SU1099293A1 - Device for measuring dynamic reversible magnetic permeability - Google Patents

Abstract

A DEVICE FOR MEASURING DYNAMIC REVERSIBLE MAGNETIC PERMEABILITY, comprising a high-frequency generator, a high-frequency exciting winding, a low-frequency generator with a low-frequency excitation winding connected to its output, a measuring winding connected in series, an amplifier, and a synchronous detector, an indicator, a unit, a unit, a tee, an indicator, a tee, an indicator, a tee, an indicator, a tee, an indicator, a tee, an indicator, a tee, an indicator, a tee, an indicator, a tee, a tempered coil, an amplifier, an amplifier, and a synchronous detector, an indicator, a tee is connected, serially connected measuring winding, amplifier, and a synchronous detector, an indicator, a unit, a unit, an indicator, a unit, an amplifier, and a synchronous detector, an outlet, a tee, connected to its output, connected in series, a coil, amplifier, and a synchronous detector, connected to its output; with the second output of the low-frequency generator, a control input of the synchronous detector is connected to the output of the gene via a phase generator a high frequency signal, characterized in that, in order to improve measurement accuracy, it is additionally equipped with a reference voltage generator, sequentially connected by a quadrature phase generator, an absolute value extraction unit, a summing amplifier and a modulator, the quadrature phase sensor input being connected to the third signal a low-frequency generator, the modulator output is connected to a high frequency (No excitation winding, the second input of the modulator is connected to the high-frequency generator output, and the output of the generator is The voltages are connected to the second input of the summing amplifier, the output of the synchronous detector is connected to the second input of the indicator, and the amplifier is broadband.

