will connect optical fiber and use immobilization with adhesive tape in groove; For the monitoring result to this device is verified, the fiber-optic grating sensor group is sticked in the residing a certain plane of deviational survey pipe 1 inwall cross guide groove, the distortion of fiber grating monitoring is just consistent with the distortion that tiltmeter is measured like this;
5) transfer first segment deviational survey pipe 1 to the aperture certain altitude, the alignment mark of pressing deviational survey pipe 1 is connected second deviational survey pipe 1 with numbering, and after pasting deviational survey pipe fiber Bragg grating strain sensor 16, cutting, fixedly connected optical fiber on the second joint deviational survey pipe, 1 outer wall, transfer the second joint deviational survey pipe 1; Using such method is transferred all deviational survey pipes 1 to the hole; When buoyancy of water in the boring causes deviational survey pipe 1 come-up, can inject proper amount of clear water to reduce to transfer resistance at deviational survey pipe 1;
6) treat that all deviational survey pipes 1 are transferred to the hole after, adjust the guide groove direction, make the sense of displacement of the direction of 16 groups of guide groove direction and deviational survey pipe fiber Bragg grating strain sensors towards sliding mass;
7) inject M5 fine sand sand-cement slurry in basement rock and deviational survey pipe 1 gap, mortar guides with Grouting Pipe, when Grouting Pipe down to from beginning slip casting behind the 1m place at the bottom of the hole; Backfill fine sand in the soil body and deviational survey pipe 1 gap;
8) do concrete pier in the aperture, in pier, bury steel bushing underground, with the Signal connector of 16 groups of protection deviational survey pipe fiber Bragg grating strain sensors; The fiber-optic signal joint is connected with optical cable 5, signal is guided to the monitoring station by optical cable 5.
Fig. 5 is the comparison diagram of the monitoring result of the monitoring result of fiber grating deep displacement monitoring system of the present invention and movable clinograph.The condition of contrastive detection is: the dark 29m of sliding mass, under cover basement rock, deviational survey pipe 1 bottom is embedded in 3m in the basement rock, deviational survey pipe 1 external diameter 70mm, internal diameter 60mm, the 2.5m outside deviational survey pipe 1,7.5m, 12.5m, 17.5m, 21.5m, 30m place respectively arrange a fiber-optic grating sensor; Movable clinograph adopts certain import famous brand name, long monitoring history is arranged, good stability in the clinograph field.
The landslide to the formation of the thrust monitoring device of pipeline as shown in Figure 6, soil pressure cell fiber-optic grating sensor 4 outputs that are the 13 pairs of pipeline 14 thrusts monitorings in landslide connect 6 inputs of light switch, 6 outputs of light switch connect 7 inputs of grating demodulation instrument, and the output of grating demodulation instrument connects on-the-spot host computer 8.And the fiber-optic grating sensor of the 13 pairs of pipeline 14 thrusts monitorings of coming down adopts fiber grating encapsulation soil pressure cell fiber-optic grating sensor 4; Soil pressure cell fiber-optic grating sensor 4 is fixed on the pipeline 14 by soil pressure cell support 21, and soil pressure cell fiber-optic grating sensor 4 is experienced the glide direction of the sensitive area of pressure towards landslide 13.The pressure of soil pressure cell fiber-optic grating sensor 3 measurements is exactly the positive thrust of the 13 pairs of pipelines 14 in landslide like this.
The landslide to the construction method of the thrust monitoring device of pipeline as shown in Figure 6, soil pressure cell fiber-optic grating sensor 4 is fixed on the pipeline 14 by soil pressure cell support 21, and soil pressure cell fiber-optic grating sensor 4 is experienced the glide direction of the sensitive area of pressure towards landslide 13.The pressure of soil pressure cell fiber-optic grating sensor 4 measurements is exactly the positive thrust of the 13 pairs of pipelines 14 in landslide like this.Soil pressure cell support 21 is made up of two circular arc steel plate clips, wherein is welded with base on one section circular arc steel plate, and soil pressure cell fiber-optic grating sensor 4 embeds in the base, and keeps certain allowance, makes soil pressure cell energy Free Transform.The clamp connection part 23 at soil pressure cell support 21 two ends connects by nut.When slide in landslide 13, the thrust of the 13 pairs of soil pressure cells in landslide can be measured by soil pressure cell fiber-optic grating sensor 4, and this measured value deducts the soil body gravity pressure that soil pressure cell fiber-optic grating sensor 4 bears, and is the thrust that landslide 13 distortion produce pipeline 14.
