SU1352424A1 - Device for testing induction traction motor with short-circuited rotor - Google Patents

Abstract

The device for testing an asynchronous traction motor (D) with a squirrel-cage rotor contains load generators (G) 2, 4, drive motors D 3, 6, booster booster G 5, mechanical and electrical connecting nodes 7, 8, respectively. The invention saves energy during testing, extends the functionality of the device and increases the reliability of the test results. 1 il. . (L oo 01 Yu 4 to 4 i f--) L S I r- kv

Description

This invention relates to electrical test engineering and can be used to test high-power asynchronous motors with a short-circuited rotor.

The purpose of the invention is to save energy during testing by using auxiliary electric machines with less energy consumption, expanding the functionality by expanding the frequency range of the test and increasing the reliability of the test results as a result of reducing the time required for the induction motor to be tested.

The drawing shows a diagram of the device.

The device contains the test asynchronous motor 1, the first load generator 2, the first drive motor 3, the second load generator 4, booster generator 5, the second drive motor 65 and also the mechanical 7 and electrical 8 connecting nodes, the mechanical connecting node 7 being rigidly fixed on the shaft of the first load generator 2, the shaft of the first. drive motor 3 is mechanically connected to the shaft of the second load generator 4, the first terminals of the main windings of the booster generator 5 and the first drive motor is connected to the common bus, and their second leads are connected respectively to the first and second terminals of the primary winding of the first load generator 2, the shaft of the second drive motor 6 is mechanically connected to the wAir of the additional booster generator 5, and connected to the respective terminals of the electrical connection assembly 8,

The device works as follows.

The second drive motor 6 by applying voltage to the windings is driven to rotate. The excitation windings of the first drive motor 3 and booster generator 5 are successively supplied with voltage. Thus, the drive motor 3 comes to rotate. By turning on the voltage on the excitation winding of the second load generator 4, the asyn test subject is rotated.

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Claims (1)

a chronny electric motor 1, the measles of which are articulated to the crust of the first load generator 2, As the asynchronous electric motor 1 is accelerated, the power consumed by it increases; consequently, the frequency of rotation of the first drive motor 3 and the frequency of the output voltage of the second load generator 4 fall. By increasing the excitation of the booster generator 5, the frequency of rotation of the first drive motor 3 rises to the desired value. Turning on the excitation of the first load generator 2 with the subsequent increase in its excitation current from zero to a value corresponding to the required load of the test asynchronous electric motor 1, presetting of the required mode is provided. The final setting of the required test mode parameters for the asynchronous motor 1 (frequency, voltage, slip, etc.) is made by adjusting the excitation. Invention Formula A device for testing an asynchronous traction motor with a short-circuited rotor, containing its electrical and mechanical connecting nodes, the first and second load generators, the first and second drive motors, the mechanical connecting node is rigidly fixed to the shaft of the first load generator, the shaft of the first drive motor mechanically connected to the shaft of the second load generator, characterized in that, in order to save energy during testing, to expand the functionality and increase the ernosti test results, it Bytes introduced buck generator, wherein the first terminals of windings of the anchor and first buck generator drive motor connected to the common bus, and the second of them. The views are connected respectively to the first and second terminals of the core winding of the first load generator, the shaft of the second drive motor is mechanically connected to the shaft of a volt g additional generator, and the phases of the stop winding of the second load generator are connected to the corresponding terminals of the electrical connection node. 35 0 0