CN1584562A - Gas pipeline leakage detecting and positioning method and system based on microwave technology - Google Patents

Abstract

A method for detecting leakage position of gas pipeline with microwave technique includes emitting TE01 and TM01 mode microwave into pipeline; measuring reflecting power, reflecting coefficient and reflecting phase-angle value, confirming that defect is existed on the pipeline when any value is exceeded over threshold value, emitting modulated microwave into pipeline and detecting time difference between emitting time and reflecting time for calculating out defect position in the pipeline according to the time difference.

Description

Gas transmission pipeline leakage detection positioning method and system based on microwave technology

The technical field is as follows:

a gas transmission pipeline leakage detection positioning method and system based on microwave technology belong to the technical field of detection of gas transmission pipeline leakage and crack fault states.

Background art:

compared with other transportation modes, the transportation mode has the advantages of high efficiency, safety, economy, small influence on environment, manpower and material resources conservation, convenience in management and control and the like, thereby playing an important role in the transportation of petroleum, natural gas and other fuel gases. But leakage accidents often occur due to aging of the piping equipment, influence of geographical and climatic conditions, and man-made damage.

Once the natural gas pipeline leaks, not only can economic loss and environmental pollution be brought, but also fire and explosion can occur, and casualty accidents can be caused. At present, the regional environment and climate change situation of China are complex, the complexity of a pipe network is increased, and the difficulty of a leak detection positioning technology is high; the gas transmission pipeline (including the oil transmission pipeline) in China is mostly used for criminals to steal gas (oil), and gas stealing points are difficult to discover through camouflage, so that the requirement on the precision of leak point positioning is high; the current partial leakage detection positioning technology also needs to arrange measuring points along the way or needs signal transmission lines, which not only increases the implementation difficulty, but also is easier to become the target of criminal destruction. Therefore, it is necessary to perform leak detection and leak positioning on the gas transmission pipeline to ensure the safe operation of the gas transmission pipeline.

The leakage detection technology of the long gas transmission pipeline is more difficult than that of the liquid pipeline because the gas has the characteristics of compressibility, small friction resistance, high pipe transmission pressure, large pressure fluctuation irregularity, high flow speed and the like. The development of the pipeline industry in China starts late, and the leakage detection technology is relatively lagged behind. At present, actual observation is mainly carried out by a plumber along a pipeline, and leakage accidents cannot be found timely and accurately. Although many works have been done by foreign pipeline engineers, there are a few satisfactory methods, especially less sophisticated methods of detecting leaks in long gas lines. Existing gas transmission pipeline leak detection methods are broadly classified into four categories:

one type is an in-pipe inspection method based on magnetic flux, eddy current, camera shooting, etc. pitching techniques, called pipe crawlers or PIG. The method has accurate positioning, but has higher requirements on the pipeline conditions, is easy to have accidents of blockage, outage and the like in actual use, and cannot carry out online monitoring;

the second type is an external detection method based on operation parameters such as pipeline pressure, temperature, flow, vibration and the like, and a large number of methods such as flow difference, pressure difference, negative pressure wave and sound wave are applied, so that the method is low in cost and can be used for continuous online monitoring, but the positioning precision is low, the method is easily disturbed by working conditions (pressure and flow) in a pump station, the missing report and the false report rate of leakage accidents are high, and a large amount of work is required for engineering application in the true sense. Although the method based on the pipeline model is more suitable in a theoretical sense, the actual pipeline model is difficult to obtain accurately, and part of pipeline parameters can change along with the long-term use of the pipeline, so that the positioning and detection results have great errors.

The third category is a number of aids developed for manual inspection, such as: portable/vehicle-mounted infrared, laser gas detector, leakage noise detector and other instruments, specially-trained animals and other instruments, and certain cable and optical fiber detection methods for specific transport media.

The fourth type is the electromagnetic wave-based detection technology closest to the present application, and is divided into two methods, namely off-line detection and on-line detection.

Patent 1 [ title: electromagnetic wave inspection method of piping system component, publication no: 1141673, publication date: 1997.01.29, tokyo-koku-shi, japan proposes that a transmission antenna of a transmission device excites an electromagnetic wave in a pipe of a pipeline system to be inspected to propagate the wave in the pipe, that a reception antenna of a reception device moves along the outside of the pipe, that the leaked electromagnetic wave is received to inspect a component of the pipeline system, and that a damaged portion such as a corrosion hole or a crack or a position of a joint or the like generated in the pipeline to be inspected is detected from a position of the reception antenna when a level of the electromagnetic wave received by the reception device reaches a peak.

Although this patent is well suited to the detection of leaks and cracks in a portion of a gas pipeline, the method has the following disadvantages: [1] the gas transmission pipeline cannot be monitored online in real time, and the pipeline is required to be inspected manually, so that the pipeline is very inconvenient; [2] the method can only inspect pipelines on the ground and cannot detect leakage and cracks of buried underground gas pipelines, and the current oil and gas fields and gas pipelines in China are basically underground pipeline transportation, so the method is not suitable for the actual situation in China.

Patent 2 [ title: pipeline protection leakage detection device and method, publication number: 1293366, publication date: 2001.05.02, China) for detecting pipe defects, cracks, leaks, pipe structural features; the principle is that electromagnetic waves are radiated in the pipeline, and the general operation of the pipeline is detected by using the principle that the structural characteristics of cracks, holes and the pipeline reflect the electromagnetic waves. The transmitting antenna and the receiving antenna are fixed in the pipeline wall, and when the pipeline is damaged, cracked, leaked or changed in structural form, the received electromagnetic waves contain corresponding characteristic information. The received electromagnetic wave signals are processed to determine the pipeline defects, cracks, leakage and pipeline structure characteristics.

The gas pipeline online leakage monitoring scheme proposed by the patent has the following disadvantages: [1] it is not proposed how to specifically detect cracks in pipes with different shapes (longitudinal and transverse cracks) distribution, and the situation of complex bent pipes; [2] the method provides that TE waves excited by a microwave source are converted into high-order TE waves, but TE fundamental modes in the pipeline are extremely unstable, a new excitation electric field is generated when a crack and a hole are crossed, the original electric field is degenerated into the high-order modes, receiving antennas are arranged on the upstream and the downstream of the crack or the hole of the pipeline, and the position and the size of the crack and the position of the crack in the pipeline are detected by measuring the time difference of reflecting and transmitting electromagnetic waves and the waveform mode degeneration high-order modes of the electromagnetic waves reflected by the crack and the hole. In the method, since the TE wave is converted into the high-order TE wave, a TE-based mode hardly exists in the pipeline; in addition, since the actual distribution of the pipes, and the shape and size of the cracks or holes, are difficult to determine, it is difficult to specify which mode is reflected. [3] Because the microwave is greatly attenuated in the gas transmission pipeline, the method does not provide a solution to the problem of limited pipeline detection distance caused by microwave attenuation. [4] This method does not give how to detect micro-cracks of a pipe effectively, since micro-cracks have little effect on the microwave transmission mode within the pipe. [5] The schematic block diagram of the electromagnetic wave receiving and transmitting device in patent 2 is difficult to detect other modes of exciting and transmitting holes and cracks in the pipeline, and the receiving circuit part also lacks necessary auxiliary circuits, such as: a first local oscillator circuit. [6] In patent 2, it is not indicated whether the microwave is emitted into the pipeline by means of continuous wave, sweep wave or modulated wave. [7] The necessary isolation and explosion-proof measures of the microwave receiving and transmitting device are not considered in the patent 2. [8] No measures are given in patent 2 as to how to ensure single mode operation and small attenuation of the microwaves in normal conditions.

The invention content is as follows:

the invention aims to provide a gas transmission pipeline leakage detection positioning method and system based on microwave technology, which can overcome the defects of the prior art, detect the position of a large transverse crack and a large longitudinal crack in a pipeline by using the change of a microwave mode, determine small cracks, holes, burrs and the like by using the change of a reflection coefficient mode and a phase and the power change of reflected waves and scattered waves, and can arrange a plurality of detection systems on a long-distance pipeline for detection so as to prevent the influence caused by microwave attenuation.

