RU81335U1 - Eddy current meter - Google Patents

Abstract

The utility model relates to the field of non-destructive testing by the method of eddy currents, and can be used to measure the thickness of various materials and their coatings, flaw detection, measurement of the electrical conductivity of materials and for other applications. The problem solved by the utility model is to increase the accuracy of measurements by reducing the influence of temperature on the eddy current transformer transducer, controlling the frequency of the excitation current generator and reducing the influence of interference in cable connections. To solve this problem, the eddy current meter contains an eddy current transformer with a ferrite core, field windings, measuring and compensation, an eddy current transformer transducer excitation generator, a phase detector and a controller, an excitation winding connected to an eddy current transformer transformer excitation generator, the end of the compensation winding is connected to a common input of the phase input detector, and the end of the measuring winding through the first amplifier is connected to the first signal input of the phase detector, the output of which is connected to the controller input, and is characterized in that the start of the measuring and compensation windings are connected and connected to the second signal input of the phase detector through the second amplifier, the control output of the controller is connected to the master input of the generator, the controller is equipped with a standard communication interface with external devices, and the eddy current transformer is located in a common housing with all other elements of the eddy current meter.

Description

The utility model relates to the field of non-destructive testing by the method of eddy currents, and can be used to measure the thickness of various materials and their coatings, flaw detection, measurement of the electrical conductivity of materials and for other applications.

Known eddy current meter [1], containing eddy current transformer, the excitation winding of which is connected to the excitation generator of the eddy current transformer, the measuring and compensation windings are connected opposite to each other and to the common input of the phase detector, the output of the measuring winding through the first amplifier is connected to the first signal input phase detector, the output of which is connected to the control unit and information processing.

The disadvantage of this eddy current meter is the low accuracy associated with the fact that the signal on the measuring winding is compared with the signal on the voltage winding. As a result of this, the temperature instability of the field winding parameters directly affects the measurement accuracy.

Known eddy current meter - flaw detector [2], which select and use several excitation frequencies to detect defects at a certain depth.

The disadvantage of this eddy current meter is its limited scope.

Known eddy current meter [3] - a portable integrating coating thickness gauge TT230 company "Time Group Inc.", working on the principle of eddy currents, capable of measuring the thickness of non-conductive coatings on a non-magnetic metal base

(enamel, rubber or paint on copper, aluminum, zinc or tin) without harming the inspected object. The TT 230 thickness gauge has an integrated eddy current transducer.

The disadvantages of this device are the inability to control electrically conductive coatings and a limited temperature range of 0-40 ° C. In addition, the design of the device, in which the eddy current meter, the processing unit and the information display are combined in one housing, makes it inconvenient for measurements in hard-to-reach places.

[4] Various electromagnetic methods for measuring the thickness of coatings are known: eddy current parametric p. 32 and induction.

The disadvantage of these methods is the limited scope for the combination of materials and coating thickness, see [4], table, p. 36.

Most eddy current meters, for example, [4], page 37, [5], [6] and many others are structurally made as a separate element (eddy current transformer transducer) connected to the information processing and display unit by cable connection.

The disadvantage of such eddy current meters is the low accuracy due to problems of the mutual influence of signals in cable connections, especially at high frequencies.

Closest to the claimed one is an eddy current meter [4], p. 32, using an eddy current phase measurement method and comprising an eddy current transformer with a ferrite core, excitation windings, measuring and compensation, an eddy current transformer transformer excitation generator, a phase detector and a controller, an excitation winding is connected with an eddy current transformer transducer excitation generator, the end of the compensation winding is connected to a common phase input of the detector, and the end of the measuring

windings through the first amplifier are connected to the first signal input of the phase detector, the output of which is connected to the input of the controller. The advantages of the eddy current phase method are higher accuracy compared to other methods and the breadth of applications, see [4], table, p. 36.

The disadvantages of this device are the dependence of the accuracy of the measurement results on temperature, low noise immunity and poor adaptability to the measurement conditions.

The problem solved by the claimed utility model is to increase the accuracy of measurements. In this utility model, increasing the accuracy of measurements refers to the following problems and methods for solving them.

Eddy current transformer has a significant dependence of the parameters on temperature. In particular, the active resistance of the field winding and the core parameters of the eddy current transformer transducer (magnetic permeability) are significantly dependent on temperature, which directly affects the measurement results. The elimination of this dependence makes the measurement process less dependent on temperature conditions and thereby increase the accuracy of measurements.

Eddy-current measurements require that the frequency of the field current of the field winding match the parameters of the materials under study, the measurement conditions, accuracy requirements, and other circumstances. The ability to set the frequency of the field current increases the accuracy and versatility of the meter.

Eddy current meters have, as a rule, a sensitive element (eddy current transformer transducer) made structurally as a separate element connected to the remaining elements of the eddy current meter and the information processing and display unit by cable connection. Small amplitudes of the output signals of eddy current transformers, especially at high

excitation current frequencies, lead to significant measurement errors. This is due to the influence of signals in the cable connections, the influence of electromagnetic interference and the volatility of the parasitic capacitance of the cable connections that connect the sensitive element to the rest of the elements of the eddy current meter. The solution to this problem is to transfer all the elements of the eddy current meter into one housing with a sensitive element.

The circuit of the inventive eddy current meter is presented in figure 1, where:

1. The eddy current transformer transducer excitation generator

2. Eddy current transformer

3. Field winding

4. Measuring winding

5. Compensation winding

6. The first amplifier

7. Phase detector

8. The second amplifier

9. Controller

10. The output of the phase detector 7

11. Controller control output

12. Standard communication interface with external devices. Significant differences of the claimed utility model are:

The beginning of the measuring 4 and compensation 5 windings are connected and connected through the second amplifier 8 to the second signal input of the phase detector 7. This solution allows you to compare the phases of the signals received on the secondary windings of the eddy current transformer 2, thereby eliminating the influence of temperature instabilities of the field winding 3 (in in particular, its active resistance) and eddy current transformer core

transducer 2 (in particular, magnetic permeability) to the measurement results.