The monitoring device of body stress as shown in Figure 7 and Figure 8, be respectively to arrange pipeline monitoring cross section, arrange evenly that in the periphery in each monitoring cross section of pipeline 14 3 body fiber- optic grating sensors 3 and 3 body fiber-optic grating sensors 3 are arranged on the plane with pipeline 14 axis normal in the both sides of the edge and the center on landslide on landslide.3 outputs of body fiber-optic grating sensor connect 6 inputs of light switch, and 6 outputs of light switch connect fiber Bragg grating (FBG) demodulator 7 inputs, and the output of fiber Bragg grating (FBG) demodulator 7 connects on-the-spot host computer 8.
This installs single pass electric principle as shown in Figure 4, the PC joint of body fiber-optic grating sensor 3 is connected with the PC joint of light switch 6 with optical fiber, the R232 of light switch 6 directly connects the R232 of bit machine 8, the PC joint of light switch 6 connects the CH1 end of fiber Bragg grating (FBG) demodulator 7SM125, and the LAN port of fiber Bragg grating (FBG) demodulator 7SM125 connects the LAN port of bit machine 8.
The construction method of the monitoring device of body stress respectively arrange pipeline monitoring cross section in the both sides of the edge on landslide and the center on landslide, and the spacing in monitoring cross section should not surpass 60m shown in Fig. 7,8.Evenly arrange that in the periphery in each monitoring cross section of pipeline 14 3 body fiber- optic grating sensors 3 and 3 body fiber-optic grating sensors 3 are arranged on the plane with pipeline 14 axis normal.When body fiber-optic grating sensor 3 is installed, scrape pipeline 14 anticorrosive coats fully off, and polishing pipeline 14 surfaces are pasted the body fiber-optic grating sensor with Instant cement 3 and are encapsulated 24 packaged body fiber-optic grating sensors 3 to smooth.After treating that three body fiber-optic grating sensor 3 paste Lists are good, the fibre that draws of body fiber-optic grating sensor 3 is caused ground in the lump, and protect.
Draw when pipeline 14 axially bears/during compressive stress, three body fiber-optic grating sensors 3 bear and draw/compressive strain; According to certain algorithm,, can obtain the size and the position of maximum strain on these pipeline 14 cross sections by this cross section three places strain.Based on the steel theory of elasticity, can obtain the size of maximum drawing/compressive stress on pipeline 14 cross sections.The selection in monitoring cross section is very important to monitoring effect.
A large amount of studies show that, the crucial performance of 13 pairs of pipeline 14 imposed stresses that come down just can be judged the acceptable stress state of pipeline 14 in the axial direction preferably to the measurement of pipeline 14 axial stresses.Therefore, the only axial strain of measuring channel 14 of body fiber-optic grating sensor 3.
It is on-the-spot that the field monitoring station is arranged on the landslide, comprises optical Fiber Closure, connects optical cable 5, light switch 6, fiber Bragg grating (FBG) demodulator 7, host computer 8, GPRS transport module 9; By the optical Fiber Closure of each fiber-optic grating sensor be connected optical cable 5 fiber-optic grating sensor of each position that will come down on 13 and receive the light switch 6 of monitoring station, 6 outputs of light switch connect fiber Bragg grating (FBG) demodulator 7, fiber Bragg grating (FBG) demodulator 7 outputs connect bit machine 8, and host computer 8 outputs connect GPRS transport module 9.The optical Fiber Closure of each fiber-optic grating sensor be connected optical cable 5 and will come down and be transferred to the light switch 6 of monitoring station in the fiber-optic grating sensor set of signals of each position on 13, light switch 6 changes each channel signal successively to fiber Bragg grating (FBG) demodulator 7, fiber Bragg grating (FBG) demodulator 7 demodulates the centre wavelength displacement of each fiber-optic grating sensor and gives host computer 8, host computer 8 calculates the signal that each monitoring variable is defeated by GPRS transport module 9 and accepts GPRS transport module 9 automatically and controls, GPRS transport module 9 is transferred to the receiving terminal that is positioned at office with each monitoring variable that host computer 8 calculates by public's cordless communication network, also can accept the signal of receiving terminal, send to next bit computer 11.
