RU11608U1 - DEVICE OF CONTACTLESS MAGNETOMETRIC CONTROL OF THE STATE OF THE METAL OF PIPELINES - Google Patents

Abstract

A device for non-contact magnetometric monitoring of the state of metal in pipelines, containing a crystal oscillator, a frequency divider, a Schmidt trigger, a linear function shaper, a threshold device, a digital indicator, metal magnetic field response sensors (flux gates), individual channels for its functional conversion into an electric signal, formed in series flux-gates, amplifiers and synchronous detectors, characterized in that the unit contains a block of electronic cells cell, analog converter, module block, analog-to-digital converter (ADC), power buffer, limit enumeration unit, sensitivity enumeration unit, background zeroing unit, control unit, automatic battery discharge indicator and light-sound indication of exceeding the threshold, while outputs of two individual channels connected to the block of electronic keys, the outputs of which through an analog converter are connected to the input of the module block and the analog input of the limit enumeration unit, the output of the latter is connected to the ADC connected to with a digital indicator, the output of the module block is connected to the control input of the limit enumeration unit and with the input of the threshold device connected to the light and sound indication of exceeding the threshold, the input of the power buffer is connected to the output of the linear function former, and its output is connected to flux probes, the enumeration node is connected to the control inputs of the amplifiers sensitivity, the background nulling unit is connected to the input of the electronic key block, the control unit is connected to the control inputs of the electronic key block and digital indicator, and the

Description

DEVICE OF CONTACTLESS MAGNETOMETRIC CONTROL OF THE STATE OF THE METAL OF PIPELINES.

The invention relates to the oil and gas industry and can be used, in particular, to monitor the condition of metal pipelines, for example in the oil and gas industry, in operating conditions without overburden work or any impact on the metal of the pipes.

During the operation of oil and gas communications under the influence of various external factors and operating conditions, various types of defects are formed in the metal of the pipelines, which develop and, over time, lead to the destruction of the metal with the appearance of local leaks, accompanied by material and environmental losses. Therefore, anticipating the development of leaks at the level of the onset of defects in the metal of the pipes is a necessary condition for the long-term trouble-free operation of pipeline systems.

A device is known for non-contact magnetometric monitoring of the state of piping materials, containing a quartz oscillator, a frequency divider, a Schmidt trigger, a linear function shaper, a threshold device, a digital indicator, metal magnetic field response sensors, (flux gates) individual channels for its functional conversion into an electrical signal formed connected in series

flux gates, amplifiers and synchronous detectors. (RF Utility Model No. 1751 of 04/18/95)

The disadvantages of the known device include the relatively low inertia, accuracy and efficiency of monitoring the condition of the metal of the pipelines, due to the sequential algorithm for calculating and fixing in the memory device only deviations from the corresponding pre-set values of the magnetic characteristic parameters: block of the sensor difference module with horizontal magnetic axes (a) and the relationship of the sensor signals with the vertical and horizontal magnetic axes (p1, J32). Since the pre-set values of the magnetic parameters differ for different grades of steel and operating conditions of pipelines, the use of the proposed air values is uninformative and ineffective. In addition, the device does not indicate the sign of the registered values, the sensitivity of the equipment is insufficient in the conditions of the underground supply of objects of control, the presence of two indicators reduces the efficiency of control.

The objective of the proposed utility model is to increase the responsiveness, accuracy and efficiency of monitoring the state of metal pipelines.

