SU789973A1 - Device for plotting dynamic inductance characteristics - Google Patents

Description

I

The invention relates to electrical engineering Nick and is used to determine the dynamic inductance characteristic of direct current electromagnetic elements when the excitation winding is released by shunting.

Devices for capturing dynamic characteristics are known, which include a core displacement sensor and a computational circuit D1. Also known are apparatus for capturing dynamic characteristics comprising a core displacement load cell and a computation circuit G and Z.

The closest to the one proposed by the technical essence is a device for capturing dynamic characteristics, containing a core position sensor, a computational circuit, and an electron-beam oscilloscope with memory, 0

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However, due to the fact that the core position sensor is placed on the movable part of the magnetic system, there is an increase in mass, the core itself, especially significant with its insignificant mass, which in turn creates errors in constructing the inductance characteristic of the electromagnetic element of a constant current. . .

The purpose of the invention is to improve the measurement accuracy and reliability of the device.

Claims (4)

The goal is achieved by the fact that a power source and a shunt resistor are interconnected in parallel and intended to be connected to the excitation winding of a direct current electromagnetic element, the core position sensor is made as a Hall element, and the computational circuit in the form of two dividing and differentiating and integrating RC circuits, while the input of the Hall element is connected to an autonomous power source, and the output to the input of one of the division units, which by its output through the integrating RC circuit The plug is connected to one of the inputs of the electron-beam oscilloscope with memorization, the input of another division unit is connected to another input of the same division unit, the other input of the latter is connected to the output differentiating the HC circuit, and the output is connected to another input of the electron-emitting-oscilloscope with memory This input differential circuit is connected in parallel to the shunt resistor. FIG. 1 is a schematic diagram of the device; in fig. 2 - an approximate form of the characteristic. . The device consists of a direct current electromagnetic element EL of the differentiating velocity chain of change of magnetic flux coupling T. C, the first dividing unit, the sensor of the position of the core DL, the second dividing unit, the integrating path chain Pro Cjj and the electron-beam oscilloscope with ELO memory. In addition, the device contains I - the measles of the electromagnetic element, C - the core of the electromagnetic element, WU - the upper stop, NU - the lower stop, PP - the counteracting spring, OB - the excitation winding of the electromagnetic element, K - the switch (switch, I - shunting ohmic resistance , C is the capacitance of the differentiating chain of the rate of change of the magnetic flux linkage, RCJ is the ohmic resistance of the differentiating chain of the rate of change of the magnetic flux linkage, R: control ohmic resistance in the control circuit nor Hall meter, ECH,., - power source in the load circuit of the meter lol la, Rpyu - adjusting resistance in the load circuit of the Hall meter, Cij - capacity of the differentiating chain of speed of change of magnetic flux, Rcohmic resistance of the differentiating chain of speed of change of magnetic flux linking, power source. Description of the device in static such an anchor of the electromagnetic element is pulled to the bottom stop. A power supply and a shunt ohmic resistance are connected in parallel to the field winding. A shunt ohmic resistance is connected to the input of the differentiating chain, the rate of change of the magnetic flux linkage, the second input of the first dividing unit (dynamic inductor of activity) and the first input of the second dividing unit (speed). The core position sensor with a Hall meter is located on the core. The control ohmic resistance and the power source in the load of the Hall meter are connected in series. A control ohmic resistance is included in the control circuit of the Hall meter. The load circuit of the Hall meter is connected to the second internal air traffic control of the second dividing unit. The output of the second dividing unit is connected to the output of the integrating path chain. The output of the integrating chain path is connected to the first input (abscissa axis) of the electron-beam oscilloscope with memory. The output of the first dividing unit is connected to the second input (ordinate axis) of the electron-beam oscilloscope with memory. The device works as follows. When the switch is turned off, the magnetic flux linkage begins to decrease and the measles of the electromagnetic element under the influence of the return spring begins to move away from the lower stop to the upper stop. In this case, the device operates dynamically and is described by dynamic equations. A voltage proportional to the magnetic flux coupling time is removed from the shunt ohmic resistance and fed to the first inputs of the first division unit of the dynamic division inductance of the second unit, as well as to the input of the differentiating magnetic flux chain, which is removed from the output voltage proportional to the rate of current change An excitation field OB of the electromagnetic element of the direct current EL and is fed to the second input of the first dividing unit. Voltage proportional to magnetic induction is removed from the load meter of the Hall meter of the QA position sensor and is supplied to the second input of the second dividing unit from which the voltage is removed proportional to the speed of the integrating circuit pathway C, which is removed from the output of the path ( displacement), the core of the electromagnetic element of the direct current EL and is fed to the first input (abscissa axis) of the electron-beam oscilloscope with an ELO memory, to the second input of which (axis nat) a voltage is supplied from the output of the dynamic inductance divider, which is proportional to the dynamic inductance of the electromagnetic elements when the bypassing of the excitation winding is released. Invention Formula A device for characterizing dynamic inductance for direct current electromagnetic elements when shunting is released to an excitation winding, comprising a psx core sensor, a computational circuit and an electron-beam oscilloscope with memory, characterized in order to improve accuracy and reliability, it contains a power source and a shunt resistor interconnected in parallel and intended to be connected to the field winding, the core position sensor is made as a Hall element, and The slanted circuit is in the form of two division blocks, differentiating and integrating RC-iienoH, while the input of the Hall element is connected to an independent power source, and the output is connected to the input of one division block, which is connected to one of the the inputs of the oscilloscope, the input of another division unit is connected to another input of the same division unit, the other input of the latter is connected to you to the differentiating RC circuit, and the output to another input of the electron-beam oscilloscope with memory, and the input of the differentiating circuit is connected in parallel with the shunt resistor. Sources of information taken into account during the examination 1. USSR Author's Certificate No. 325597, cl. q 05 B 23/02, 1970. 2. USSR author's certificate No. 595707, cl. Q 05 B 23/02, 1976. 3. Determination of the dynamic characteristics of the contact of alternating current, M., Electrosila, 1970, No. 28. 4. USSR author's certificate No. 164362, cl. g 05 23/02, 1963.