Wherein:
Light switch: select for use light to swell scientific and technological SUM-FSW;
Fiber Bragg grating (FBG) demodulator: select SM125 for use;
Host computer and program: select for use and grind magnificent IPC-610, program is self-editing;
GPRS transport module: Siemens MC 35i.
The receiving terminal that is positioned at office comprises following 2 parts:
(1) the GPRS receiver module 10, are used to receive the monitoring variable that field monitoring station GPRS transport module 9 sends, and are transferred to terminal next bit computer 11, send feedback command also can for on-the-spot GPRS transport module 9;
(2) next bit computer 11 and program are used for the signal of download terminal GPRS receiver module 10, and calling program analyzes automatically, and analysis result and alarming threshold value are compared, and implement in the time of necessary to report to the police;
(3) alarm 12, are used for when analysis result surpasses alarming threshold value the sound alarm signal taking place; Alarm 12 is by next bit computer 11 and programmed control.
The principle of work of this system is such, when slide in landslide 13, the deviational survey pipe 1 that is embedded in 13 deeps, landslide come down 13 soil body thrusts and the strain that bends, deviational survey pipe fiber-optic grating sensor 16 on the deviational survey pipe 1 is experienced stretching strain, by calculating the horizontal shift that can draw on the deviational survey pipe, the horizontal shift in 13 deeps of promptly coming down; Come down in 13 active procedures, pipeline 14 bears landslide 13 thrusts and body 14 strain variation takes place, and measures by body fiber-optic grating sensor 3; On the surface of contact on pipeline 14 and landslide 13, the thrust of the 13 pairs of pipelines 14 in landslide is measured by soil pressure cell fiber-optic grating sensor 4.By connecting optical cable 5, above-mentioned three sensor signals are transferred to light switch 6, light switch 6 is given fiber Bragg grating (FBG) demodulator 7 with conversion of signals, fiber Bragg grating (FBG) demodulator 7 demodulates sensor wavelength centre wavelength displacement and sensing is given host computer 8, host computer 8 is calculated as monitoring variable automatically with the centre wavelength displacement that (FBG) demodulator demodulates, and monitoring variable sent to on-the-spot GPRS transport module 9, GPRS transport module 9 is transferred to terminal GPRS receiver module 10 by public's cordless communication network with signal, terminal GPRS receiver module 10 sends to terminal next bit computer 11, terminal next bit computer 11 provides warning with each monitoring variable and alarming threshold value contrast in the time of necessary.Finally just can measure stress suffered on the pipeline 14.
Wherein:
GPRS receiver module 10: select Siemens MC 35i for use;
Next bit computer 11 and program: slave computer is selected for use and is ground magnificent IPC-610; Program is self-editing.
Alarm 12: select Bosch DS-7400 for use.
Just can measure stress suffered on the pipeline 14.
Through monitoring for a long time, this example location is accurate, spatial resolution is high; Be easy to make up monitoring system, be easy to realize the real-time automatic collecting analysis and the long-range issue of pipeline landslide 13 Monitoring Data, remote live is reported to the police automatically.Avoided loaded down with trivial details artificial image data, reduced time of fire alarming, this to the pipeline emergency measure take most important.
Claims (5)
1. monitoring and warning pipeline landslide depth displacement method, it is characterized in that with monitoring be divided into the landslide depth displacement monitoring, three parts are monitored to the thrust monitoring and the pipeline strain of pipeline in the landslide:
The landslide depth displacement monitoring method is: the deviational survey pipe (1) that will be pasted with fiber-optic grating sensor is to be stained with the direction of fiber-optic grating sensor one side towards landslide (13) potential slip, and upward insertion is passed all potential slipping planes (15) and extended in the boring of 3~5m below the bedrock surface on landslide (13); Fibre-optical splice is connected with optical cable (5), signal is guided to the monitoring station by optical cable (5); In the monitoring station, host computer (8) calls self-editing program, control fiber Bragg grating (FBG) demodulator (7), and the real-time automatic collecting of realization data is measured the maximum stretching strain that deviational survey pipe (1) bears; If the deviational survey pipe (1) in the basement rock is a fixed constraint, utilize the double integral algorithm, the stretching strain by deviational survey pipe (1) distributes and just can solve the sag of deviational survey pipe (1), and this amount of deflection promptly is the landslide depth displacement amount;
The landslide to the thrust monitoring method of pipeline is: with being fixed on sensitive area that encapsulation soil pressure cell fiber-optic grating sensor (4) on the pipeline (14) and soil pressure cell fiber-optic grating sensor (4) the experience pressure glide direction measuring pressure towards landslide (13); The pressure measured of soil pressure cell fiber-optic grating sensor (4) (13) positive thrust that comes down exactly like this to pipeline;
The pipeline strain monitoring method is: on the pipeline (14) of the center on both sides of the edge of (13), landslide and landslide, evenly arrange pipeline (14) monitoring cross section, and the spacing in monitoring cross section should not surpass 60m; On each monitoring cross section of pipeline (14), evenly arrange 3 body strain fiber-optic grating sensors (3), the axial strain of monitoring pipeline (14).
