RU2356019C2 - Device to remotely reveal pressure pipeline faulty insulation and walls - Google Patents

Abstract

FIELD: physics, measurements.

SUBSTANCE: invention relates to pulsed hardware intended for gaining information about parasitic emissions in lines with uniformly distributed parametres and can be used to reveal the pressure pipeline insulation and walls with the help of acoustic waves and E₀₀-type electromagnetic sounding waves. The proposed device differs from known ones in that the pressure emergent drop alarm incorporates electromagnetic reflectors of the E₀₀-type surface waves arranged on opposite ends of pipeline under control and a reflectometre with wire-counter balance connected with the pipeline wall controlled part. Note here that aforesaid insulated wire-counter balance is arranged perpendicular to the pressure pipeline wall in the ground plane, the reflectometre casing being isolated from the ground. Since the said reflectometre records the waves propagating both inside the pressure pipeline (hydraulic shock wave) and on over its surface (E₀₀-type surface electromagnetic wave).

EFFECT: efficiency and accuracy of revealing pressure pipeline insulation and wall faults are increased.

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Description

The invention relates to devices of pulsed technology for obtaining information about the locations of spurious emissions with wave impedance in lines with uniformly distributed parameters. In particular, it can be used to determine the places of damage to the insulation and the wall of the pressure pipe during its operation by waves of various physical nature: by the acoustic waves generated when the medium is discharged due to damage to the pipe wall, and by electromagnetic sounding waves of type E ₀₀ reflected from the place of violation insulation and walls of the pressure pipe, which are reflected by characteristic features on the compared with each other, recorded at different times in the diagrams during echosounding (reflectivity metrics) of fault locations in the linear part of the pressure pipe with uniformly distributed parameters.

A device for echo-pulse acoustic control is based on sending short pulses of ultrasonic vibrations to a controlled product and on recording the intensity and time of arrival of echo signals reflected from defects or product boundaries, containing a piezoelectric transducer, pulse generator, synchronizer, sweep generator, amplifier, cathode ray tube (BC Makarin. Means of non-destructive testing of castings. M., "Higher School", 1988, p.30).

The disadvantage of the above device is the significant cost of time and money when examining extended objects. In addition, the impossibility of providing operational control of the pressure pipe, as well as recording the time of onset of insulation damage and leakage.

The closest in technical essence and the achieved effect, which allows you to remotely determine the place and time of damage to the pressure pipe when registering a pressure drop at the ends of the monitored section of the pressure pipe, is an emergency pressure drop signaling device in the pressure pipe (patent No. 2050532), containing two cavities connected in parallel channels with nozzles, a nozzle-flapper, while the upper cavity is an air-hydraulic cap.

The device operates as follows: if the pressure pipe is damaged and the pressure drop signal reaches the emergency pressure drop signaling device, the air-hydraulic cap discharges part of the liquid through the damper nozzle, disrupting the electrical contact between them, which is a sign of pressure drop in the pressure pipe due to damage. With smooth (operational) pressure changes, the fluid pressure is equalized in the cap and pressure pipe through the nozzles without opening the shutter pressed to the nozzle. When installing an emergency fall detector at the ends of a monitored operated section of a pressure pipeline, the place of damage is determined by the time delay of the waves recorded at the ends of the section.

A significant drawback of the above emergency drop alarm in the pressure pipe is:

- the presence of an electrical contact in the liquid, which during long-term operation in standby mode leads to failures due to a change in the transition resistance over time (wear and corrosion of the contacts, change in the properties of the boundary layer of liquid on the contacts);

- the impossibility of assessing the accuracy and reliability of measuring the distance to damage, since only one measurement is made in standby mode;

- lack of control over the dynamics of damage due to thinning of the wall of the pressure pipe due to corrosion and the inability to assess the violation of the insulation of the wall of the pressure pipe.