The outline of the defect detection principle of the gas transmission pipeline based on the microwave technology is introduced firstly as follows:

the metal circular pipe can be regarded as a circular waveguide for guiding electromagnetic waves. According to the electromagnetic wave propagation theory, the propagation law of microwaves in a waveguide mainly depends on the frequency, mode, cross-sectional shape and size of the waveguide and the characteristics of the medium in the waveguide. When any of the above parameters is changed, the propagation characteristics of the electromagnetic wave will be changed. If there is a defect, crack, hole, and deposit of other matter somewhere in the pipe, there will be reflection and scattering of the wave. If the wave is transmitted in a single mode in the pipeline, when cracks and fissures exist in the pipeline, the cracks and fissures can cut off induced current on the surface wall, so that the distribution of the electromagnetic field is distorted, other high-order modes can be propagated in the pipeline, and the propagation characteristics of the wave in the pipeline can be changed.

A circular waveguide (i.e., σ ∞) is formed by considering a metal as an ideal conductor, with a pipe radius a. When TE is propagated in the pipeline₀₁And (3) the electromagnetic field distribution in the pipeline is as follows:

<math> <mrow> <msub> <mi>E</mi> <mi>&Phi;</mi> </msub> <mo>=</mo> <mo>-</mo> <mo></mo> <mfrac> <mrow> <mi>j&omega;</mi> <msub> <mi>&mu;</mi> <mn>0</mn> </msub> <mi>a</mi> </mrow> <mn>3.82</mn> </mfrac> <msub> <mi>H</mi> <mi>m</mi> </msub> <msub> <mi>J</mi> <mn>1</mn> </msub> <mrow> <mo>(</mo> <mfrac> <mn>3.832</mn> <mi>a</mi> </mfrac> <mi>r</mi> <mo>)</mo> </mrow> <msup> <mi>e</mi> <mrow> <mi>j</mi> <mrow> <mo>(</mo> <mi>&omega;t</mi> <mo>-</mo> <mi>&beta;z</mi> <mo>)</mo> </mrow> </mrow> </msup> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>1</mn> <mo>-</mo> <mn>1</mn> <mo>)</mo> </mrow> </mrow> </math>

<math> <mrow> <msub> <mi>H</mi> <mrow> <mi>r</mi> <mo>=</mo> </mrow> </msub> <mfrac> <mi>j&beta;&alpha;</mi> <mn>3.82</mn> </mfrac> <mi></mi> <msub> <mi>H</mi> <mi>m</mi> </msub> <msub> <mi>J</mi> <mrow> <mn>1</mn> <mi></mi> </mrow> </msub> <mrow> <mo>(</mo> <mfrac> <mn>3.832</mn> <mi>a</mi> </mfrac> <mo>)</mo> </mrow> <msup> <mi>e</mi> <mrow> <mi>j</mi> <mrow> <mo>(</mo> <mi>&omega;t</mi> <mo>-</mo> <mi>&beta;z</mi> <mo>)</mo> </mrow> </mrow> </msup> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>1</mn> <mo>-</mo> <mn>2</mn> <mo>)</mo> </mrow> </mrow> </math>

<math> <mrow> <msub> <mi>H</mi> <mi>z</mi> </msub> <mo>=</mo> <msub> <mi>H</mi> <mi>m</mi> </msub> <msub> <mi>J</mi> <mn>0</mn> </msub> <mrow> <mo>(</mo> <mfrac> <mn>3.832</mn> <mi>a</mi> </mfrac> <mi>r</mi> <mo>)</mo> </mrow> <msup> <mi>e</mi> <mrow> <mi>j</mi> <mrow> <mrow> <mo>(</mo> <mi>&omega;t</mi> <mo>-</mo> <mi>&beta;z</mi> <mo>)</mo> </mrow> <mi></mi> </mrow> </mrow> </msup> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>1</mn> <mo>-</mo> <mn>3</mn> <mo>)</mo> </mrow> </mrow> </math>

E_r＝E_z＝H_Φ＝0 (1-4)

boundary condition J of conductor and air_s＝n×H|_sThe induced current on the inner surface wall of the pipeline can be obtained as

<math> <mrow> <msub> <mrow> <msub> <mi>J</mi> <mi>&Phi;</mi> </msub> <mo>=</mo> <mi>H</mi> </mrow> <mrow> <mi>m</mi> </mrow> </msub> <msub> <mi>J</mi> <mn>0</mn> </msub> <mrow> <mo>(</mo> <mn>3.832</mn> <mo>)</mo> </mrow> <msup> <mi>e</mi> <mrow> <mi>j</mi> <mrow> <mo>(</mo> <mi>&omega;t</mi> <mo>-</mo> <mi>&beta;z</mi> <mo>)</mo> </mrow> </mrow> </msup> <mrow> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>2</mn> <mo>)</mo> </mrow> </mrow> </mrow> </math>

If there are longitudinal cracks, fissures, on the inner pipe wall, these fissures will interrupt the inner pipe wall current. The result is: where the wave will be reflected and scattered, TE₀₁The field distribution of the mode will change, eliminating the propagation TE in the pipe₀₁And (5) outside the die. There are also other higher order modes present. By detecting TE₀₁The change in mode as the mode propagates through the pipe can determine whether longitudinal cracks, fissures (and cracks, fissures distributed along the axial direction of the pipe) exist within the pipe.

If TM is propagated in the pipe₀₁Mode, electromagnetic field distribution in pipeComprises the following steps:

<math> <mrow> <msub> <mi>E</mi> <mi>r</mi> </msub> <mo>=</mo> <mfrac> <mi>j&omega;a</mi> <mn>2.405</mn> </mfrac> <msub> <mi>E</mi> <mi>m</mi> </msub> <msub> <mi>J</mi> <mn>1</mn> </msub> <mrow> <mo>(</mo> <mfrac> <mn>2.405</mn> <mi>a</mi> </mfrac> <mi>r</mi> <mo>)</mo> </mrow> <msup> <mi>e</mi> <mrow> <mi>j</mi> <mrow> <mo>(</mo> <mi>&omega;t</mi> <mo>-</mo> <mi>&beta;z</mi> <mo>)</mo> </mrow> </mrow> </msup> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>3</mn> <mo>-</mo> <mn>1</mn> <mo>)</mo> </mrow> </mrow> </math>

<math> <mrow> <msub> <mi>E</mi> <mi>z</mi> </msub> <mo>=</mo> <msub> <mi>E</mi> <mi>m</mi> </msub> <msub> <mi>J</mi> <mn>0</mn> </msub> <mrow> <mo>(</mo> <mfrac> <mn>2.405</mn> <mi>a</mi> </mfrac> <mi>r</mi> <mo>)</mo> </mrow> <msup> <mi>e</mi> <mrow> <mi>j</mi> <mrow> <mo>(</mo> <mi>&omega;t</mi> <mo>-</mo> <mi>&beta;z</mi> <mo>)</mo> </mrow> </mrow> </msup> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>3</mn> <mo>-</mo> <mn>2</mn> <mo>)</mo> </mrow> </mrow> </math>

<math> <mrow> <msub> <mi>H</mi> <mi>&Phi;</mi> </msub> <mo>=</mo> <mfrac> <mi>j&omega;&epsiv;a</mi> <mn>2.405</mn> </mfrac> <msub> <mi>E</mi> <mi>m</mi> </msub> <msubsup> <mi>J</mi> <mn>1</mn> <mo>&prime;</mo> </msubsup> <mrow> <mo>(</mo> <mfrac> <mn>2.405</mn> <mi>a</mi> </mfrac> <mi>r</mi> <mo>)</mo> </mrow> <msup> <mi>e</mi> <mrow> <mi>j</mi> <mrow> <mo>(</mo> <mi>&omega;t</mi> <mo>-</mo> <mi>&beta;z</mi> <mo>)</mo> </mrow> </mrow> </msup> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>3</mn> <mo>-</mo> <mn>3</mn> <mo>)</mo> </mrow> </mrow> </math>

E_Φ＝H_r＝H_z＝0 (3-4)

because the magnetic field near the tube wall is only H_ΦComponent, hence wall current, is only J_zComponent of induced current of magnetic field on inner surface wall

<math> <mrow> <mi>J</mi> <mo>=</mo> <msub> <mi>a</mi> <mi>z</mi> </msub> <mfrac> <mi>j&omega;&epsiv;a</mi> <mn>2.405</mn> </mfrac> </mrow> </math><math> <mrow> <msub> <mi>E</mi> <mi>m</mi> </msub> <msubsup> <mi>J</mi> <mn>1</mn> <mo>&prime;</mo> </msubsup> <mrow> <mo>(</mo> <mn>2.405</mn> <mo>)</mo> </mrow> <msup> <mi>e</mi> <mrow> <mi>j</mi> <mrow> <mo>(</mo> <mi>&omega;t</mi> <mo>-</mo> <mi>&beta;z</mi> <mo>)</mo> </mrow> </mrow> </msup> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>4</mn> <mo>)</mo> </mrow> </mrow> </math>

Obviously, any a_ΦThe directional cracks, fissures will intercept the induced current on the inner surface wall. The result is: where the wave will be reflected and scattered, TM₀₁The field distribution of the mode will change, eliminating propagation in the pipe₀₁In addition to the modes, other higher order modes exist. Then by detecting TM₀₁The change in mode as the mode propagates through the pipe can determine whether transverse cracks, fissures (and cracks, fissures distributed radially along the pipe) are present within the pipe.

