CN215569800U - Railway water supply pipe network leak detection system based on time domain reflection technology - Google Patents

Abstract

The utility model relates to the technical field of water supply pipe networks, in particular to a railway water supply pipe network leak detection system based on a time domain reflection technology, which comprises the following steps: the device comprises a rail, a time domain reflector and a metal water supply pipe, wherein the rail is positioned on the ground, the metal water supply pipe is positioned under the ground, a first signal receiving and transmitting end of the time domain reflector is electrically connected with the rail, a second signal receiving and transmitting end of the time domain reflector is electrically connected with the metal water supply pipe, and the first signal receiving and transmitting end of the time domain reflector, the rail, soil, the metal water supply pipe and a second signal receiving and transmitting end of the time domain reflector are sequentially conducted to form a reflection circuit of a voltage step signal. Aiming at the characteristics of a railway water supply pipe network, a rail, a metal pipeline or a metal tracer line is used as a signal output end/receiving end, earth soil is used as a conductor to form a closed loop, and the leakage point of the pipe network is determined by detecting the intensity of a received signal and identifying the abnormal point of the dielectric constant of the soil.

Description

Railway water supply pipe network leak detection system based on time domain reflection technology

Technical Field

The utility model relates to the technical field of water supply pipe networks, in particular to a railway water supply pipe network leak detection system based on a time domain reflection technology.

Background

The water resource shortage in China, the water resource per capita amount is only 2300 cubic meters, which is equivalent to about 1/4 in the average level in the world. With the increasing population and the rapid development of economy in China, the contradiction between water resource supply and demand is continuously intensified, and under the state of the existing water resource, the reduction of the water leakage amount and the improvement of the utilization efficiency of the water resource are urgent. According to survey, the leakage rate of the domestic urban water supply network is over 15 percent, the leakage rate of the railway water supply network is over 20 percent, and the leakage rate of the water supply in developed countries is about 10 percent generally. If the leak rate could be reduced by 10 percentage points, at least 52 million tons of water could be saved.

At present, the pipe network leakage detection mainly adopts a manual mode, and the listening method is the most common method applied by tap water enterprises, but has high labor and material cost and causes damage to the bodies of leakage detection workers.

At present, a domestic patent library has no patent specially suitable for leakage detection of a water supply pipe network of a railway system, a large number of sensors are arranged at nodes of the pipe network, signals such as pressure, flow and noise in a pipeline are monitored, a hydraulic model or a neural network deep learning model is established, and leakage points of the pipe network are identified. Application number 201911313009.7 provides a method of water supply pipe network leakage monitoring and location, through installing a large amount of sensors in the pipe network, utilize the water balance model discernment subregion of leaking, compare noise spectrum signal location leakage point again, the water balance model parameter that this method adopted relies on empirical value, the reliability is not high, install a large amount of sensors simultaneously in the water supply pipe network, frequently close the valve and do the test of closing water, influence daily production domestic water demand, investment cost is higher, reduce user satisfaction, it is great to implement the degree of difficulty. Application number 201810702647.7 provides a real-time leakage analysis method for a water supply network, which comprises the steps of establishing a simulation model through water quantity, pressure and pipeline parameters of the water supply network, matching the difference between a predicted value and an actual value, identifying the leakage condition, wherein the leakage condition is identified, but the quality of online monitoring data of the water supply network is uneven, a large amount of data cannot be accurately and rapidly processed on the premise of higher frequency, and the false alarm rate is higher. The initial leakage positioning method based on clustering and deep belief networks, which is proposed by application number 201810527186.4, identifies the leakage area by establishing and training a leakage area identification model, but the method cannot accurately identify the position of the leakage point. Application number 201811283725.0 proposes a leakage identification method based on a long-and-short-term memory neural network model, which trains the long-and-short-term memory neural network model after processing data obtained by a sensor, and identifies abnormal flow points. Application No. 201710998436.8 proposes a neural network model based on gated cyclic units, which identifies whether a leak has occurred by the cosine distance of the relative value of the model-calculated time series vector and the reference data. The neural network model identification process is too complicated, the problems of high false alarm rate, low reliability in actual operation and the like exist, and the manpower, material resources and financial resources of a water department are wasted. Therefore, a leakage detection method suitable for the characteristics of the railway water supply network is urgently needed.