Description

The invention relates to magnetic measurements and can be widely applied, with non-destructive testing of ferromagnetic materials and products. A device for determining a reversible magnetic permeability is known, comprising a transducer with two ophthalmic exciters and one measuring, two DC sources and a measuring circuit and implementing a pulse-induction test method ij. However, the measurement performance of the device is low, and its application is limited only by the area of constant fields. The closest in technical essence to the invention is a device for measuring dynamic reversible magnetic permeability, comprising a high-frequency generator, a high-frequency exciting winding, a low-frequency generator with a low-frequency exciting winding connected to its output, serially connected measuring winding, amplifier, synchronous detector and an indicator, the second input of which is connected to the output of the low-frequency generator through the unit for forming the voltage, and A synchronous detector is connected via a phase generator to a second output of a high frequency generator 2 However, in known devices for measuring reversible magnetic permeability in a dynamic mode, subject to the condition of amplitude of a high frequency field, the amplitude of private cycles, and consequently, the conditions for obtaining them in different points of the low-frequency loop, do not remain constant, and periodically — with the double frequency of the low-frequency Paul — change from the maximum value (the area of the low-frequency loop peaks) to the minimum ( areas of residual inductions). This significantly reduces the accuracy and reliability of the measurement or control. The purpose of the invention is to improve the measurement accuracy. The goal is achieved by the fact that a device for measuring dynamic reversible magnetic permeability, comprising a high-frequency generator, a high-frequency exciting winding, a low-frequency generator with a low-frequency exciting winding connected to its output, a measuring winding connected in series, an amplifier and a synchronous detector, an indicator that enters through the unit the formation of the reference voltage is connected to the second output of the low-frequency generator, and the control input of the synchronous detector is black a phase generator connected to the high-frequency generator output, additionally equipped with a reference voltage generator, sequentially connected by a quadrature phase generator, an absolute value extraction unit, a summing amplifier and a modulator, the quadrature phase-phase sensor input being connected to the third output of the low-frequency generator, the output of the modulator is connected high-frequency exciting winding, the second input of the modulator with the output of the high-frequency generator, the output of the reference voltage generator is connected to the second input of the su miruyuschego amplifier, the output of the synchronous detector - a second input indicator, and a broadband amplifier is configured. Figure 1 shows the structural diagram of the proposed device; figure 2 - diagrams of signals in its characteristic points. Device for measuring dynamic reversible magnetic permeability, contains a high-frequency generator 1, a high-frequency exciting winding 2, a low-frequency generator 3 with a low-frequency exciting winding 4 connected to its output, a measuring winding 5 connected in series, an amplifier 6, a synchronous detector 7 and an indicator 8, second the input of which is connected to the output of the low-frequency generator 3 through the voltage-generating unit 9, and the control input of the synchronous detector 7 is connected to the second via a phase-sensing sensor 10 generator output of high frequency generator 1, reference voltage generator 11, quadrature phase generator 12 connected in series, absolute value section 13, summing amplifier 14 and modulator 15, the input of quadrature phase sensor 12 being connected to the output of low frequency generator 3, modulator output 15 is connected to the high-frequency exciting winding 2, the second input of the modulator 15 is connected to the output of the high-frequency generator 1, the output is connected to the second input of the summing amplifier 14, the output of the synchronous detector 7 is connected to the second input of the speaker 8, and the amplifier 6 is broadband. . The device works as follows. The controlled ferromagnetic sample is magnetized simultaneously by two alternating magnetic fields of high and low frequency. The low frequency and constant amplitude field is created by the generator 3 low often and connected to its output by a low-frequency exciting winding 4. The magnitude of the low-frequency field is sufficient for nonlinear magnetization reversal of the test material, up to its technical extent. The high frequency field in amplitude is not constant, but varies according to the law -t-H4lE-fe - | / t), where 9 and C (is the circular frequency and the amplitude of the low frequency field CO and And is the circular frequency and the amplitude of the intensity modulated high-frequency field. This modulation law is obtained on the basis of the equality of the amplitude of the intensity of dynamic partial cycles, regardless of what point of the low-frequency hysteresis loop they are in. The magnitude of the intensity is numerically determined by the negative increment of the total exciting fields that do not actually cause the occurrence of private cycles The law of modulation of the amplitude of the high-frequency field — its modular function (Fig.2.2) is achieved by summing on the summing voltage detector 14 a constant voltage (Fig.2.2) going from a generator 11 of reference voltages and a voltage varying according to the absolute cosine law, obtained as a result of successive transformation of a sinusoidal voltage from a generator 3 of low frequency (Fig.2 O) in quadrature phase encoder 12 (Fig.2 5), performed for example, in the form of an integrator and in block 13, the allocation of absolute values (Fig. 2b), made, for example, in the form of a full-wave rectifier. The modulator 15, to one input of which a modulating voltage is supplied from summing amplifier 14, and to the other - carrier voltage, removed from a high frequency generator 1, in combination with a high-frequency exciting winding 2 connected to its output, creates a high-frequency exciting field with a given periodic law of amplitude variation (Fig. 2 d). For a given normalized range of the intensity of dynamic partial cycles, according to the definition of a partial reversible cycle ((Itz --rr, where (Ot is the permeability on the private cycle, yI and jB is the span of intensity and corresponding increment of induction) for the time interval during which the private cycle is formed, is proportional to the value of permeability on a particular (or reversible) hysteresis cycle. The measuring channel, consisting of series-connected measuring winding 5, is broadband The cell 6, the synchronous detector 7 and the indicator 8 provide the selection of a periodic voltage proportional to the instantaneous values of the reversible magnetic permeability, and its observation and measurement. The specified cutoff interval on the control input of the synchronous detector 7 (the time interval during which the frequency cycle) is provided by a phase gage 10.,. Thus, for each high-frequency cycle, a voltage is generated at the output of the synchronous detector 7, the value of which is proportional to induction lv for this cycle. The broadband amplifier 6, which transmits the entire complex signal spectrum, matches the measuring circuit with the input of the synchronous detector 7. Either an electronic oscillograph can be used as an indicator 8, with which you can observe both the time dependence of the dynamic reversible magnetic permeability and its dependence on or a controlled amplitude voltmeter, which can be used to directly measure the instantaneous values of the reversible permeability. In both cases, a low-frequency control voltage is needed, which is generated by a voltage-generating unit 9 connected between the low-frequency generator 3 and the third indicator input 8. The proposed device, in which the amplitude of the high-frequency field is modulated according to law allows to obtain the normalized characteristics of the resulting private cycles and eliminates the disadvantages inherent in the basic object. . Thus, the main advantages of the proposed device are the normalization of specified conditions for the formation of dynamic private cycles, regardless of their location on the low-frequency hysteresis loop, improving the accuracy and reliability of measurement or control, the fundamental absence of conditions under which the private cycles disappear on the low-frequency loop. This is important because the lower bound on the frequency of the high-frequency field can be shifted to hundreds of hertz - units of kilohertz.

Claims (1)

DEVICE FOR MEASURING DYNAMIC REVERSIBLE MAGNETIC PERMEABILITY, comprising a high-frequency generator, a high-frequency exciting winding, a low-frequency generator with a low-frequency exciting winding connected to its output, a measuring winding connected in series, an amplifier and a synchronous detector, an indicator, the input to which is through the op forming unit connected to the second output of the low-frequency generator, and the control input of the synchronous detector through a phase detector is connected to the output of the generator A high frequency generator, characterized in that, in order to increase the measurement accuracy, it is additionally equipped with a reference voltage generator, connected in series with a quadrature phase detector, an absolute value extraction unit, a summing amplifier and a modulator, and the input of the quadrature phase detector is connected to the third output of the low voltage generator frequency, the output of the modulator is connected to the high-frequency exciting winding, the second input of the modulator is with the output of the high-frequency generator, the output of the reference voltage generator with It is connected with the second input of the summing amplifier, the output of the synchronous detector with the second input of the indicator, and the amplifier is made of broadband. Fig f C2 Ш660Т ^<П, Ж