In general, the orientation of cracks on the inner wall of a pipe is arbitrary and we can break it down into a transverse component and a longitudinal component and propagate TE in the pipe separately₀₁Mode and TM₀₁And (5) molding. The presence of both transverse and longitudinal components of the pipe is detected by detecting changes in its mode, thereby determining the presence and orientation of cracks, fissures, and the like in the pipe.

If the modulated microwave pulses are to be separated, as shown in FIG. 1With TE₀₁Mode and TM₀₁The die is injected into the metal pipe from the a end, and the other end of the metal pipe is matched with a load. If there is a defect at point B, the modulated wave pulse is reflected at point B. For TE₀₁Mode of cutoff wavelength λ_C1.640a, the phase velocity of the wave in the waveguide is

<math> <mrow> <msub> <mi>v</mi> <mi>P</mi> </msub> <mo>=</mo> <mfrac> <mi>c</mi> <msqrt> <mn>1</mn> <mo>-</mo> <msup> <mrow> <mo>(</mo> <mi>&lambda;</mi> <mo>/</mo> <mn>1.640</mn> <mi>a</mi> <mo>)</mo> </mrow> <mn>2</mn> </msup> </msqrt> </mfrac> <mi></mi> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>5</mn> <mo>)</mo> </mrow> </mrow> </math>

The positions of the longitudinal cracks and the cracks can be calculated by measuring the time delta t required by the modulation wave pulse to make a round trip, namely:

<math> <mrow> <mi>&Delta;l</mi> <mo>=</mo> <mfrac> <mrow> <msub> <mi>v</mi> <mi>P</mi> </msub> <mi>&Delta;t</mi> </mrow> <mn>2</mn> </mfrac> <mo>=</mo> <mfrac> <mi>c&Delta;t</mi> <mrow> <mn>2</mn> <msqrt> <mn>1</mn> <mo>-</mo> <msup> <mrow> <mo>(</mo> <mi>&lambda;</mi> <mo>/</mo> <mn>1.640</mn> <mi>a</mi> <mo>)</mo> </mrow> <mn>2</mn> </msup> </msqrt> </mrow> </mfrac> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>6</mn> <mo>)</mo> </mrow> </mrow> </math>

for TM₀₁Mode of cutoff wavelength λ_C2.620a, the phase velocity of the wave in the waveguide is

<math> <mrow> <msub> <mi>v</mi> <mi>P</mi> </msub> <mo>=</mo> <mfrac> <mi>c</mi> <msqrt> <mn>1</mn> <mo>-</mo> <msup> <mrow> <mo>(</mo> <mi>&lambda;</mi> <mo>/</mo> <mn>2.620</mn> <mi>a</mi> <mo>)</mo> </mrow> <mn>2</mn> </msup> </msqrt> </mfrac> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>7</mn> <mo>)</mo> </mrow> </mrow> </math>

The positions of transverse cracks and cracks can be calculated by measuring the time delta t required by the modulation wave pulse to make a round trip, namely:

<math> <mrow> <mi>&Delta;l</mi> <mo>=</mo> <mfrac> <mrow> <msub> <mi>v</mi> <mi>P</mi> </msub> <mi>&Delta;t</mi> </mrow> <mn>2</mn> </mfrac> <mo>=</mo> <mfrac> <mi>c&Delta;t</mi> <mrow> <mn>2</mn> <msqrt> <mn>1</mn> <mo>-</mo> <msup> <mrow> <mo>(</mo> <mi>&lambda;</mi> <mo>/</mo> <mn>2.620</mn> <mi>a</mi> <mo>)</mo> </mrow> <mn>2</mn> </msup> </msqrt> </mrow> </mfrac> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>8</mn> <mo>)</mo> </mrow> </mrow> </math>

here, c is the speed of light, and λ is the wavelength of the modulated wave.

The change in the propagation wave mode is not only related to the orientation and length of the crack, but also to the depth of the crack. The induced current of the electromagnetic wave on the metal surface is not distributed on the absolute surface but in a thin layer. According to the skin effect of electromagnetic waves, the electromagnetic waves in metal attenuate exponentially with the penetration depth, and the induced current also attenuates exponentially with the penetration depth, i.e.

J＝J₀e^-aze^j(ωt-βz) (9)

Wherein, J₀The value of the induced current on the surface of the conductor, <math> <mrow> <mi>a</mi> <mo>=</mo> <msqrt> <mi>&pi;f&mu;&sigma;</mi> </msqrt> </mrow> </math> is the attenuation constant of the conductor to the electromagnetic wave. As a result, the deeper the crack on the metal surface, the more the cut-off feelingThe more current should be, and therefore the greater the change to the propagation mode.

For a surface wall crack with a small size, because the cut induced current is small and the influence of the crack on the propagation wave mode is small, small cracks and cracks in the pipeline cannot be judged by the mode change of the propagation, but the small cracks and the small cracks scatter electromagnetic waves, and the detection is needed by a scattered wave method.

The metal foreign bodies on the inner surface wall of the pipeline are mostly metal crystals with smaller volume or small metal burrs. The small metal crystals can be regarded as metal balls with small radius, and the small metal burrs can be regarded as metal cylinders with small radius. Scattering occurs when electromagnetic waves impinge on these small metal spheres and small metal cylinders. The far-zone scattered field of the electromagnetic wave to the conductor ball with the radius of a is

<math> <mrow> <msub> <mi>E</mi> <mi>&theta;c</mi> </msub> <mo>=</mo> <mfrac> <mrow> <msub> <mi>E</mi> <mn>0</mn> </msub> <msup> <mi>e</mi> <mrow> <mo>-</mo> <mi>jkr</mi> </mrow> </msup> </mrow> <mi>kr</mi> </mfrac> <mi>cos</mi> <mi>&Phi;</mi> <munderover> <mi>&Sigma;</mi> <mrow> <mi>n</mi> <mo>=</mo> <mn>1</mn> </mrow> <mo>&infin;</mo> </munderover> <msub> <mi>a</mi> <mi>n</mi> </msub> <mo>&lsqb;</mo> <msub> <mi>c</mi> <mi>n</mi> </msub> <mfrac> <mi>d</mi> <mi>d&theta;</mi> </mfrac> <msubsup> <mi>P</mi> <mi>n</mi> <mo>&prime;</mo> </msubsup> <mrow> <mo>(</mo> <mi>cos</mi> <mi>&theta;</mi> <mo>)</mo> </mrow> <mo>+</mo> <msub> <mi>d</mi> <mi>n</mi> </msub> <mfrac> <mrow> <msubsup> <mi>P</mi> <mi>n</mi> <mo>&prime;</mo> </msubsup> <mrow> <mo>(</mo> <mi>cos</mi> <mi>&theta;</mi> <mo>)</mo> </mrow> </mrow> <mrow> <mi>sin</mi> <mi>&theta;</mi> </mrow> </mfrac> <mo>&rsqb;</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>10</mn> <mo>-</mo> <mn>1</mn> <mo>)</mo> </mrow> </mrow> </math>