SUMMERY OF THE UTILITY MODEL

The utility model provides a railway water supply pipe network leakage detection system based on a time domain reflection technology, which solves the technical problems of abundant personnel experience, difficult implementation of sensors installed in old pipe networks, high investment cost, high false alarm rate of leakage point identification, low positioning precision and long time consumption of the existing railway water supply pipe network leakage detection.

The utility model provides a railway water supply network leak detection system based on a time domain reflection technology for solving the technical problems, which comprises the following components: the device comprises a rail, a time domain reflectometer and a metal water supply pipe, wherein the rail is positioned on the ground, the metal water supply pipe is positioned under the ground, a first signal transceiving end of the time domain reflectometer is electrically connected with the rail, a second signal transceiving end of the time domain reflectometer is electrically connected with the metal water supply pipe, and the first signal transceiving end of the time domain reflectometer, the rail, soil, the metal water supply pipe and a second signal transceiving end of the time domain reflectometer are sequentially conducted to form a reflection circuit of a voltage step signal.

Optionally, the first signal transceiving end of the time domain reflectometer is electrically connected to the rail through a coaxial cable FB, and the second signal transceiving end of the time domain reflectometer is electrically connected to the metal water feed pipe through a coaxial cable FC.

Optionally, the probe of the coaxial cable FB is fixedly connected to the rail through a clip or an adhesive tape, and the probe of the coaxial cable FC is fixedly connected to the metal water supply pipe through a clip or an adhesive tape.

Optionally, the probe of the coaxial cable FC is electrically connected to a metal valve, a metal pipeline of a water supply valve well, or a metal trace line in the well.

Optionally, the actually measured resistance value range of the coaxial cable FC is 1-2 Ω.

Optionally, the model of the time domain reflectometer is a portable TDR 100.

Has the advantages that: the utility model provides a railway water supply network leak detection system based on a time domain reflection technology, which comprises the following components: the device comprises a rail, a time domain reflector and a metal water supply pipe, wherein the rail is positioned on the ground, the metal water supply pipe is positioned under the ground, a first signal receiving and transmitting end of the time domain reflector is electrically connected with the rail, a second signal receiving and transmitting end of the time domain reflector is electrically connected with the metal water supply pipe, and the first signal receiving and transmitting end of the time domain reflector, the rail, soil, the metal water supply pipe and a second signal receiving and transmitting end of the time domain reflector are sequentially conducted to form a reflection circuit of a voltage step signal. Aiming at the characteristics of a railway water supply pipe network, a rail, a metal pipeline or a metal tracer line is used as a signal output end/receiving end, earth soil is used as a conductor to form a closed loop, and the leakage point of the pipe network is determined by detecting the intensity of a received signal and identifying the abnormal point of the dielectric constant of the soil.

The foregoing description is only an overview of the technical solutions of the present invention, and in order to make the technical solutions of the present invention more clearly understood and to implement them in accordance with the contents of the description, the following detailed description is given with reference to the preferred embodiments of the present invention and the accompanying drawings. The detailed description of the present invention is given in detail by the following examples and the accompanying drawings.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the utility model and together with the description serve to explain the utility model without limiting the utility model. In the drawings:

FIG. 1 is a schematic diagram of a railway water supply network leak detection system based on time domain reflection technology according to the present invention;

FIG. 2 is a plan view of a railway water supply network relationship of the railway water supply network leak detection system based on the time domain reflection technology of the present invention;

FIG. 3 is a cross-sectional view of a railway water supply network relationship of a railway water supply network leak detection system based on a time domain reflection technique according to the present invention;

FIG. 4 is a reflection coefficient I curve diagram of a railway water supply network leak detection system based on the time domain reflection technology;

FIG. 5 is a first derivative curve diagram of a first method of the railway water supply network leak detection system based on the time domain reflectometry of the present invention;

FIG. 6 is a filtered discrete point diagram of a second method of the railway water supply network leak detection system based on the time domain reflection technology;

FIG. 7 is a first derivative curve diagram of a second method of the railway water supply network leak detection system based on the time domain reflectometry technique of the present invention.

