SU892381A1 - Device for measuring magnetic induction - Google Patents

Description

The invention relates to electrical engineering and can be used to determine magnetic induction in the air gap. Asynchronous motors.

A known measuring installation, which consists of a probe with an integrated Hall sensor, a vector meter, a differential amplifier, an oscilloscope, a recording device and an angle sensor of rotation of the probe along the air gap Clj.

The known installation allows you to record directly the voltage of the Hall sensor CD (<£), proportional to the induction in the air gap. However, voltage measurement requires a lot of labor, since it is taken away separately for tot = 0 and for ω t = ^. The initial reference point of the recorded curves is set using a vector meter and an oscilloscope. This definition of a reference point is inaccurate due to the subjectivity of the operator.

The purpose of the invention is to increase the accuracy of determining magnetic induction.

This goal is achieved by the fact that in the device for measuring magnetic induction in the air gap of electric motors containing a magnetic induction sensor, measuring and recording units, the measuring unit is made in the form of series-connected reference voltage shaper, phase shifter and shaper of two voltage perpendicular in time, the first output which is connected to the reference input of the first phase-sensitive meter, and the second to the same input of the second phase-sensitive meter voltage, and the sensor is connected to the second inputs of the first and second phase-sensitive voltage meters connected to the inputs of the recording unit.

get two folk relative to which are served the first and second dimensions 5 and 6

The drawing shows a block diagram of a device for determining magnetic induction in the air gap of an induction motor.

The device consists of a sensor 1, a shaper 2 of the reference voltage, a phase shifter 3, a shaper 4 of two reference voltages perpendicular in time, two phase-sensitive meters 5 and 6, and a two-channel recording device 7.

The device operates as follows ..

A voltage is applied from the former 2 of the reference voltage to the phase shifter 3, the frequency of which corresponds to the frequency of the time harmonic of the magnetic induction of interest in the air gap of the electric motor. Phase shifter 3 rotates the voltage at the desired time angle wt, at which the U ^ cL curve is recorded, and is fed to the input of the shaper 4 of two reference voltages, at the output of which the stresses shifted by the other = i are applied to the phase-sensitive voltage reference inputs. The measured signal 1 ^, directly proportional to the induction in the air gap of the electric motor, from the sensor 1 is fed to the second inputs of the phase-sensitive voltage meters 5 and 6. Signal 1) d at the output of the phase-sensitive voltage meter 5 is represented by the projection onto the reference voltage npnLut = 0, and at the output of the phase-sensitive voltage meter 6 is represented by the projection onto the reference voltage when £ - ^ - ..

Slowly moving the sensor. Along the air gap of the electric motor j, the voltage of the ID sensor changes in magnitude and phase, and at the outputs of the phase-sensitive measurements 5 ^and 6 the voltages obtain continuous curves l ^ Wnpw wi = 0 πυ ^, Ιά.) device 7.

Since the quality of the electric motor is determined by the directly and backward rotating components of each U-th spatial harmonic magnetic induction in the air gap В U _n p and Βυ _οδ · _ρ , which according to the well-known method can be easily calculated from the curves; UzcLujt = O and then using the setting “o” 5

SO well, with access to a computer, you can ultimately get a spectrum of rotating components of magnetic induction in the air gap of an induction motor.

Using the proposed device can reduce the complexity of determining the distribution of magnetic induction along the air ι gap, since the whole process of determining U _A (<i) ujt = O and Cd (cl) ujt = usually lasts no more than one minute, while the sensor using a special device makes one revolution along. air gap of the tested motor. During this time, the tested motor does not have time to warm up and its parameters remain virtually unchanged, as a result of which an increase in accuracy is achieved ₍ Shaper 2 of the reference voltage and phase shifter 3 allow you to quickly and accurately set the desired frequency and phase of the reference voltage, and shaper 4 accurately decomposes it into two perpendicular reference voltages, excluding subjective error.