<math> <mrow> <msub> <mi>E</mi> <mi>&Phi;c</mi> </msub> <mo>=</mo> <mo>-</mo> <mi>j</mi> <mfrac> <mrow> <msub> <mi>E</mi> <mn>0</mn> </msub> <msup> <mi>e</mi> <mrow> <mo>-</mo> <mi>jkr</mi> </mrow> </msup> </mrow> <mi>kr</mi> </mfrac> <mi>sin</mi> <mi>&Phi;</mi> <munderover> <mi>&Sigma;</mi> <mrow> <mi>n</mi> <mo>=</mo> <mn>1</mn> </mrow> <mo>&infin;</mo> </munderover> <msub> <mi>a</mi> <mi>n</mi> </msub> <mo>&lsqb;</mo> <msub> <mi>d</mi> <mi>n</mi> </msub> <mfrac> <mi>d</mi> <mi>d&theta;</mi> </mfrac> <msubsup> <mi>P</mi> <mi>n</mi> <mo>&prime;</mo> </msubsup> <mrow> <mo>(</mo> <mi>cos</mi> <mi>&theta;</mi> <mo>)</mo> </mrow> <mo>+</mo> <msub> <mi>c</mi> <mi>n</mi> </msub> <mfrac> <mrow> <msubsup> <mi>P</mi> <mi>n</mi> <mo>&prime;</mo> </msubsup> <mrow> <mo>(</mo> <mi>cos</mi> <mi>&theta;</mi> <mo>)</mo> </mrow> </mrow> <mrow> <mi>sin</mi> <mi>&theta;</mi> </mrow> </mfrac> <mo>&rsqb;</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>10</mn> <mo>-</mo> <mn>2</mn> <mo>)</mo> </mrow> </mrow> </math>

<math> <mrow> <msub> <mi>H</mi> <mi>&theta;c</mi> </msub> <mo>=</mo> <mi>j</mi> <mfrac> <mrow> <msub> <mi>E</mi> <mn>0</mn> </msub> <msup> <mi>e</mi> <mrow> <mo>-</mo> <mi>jkr</mi> </mrow> </msup> </mrow> <mi>kr&eta;</mi> </mfrac> <mi>sin</mi> <mi>&Phi;</mi> <munderover> <mi>&Sigma;</mi> <mrow> <mi>n</mi> <mo>=</mo> <mn>1</mn> </mrow> <mo>&infin;</mo> </munderover> <msub> <mi>a</mi> <mi>n</mi> </msub> <mo>&lsqb;</mo> <msub> <mi>d</mi> <mi>n</mi> </msub> <mfrac> <mi>d</mi> <mi>d&theta;</mi> </mfrac> <msubsup> <mi>P</mi> <mi>n</mi> <mo>&prime;</mo> </msubsup> <mrow> <mo>(</mo> <mi>cos</mi> <mi>&theta;</mi> <mo>)</mo> </mrow> <mo>+</mo> <msub> <mi>c</mi> <mi>n</mi> </msub> <mfrac> <mrow> <msubsup> <mi>P</mi> <mi>n</mi> <mo>&prime;</mo> </msubsup> <mrow> <mo>(</mo> <mi>cos</mi> <mi>&theta;</mi> <mo>)</mo> </mrow> </mrow> <mrow> <mi>sin</mi> <mi>&theta;</mi> </mrow> </mfrac> <mo>]</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>10</mn> <mo>-</mo> <mn>3</mn> <mo>)</mo> </mrow> </mrow> </math>

<math> <mrow> <msub> <mi>H</mi> <mi>&Phi;c</mi> </msub> <mo>=</mo> <mi>j</mi> <mfrac> <mrow> <msub> <mi>E</mi> <mn>0</mn> </msub> <msup> <mi>e</mi> <mrow> <mo>-</mo> <mi>jkr</mi> </mrow> </msup> </mrow> <mi>kr&eta;</mi> </mfrac> <mi>cos</mi> <mi>&Phi;</mi> <munderover> <mi>&Sigma;</mi> <mrow> <mi>n</mi> <mo>=</mo> <mn>1</mn> </mrow> <mo>&infin;</mo> </munderover> <msub> <mi>a</mi> <mi>n</mi> </msub> <mo>&lsqb;</mo> <msub> <mi>c</mi> <mi>n</mi> </msub> <mfrac> <mi>d</mi> <mi>d&theta;</mi> </mfrac> <msubsup> <mi>P</mi> <mi>n</mi> <mo>&prime;</mo> </msubsup> <mrow> <mo>(</mo> <mi>cos</mi> <mi>&theta;</mi> <mo>)</mo> </mrow> <msub> <mi>d</mi> <mi>n</mi> </msub> <mfrac> <mrow> <msubsup> <mi>P</mi> <mi>n</mi> <mo>&prime;</mo> </msubsup> <mrow> <mo>(</mo> <mi>cos</mi> <mi>&theta;</mi> <mo>)</mo> </mrow> </mrow> <mrow> <mi>sin</mi> <mi>&theta;</mi> </mrow> </mfrac> <mo>&rsqb;</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>10</mn> <mo>-</mo> <mn>4</mn> <mo>)</mo> </mrow> </mrow> </math>

The average power of the far field is:

<math> <mrow> <mi>s</mi> <mo>=</mo> <mfrac> <mn>1</mn> <mn>2</mn> </mfrac> <mi>Re</mi> <mrow> <mo>(</mo> <msub> <mi>E</mi> <mi>s</mi> </msub> <mo>&times;</mo> <msubsup> <mi>H</mi> <mi>s</mi> <mn>3</mn> </msubsup> <mo>)</mo> </mrow> <mo>=</mo> <mfrac> <mn>1</mn> <mn>2</mn> </mfrac> <mi>Re</mi> <mrow> <mo>(</mo> <msub> <mi>E</mi> <mi>&theta;s</mi> </msub> <msubsup> <mi>H</mi> <mi>&Phi;s</mi> <mn>3</mn> </msubsup> <mo>-</mo> <msub> <mi>E</mi> <mi>&Phi;s</mi> </msub> <msubsup> <mi>H</mi> <mi>&theta;s</mi> <mn>3</mn> </msubsup> <mo>)</mo> </mrow> <msub> <mi>a</mi> <mi>r</mi> </msub> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mo>-</mo> <mrow> <mo>(</mo> <mn>11</mn> <mo>)</mo> </mrow> </mrow> </math>

theory and experiment prove that for a conductor pellet with radius a, when obvious scattering occurs, the relationship between the radius a and the wavelength lambda corresponds to a certain frequency:

ka 1, K2 pi/lambda, lambda is wavelength (12)

Therefore, when the terminal is connected with a matched load, the foreign matter in the metal pipeline can be detected by extracting scattered wave power at the incident end. For the detection of the burrs in the pipeline, the detection principle is the same as that described above. Small cracks, fissures are also detected by extracting the scattered wave power.

In general, when a defect exists in a pipe, the mode of the reflection coefficient of the microwave reflected wave increases monotonously with the increase of the degree of the defect, and when the size of the defect is zero, the mode of the reflection coefficient is also zero. Therefore, the method for measuring the reflection coefficient modulus can only be used for detecting the defect with larger size; the phase of the reflection coefficient is particularly sensitive to imperfections of the pipe, which undergo sudden changes when the thickness of the imperfection is zero. The presence of defects can be determined by measuring the phase of the reflection coefficient, which is particularly effective, especially when the size of the defects is small. The mode and phase angle of the reflection coefficient are changed due to the introduction of the defect, and the change amount is changed along with the working frequency. The defect has less influence on the mode of the reflection coefficient; the phase angle of the reflection coefficient is very sensitive to imperfections and at some frequencies the phase difference can reach + -pi.

Based on the principle, the cracks and the inner surface metal foreign bodies in the pipeline can be judged by detecting the following information, and the characteristic signals to be extracted are as follows:

1. TE in pipe₀₁Mode and TM₀₁Molding;

2. reflection coefficient mode and phase angle of the reflected wave;

3. reflected wave power Pr or scattered wave power Ps passing through the section of the incident point;

4. the modulation wave pulse returns to the incident point after being reflected from the incident point to the defect by the time delta t.

