RU143178U1 - DEVICE FOR DETERMINING THE THICKNESS OF MAGNETIC DEPOSITS ON THE SURFACE OF PIPES BY THE VORTEX RAY METHOD - Google Patents

Abstract

An eddy current device for controlling the thickness and magnetic properties of deposits on the pipe surface, containing a generator of rectangular periodic current pulses, an eddy current sensor with an exciting coil, whose radius R is chosen from condition 3 (δ + δ)> R> l, 0 (δ + δ), where δ and δ, the nominal and maximum thickness of the pipe wall and deposits, respectively, and the measuring coil, the processing unit of the signal information of the measuring coil, amplifier, analog-to-digital converter, microcontroller, indicators of thickness and conductivity, you the stroke of the square-wave pulse generator is connected to the exciting coil of the eddy current sensor, the measuring coil is connected to the input of the amplifier, the output of the amplifier is connected to the input of the analog-to-digital converter, the output of the analog-to-digital converter is connected to the input of the microcontroller, the indicator of the thickness of deposits is connected to the first output of the microcontroller, and the second - sediment conductivity indicator, characterized in that the eddy current sensor is equipped with a magnetic flux meter of the exciting coil and of boiling currents, the device is equipped with a data processing unit for the magnetic flux meter, the period of the current pulse of the generator is chosen from the condition T≥3 Rμ (δ σ + δ σ μ), where δ and σ are the nominal values of the thickness and conductivity of the metal, δ, σ and μ - maximum values of thickness, conductivity and permeability of deposits, μ-magnetic constant, a deposit permeability indicator is connected to the third output of the microcontroller, an algorithm for determining the magnetic permeability is implemented in the microcontroller and

Description

The invention relates to non-destructive testing methods and can be used in thermal and nuclear power plants, oil and gas pipelines in chemical and petrochemical enterprises. The technical feasibility of the invention lies in the fact that the presence of deposits (especially magnetic) significantly complicates the process of conducting eddy current non-destructive testing.

Closest to the proposed technical solution is a device for determining the thickness of non-magnetic deposits on the surface of the pipes by a pulsed eddy current method [1]. The measurement is implemented by an overhead sensor, the radius of the exciting coil of which is selected in accordance with the configuration of the test object, the period of the exciting pulse current is determined depending on the electrophysical parameters of the pipe metal and deposits. The proposed algorithm for processing the pulse periodic response of the measuring coil allows us to determine both the wall thickness and the electrical conductivity of the pipe wall, and similar deposition parameters. The disadvantages of this device include the inability to control magnetic deposits, while it is magnetic deposits to a greater extent complicate the process of conducting eddy current non-destructive testing. In addition, information on the magnetic properties of the material of the object greatly simplifies its structural analysis.

The technical task of the proposed technical solutions are:

determination of the type of deposit - non-magnetic or magnetic, and

determination of the thickness of the magnetic deposit and its magnetic properties.

The technical effect obtained by solving the technical problem of determining the structure of deposits by analyzing its thickness, electrical conductivity and magnetic permeability is achieved by the fact that in the known device containing a generator of rectangular periodic current pulses, an eddy current sensor with an exciting coil, the radius R _of which is chosen from conditions where and nominal and maximum wall thickness of the pipe and deposits, respectively, and the measuring coil, the information processing unit of the signal of the measuring coil, amplifier, analog-to-digital converter, microcontroller, thickness and conductivity indicators, where the output of the rectangular pulse generator is connected to the exciting coil of the eddy current sensor, the measuring coil is connected to the input of the amplifier, the output of the amplifier is connected to the input of the analog-to-digital converter, the output of the analog-to-digital converter is connected nen with the input of the microcontroller, the sediment thickness indicator is connected to the first output of the microcontroller, the sediment conductivity indicator is connected to the second, the signal processing algorithm determines the wall thickness and conductivity of the pipe metal, according to the utility model, the eddy current sensor is equipped with a magnetic flux meter of the exciting coil and eddy currents, the device is equipped with by the information processing unit of the magnetic flux meter, the period Tv of the generator current pulses is selected from the condition Where and - nominal values of the thickness and conductivity of the metal, , and - maximum values of thickness, conductivity and permeability of deposits, μ ₀ - magnetic constant, a deposit magnetic permeability indicator is connected to the third output of the microcontroller, the microcontroller implements an algorithm for determining the magnetic permeability and thickness of the magnetic deposition by fixing at certain points in time increments that are introduced depending on the vortex currents, voltage of the measuring coil in relation to its value for an object without deposition and a comparison of these increments their values at the nodes of the calibration obtained by experiment or simulation, a grid located in the microcontroller memory.

In FIG. 1 shows a block diagram of the proposed device.

In FIG. Figure 2 shows the time diagram of the introduced flux during magnetic and non-magnetic deposition.