The objective of the claimed technical solution is to create a device for remote detection of damaged insulation and wall of the pressure pipe, in which the above disadvantages are absent, the reliability and accuracy of detection of damage to the insulation and wall of the pressure pipe is increased due to the reliable assessment of the results of a set of statistical data and their evaluation according to the criteria Student and Cochran, providing protection against interference resulting from adjacent sections of the monitored pressure pipeline, pu placing it electromagnetic surface wave reflectors on the opposite ends of the flowline and controlled registration traces electromagnetic surface wave type E _00.

This object is achieved in that the device for remote detection of damaged insulation and the wall of the pressure pipe, containing an emergency drop detector with cavities connected in parallel with channels with nozzles and a damper nozzle, while the emergency drop detector is equipped with electromagnetic reflectors of surface waves made in the form metal disc-reflectors of electromagnetic surface waves of type E ₀₀ and placed at opposite ends of the controlled section of the pressure pipe, reflectometer with an insulated counterbalance wire connected by an electric circuit to a controlled portion of the pressure pipe wall, while the isolated counterbalance wire is perpendicular to the pressure pipe wall in the ground plane, with the reflectometer case isolated from the ground, and the operation of the reflectometer carried out in the registration mode of reflectograms of electromagnetic surface waves of type E ₀₀ .

A comparative analysis of the invention and the prototype allows us to conclude that it is new that the device for remote detection of damaged insulation and the wall of the pressure pipe is equipped with an emergency drop signaling device with electromagnetic reflectors of surface waves made in the form of metal disk reflectors of electromagnetic surface waves of type E ₀₀ and located at opposite ends of the controlled section of the pressure pipe, reflectometer with a counterweight wire, nym electrical circuit controlled flowline wall portion, wherein the wire-counterweight is disposed perpendicularly to the wall of the discharge pipe in the ground plane, wherein the OTDR operation is carried out in the registration mode OTDR electromagnetic surface wave type E _00. This ensures that the invention meets the criterion of "novelty."

Comparison of the proposed solution not only with the prototype, but also with other technical solutions in the art allows us to conclude that the criteria of the invention are “inventive step”.

The drawing shows a diagram of a device for remote detection of damaged insulation and pressure pipe wall.

The device consists of an emergency pressure drop signaling device 1, electromagnetic reflectors of surface waves E ₀₀ , made in the form of metal discs-reflectors 2, located on opposite areas of the monitored pressure pipe 3, the reflectometer 4 with a counterbalance wire 5. The reflectometer 4 is connected by an electric circuit 6 to a controlled a section of the wall of the pressure pipe 3, while the counterweight wire 5 is perpendicular to the wall of the pressure pipe 3 in the plane of the earth 7, when isolated, respectively Actually, the OTDR housing 4 is off the ground.

The device operates as follows.

The emergency fall detector 1 and electromagnetic reflectors of surface waves E ₀₀ , made in the form of metal discs-reflectors 2, are installed on a controlled section of a pressure pipeline 3. Sequentially, probing pulses are sent from both ends of the pressure pipe 3 in a traveling wave mode E ₀₀ by excitation of it with a microwave generator of an OTDR 4 connected by an electric circuit 6 to the beginning of a controlled section of a pressure pipeline 3, and the location of the counterweight wire and 5 perpendicular to the pressure pipe 3 in the plane of the earth’s surface 7. Register each time the memory of the reflectometer 4 (as a reflectometer can be used as a digital reflectometer commercially available Flight-205 of the Scientific and Production Enterprise “Systems for Testing Electric Lines”) insulation state between the pressure section pipeline and ground. Then determine the change in the insulation state of the pressure pipe 3 when combining traces and evaluating their characteristic deviation in time by changing the sign of the reflected wave in the place of leakage of part of the energy of the reflected signal (insulation failure is characterized by a negative reflected pulse on the trace, and wetting, for example with oil product, of the earth in its place a leak imposes a positive impulse on the trace, as a rule, of a different duration). When the emergency pressure drop alarm is triggered on the fact of the discharge of the medium (liquid, gas, etc.) from the pressure pipe 3, the average statistical distance from the beginning of the controlled section to the place of damage is successively determined, its accuracy according to the Student criterion and reliability according to the Cochran criterion. To do this, record five reflectograms and determine at each distance to the place of damage, sequentially combining them with the reflectogram of a serviceable section of the pressure pipe 3 and assessing the location of the medium discharge from the ends of the controlled section by the location in time of the wave E ₀₀ reflected from the leak from the ends of the trace limited by the start pulse and an impulse reflected from the end of each controlled section of the pressure pipe 3 by electromagnetic reflectors of surface waves made in in the form of metal disk reflectors 2, according to the following formulas:

where X is the distance to the damage site of the i-th site, m; L _i - distance to the end of the controlled i-th section of the pressure pipe, m; t _i is the double-wave travel time of the distance to the damage site of the i-th section, s; T _i - the double run time of the wave distance to the end of the controlled i-th section of the pressure pipe, s.

X _cp. - the mathematical expectation of the distances to the place of damage to the pipe wall of the pressure pipe (registered after the signal), m; ∑x _i - the sum of the fixed distances after the signal, m; n is the number of measurements of distances to the place of damage after the signal.

where t is a criterion of sufficient accuracy of the mathematical expectation when assessing the distance to the place of discharge of the medium from the pressure pipe (student criterion); X _1cp. X _2cp. - the mathematical expectation of estimating the distances to the place of damage to the insulation of the pressure pipe before signaling the discharge of the medium in the first and second half of the sample X _i (for an odd number of estimates in the sample, it is possible to allow a discrepancy in the number of measurements in half-samples per unit), m; n ₁ , n ₂ - the number of measurements of the distance to the place of damage to the pressure section of the pipeline with a leak in the first and second half of the sample, respectively; S ₁ , S ₂ - standard deviations in each half of the sample when assessing the place of leakage of the medium from the pressure pipe, respectively.

G is the criterion for the reliability of the result or uniformity of the sample (Cochran criterion).

Using the proposed device for remote detection of damaged insulation and the wall of the pressure pipe in comparison with the prototype allows you to efficiently and accurately detect the damaged insulation and the wall of the pressure pipe due to:

- operation of the OTDR (for example, the Rays-205 OTDR) in the mode of recording OTDR traces of electromagnetic surface waves of type E ₀₀ , in which the OTDR probes the monitored section of the pressure pipe as a single-wire guide line with uniformly distributed parameters of the electromagnetic surface wave of E ₀₀ type, which is formed by connecting the OTDR to counterbalance wire with an electric circuit with a controlled section of the pressure pipe and the location of the counterweight wire endikulyarno to the ground plane, isolated from ground reflectometer housing;

- providing protection against interference resulting from adjacent adjacent sections of the monitored pressure pipe by placing electromagnetic reflectors of surface waves at its ends made in the form of metal disk reflectors of electromagnetic surface waves of type E ₀₀ ;

- providing a remote assessment of the reliability of the result by determining the fact of the leakage of the medium (liquid or gas) from the pressure pipe based on registration on a reflectometer of waves propagating both inside the pressure pipe (hydroshock wave) and along its surface (surface electromagnetic wave E ₀₀ );

- ensuring the accuracy and reliability of determining the distance to the place of damage to the insulation of the wall of the pressure pipe by the possibility of collecting statistics and evaluations according to the criteria of Student and Cochran.

Claims (1)

A device for remote detection of damaged insulation and the wall of the pressure pipe, containing an emergency drop detector with cavities connected in parallel with channels with nozzles and a damper nozzle, characterized in that the emergency drop detector is equipped with electromagnetic reflectors of surface waves made in the form of metal disk-reflectors electromagnetic surface waves of type E ₀₀ and placed at opposite ends of the controlled section of the pressure pipe an ode, a reflectometer with a counterbalance wire connected by an electric circuit to a controlled section of the pressure pipe wall, the insulated counterbalance wire being perpendicular to the pressure pipe wall in the ground plane with the reflectometer body isolated from the ground, respectively, and the reflectometer is operated in electromagnetic reflectogram recording mode surface waves of type E ₀₀ .