The problem is solved due to the fact that a non-contact magnetometric control of the state of the metal of the pipelines, containing a crystal oscillator, a frequency divider, a Schmidt trigger, a linear function shaper, a threshold device, a digital indicator, metal magnetic field response sensors, individual channels of its functional conversion into electric a signal formed by series-connected flux gates.

amplifiers and synchronous detectors, an electronic key block, an analog converter, a module block, an analog-to-digital converter (ADC), a power buffer, a limit enumeration unit, a sensitivity enumeration unit, a background zeroing unit, a zeroing unit, a control unit, an automatic battery discharge indicator, and a light-blast indication of exceeding a threshold while the outputs of two individual channels are connected to the electronic key block, the outputs of which through an analog converter are connected to the input of the module block and the analog input of the node limit ribs, the output of the latter is connected to the ADC connected to the digital adjuster, the output of the module block is connected to the control input of the limit search and to the input of the threshold device connected to the light and sound indication of exceeding the threshold, the input of the power buffer is connected to the output of the linear function former, and its output is connected with flux gates, a sensitivity enumeration unit is connected to the control inputs of the amplifiers, the background nulling unit is connected to the input of the electronic key block, the control unit is connected to the control inputs s block of electronic keys and digital display, and automatic battery discharge display unit connected to the digital indicator.

The drawing shows a diagram of a non-contact magnetometric control of the state of the metal pipelines.

The non-contact magnetometric state of monitoring metal pipelines contains: two flux-gate sensors -1.2, signal amplifiers - 3.4, synchronous detectors - 5.6, crystal oscillator - 7, frequency divider - 8, Schmidt trigger - 9, linear phase response shaper - 10, power buffer -11, sensitivity enumeration node - 12, electronic switch block - 13, analog converter - 14, module block -15, limit enumeration node - 16, ADC -17, digital indicator -18, threshold device

- 19, a signaling device with light and sound indication - 20, a background zeroing unit - 21, a control unit -22, an automatic battery discharge indication unit-23.

The proposed device operates as follows. Sensors 1 and 2 contain signals whose amplitudes are proportional to the magnetic field strength of the objects under control. The output signals of sensors 1 and 2 are fed to amplifiers - 3.4, the amplification of which is selected by the sensitivity enumeration unit - 12, and follow to the measuring inputs of synchronous detectors - 5, 6, whose control inputs receive reference frequencies from a crystal oscillator - 7 through a frequency divider - 8. The pulses of the reference frequency, passing through the Schmidt trigger - 9, are converted into a linear function of the excitation voltage of the sensors in the shaper of the linear function - 10 and enter the power buffer - 11, from the output of which the excitation voltage is applied to the winding excitation fluxgates 1 and 2, in the measuring windings of which the quasi-constant component of the intensity of the studied magnetic field is converted to alternating voltage.

The analog signals coming from the outputs of synchronous detectors 5 and 6 and the zeroing unit - 21 are processed accordingly by the command of the control unit - 22 on the analog converter - 14 using the key block - 13. From the output of the analog converter 14, useful information is sent to the module blocks - 15 and to the analogue input of the limit search node - 16, where it is further converted to a digit on the ADC - 17 and displayed on the digital indicator - 18, on which, in addition, the operation mode of the contactless magnetometric con Troll. The electrical signals from the output of the module block - 15 are compared with the set point - Vn on the threshold device-19 and, in the case of its turning, a light-sound indication occurs

exceeding the threshold - 20. The output signal of the module block 15 controls the operation of the limit sorting unit 16 so as not to overload the ADC - 17, and in the event of a battery discharge, the automatic battery discharge indication unit - 23 is triggered and the corresponding flickering symbols appear on the indicator 18. The stabilized power supply creates normal conditions for the operation of all nodes of the device, regardless of the change in battery voltage until it is almost completely discharged.

With mechanical stochastic {loading of the pipeline, the domain structure of the metal changes and the uncompensated, at the time of loading, energy, due to the motion of the Bloch walls, is absorbed in the form of free magnetic energy. Magnetic energy pulses during stochastic loading of a metal form a continuous spectrum of a quasiconstant component of the pipeline’s own magnetic field, which are sensed by flux gates 1 and 2, excited by a voltage of a linear function of a triangular shape, the expansion of which into a Fourier series has only odd harmonics, namely:

UB -Uo (sin rat - sin (3 rat / 9) + sin (5 o) t / 25) -...)

UB is the current value of the voltage modulating the quasi-coupled component of the magnetic field of the pipe;

Uo is the amplitude value of the excitation.

