SU1168798A1 - Eddj-current cauge of thickness of dielectric coating - Google Patents

Abstract

VORTEX THREE DIELECTRIC COATING THICKNESS MEASUREMENT, containing series-connected harmonic current generator, eddy current transducer, amplifier, amplitude detector and logarithmic amplifier, as well as an indicator, characterized in that, in order to improve the accuracy of control, it has been used by the fraser, and the indicators have been drawn by a number of disconnecting receptacles, as well as an array of patterns, in order to improve the accuracy of control, there are a number of receptacle patterns, and a set of receptacles, and an indicator, which also had an offset pattern, in order to improve the accuracy of control, it was a set of receptacle patterns, and there are a number of patterns, and an indicator, which is used by the fraser, and an indicator, which is used by the fraser, in order to improve the accuracy of control, it is a pattern, and the indicators, as well as an indicator, have been used by the developers, and the indicators have been drawn by the application, in order to improve the accuracy of control, they were made by a template, in order to improve the accuracy of control, they were made by a template, in order to improve the accuracy of control, they could be used as a template. the detector, connected by the second input to the output of the amplifier, the function of the phase angle in its cotangent, and the adder, W The input of which is connected to the output of the logarithmic amplifier, and the output is connected to the indicator. CO oo

Description

11 The invention relates to non-destructive testing and can be used to measure the thickness of dielectric coatings on non-ferromagnetic electrically conductive bases. The eddy current thickness gauge of dielectric coatings containing successively connected generator, eddy current transducer, separation of two quadrature components of the signal of the eddy current transducer, connected via normalizing transducers to the adder, and connected to the output of the last indicator (1}. , which is associated with an increase in error with increasing degree of variation of the electrical conductivity of the base. The closest to the invention to the technical essence is the eddy current thickness gauge - dielectric coatings containing sequentially connected harmonic current generator, eddy current transducer, amplifier, amplitude detector, logarithmic amplifier and 2J indicator. However, the known thickness gauge does not provide the required control accuracy, this is due to control of dielectric coatings on a weakly conductive or thin-walled foundation is necessary to suppress the variation of the specific electrical tion conduction base excitation current frequency is practically achieved. The latter is associated with an increase as the frequency of cable losses increases and with resonant effects in the system, the whirlwind transducer is a connecting cable. The purpose of the invention is to increase the accuracy of control. The goal is achieved by the fact that an eddy current thickness gauge of dielectric coatings containing a harmonic current generator connected in series, a eddy current transducer, an amplifier, an amplitude detector and a logarithmic amplifier, as well as an indicator, are provided with a serially connected phase shifter, connected to the generator input, a phase detector connected by a second input to the output of the amplifier, a functional converter of the phase angle into its cotangent and an adder, the second input of which is connected n to the output of the logarithmic amplifier, and the output to the indicator, FIG. 1 shows a block diagram of the eddy current thickness gauge of dielectric coatings; FIG. 2 shows the dependence of measurement errors on the variations in conductivity of the base; the eddy thickness gauge contains series-connected harmonic current generator 1 , eddy current transducer 2, amplifier 3, amplitude detector 4, logarithmic amplifier 5, adder 6 and indicator 7, sequentially connected phase shifter 8, the input of which is connected to you the generator 1, the phase detector 9, the second input of which is connected to the output of the amplifier 3, and the functional converter 10 of the phase angle into its cotangent, vrsod; which is connected to the second input of the adder 6, the eddy current thickness gauge of dielectric coatings works as follows. Generator 1 powers eddy current transducer 2 installed above the controlled area. The signal from the measuring winding of the V-current converter 2 is fed to the amplifier 3 and is fed after amplifying simultaneously to the input of the amplitude detector 4 and the second input of the phase amplifier 3. To the second input of the latter through the phase shifter 8 is supplied - the reference voltage from the generator 1, Output signal of the phase detector 9 enters the functional converter 10 phase angle in its cotangent. The output signal of the adder 6 represents the algebraic sum of the signals from the logarithmic amplifier 5 and the functional converter .10 of the phase angle into its cotangent. Thus, the conversion function of the output signal of the eddy current transducer 2 has the form W CA - K Ctg tf, where W is a value uniquely related to the thickness of the dielectric coating (gap) J

Claims (1)

Eddy current thickness gauge of dielectric coatings, containing a series-connected harmonic current generator, eddy current transducer, amplifier, amplitude detector and logarithmic amplifier, as well as an indicator, characterized in that, in order to increase the accuracy of control, it is equipped with a phase-shifter connected in series with the input connected to the generator a detector connected to the amplifier output by a second input, a phase angle functional converter in its cotangent, and an adder, the second input otorrhea connected to the output of the logarithmic amplifier, and an output connected to the indicator. FIG. 1