Detailed Description

The principles and features of this invention are described below in conjunction with the following drawings, which are set forth by way of illustration only and are not intended to limit the scope of the utility model. The utility model is described in more detail in the following paragraphs by way of example with reference to the accompanying drawings. Advantages and features of the present invention will become apparent from the following description and from the claims. It is to be noted that the drawings are in a very simplified form and are not to precise scale, which is merely for the purpose of facilitating and distinctly claiming the embodiments of the present invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When a component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When a component is referred to as being "disposed on" another component, it can be directly on the other component or intervening components may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

As shown in fig. 1, the utility model provides a railway water supply network leak detection system based on a time domain reflection technology, which is characterized by comprising: the device comprises a rail, a time domain reflectometer and a metal water supply pipe, wherein the rail is positioned on the ground, the metal water supply pipe is positioned under the ground, a first signal transceiving end of the time domain reflectometer is electrically connected with the rail, a second signal transceiving end of the time domain reflectometer is electrically connected with the metal water supply pipe, and the first signal transceiving end of the time domain reflectometer, the rail, soil, the metal water supply pipe and a second signal transceiving end of the time domain reflectometer are sequentially conducted to form a reflection circuit of a voltage step signal.

Specifically, the TDR apparatus includes: the device comprises a signal transmitter, a signal receiver, a signal processor, a coaxial cable and a probe. The signal transmitting and receiving are connected through coaxial cables FB and FC, the rail and the water supply pipe are a signal transmitting source and a signal receiving source, the coaxial cables are required to be grounded, the embodiment takes the rail as the signal receiving source for explanation, and the position relationship is shown in fig. 2 and fig. 3. The point B of the coaxial cable is fixed on the rail, the probe is fixed by a clamp or an adhesive tape and the like, and theoretically, the rail can be considered as an infinite-length metal wire. The coaxial cable C point is connected to a metal valve of a water supply valve well, a metal pipeline or a metal tracing line in the well, a probe is fixed in a clamp or an adhesive tape mode, sand paper is used for polishing and rusting, and the actual measurement resistance between the FCs is guaranteed to be as low as 1-2 omega. Point D represents the distal end of the service pipe and point E represents the location of the unknown leak point.

TDR instrument signal output part probe, fix at the metal feed pipe through coaxial cable FC, output voltage step signal, propagate along pipeline CD, each point signal is done the conductor with earth soil on the pipeline, it is even to think soil property along the line, the fluctuation of soil dielectric constant is less, reflected signal transmits on the rail, coaxial cable FB transmits reflected signal for TDR instrument signal receiver, reflected signal carries soil dielectric constant information, to leakage point E department, this point dielectric constant should have obvious difference more on every side.

Generally, it is considered that the transmitted signal and the reflected signal have the same frequency, the reflected signal intensity is attenuated due to the influence of the dielectric constant, the input signal and the output signal are attenuated due to the impedance influence along with the propagation distance, and the input signal intensity T is defined_inDefining the output signal strength T_outDefining the reflection coefficient

The reflection coefficient I is stable when the dielectric constant of the soil is stable, and the change of the reflection coefficient I represents the change of the dielectric constant. Meanwhile, because the rail is approximately an infinite length of metal conductor,

defining the apparent distance of signal propagation along the metal wire as S, i.e. the distance of transmitted electromagnetic signal in a certain time, defining the relative dielectric constant of soil as E, defining the actual distance of tested metal wire as L, and having

Where c is the electromagnetic signal propagation velocity and t is the round trip time of the signal traveling along the two endpoints of the probe.

