SU885872A1 - Method of measuring non-magnetic material electrical conductivity - Google Patents

Description

(54) METHOD OF MANUFACTURING A SPECIFIED ESTIMATE CONDUCTIVITY OF NON-MAGNETIC TUBES

Claims (2)

The invention relates to non-destructive testing methods and can be used in any branch of mechanical engineering for the defectology of various metal products for struktroskopii. The known method of measuring specific electrical conductivity based on the use of a double bridge, a DC potentiometer and an eddy current transducer is {I J. However, measurements using a double bridge or a DC potentiometer are carried out on special fabricated samples, have low productivity and are used mainly under laboratory conditions. The closest to the present invention is a method based on the eddy current method, which means that using a eddy current transducer, a primary electromagnetic field is created in the measured metallic product, which excites 1ph; eddy currents in the metal, depending on the specific electrical conductivity , the structure of the product and the gap between the metal surface and the transducer. Eddy currents induce a secondary field interacting with the first g-. This results in a change in inductance and resistance of the converter, which contain useful information about the parameter being measured. The method of measuring the electrical conductivity in non-magnetic metals is to include an eddy current transducer into a resonant circuit, measure the capacitance of the circuit in a sinusoidal manner by the amplitude-modulated signal, measure the L2J value. The disadvantage of this method is the low accuracy of measurements of the specific electrical conductivity of nonmagnetic metals with a low value of electrical conductivity. The purpose of the invention is to improve the accuracy of measurement of the specific electrical conductivity of nonmagnetic metals with low electrical conductivity. The goal is achieved by changing the inductance or capacitance of the circuit with. a frequency twice as large as the frequency of the voltage supplying the loop, and increase the depth of the modulation of the amplitude-modulated loop signal until generation occurs in it. Fig. I shows the angograms of the relative resistance introduced depending on changes in the capacitance of the circuit; Fig. 2 shows the same, depending on changes in the inductance of the core; FIG. 3 shows the dependence of the depths of modulation of the capacitance; Fig. 4 shows the dependence of the depth U, the modulation of the inductance; Fig. 3 is a block diagram of a device implementing the method. The device contains generators 1 and 2 of sinusoidal voltage, eddy current transducer 3, including a circuit into the resonant circuit A, under. An amplifier 5 connected to its output, an amplitude detector b, an indicator 7. The method is carried out as follows. The eddy current transducer 3 is installed on the surface of the monitored material, the resonant circuit is energized by the generator 1, the alternating voltage of the generator 2 changes the capacitance or inductance of the resonant circuit 4, and the voltage frequency of the generator. 2 choose twice the frequency of the generator 1. Then increase the modulation depth of the capacitance or inductance of the circuit by increasing the voltage of the generator 2. When lasing occurs in a co-ordinate output, it increases sharply as a voltage amplitude, pointer arrows 7. Determine the voltage level of the generator 2, at which the generation of oscillations in the resonant circuit increases, and by this, we judge about the value of the specific electrical conductivity of the metal product. The measurements are carried out at the time of the parametric excitation of oscillations in the circuit, when the highest amplitude sensitivity of a resonant circuit with a eddy current transducer included in it takes place. The following hodographs are relative, 1 Bn / shy (jyben / cc; bo eddy current transducer capacitance C or inductance L of a circuit with a frequency twice as large as frequency (jy of the supply voltage at different values of the generalized parameter f is ECP (where a is the radius of the magnetic field of the vacuum G) is specific electrical conductivity) and different depths — modulation of the capacitance and inductance of the circuit. It follows from the above graphs that as the modulation depth increases, the resistance of the circuit decreases. This leads to an increase in the output voltage amplitude of the circuit by the specific electrical conductivity of C. At a certain iJ, the active resistance of the circuit becomes equal to O, which indicates the excitation of oscillations in the circuit. At this point, the amplitude sensitivity of the circuit with the BTP at 6 is maximum. Figures 3 and 4 show the dependences of the depth V of modulation of the capacitance and inductance (Fig. 4) of the circuit, at which generation occurs on the value of C for different values of the generalized gap parameter Q 2/0 (COT (where b is the CAP melody gap and surface according to the dependences between 9 and (Y, there is an unambiguous relationship that can be used to measure 1shz values (J non-magnetic 1-1 metals, because in this case the sensitivity in G is maximum. Thanks to measuring At parametric excitation oscillates in the loop, when the amplitude sensitivity of the resonant circuit is the highest by electrical conductivity (Y, measurement accuracy is improved for non-magnetic metals with a 1-h electrical conductivity value. Invention Method A method for measuring the electrical conductivity of non-magnetic metals, which consists in including a eddy current transducer in resonant circuit, change the capacitance of the circuit by a sinusoidal law and determine the measurement of the measured amplitude-modulated signal in order to improve the measurement of the specific electrical conductivity of non-magnetic metals with low electrical conductivity, the inductance or capacitance of the circuit is changed at a frequency of two higher frequencies of the voltage supplying the circuit, and increases the amplitude modulation depth modulated signal of the contour until generation occurs in it. Sources of information taken into account in the examination 1.Naumov N.M., Miklev P.G., - Resistometric non-destructive testing of deformable aluminum alloys. M., Metallurgists, 1974, p.119120. 2. USSR author's certificate number 746277, cl. G 01 N 27/90, 1978 (prototype). 0.8 0.6 QM 1U xi, Jz 68 YU Phil