In the prototype, the phase difference is measured between the signals on the field winding and on the secondary windings, thus, the above factors fully affect the accuracy of the measurements.

The connection of the controller 9 with the input of the generator 1 of the eddy current transformer transducer 2 allows you to control the generator from the controller 9 by setting the frequency of the excitation current of the eddy current transformer 2, so that it matches the parameters of the materials under study, measurement conditions and accuracy requirements.

The prototype does not address the issue of changing the frequency of the excitation current of the eddy current transformer transformer.

The presence of the controller 9 of the standard interface for communication with external devices 12 allows, with the selected design of the eddy current meter, to connect controls (keyboard), display means (display) or other, more powerful means of control, processing and display of information to it.

The prototype does not consider a method of controlling the operation of an eddy current meter and a means of displaying information.

The location of the eddy current transformer transducer 2 in one housing with all the elements of the eddy current meter eliminates the influence of cable connections on the measurement accuracy. Due to this, it becomes possible to increase the frequency of the excitation current of the eddy current transformer transducer 2, use the eddy current transformer transducer 2 of a smaller diameter, and thereby increase the locality of the eddy current control.

The prototype does not consider the design of the meter.

Consider the main elements of the eddy current meter.

The eddy current transformer transducer 2 excitation generator 1 is designed to generate current in the excitation winding 3 of the eddy current transformer transformer 2. As a generator 1 of the eddy current transformer transducer 2, a harmonic signal generator with frequency control can be used.

The eddy current transformer transducer 2 is a sensitive element of the eddy current meter, it is a ferrite core with field windings 3, measuring 4 and compensation 5. The field winding 3 is located in the middle of the ferrite core. Measuring 4 and compensation 5 windings have identical characteristics and are located on the opposite ends of the core.

Amplifiers 6 and 8 are designed to amplify small-amplitude signals from the windings of an eddy current transformer transducer 2.

The phase detector 7 is designed to determine the phase difference of the signal from the compensation 5 windings and the difference signal measuring 4 and compensation 5 windings. The signal at the output of the phase detector 7 is proportional to the phase difference of the compared signals.

The controller 9 is designed to process the signal 10 coming from the phase detector 7, control the frequency of the generator 1 and communicate via a standard communication interface with the information processing and display unit. The controller 9 can be implemented in the form of a single-chip microcomputer having an analog input for receiving a signal from a phase detector, a digital control output of the generator 1 and a standard communication interface for exchanging with the information processing and display unit.

Consider the work of the inventive eddy current meter.

Before starting work through the standard communication interface 12, the control codes 9 enter the controller 9, which specify, in particular, the frequency of the generator 1, which is selected by the operator based on the parameters of the material of the object of study, the requirements for resolution

etc. The controller 9 through the control output 11 supplies the appropriate frequency setting of the field current of the eddy current transformer 2 to the excitation generator 1 of the eddy current transformer 2. The excitation generator 1 of the eddy current transformer 2 generates a current in the excitation winding 3 of the eddy current transformer 2, which causes the appearance of signals (EMF ) on measuring 4 and compensation 5 windings. The eddy current transformer is located in close proximity to the remaining elements of the eddy current meter, so that the problem of electromagnetic compatibility is solved relatively easily and interference in the conductors of the communication circuits has little effect on the measurement results. The temperature dependence of the parameters of the field winding 3 and the core of the eddy current transformer 2 does not affect the measurement results, since only signals received from the secondary windings 4 and 5 are used. The signal received from the compensation winding 5 through the amplifier 8 and the difference signal from the measuring 4 and compensation 5 windings through the amplifier 6 are fed to the signal inputs of the phase detector 7, where the difference of their phases is determined. In the absence of the object of study, the difference signal with the measuring 4 and compensation 5 windings is zero, otherwise it has an amplitude and phase determined by the parameters of the object of study. The phase detector 7 generates a signal 10 proportional to the phase difference between the signal from the compensation winding 5 and the difference signal from the measuring 4 and compensation 5 windings. The signal 10 is fed to the input of the controller 9, where it is converted into a digital code and integrated to average the measurement results. The measurement results through a standard communication interface with external devices 12 are received on the processing unit and information display.

Thus, the inventive eddy current meter can be implemented and provides improved measurement accuracy.

INFORMATION SOURCES:

1. Patent SU No. 932207.

2. Patent SU No. 832442.

3. http://www.nw-technology.ru/catalog/time_th220-230.html.

4. Journal Review “In the World of Non-Destructive Testing”, No. 2 (40) June 2008.

5. http://www.biolight.ru/item.php?id=0007464.

6.http: //www.aka-control.ru/serial_ve2000.html.

Claims (1)

Eddy current meter containing a eddy current transformer with a ferrite core, field windings, measuring and compensation, an eddy current transformer transducer generator, a phase detector and a controller, a field winding connected to a generator, the end of the compensation winding connected to a common input of the phase detector, and the end of the measuring winding through the first amplifier is connected to the first signal input of the phase detector, the output of which is connected to the input an oller, characterized in that the start of the measuring and compensation windings are connected and connected through a second amplifier to the second signal input of the phase detector, the control output of the controller is connected to the master input of the generator, the controller is equipped with a standard communication interface with external devices, and the eddy current transformer is located in a common housing with all other elements of the eddy current meter.