The method is characterized in that: the method is controlled by an industrial personal computer of a monitoring center to execute the following steps:

1) initializing an industrial personal computer of a monitoring center:

given TE₀₁Mode change overrun threshold, TM, of mode microwaves₀₁Mode change overrun threshold of mode microwave; an overrun threshold of the reflection coefficient mode, an overrun threshold of the reflection coefficient phase angle; the power of the reflected wave and/or the scattered wave exceeds a threshold value;

2) starting microwave source to alternatively emit TE to pipeline₀₁And TM₀₁Single mode microwaves, the frequency of the microwaves being the sensitive frequency that ensures single mode transmission of the microwaves in the pipe and maximizes the reflected or scattered power;

3) receiving TE detected by a propagation mode detector₀₁And TE₀₁A mode of the wave; receiving the reflection coefficient mode and the phase angle value detected by the phase angle detector; receiving reflected wave power or scattered wave power detected by a power meter;

4) when the above TE is present₀₁And TM₀₁When the mode detection value of the wave exceeds the change over-limit threshold value, or the detection values of the reflection coefficient mode and the phase angle exceed the change over-limit threshold value, or the reflected wave power or the scattered wave power exceeds the over-limit threshold value, starting the microwave source to emit pulse modulation waves to scan the pipeline;

5) acquiring the time difference delta t between the incidence and the receiving reflection of the pulse modulation microwave detected by the pulse round-trip detector, and calculating the position delta l of the defect:

<math> <mrow> <mi>&Delta;l</mi> <mo>=</mo> <mfrac> <mtext>c&Delta;t</mtext> <mrow> <mn>2</mn> <msqrt> <mn>1</mn> <mo>-</mo> <msup> <mrow> <mo>(</mo> <mi>&lambda;</mi> <mo>/</mo> <mn>1.640</mn> <mi>a</mi> <mo>)</mo> </mrow> <mn>2</mn> </msup> </msqrt> </mrow> </mfrac> <mo>,</mo> </mrow> </math> when transmitting TE₀₁When the mode microwave is generated; or <math> <mrow> <mi>&Delta;l</mi> <mo>=</mo> <mfrac> <mi>c&Delta;t</mi> <mrow> <mn>2</mn> <msqrt> <mn>1</mn> <mo>-</mo> <msup> <mrow> <mo>(</mo> <mi>&lambda;</mi> <mo>/</mo> <mn>2.620</mn> <mi>a</mi> <mo>)</mo> </mrow> <mn>2</mn> </msup> </msqrt> </mrow> </mfrac> <mo>,</mo> </mrow> </math> When transmitting TM₀₁When the mode microwave is generated;

wherein c is the speed of light, lambda is the wavelength of the modulating wave, a is the radius of the pipeline to be measured, and delta l is the distance between the inlet of the pipeline and the defect.

The power of the reflected wave and scattered wave is equal to the transmitted TE₀₁And TM₀₁5% of the power of the single mode microwave.

The system is characterized in that: it comprises a microwave transmitting and receiving unit, a detecting unit and a monitoring center; wherein,

microwave transmitting and receiving unit:

the microwave power supply, the electric control attenuator, the power amplifier and the bidirectional coupler are sequentially connected through a coaxial cable, and an isolated explosion-proof device, a waveguide-coaxial converter and a rectangular-circular waveguide filter are sequentially connected with the bidirectional coupler through the coaxial cable; the rectangular-circular waveguide filter is connected with a transition joint, and the other end of the transition joint is connected with the input end of the pipeline to be tested; the control end of the microwave source is connected with the monitoring center;

a detection unit:

comprises two propagation mode detectors respectively arranged at two ends of effective detection length of pipeline to be detected, and arranged along radial direction of pipeline for detecting TE₀₁An open loop probe of the die, and a probe mounted axially along the pipe for detecting the TM₀₁A closed small coupling ring of the die; the tail end of the effective detection length of the pipeline is also provided with a matching load for preventing microwave reflection; the signal output ends of the open-circuit annular probe and the closed small coupling ring are sequentially connected with a safety grid for isolation and explosion prevention and a data acquisition terminal RTU (remote terminal unit) containing an A/D (analog/digital) converter, a control module and a serial communication interface, and the data acquisition terminal RTU is connected with the monitoring center in a wired or wireless mode;

the reference signal input end of the reflection coefficient mode and phase angle detector is connected with the reference signal output end of the bidirectional coupler through a coaxial cable, the signal input end of the reflection coefficient mode and phase angle detector is connected with the microwave signal output end of the bidirectional coupler through a coaxial cable, and the output end of the reflection coefficient mode and phase angle detector is connected with the monitoring center;

the power meter is used for detecting the microwave power reflected or scattered back by the pipeline, the input end of the power meter is connected with the power output end of the bidirectional coupler through a coaxial cable, and the output end of the power meter is connected with the monitoring center;

the pulse round-trip time detector is used for detecting the time difference between the emission and the receiving of the pulse modulation wave to the reflected wave, the reference signal input end of the pulse round-trip time detector is connected with the reference signal output end of the bidirectional coupler through a coaxial cable, the signal input end of the pulse round-trip time detector is connected with the microwave signal output end of the bidirectional coupler through a coaxial cable, and the output end of the pulse round-trip time detector is connected with the monitoring center;

the monitoring center: the system comprises an industrial personal computer which controls a microwave transmitting and receiving unit, receives detection data uploaded by a detection unit and calculates the position delta l of a defect in a pipeline.

The reflection coefficient mode and phase angle detector comprises a Wiltron560A scalar network analyzer for detecting the reflection coefficient mode and an HP8408S vector network analyzer for detecting the reflection coefficient phase angle, wherein reference signal input ends of the Wiltron560A scalar network analyzer and the HP8408S vector network analyzer are respectively connected with a reference signal output end of the bidirectional coupler through coaxial cables, signal input ends of the Wiltron560 scalar network analyzer and the HP8408S vector network analyzer are respectively connected with a microwave signal output end of the bidirectional coupler through the coaxial cables, and output ends of the Wiltron560 scalar network analyzer and the HP8408S vector network analyzer are respectively connected with a monitoring center.

Experiments prove that the method can effectively identify whether the gas pipeline has defects or not, and can accurately position the positions of the defects, thereby achieving the expected purpose.

Description of the drawings:

FIG. 1: a gas pipeline leak detection system schematic;

FIG. 2: gas transmission pipeline leakage detection and positioning method flow chart based on microwave technology

FIG. 3: an open loop probe placement position schematic;

201: a pipeline; 202: annular probe ring

FIG. 4 is a schematic view of the closed small coupling ring placement;

301: a pipeline; 302: closed small coupling

Fig. 5 (a): an interrupt pin diagram of a Rabbit chip in the RCM2200 module;

fig. 5 (b): an interrupt logic diagram of a Rabbit chip in the RCM2200 module;

fig. 5 (c): the time difference between the incident and reflected modulated pulse waves is shown;

FIG. 6: an RTU data acquisition and transmission schematic diagram for a transmission mode detector;

fig. 7 (a): a graph of the reflection intensity versus the extent of defect cracking;

fig. 7 (b): and the reflection phase is plotted against the degree of defect cracking.

The specific implementation mode is as follows:

detection method

With reference to the schematic flow chart of the detection and positioning method in fig. 2, the work flow of the whole system is controlled by the monitoring center, and the process is as follows:

【1】 Starting a microwave source and each detection and measurement unit module;

before the whole system works, the following work should be carried out:

1. when the pipe shape and distribution are relatively regular, TE₀₁Sum of waves TM₀₁The mode change overrun threshold, reflected power overrun threshold, scattered power overrun threshold of the wave should ideally be 0. However, since the distribution shape of the actual pipeline is complicated and varied, even if there is no defect, the pipeline still has a certain degree of reflection, scattering and mode change to the incident microwave. Therefore, it is necessary to set TE separately by detecting the initial state of the pipeline without failure before the detection₀₁Sum of waves TM₀₁The mode of the wave changes an overrun threshold, a reflected power overrun threshold and a scattered power overrun threshold. The initial state is detected when the system is installed, and the pipeline is generally considered to have no defects, and in this case, the mode change signal can be extracted at the position where r is 0 at the incident end and the exit end of the pipeline. First testing TE propagating in a metal pipe₀₁The induced voltage value extracted by the open-circuit annular electric probe is the current TE of the pipeline₀₁A modulo threshold; the TM propagating in the pipe is then retested₀₁The current value of the induced current extracted by the small coupling loop is the current TM of the pipeline₀₁A modulo threshold.