In FIG. 3. The calibration grid is shown.

The block diagram of the device is shown in FIG. 1. The control object consists of a metal layer 1 and a deposition layer 2. The eddy current sensor, the exciting coil 3 of which is connected to the generator 4, is located above the control object. The eddy current sensor is equipped with a magnetic flux meter 5 of the exciting coil and eddy currents connected to the amplifier 6. The amplifier 6 is connected to an analog-to-digital converter 7, which is connected to a computer or microcontroller 8. The measuring coil 9 is connected to the amplifier 10. The amplifier 10 is connected to an analog a digital converter 11, which is connected to a personal computer or microcontroller 8. The microcontroller 8 is connected to a deposition thickness indicator 12, a deposition conductivity indicator 13, and an indicator m permeability sediments 14.

The device operates as follows: On the surface of a two-layer control object (pipe wall, flat surface) from the side of metal layer 1 (the more distant is the deposition layer 2) there is an eddy current sensor, the exciting coil 3 of which is fed from the generator 4 by a pulse current i _in with a period (Where , - the nominal and maximum value of the electrical conductivity of the metal layers and deposits, , - nominal and maximum value of the thickness of the metal layers and deposits, - the maximum value of the magnetic permeability of the deposit). The signal of the measuring coil 9 is amplified by an amplifier 10 and through an analog-to-digital converter 11 enters a personal computer or microcontroller 8. The eddy current sensor is equipped with a magnetic flux meter 5 of the exciting coil and eddy currents, the signal of which is amplified by an amplifier 6 and also fed to the analog-to-digital converter 7 personal computer or microcontroller 8. If the introduced magnetic flux in the final stage of the damping process (figure 2) changes its sign, then the object is magnetic and 8, the microcontroller starts a signal processing algorithm, resulting in the presence of an object with a magnetic deposition. According to this algorithm, the thickness and magnetic permeability of the deposition is determined by fixing at certain time instants of increments of the insertion voltage, depending on the eddy currents, of the measuring coil with respect to its value for the object without deposition and comparing these increments with their values in calibration nodes obtained experimentally or by modeling , the grid located in the memory of the microcontroller, (figure 3).

Information about the thickness of the deposition, the electrical conductivity of the deposition and the magnetic permeability of the deposition is received on the indicators 12, 13 and 14, respectively.

Thus, due to the joint use of the eddy current sensor, consisting of the exciting and measuring coils, the magnetic flux meter built into the eddy current sensor, in accordance with the signal processing algorithm embedded in the microcontroller, the thickness of the magnetic deposit is measured and the magnetic properties of this deposit are quantified, which characterizes to a large extent its structural state.

This circumstance is of particular interest to specialists operating production facilities.

Information sources:

1. Patent of the Russian Federation RU 02487343. C1, M. Cl. G01B 07/17/2013

Claims (1)

Apparatus eddy current thickness and magnetic properties of the deposits on the surfaces of pipes, comprising a generator of rectangular periodic current pulses eddy current sensor with an exciting coil, a radius R _which is selected from the condition 3 (δ _m ⁿ + δ _o ^m)> R _a> l, 0 ( δ _m ⁿ + δ _o ^m ), where δ _m ⁿ and δ _o ^m , nominal and maximum wall thickness of the pipe and deposits, respectively, and the measuring coil, the processing unit of the signal information of the measuring coil, amplifier, analog-to-digital converter, microcontroller, thickness indicators and electro conductivity, the output of the square-wave pulse generator is connected to the exciting coil of the eddy current sensor, the measuring coil is connected to the input of the amplifier, the output of the amplifier is connected to the input of the analog-to-digital converter, the output of the analog-to-digital converter is connected to the input of the microcontroller, the sediment thickness indicator is connected to the first output of the microcontroller, to the second - sediment conductivity indicator, characterized in that the eddy current sensor is equipped with a magnetic field flux meter conductive coil and the eddy currents, the apparatus is provided with an information processing unit measuring the magnetic flux _in the generator period T of the current pulses is selected _in the condition T ≥3 R _in μ ₀ (δ _m σ ⁿ _m ⁿ + δ _o σ _o ^{m m m} μ _u) , where δ ⁿ _m and σ ⁿ _m are the nominal values of the thickness and electrical conductivity of the metal, δ _о ^m , σ _о ^m and μ _g ^{m are the} maximum values of the thickness, electrical conductivity and magnetic permeability of the deposits, μ _{0 is the} magnetic constant, connected to the third output of the microcontroller deposition magnetic permeability indicator, microcontroller implements al an algorithm for determining the magnetic permeability and thickness of a magnetic deposit by fixing, at certain points in time, increments of the insertion voltage, depending on the eddy currents, of the measuring coil with respect to its value for an object without deposit and comparing these increments with their values in calibration nodes obtained experimentally or by modeling grid in the memory of the microcontroller.