2. monitoring and warning pipeline landslide depth displacement system of monitoring and warning pipeline landslide depth displacement method according to claim 1 is characterized in that landslide depth displacement monitoring device, landslide the receiving terminal of the thrust monitoring device of pipeline, pipeline strain monitoring device, field monitoring station, office being made of; The automatic light switch (6) that connects the field monitoring station is respectively exported to the soil pressure cell fiber-optic grating sensor (4) of the thrust monitoring device of pipeline and the body fiber-optic grating sensor (3) of pipeline strain monitoring device in the deviational survey pipe fiber-optic grating sensor (16) of on-the-spot landslide depth displacement monitoring device, landslide, automatically light switch (6) output connects the input of fiber Bragg grating (FBG) demodulator (7), and the output of fiber Bragg grating (FBG) demodulator (7) also connects the input of bit machine (8); The output of host computer (8) connects GPRS transport module (9), connects the input of next bit computer (11), the output device taking alarm (12) and the display of next bit computer (11) by the receiving terminal GPRS receiver module (10) of office.
3. monitoring and warning pipeline landslide depth displacement according to claim 2 system, the electric principle that it is characterized in that this system is: monitor landslide depth displacement respectively, the landslide is to three fiber-optic grating sensors--the deviational survey pipe fiber-optic grating sensor (16) of the thrust and the pipeline strain of pipeline, soil pressure cell fiber-optic grating sensor (4), the PC joint of body fiber-optic grating sensor (3) is connected with (PC) joint of light switch (6) with optical fiber, (R232) of light switch (6) directly connects (R232) of bit machine (8), (PC) joint of light switch (6) connects (CH1) end of fiber Bragg grating (FBG) demodulator (7) SM125, (LAN) port of fiber Bragg grating (FBG) demodulator (7) SM125 connects (LAN) port of bit machine (8), (R232) port of host computer (8) connects (R232) port of GPRS transport module (9) Siemens MC 35i, GPRS transport module (9) is through antenna GSM, GPRS network, received next bit computer (11) is received in the back by (R232) (R232) by GPRS receiver module (10) antenna GSM, the output of next bit computer (11) is by (R232) device taking alarm (12) DS-7400 (R232), and the output of next bit computer (11) is by (VGA) end of (VGA) termination display;
Monitoring landslide depth displacement, landslide are defeated by host computer (8) to the output signal of three fiber-optic grating sensors of the thrust of pipeline and pipeline strain through the centre wavelength displacement that fiber Bragg grating (FBG) demodulator (7) fiber grating (7) demodulates each fiber-optic grating sensor; Host computer (8) calculates the signal that each monitoring variable is defeated by GPRS transport module (9) and accepts GPRS transport module (9) automatically and controls, GPRS transport module (9) is transferred to the receiving terminal GPRS receiver module (10) that is positioned at office with each monitoring variable that host computer (8) calculates by public's cordless communication network, also can accept the signal of receiving terminal, after sending to next bit computer (11) processing, report to the police by the display demonstration and by alarm (12).