2. For a pipeline with a specific size (pipeline radius), a proper frequency point is found, so that the single-mode propagation of the microwave in the pipeline is ensured, and the power attenuation is relatively minimum. How to determine a microwave transmission frequency satisfying the above requirements according to a specific pipeline can be determined by comparing a "pipe diameter-attenuation characteristic curve" and a "pipe diameter-cutoff frequency curve". The details can be found in the relevant microwave principle introduction documents, and also in the following curve relations:

such as The document [1] Kawahara N.Experimental wireless microphone for The introduction of The interface of tube, The third International Microprocessor Symposium, 1997.137-140; (Kawahara N, test Wireless micro robot for pipe inner surface inspection, third International micro robot seminar, 1997.137-140)

Document [2] Sasaya T, Shibata T, Kawahara N.Microwave energy supply in-pipe Micromachine, the fourth International Micromachine Symposium, 1998.159-164; (Sasaya T, Shibata T, Kawahara N, microwave Wireless energy supply of micro-robot in pipe, fourth International seminar of micro-robots, 1998.159-164)

Documents [3] Mdsp J O, Yoo T, Chang K.thermal and experimental in-duction of microwave power transmission, IEEE Trans. microwave thermal The c, 1992, MT-40(12) (Mespaden J O, Yoo T, Chang K., silicon rectifier diode antenna for microwave power transmission, IEEE Trans. microwave thermal Thec, 1992, MT-40(12))

3. Since the reflected and scattered wave power is related to the frequency of the microwave. Before the system is started, the sweep source is also applied to find a microwave frequency range, i.e., a frequency range in which the measured reflected and scattered wave powers are maximized.

And taking the intersection of the frequency ranges measured by the 2 and the 3, wherein any frequency in the intersection range can be used as a sensitive frequency point. Later in operation, mode detection and power measurement are performed for the sensitive frequency point.

The incident microwave power during working generally needs to consider the explosion-proof problem on site, and has no special value range.

The sizes of the cracks and the cracks are in direct proportion to the powers of the reflected waves and the scattered waves, and a large number of experiments prove that the cracks and the cracks usually appear in the pipeline when the powers of the reflected waves and the scattered waves account for 5% of the power of the incident waves near the sensitive frequency. If the transmission mode of the microwave in the pipeline is greatly changed, the power measured by the power meter is mainly reflected wave power, and if the mode of the wave in the pipeline is hardly changed, the power measured by the power meter is scattered wave power. As described by the formula:

setting: thresh _ TE is the mode change overrun threshold for TE waves, Thresh _ TM is the mode change overrun threshold for TM waves, V_TETo detect induced voltage changes in the TE wave mode, I_TMTo detect induced current of TM wave mode changes.

When V is_TE≧ 2Thresh _ TE or I_TMAnd if the power is more than or equal to 2Thresh _ TM, the power measured by the power meter is mainly reflected wave power.

When Thresh _ TE is less than or equal to V_TE2Thresh _ TE or Thresh _ TM is less than or equal to I_TMAnd (4) less than or equal to 2Thresh _ TM, the power measured by the power meter is the scattered wave power.

Generally, in a real, non-ideal pipe, reflected and scattered waves are nearly co-existing in the pipe. Therefore, in a strict sense, the two thresholds should be combined to form one threshold, that is, the threshold should be exceeded by the reflected wave and the scattered wave. To facilitate analysis of micro-cracks or larger cracks, the two are sometimes discussed separately. In the present invention, the power of the reflected wave and the scattered wave is detected only to know whether there is a defect in the pipe, and therefore, it is not necessary to set the overrun thresholds separately for the reflected wave and the scattered wave.

4. Determination of the reflection coefficient mode and the phase angle overrun threshold:

when the microwave is transmitted in an actual pipeline, reflected waves of different degrees still exist, so that the reflection coefficient mode and the phase angle overrun threshold value need to be calibrated. Later on if the detected value exceeds the thresholdValue, then there is a defect in the pipe. Determination of threshold and TE₀₁Sum of waves TM₀₁The mode change overrun threshold of the waves is similar and is performed at the time of installation of the system, and the detection means employs a Wiltron560A scalar network analyzer and an HP8408S vector network analyzer to detect the reflectance mode and the threshold value, respectively, as the overrun threshold detected.

【2】 Performing TE wave and TM wave propagation mode detection, reflection coefficient mode and phase angle detection, reflected wave power and scattered wave power detection in parallel;

the 3 modules are used for detecting whether leakage faults exist in the monitored gas transmission pipeline. The three modules are simultaneously and concurrently executed, and different detection methods are adopted for judgment. When the detection threshold of any one of the 3 modules generates overrun alarm, the pulse modulation wave scanning is started immediately for positioning; and if no alarm exists, detecting in the next period.

【3】 Starting pulse modulation wave scanning to position;

the module is started after any one of the 3 modules generates threshold overrun alarm, a microwave source transmits pulse modulation microwaves to the pipeline, then a pulse round-trip time detector detects the arrival time delta t of an echo reflected by the defect of the pipeline, and the calculation is carried out by using a formula:

<math> <mrow> <mi>&Delta;l</mi> <mo>=</mo> <mfrac> <mrow> <msub> <mi>v</mi> <mi>P</mi> </msub> <mi>&Delta;t</mi> </mrow> <mn>2</mn> </mfrac> <mo>=</mo> <mfrac> <mi>c&Delta;t</mi> <mrow> <mn>2</mn> <msqrt> <mn>1</mn> <mo>-</mo> <msup> <mrow> <mo>(</mo> <mi>&lambda;</mi> <mo>/</mo> <mn>1.640</mn> <mi>a</mi> <mo>)</mo> </mrow> <mn>2</mn> </msup> </msqrt> </mrow> </mfrac> </mrow> </math> when transmitting TE₀₁When the mode microwave is generated; or <math> <mrow> <mi>&Delta;l</mi> <mo>=</mo> <mfrac> <mrow> <msub> <mi>v</mi> <mi>P</mi> </msub> <mi>&Delta;t</mi> </mrow> <mn>2</mn> </mfrac> <mo>=</mo> <mfrac> <mi>c&Delta;t</mi> <mrow> <mn>2</mn> <msqrt> <mn>1</mn> <mo>-</mo> <msup> <mrow> <mo>(</mo> <mi>&lambda;</mi> <mo>/</mo> <mn>2.620</mn> <mi>a</mi> <mo>)</mo> </mrow> <mn>2</mn> </msup> </msqrt> </mrow> </mfrac> </mrow> </math> When transmitting TM₀₁When the mode microwave is generated;

a specific location Δ l of the pipe leak or defect is obtained, i.e. the distance from the pipe inlet to the defect location. The modulated wave is essentially a wave in which a microwave is modulated into a pulse to detect a pulse edge of a reflected wave in cooperation with a pulse round trip time detector, and the frequency of the modulated wave is not particularly limited as long as the detection resolution of the pulse round trip time detector is satisfied. The duration of the modulated pulse is preferably less than 1 second to avoid standing waves from being formed between the reflected wave and the incident wave, which affects the accuracy of the edge detection of the reflected pulse.

Second, detecting system

As shown in fig. 1, the detection system is accessed along the axial direction of the metal round gas transmission pipeline (corresponding to the transmission waveguide) to be detected through a rectangular-round waveguide filter, and comprises: a microwave transmitting and receiving unit; a detection unit: comprises a microwave transmission mode change detector, a reflection coefficient mode and phase angle detector, a reflected wave and scattered wave power measurer and a pulse round-trip time detector; and monitoring the center. The whole detection system device is basically positioned at one end (upstream end or downstream end) of the pipeline, and the detection device is arranged at certain intervals (effective detection distance according to the frequency, the emission power and the geometric dimension of the pipeline) along the pipeline in consideration of the attenuation of the power transmitted by the microwave along the pipeline.