The use of the installation in combination with a computer allows automatic, ’’ design of asynchronous motors. j

Claims (1)

The invention relates to electrical engineering and can be used to determine the magnetic induction in an air gap. Synchronous electric motors. The known measurement setup, which consists of a probe with a built-in Hall sensor, a vector meter, a differential amplifier, an oscilloscope, a recording device and a probe rotation angle sensor along the CO air gap. The known setup allows you to record the Hall sensor voltage U (ci), proportional to the induction in the air gap. However, voltage measurement requires a lot of work, since U C is taken separately with (and with UJ. The initial reference point of the recorded curves is set using a vector meter and an oscilloscope. This definition of the reference point is inaccurate due to the subjectivity of the operator. accuracy of magnetic induction. The goal is achieved by the fact that, in a device for measuring magnetic induction in the air gap of electric motors j, there is a magnetic induction sensor measuring and recording The main unit, the measuring unit are made in the form of serially connected reference voltage generator, phase shifter and two voltage generator perpendicular in time, the first output of which is the connection of the reference input of the first phase-sensitive meter, and the second with the same input of the second phase-sensitive voltage meter, and the sensor connected to the second inputs of the first and second phase-sensitive voltage meters connected to the inputs of the recording unit. 3 The drawing shows a block diagram of a device for determining the magnetic induction in an air gap of an induction motor. The device consists of a sensor 1, a driver 2 of a reference voltage, a phase shifter 3, a driver A two perpendicular in time of the reference voltages, two phase-sensitive meters 5 and 6 of the voltage and a two-channel recording device 7. The device works as follows From the former 2 of the reference voltage The voltage on the phase shifter 3 is applied to a voltage whose frequency corresponds to the frequency of the time harmonic of magnetic induction of interest in the air gap of the electric motor. The voltage phase shifter 3 rotates to the desired time angle uut, at which the UdS circuit is recorded, and is fed to the input of the C driver of two reference voltages, at the output of which two voltages are received, shifted one to the other Haujt-, which are applied to the reference inputs the first and second phase-sensitive measurements of voltage 5 and 6. The measured signal (directly proportional to the induction in the air gap of the electric motor, from sensor 1 is fed to the second inputs of phase-sensitive voltage meters 5 and 6. The signal U at the output of the phase-sensitive voltage meter 5 is projected onto the reference voltage npMjt 0, and the output of the phase-sensitive meter 6 voltage - by the projection on the reference voltage npHujt. Slowly moving the sensor. of the air gap of the electric motor j the voltage of the sensor U varies in magnitude and phase, and at the outputs of the phase-drain Measurements 5 and 6 of the voltage are obtained by continuous curves u) iid (a1) coming, which are recorded by a two-channel recording device. Since the quality of an electric motor is determined by direct and reverse rotating components of each U-th spatial harmonic magnetic induction in the air gap B and BUo $ -p, which, using the well-known method, can be easily calculated from the lUicLuut O and ° curves using a computer with output to a computer, you can ultimately obtain a spectrum of rotating magnetic induction components. onnogo motor. The use of the proposed device reduces the laboriousness of determining the distribution of nitric induction along the air gap, since the whole process of determining Od (i) and Dsd (ct) u) t | - usually lasts no more than one minute while the sensor makes one turn with a special device along the air gap of the engine being tested. During this time, the electric motor does not have time to heat up. C and its parameters remain practically unchanged, as a result of which an increase in accuracy is achieved. The shaper 2 of the reference voltage: e1ni and the phase shifter 3 allow you to quickly and accurately set the desired frequency and phase of the reference voltage, and the shaper k accurately decomposes it into two perpendicular voltage: NOx voltage, excluding the subjective error. The use of the installation in combination with a computer allows for automated design of asynchronous electric motors. j The invention The device for measuring the magnetic induction in the air gap of induction motors, containing a magnetic induction sensor, measuring and recording units, distinguished by the fact that, in order to improve the accuracy of determining the magnetic induction, the measuring unit is designed as a serially connected reference generator voltage, phase shifter and driver of two voltages perpendicular in time, the first output of which is connected to the reference input of the first phase-sensitive measurement erator voltage, and the second to the same input of the second phase-sensitive voltage meter, wherein the sensor is connected to the second inputs of the first and second phase sensitive gauges voltage, connected with the inputs of the recording unit. Sources of information taken into account in the examination 1. Electrical machines and apparatus. Express information .. M.., 1976, W 19, p.3-18.