The position of a leakage point E is positioned to be L_CE＝L_CB+L_BEWherein L is_CBKnown according to the formula

The portable TDR100 is selected by a TDR instrument, a pulse output signal is 250mv, an output impedance is 50 ohms, 20-2048 waveforms can be generated in a given time, 2048 acquisition points are set, and the TDR instrument is connected to a computer and controlled by LabView software. Test pipe length L_BE＝1.9m，L_DE＝3.1m。

The reflectance curve is shown in fig. 4, where the leftmost region of the curve, due to high impedance mismatch and corresponding multiple reflections introduced by the instrument-to-conduit connection, causes spurious reflections, I jumps from 0 to a position of at least 0.7, with the abscissa of the point being S_BCoordinate of (B), apparent distance of point (B) S_B＝4.3m，

S_DAnd S_ECannot be determined by finding the jumping points. In many methods based on TDR measurements, S is estimated by determining the point at which the slope of the reflectance curve is the greatest_DAnd S_ECorresponding to the minimum value of the first derivative of the reflectance curve being S_EThe maximum value of the first derivative of the reflection coefficient curve is S_D。

Before the derivative is obtained, data in the reflection coefficient curve needs to be processed, in the first method, the reflection coefficient curve is fitted by adopting a high-order polynomial, and then the derivative is obtained, wherein the derivative curve is shown in a figure 5. The method comprises the following specific steps:

screening samples. Taking the sample from point B to the end of the TDR sample signal as { x_kN, n is the number of sampling points, x₁For signal values corresponding to B points, x_nThe signal value corresponding to the end of the sampling point.

And (2) polynomial fitting derivation. For x_kPerforming polynomial fitting:

solving for w using least squares_NThen, a polynomial fitting formula is obtained, and the first derivative is obtained.

Determining the apparent distance S of the leak point E according to the local minimum value point of the first derivative image_E7.968m, apparent distance S of the end of the wire_D＝14.821m。

Detecting leakage point L by excavation_BEThe actual distance is 1.70 m.

In the second method, fast Fourier transform, low-pass filtering, inverse Fourier transform and first derivative are adopted, the filtered data is shown in figure 6, and the derivative curve is shown in figure 7.

The method comprises the following specific steps:

screening samples. Taking the sample from point B to the end of the TDR sample signal as { x_kN, n is the number of sampling points, x₁For signal values corresponding to B points, x_nThe signal value corresponding to the end of the sampling point.

And eliminating the linear trend term. { x_kFor the data portion of the acquired original TDR signal after point B, a polynomial function is used

Indicating its trend term. Trend item of it

By finding

And discrete data x_BThe error of (n) is the smallest after quadratic, for the coefficient a_jAnd (4) obtaining.

Taking m as 1, the sample { x can be obtained_kLinear trend terms of. The sample after eliminating the linear trend term is { y_k}，k＝1，2，3....n。

3) For discrete sequences y_kA Fast Fourier Transform (FFT) is performed. Y is_kIs the signal spectrum after fourier transform.

The spectrogram that plots the fourier transform is shown in fig. 6, and the filtering is performed according to a threshold value of Δ ═ 60dB, so as to filter out the signal groups with frequencies greater than fn, and the threshold value can maximally store the useful signals and remove the noise. The amplitude M1 corresponding to the frequency fm and the amplitude M2 corresponding to the frequency fn are related as follows:

4) the filtered spectrum is denoted as Z_kTo the signal Z_kPerforming an inverse Fourier transform to reconstruct the signal, noting that the reconstructed signal is { z }_k}，k＝1，2，3....n。

5) Computing Fourier transformed signal { z_kDerivative of, its derivative z'_kCan pass through { z_kThe two sides of the expression are derived:

determining the apparent distance S of the leak point E according to the local minimum value point of the first derivative image_E7.968m, apparent distance of wire end

Detecting leakage point L by excavation_BEThe actual distance is 1.70 m.