1. The microwave transmitting and receiving unit includes: the device comprises a microwave source, an electric control attenuator, a power amplifier, a bidirectional coupler, an isolation explosion-proof device, a waveguide-coaxial converter, a rectangular-circular waveguide transition device and a transition joint. The unit is responsible for transmitting microwaves for detecting pipeline leakage into the gas transmission pipeline, receiving the microwaves reflected or scattered back by the gas transmission pipeline and transmitting the microwaves to a corresponding detector for processing. The following is introduced one by one:

a microwave source: receiving the control of the monitoring center and generating a microwave signal for detection;

electric control attenuator and power amplifier: the power used for adjusting and controlling the microwave signal is adjusted before the system is started;

the bidirectional coupler: referring to fig. 1, the bidirectional coupler is used for (1) transmitting microwave generated by a microwave source to a metal gas transmission pipeline to be tested; (2) transmitting the reference signal generated by the microwave source to the corresponding detection and measurement unit; (3) transmitting the microwave signals reflected and scattered back from the gas transmission pipeline to a corresponding detection and measurement unit;

isolation explosion-proof device: an electrically isolated explosion-proof safety device for an oil and gas field;

waveguide-coaxial converter: the microwave signal before the rectangular-circular waveguide transition device is transmitted through a coaxial cable, and the waveguide-coaxial converter is used for converting the microwave transmission medium from the coaxial cable into a rectangular waveguide;

rectangular-circular waveguide transition: converting the microwave transmission medium from a rectangular waveguide into a circular waveguide;

transition joint: a transition joint connecting the circular waveguide and the pipelines with different calibers;

in addition, a terminal for effectively detecting the length of the pipeline is connected with a matched load, so that the situation that reflected waves are generated and the measuring result is influenced when no fault exists is prevented.

2. Microwave transmission mode change detector: an open loop probe is placed radially at each of the inlet (upstream) and outlet (downstream) ends of the effective test length of the conduit for microwave TE₀₁Extraction of pattern changes, see fig. 3. At the pipe radial direction r equal to 0, the electric field strength E_ΦIf the change in (c) does not exceed the threshold value, indicating that the mode in the pipeline has not changed, then there is no longitudinal crack in the pipeline; if E is_ΦIf the variation of (2) exceeds the threshold value, the pipeline is indicated to have other modes of reflected wave and scattered wave, namely defects in the pipeline. Also, a small closed coupling ring is axially disposed at each of the inlet (upstream) and outlet (downstream) ends of the effective detection length of the conduit for microwave TM₀₁Extraction of the mode change, see fig. 4, if at the pipe radial direction r-0, the magnetic field strength H is_ΦIf the change in (d) does not exceed the threshold value, indicating that the mode in the pipe has not changed, then there is no transverse crack in the pipe; if E is_ΦIf the variation of (2) exceeds the threshold value, the pipeline is indicated to have other modes of reflected wave and scattered wave, namely defects in the pipeline. The propagation mode detector shown in fig. 1 includes an open loop probe and a small closed coupling loop, where r of the open loop probe is equal to 0, and the physical quantity actually detected by the small closed coupling loop is equal to 0, and the induced voltage value at the inlet end (upstream) and the outlet end (downstream) of the pipeline is equal to 0. The voltage (current) can characterize E there_ΦAnd H_ΦAnd the output ends of the two are connected to the monitoring center, and the detected data are transmitted to the monitoring center for processing. Open loop probe and closeThe distance between the measuring points of the two small coupling rings is determined according to the specific length of the pipeline, and is generally 20 cm-100 cm.

The induced voltage and induced current collected by the open-circuit annular probe and the closed small coupling ring are input to an analog input port of an A/D data collection chip, and then signals are transmitted to a monitoring center in a wireless digital spread spectrum radio station or microwave special line mode or an Ethernet mode through a control module control and serial communication interface. The invention adopts a remote data acquisition Terminal RTU (remote Terminal Unit) which takes an RCM2300 control chip of ZWord company as a core processing chip, and the figure 6 shows. The RTU comprises an A/D conversion card and an RCM2300 module, wherein the RCM2300 module is provided with an RS232 interface, and data can be transmitted to a monitoring center in a radio station mode, a microwave special line mode and the like. An RCM2200 module may also be employed, which may transmit data to the monitoring center via ethernet.

The output port type of the RTU system adopted by the invention is RS 232. The format and time interval of the signal output may be set by the user through a programmer. The monitoring center sends a data uploading command to the RTU every 20 seconds, the data sent by the RTU comprises data in the past 20 seconds, the data are broadcasted through a digital radio station with an RS232 interface, and the data comprise pipeline upstream and downstream data in the past 20 seconds.

The basic technical indexes of the main RTU series are as follows:

analog quantity input, 8 paths;

the resolution of the AD converter is 12 bits, and the sampling rate is not lower than 50 ms;

inputting a pulse quantity: 6 paths of input are photoelectrically isolated, and the minimum current drawn is not more than 2 milliamperes;

an RS232 interface;

the external dimension is as follows: 145 × 90 × 38(I type, external direct current 24V power supply) 45 × 90 × 72(II type, external alternating current 220V power supply);

working temperature range: 40 ℃ below zero to 85 DEG C

Since pumping stations of oil fields and long-distance pipeline systems belong to areas with high explosion-proof requirements, the RTU in FIG. 6 must be connected to an open-circuit ring probe and a closed small coupling ring on the upstream and downstream of the pipeline through a safety grid isolation explosion-proof device.

3. Reflectance mode and phase angle detector: as shown in fig. 1, a reflectance mode and a phase angle detector are connected to the reference signal and microwave reflection signal outputs of the bidirectional coupler. The reflectance mode and phase angle detector comprises a Wiltron560A scalar network analyzer, and an HP8408S vector network analyzer. The detection of the reflectance mode can be measured with a standing wave tester of a Wiltron560A scalar network analyzer, and the reflectance phase angle is analyzed with an HP8408S vector network analyzer.

4. A power meter: for detecting reflected and scattered wave power. As shown in fig. 1, the pipe termination matches the load, and if there are no cracks, fissures, or other metallic foreign objects in the pipe, there is no reflected signal at the incident end. Therefore, the power of the reflected or scattered wave can be measured at the incident end with a power meter. There are many varieties of microwave power measurement instruments on the market, such as: the 69660A type microwave power meter of Marconi company is provided with a GPIB interface and can conveniently communicate with a monitoring industrial personal computer. As for the other models, they are not described here. Specific measurement methods and principles can also be found in the following documents:

[1] lijing spring, Niujia, Huangjia, microwave signal power spectrum analyzer measuring method, wireless communication, No.3, 2003

[2] Shenxian Yanguang, Zhang Guangchun, and the analysis and design of microwave virtual time-frequency analyzer, astronavigation measuring technique, Vol.23, No.2, 2003

5. A pulse round trip time detector: when any one detection result of the microwave transmission mode change detector, the reflection coefficient mode and phase angle detector and the reflected wave and scattered wave power detector finds that a leakage fault exists in the pipeline, the pulse round-trip time detector is started to position the leakage position. The pulse round trip time detector adopts a time comparator, the time comparator shown in fig. 5(a) adopts a RabbitCore RCM2200microprocessor module of Zword company running a μ C-OS2 embedded operating system as a main processor, and inputs an incident microwave modulation pulse signal and a reflected pulse signal to PE0 and PE1 ports of the RCM2200 respectively, namely an external interrupt input port of the RCM 2200:

INT0A (PE0) and INT1A (PE 1). Then, writing an RCM2200 single-chip interrupt service program through an embedded C language, and calculating the time difference delta t of the two signals by comparing the occurrence time intervals of two external interrupts INT0A and INT 1A. For a detailed description and programming of the RCM2200, see Zword corporation "RabbitCoreRCM 2200 User's Manual" and "Dynamic C User's Manual" technical documents. The above hardware is only one of choice, and the system may select other types of chips, modules and operating systems as desired. Fig. 5(b) is the interrupt logic of the rabbitt chip in the RCM2200 module; FIG. 5(c) is a diagram illustrating the time difference between incident and reflected modulated pulse waves.

6. A monitoring center: the invention adopts an industrial personal computer for monitoring, and is responsible for all scheduling work of the whole system, including starting a microwave source; the various detectors are activated and communicate with them, obtaining the results of the detection, and performing some necessary data display and storage.

Thirdly, testing results:

1. transmission mode change based detection

Iron seamless steel pipes with the radius of 30mm and the same defective steel pipes are selected as tested samples. For a seamless high-quality steel pipe, a mode change signal is extracted at a position where r is 0 at an incident end and an exit end. When TE is propagated in the steel pipe₀₁During molding, an induction voltage cannot be extracted by using an open-circuit annular electric probe; when TM is propagated in the steel pipe₀₁In mode, no induced current can be extracted with a small coupling ring, which indicates that the mode propagating in the tube is unchanged. In the defective steel pipe, the emission power at the incident end was TE of 500mW₀₁Induced voltage VTE extracted by open-circuit annular electric probe during mode microwave₀₁12.78(mV), when TM with incident end transmitting power of 500mW is transmitted in the steel pipe₀₁In the case of the mode microwave, the induced current i extracted by the small coupling loop is 207 μ a (the result is the maximum value measured in 5GHz to 12 GHz).