The measurement of the useful signal is proportional to the controlled value of the components of the magnetic field intensity taken from the measuring winding of the flux gate, due to the peculiarities of the operating modes of which are produced by the second clear harmonic, which is not in the modulating voltage:

and t -. sin 2 cot

Thus, the selectivity of the described non-contact magnetometric control device is ensured by its structural construction, application of the possibility of changing the sensitivity in the device, which makes it possible to increase the reliability and stability of the operation of flux-gate sensors in the case of the underground position of the examined pipeline.

The horizontal component of the pipeline’s own magnetic field is an experimentally determined informational characteristic that reflects the spatial location of the defective area.

To realize the extreme properties of the magnetic responses of pipelines using flux-gates when solving various applied problems of searching for defects and identifying them, in the device of the sensor block, to increase the monitoring efficiency, it is possible to use two sensors located coaxially relative to the pipeline with a variable distance between them to determine the gradient horizontal components of the magnetic field, and their coplanar or perpendicular.

The proposed device non-contact magnetometric control allows you to measure all the components of the magnetic field of the pipeline, both remotely from the surface of the earth and near the surface of the pipes, as well as to process electrical signals, performing operations of differences and sums of channels, to investigate

1 / Gx1 / 7

spatial distribution of magnetic parameters along the pipeline.

The background zeroing unit allows one to subtract from the readings of the proposed device the quasi-average value of the magnetic background at the measurement site, to display deviations in the search mode for local magnetic anomalies, and then conduct a detailed analysis based on measuring the totality of the pipe’s magnetic field.

A higher efficiency of monitoring the state of the metal, in comparison with the prototype, is achieved due to the ability to switch the sensitivity of the sensors and automatically enumerate the limits of the readings of sound and sound indications.

A higher accuracy of monitoring the state of the metal, in comparison with the prototype, is achieved by measuring not only the values of the magnetic parameters, but also their deviations from the quasi-average value, exceeding the threshold with light and sound indication.

A higher efficiency of monitoring the state of the metal, compared with the prototype, is achieved by studying the spatial distribution, determining the sums, differences, signs and values of the deviation of the magnetic parameters, which allows ranking anomalies in the normal operation of the pipeline.

Thus, the proposed technical solution, in comparison with the prototype, can improve the efficiency, accuracy and effectiveness of monitoring the state of the metal pipelines.

The technical and economic advantages of the proposed technical solution, in comparison with the prototype, are characterized by an increase in the accuracy, locality and effectiveness of the control and the possibility of gradation of the revealed anomalies of the pipeline in the mode of its normal functioning.

Claims (1)

A device for non-contact magnetometric monitoring of the state of metal in pipelines, containing a crystal oscillator, a frequency divider, a Schmidt trigger, a linear function shaper, a threshold device, a digital indicator, metal magnetic field response sensors (flux gates), individual channels for its functional conversion into an electric signal, formed in series flux-gates, amplifiers and synchronous detectors, characterized in that the unit contains a block of electronic cells cell, analog converter, module block, analog-to-digital converter (ADC), power buffer, limit enumeration unit, sensitivity enumeration unit, background zeroing unit, control unit, automatic battery discharge indicator and light-sound indication of exceeding the threshold, while outputs of two individual channels connected to the block of electronic keys, the outputs of which through an analog converter are connected to the input of the module block and the analog input of the limit enumeration unit, the output of the latter is connected to the ADC connected to with a digital indicator, the output of the module block is connected to the control input of the limit enumeration unit and with the input of the threshold device connected to the light and sound indication of exceeding the threshold, the input of the power buffer is connected to the output of the linear function former, and its output is connected to flux probes, the enumeration node is connected to the control inputs of the amplifiers sensitivity, the background nulling unit is connected to the input of the electronic key block, the control unit is connected to the control inputs of the electronic key block and digital indicator, and the omaticheskoy indicating low battery connected to a digital indicator.