Preferably, in this scheme, in addition to only one rail, for example, the first-1 rail in fig. 3, a plurality of rails may be connected simultaneously, the first-1 rail and the second-1 rail are connected simultaneously, and the input signal strength is T_in1And T_in2The reflection coefficient curves are respectively I₁,I₂The corresponding B, C, D point apparent distance coordinates are respectively S_B1、S_D1、S_E1And S_B2、S_D2、S_E2The interval M ═ min (S) is defined_B1，S_B2)，max(S_D1，S_D2)]Within this interval, I₁Has a first derivative function of X, an expected value of E (X), I₂The first derivative function of (a) is Y, the expected value e (Y), and then there is covariance Cov (X, Y) ═ e (xy) — e (X) e (Y), when the covariance approaches 1, it means that the correlation between the two reflection signals is strong, the change rule tends to be consistent, the obtained result is reliable, otherwise, when the covariance approaches 1, it means that the two reflection signals are independent, the difference of the change rule is large, and it needs to be measured again.

As will be appreciated by one skilled in the art, embodiments of the present application may be provided as a method, system, or computer program product. Accordingly, the present application may take the form of an entirely hardware embodiment, an entirely software embodiment or an embodiment combining software and hardware aspects. Furthermore, the present application may take the form of a computer program product embodied on one or more computer-usable storage media (including, but not limited to, disk storage, CD-ROM, optical storage, and the like) having computer-usable program code embodied therein.

The present application is described with reference to flowchart illustrations and/or block diagrams of methods, apparatus (systems), and computer program products according to embodiments of the application. It will be understood that each flow and/or block of the flow diagrams and/or block diagrams, and combinations of flows and/or blocks in the flow diagrams and/or block diagrams, can be implemented by computer program instructions. These computer program instructions may be provided to a processor of a general purpose computer, special purpose computer, embedded processor, or other programmable data processing apparatus to produce a machine, such that the instructions, which execute via the processor of the computer or other programmable data processing apparatus, create means for implementing the functions specified in the flowchart flow or flows and/or block diagram block or blocks.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solutions of the present invention and not for limiting the same, and although the present invention is described in detail with reference to the above embodiments, those of ordinary skill in the art should understand that: modifications and equivalents may be made to the embodiments of the utility model without departing from the spirit and scope of the utility model, which is to be covered by the claims.

Claims (6)

1. Railway water supply pipe network leak detection system based on time domain reflection technique, its characterized in that includes: the device comprises a rail, a time domain reflectometer and a metal water supply pipe, wherein the rail is positioned on the ground, the metal water supply pipe is positioned under the ground, a first signal transceiving end of the time domain reflectometer is electrically connected with the rail, a second signal transceiving end of the time domain reflectometer is electrically connected with the metal water supply pipe, and the first signal transceiving end of the time domain reflectometer, the rail, soil, the metal water supply pipe and a second signal transceiving end of the time domain reflectometer are sequentially conducted to form a reflection circuit of a voltage step signal.

2. The time domain reflectometry based railway water supply network leak detection system of claim 1, wherein a first signal transceiving end of the time domain reflectometer is electrically connected with the rail through a coaxial cable FB, and a second signal transceiving end of the time domain reflectometer is electrically connected with the metal water supply pipe through a coaxial cable FC.

3. The time domain reflectometry based railway water supply network leak detection system of claim 2, wherein the probe of the coaxial cable FB is fixedly connected with the rail by a clip or an adhesive tape, and the probe of the coaxial cable FC is fixedly connected with the metal water supply pipe by a clip or an adhesive tape.

4. The railway water supply network leak detection system based on the time domain reflectometry technology as claimed in claim 2, wherein the probe of the coaxial cable FC is electrically connected with a metal valve of a water supply valve well, a metal pipeline, or a metal trace line in the well.

5. The railway water supply network leak detection system based on the time domain reflection technology as claimed in claim 2, wherein the measured resistance value of the coaxial cable FC is in a range of 1-2 Ω.

6. The railway water supply network leak detection system based on the time domain reflectometry technology of claim 1, wherein the time domain reflectometer is of a portable type TDR 100.

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