Will f is₁Rectangular wave modulation f 1MHz₂A sine wave of 12GHz as a modulation wave and TE₀₁The model is injected into a steel pipe, the terminal of a defective steel pipe is connected with a matched load, the time difference between the reflected wave given by a time comparator and the incident modulation wave is 7.85ns, and the defect position 56.2cm away from the input end can be calculated by the formula (8). And connecting the end of the defective steel pipe with a matching load, and measuring the power P of the reflected wave and the scattered wave at the input end to be 38 mW.

The test sample steel pipe was cut at a length of 56.2cm, and a crack of about 3mm in length was found at a distance of 2.5cm from the cut.

2. Based on reflection coefficient mode and phase angle detection

And simulating the defect crack within the range of 0.1-2 mm at the same position of the iron seamless steel pipe. The relationship between the reflection intensity and the degree of defect cracking was examined by using a standing wave tester 560-97N50-1 of a Wiltron560A scalar network analyzer, and the measurement results are shown in FIG. 7 (a); the relationship between the reflection phase and the degree of defect cracking was measured by an HP8408S vector network analyzer, and the measurement results are shown in fig. 7 (b). The solid line in the figure is the result of theoretical calculation, the "+" sign shows the result of actual measurement, the abscissa shows the width of the defect in mm, and the microwave operating frequency is 12 GHz. As can be seen from the following figures, the results of theoretical analysis are quite consistent with the results of actual measurements.

From the experimental situation of the two methods described above, it is possible to use the method for detecting the presence and location of cracks, fissures, in metal pipes.

The method provided by the invention uses the principle of modern microwave communication technology for reference in signal acquisition, reasonably designs and detects the position of sensing, adopts three modes of microwave mode change detection, reflection coefficient mode and phase angle change detection and reflected wave and scattered wave power detection to judge whether the pipeline has defects or not in parallel, and then calculates the defect distance to ensure that the detection result is accurate and reliable.

Claims (4)

1. The gas transmission pipeline leakage detection and positioning method based on the microwave technology is characterized in that the method is controlled by an industrial personal computer of a monitoring center to execute the following steps:

1) initializing an industrial personal computer of a monitoring center:

given TE₀₁Mode change overrun threshold, TM, of mode microwaves₀₁Mode change overrun threshold of mode microwave; an overrun threshold of the reflection coefficient mode, an overrun threshold of the reflection coefficient phase angle; the power of the reflected wave and/or the scattered wave exceeds a threshold value;

2) starting microwave source to alternatively emit TE to pipeline₀₁And TM₀₁Single mode microwaves, the frequency of the microwaves being the sensitive frequency that ensures single mode transmission of the microwaves in the pipe and maximizes the reflected or scattered power;

3) receiving TE detected by a propagation mode detector₀₁And TM₀₁A mode of the wave; receiving the reflection coefficient mode and the phase angle value detected by the phase angle detector; receiving reflected wave power or scattered wave power detected by a power meter;

4) when the above TE is present₀₁And TM₀₁When the mode detection value of the wave exceeds the change over-limit threshold value, or the detection values of the reflection coefficient mode and the phase angle exceed the change over-limit threshold value, or the reflected wave power or the scattered wave power exceeds the over-limit threshold value, starting the microwave source to emit pulse modulation waves to scan the pipeline;

5) acquiring the time difference delta t between the incidence and the receiving reflection of the pulse modulation microwave detected by the pulse round-trip detector, and calculating the position delta l of the defect:

<math> <mrow> <mi>&Delta;l</mi> <mo>=</mo> <mfrac> <mi>c&Delta;t</mi> <mrow> <mn>2</mn> <msqrt> <mn>1</mn> <mo>-</mo> <msup> <mrow> <mo>(</mo> <mi>&lambda;</mi> <mo>/</mo> <mn>1.640</mn> <mi>a</mi> <mo>)</mo> </mrow> <mn>2</mn> </msup> </msqrt> </mrow> </mfrac> <mo>,</mo> </mrow> </math> when transmitting TE₀₁When the mode microwave is generated; or <math> <mrow> <mi>&Delta;l</mi> <mo>=</mo> <mfrac> <mi>c&Delta;t</mi> <mrow> <mn>2</mn> <msqrt> <mn>1</mn> <mo>-</mo> <msup> <mrow> <mo>(</mo> <mi>&lambda;</mi> <mo>/</mo> <mn>2.620</mn> <mi>a</mi> <mo>)</mo> </mrow> <mn>2</mn> </msup> </msqrt> </mrow> </mfrac> <mo>,</mo> </mrow> </math> When transmitting TM₀₁When the mode microwave is generated;

wherein c is the speed of light, lambda is the wavelength of the modulating wave, a is the radius of the pipeline to be measured, and delta l is the distance between the inlet of the pipeline and the defect.

2. As in claimThe method for detecting and locating the leakage of a gas pipeline based on microwave technology as claimed in claim 1, wherein the power of the reflected and scattered waves exceeds a threshold value equal to the transmitted TE₀₁And TM₀₁5% of the power of the single mode microwave.

3. The gas transmission pipeline leakage detection positioning system based on the microwave technology is characterized by comprising a microwave transmitting and receiving unit, a detection unit and a monitoring center; wherein,

microwave transmitting and receiving unit:

the microwave power supply, the electric control attenuator, the power amplifier and the bidirectional coupler are sequentially connected through a coaxial cable, and an isolated explosion-proof device, a waveguide-coaxial converter and a rectangular-circular waveguide filter are sequentially connected with the bidirectional coupler through the coaxial cable; the rectangular-circular waveguide filter is connected with a transition joint, and the other end of the transition joint is connected with the input end of the pipeline to be tested; the control end of the microwave source is connected with the monitoring center;

a detection unit:

comprises two propagation mode detectors respectively arranged at two ends of effective detection length of pipeline to be detected, and arranged along radial direction of pipeline for detecting TE₀₁An open loop probe of the die, and a probe mounted axially along the pipe for detecting the TM₀₁A closed small coupling ring of the die; the tail end of the effective detection length of the pipeline is also provided with a matching load for preventing microwave reflection; the signal output ends of the open-circuit annular probe and the closed small coupling ring are sequentially connected with a safety grid for isolation and explosion prevention and a data acquisition terminal RTU (remote terminal unit) containing an A/D (analog/digital) converter, a control module and a serial communication interface, and the data acquisition terminal RTU is connected with the monitoring center in a wired or wireless mode;

the reference signal input end of the reflection coefficient mode and phase angle detector is connected with the reference signal output end of the bidirectional coupler through a coaxial cable, the signal input end of the reflection coefficient mode and phase angle detector is connected with the microwave signal output end of the bidirectional coupler through a coaxial cable, and the output end of the reflection coefficient mode and phase angle detector is connected with the monitoring center;

the power meter is used for detecting the microwave power reflected or scattered back by the pipeline, the input end of the power meter is connected with the power output end of the bidirectional coupler through a coaxial cable, and the output end of the power meter is connected with the monitoring center;

the pulse round-trip time detector is used for detecting the time difference between the emission and the receiving of the pulse modulation wave to the reflected wave, the reference signal input end of the pulse round-trip time detector is connected with the reference signal output end of the bidirectional coupler through a coaxial cable, the signal input end of the pulse round-trip time detector is connected with the microwave signal output end of the bidirectional coupler through a coaxial cable, and the output end of the pulse round-trip time detector is connected with the monitoring center;

the monitoring center: the system comprises an industrial personal computer which controls a microwave transmitting and receiving unit, receives detection data uploaded by a detection unit and calculates the position delta l of a defect in a pipeline.

4. The gas transmission pipeline leakage detection and positioning system based on microwave technology as claimed in claim 3, wherein said reflectance mode and phase angle detector comprises a Wiltron560A scalar network analyzer for detecting reflectance mode and an HP8408S vector network analyzer for detecting reflectance phase angle, reference signal inputs of said Wiltron560A scalar network analyzer and HP8408S vector network analyzer are respectively connected with reference signal outputs of said bidirectional coupler through coaxial cables, signal inputs thereof are respectively connected with microwave signal outputs of said bidirectional coupler through coaxial cables, and outputs thereof are respectively connected with a monitoring center.

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