4. construction method as the monitoring and warning pipeline landslide depth displacement system of monitoring and warning pipeline landslide depth displacement system as described in the claim 2 is characterized in that its construction method is as follows:
The construction method of landslide depth displacement monitoring device:
1) go up on the landslide (13) of intending monitoring with the boring of geology drilling process, boring need be passed all potential slipping planes (15), and extends to the following 3~5m of bedrock surface; Requiring the whole bore open of boring is Φ 110mm, and hole deviation is less than requiring a complete set to manage and protect wall except that bedrock hole in 1 ° of well process;
2) be ready to the conventional deviational survey pipe (1) of a joint ABS or PVC; By drilling depth deviational survey pipe (1) is carried out pre-connection by joint, and make alignment mark and numbering, remove connection then at joint;
3) it is preceding to transfer deviational survey pipe (1), carries out hole operation clearly in boring, and till slime water became cleaning muddy water, it was unobstructed to guarantee to hole, and guarantees transferring smoothly of deviational survey pipe (1); Transfer the deviational survey pipe (1) that is pasted with sensor immediately after carrying brill;
4) on first deviational survey pipe (1) outer wall, paste the fiber grating strain sheet, and cutting on deviational survey pipe (1) outer wall, will connect optical fiber and use immobilization with adhesive tape in groove; For this monitoring result is verified, the fiber-optic grating sensor group is sticked in the residing a certain plane of deviational survey pipe (1) cross guide groove;
5) transfer first segment deviational survey pipe (1) aperture certain altitude, the alignment mark of pressing deviational survey pipe (1) is connected second deviational survey pipe (1) with numbering, and after pasting fiber Bragg grating strain sensor (16), cutting, fixedly connected optical fiber on second joint deviational survey pipe (1) outer wall, transfer the second joint deviational survey pipe (1); Using such method is transferred all deviational survey pipes (1) to the hole; When buoyancy of water in the boring causes deviational survey pipe (1) come-up, can inject proper amount of clear water to reduce to transfer resistance at deviational survey pipe (1);
6) treat that all deviational survey pipes (1) are transferred to the hole after, adjust the guide groove direction, make the sense of displacement of the direction of 16 groups of guide groove direction and fiber Bragg grating strain sensors towards sliding mass;
7) inject M5 fine sand sand-cement slurry in basement rock and deviational survey pipe (1) gap, mortar guides with Grouting Pipe, when Grouting Pipe down to from beginning slip casting behind the 1m place at the bottom of the hole; Backfill fine sand in the soil body and deviational survey pipe (1) gap;
8) do concrete pier in the aperture, in pier, bury steel bushing underground, with the Signal connector of protection fiber Bragg grating strain sensor (16) group; The fiber-optic signal joint is connected with optical cable (5), signal is guided to the monitoring station by optical cable (5);
The landslide is to the construction method of the thrust monitoring device of pipeline:
Soil pressure cell fiber-optic grating sensor (4) is fixed on the pipeline (14) by soil pressure cell support (21), and soil pressure cell fiber-optic grating sensor (4) is experienced the glide direction of the sensitive area of pressure towards landslide (13); Soil pressure cell support (21) is made up of two circular arc steel plate clips, wherein is welded with base on one section circular arc steel plate, and soil pressure cell fiber-optic grating sensor (4) embeds in the base, and keeps certain allowance, makes soil pressure cell energy Free Transform; The clamp connection part (23) at soil pressure cell support (21) two ends connects by nut;
The construction method of the monitoring device of body stress:
Respectively arrange pipeline monitoring cross section in the both sides of the edge on landslide and the center on landslide, and the spacing in monitoring cross section should not surpass 60m; Periphery in each monitoring cross section of pipeline (14) is evenly arranged 3 body fiber-optic grating sensors (3), and 3 body fiber-optic grating sensors (3) are arranged on the plane with pipeline (14) axis normal; Body fiber-optic grating sensor (3) is installed in smooth pipeline (14) surface, pastes body fiber-optic grating sensor encapsulation (24) packaged body fiber-optic grating sensors (3) with Instant cement; The fibre that draws of body fiber-optic grating sensor (3) is caused ground in the lump, and protect.
5. the construction method of monitoring and warning pipeline landslide depth displacement according to claim 4 system is characterized in that described deviational survey pipe fiber-optic grating sensor 16 is divided into to survey two kinds of axial strain and thermometric degree; The deviational survey pipe fiber-optic grating sensor 16 of surveying axial strain adopts Instant cement to be pasted on deviational survey pipe 1 outer wall, then with foam seal glue sealing deviational survey pipe fiber-optic grating sensor 16; Freely place deviational survey pipe fiber-optic grating sensor 16 a distance on deviational survey pipe 1 of thermometric degree, and deviational survey pipe fiber Bragg grating strain sensor is carried out temperature compensation for 16 groups.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN2008101195571A CN101667327B (en) | 2008-09-03 | 2008-09-03 | Method and system for monitoring and warning pipeline landslide depth displacement and method for constructing system |
Applications Claiming Priority (1)
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