RU89714U1 - DEVICE FOR DETERMINING FREQUENCY OF CURRENT ROTOR CURRENT OF ASYNCHRONOUS MOTOR - Google Patents

Abstract

A device for determining the frequency of the rotor current of an induction motor, characterized in that the first signal sensor is connected to the first phase of the stator of the induction motor, to which the programmer for determining the module of the resulting stator current vector module, the first programmer for discrete Fourier transform, the first programmer for selecting the main frequency and the programmer for determining rotor current frequency, which is connected either to the display or to the computer, while the second signal sensor connected to the second phase of the stator an asynchronous motor and a third signal sensor connected to the third phase of the stator of the asynchronous motor are connected to the programmer for determining the module of the resulting stator current vector, and the second discrete Fourier transform programmer, the second fundamental frequency extraction programmer and the rotor current frequency determination programmer are connected to the first signal sensor.

Description

The utility model relates to electrical engineering, mainly to electric machines and measuring equipment, designed to determine the frequency of the rotor current of an induction motor.

Analogues of the device for determining the frequency of the rotor current of an induction motor are unknown to the authors.

The objective of the utility model is to create a device for determining the frequency of the rotor current of an induction motor.

According to a utility model, in a device for determining a rotor current frequency of an induction motor, a stator current result vector module programmer, a first discrete Fourier transform programmer, a first fundamental frequency allocation programmer and a rotor current frequency frequency programmer that is connected either to a display or with a computer. The second signal sensor connected to the second phase of the stator of the induction motor and the third signal sensor connected to the third phase of the stator of the induction motor are connected to the programmer for determining the module of the resulting stator current vector. A second discrete Fourier transform programmer, a second fundamental frequency allocation programmer, and a rotor current frequency determination programmer are sequentially connected to the first signal sensor.

The proposed technical solution is quite simple in design.

Figure 1 shows a diagram of a device for determining the frequency of the rotor current of an induction motor.

A device for determining the frequency of the rotor current of an induction motor contains a first signal sensor 1 (DS1) connected to the first phase of the stator of the induction motor. The first sensor of signal 1 (DS1) is connected in series with the programmer for determining the module of the resulting current vector of stator 2 (PMRVTS), the first programmer of discrete Fourier transform 3 (PDPF1), the first programmer for selecting the main frequency 4 (POCH1) and the programmer for determining the frequency of rotor current 5 (ПЧТР ), which is associated with a display or computer (not shown in figure 1). The second signal sensor 6 (DS2) is connected to the second phase of the stator of the induction motor. A programmer for determining the module of the resulting stator current vector 2 (PMRVTS) is connected to the second signal sensor 6 (DS2). The third signal sensor 7 (DS3) is connected to the third phase of the stator of the induction motor. The third signal sensor 7 (DS3) is connected to the programmer for determining the module of the resulting current vector of stator 2 (PMRVTS). A second discrete Fourier transform programmer 8 (PDPF2), a second fundamental frequency allocation programmer 9 (POC2) and a rotor 5 current frequency frequency programmer (PTCR) are connected in series to the first signal sensor 1 (DS1).

As signal sensors 1 (ДС1), 6 (ДС2) and 7 (ДС3) current sensors can be used - an industrial device KEI-0,1. The programmer for determining the module of the resulting stator current vector 2 (PMRVTS), the programmers for discrete Fourier transforms 3 (PDPF1) and 8 (PDPF2), the programmers for extracting the fundamental frequency 4 (POCH1) and 9 (POCH2), the programmer for determining the frequency of the rotor current 5 (PCTR) be performed on a microcontroller series 51 manufactured by amtel AT89S53.

From the outputs of the signal sensors 1 (ДС1), 6 (ДС2) and 7 (ДС3), the signals are fed to the inputs of the programmer for determining the module of the resulting stator current vector 2 (PMRVTS), where the module of the resulting stator current vector is determined by the formula

where - i _a , i _b , i _c - instantaneous currents of the stator windings.

Then, simultaneously, in the discrete Fourier transform programmers 3 (PDPF1) and 8 (PDPF2), a discrete Fourier transform of the module of the resulting vector of stator current and current of one of the supply phases is performed, where the amplitude-frequency characteristics of the signals received at the inputs of the programmers for selecting the main frequency 4 ( POC1) and 9 (POC2), respectively, where the main frequency component f _{s0 of the} module of the resulting stator current vector module and the main, with the largest amplitude, component of one of the stator currents with frequency f _c mains supply. Next, the selected main frequencies are fed to the inputs of the programmer for determining the frequency of the rotor current 5 (PCTR), where the rotor current frequency is determined by the formula

_{f p = f c -2 · f} s0

and it is either transmitted to a computer or displayed.

Claims (1)

A device for determining the frequency of the rotor current of an induction motor, characterized in that the first signal sensor is connected to the first phase of the stator of the induction motor, to which the programmer for determining the module of the resulting stator current vector module, the first programmer for discrete Fourier transform, the first programmer for selecting the main frequency and the programmer for determining rotor current frequency, which is connected either to the display or to the computer, while the second signal sensor connected to the second phase of the stator an asynchronous motor and a third signal sensor connected to the third phase of the stator of the asynchronous motor are connected to the programmer for determining the module of the resulting stator current vector, and the second discrete Fourier transform programmer, the second fundamental frequency extraction programmer and the rotor current frequency determination programmer are connected to the first signal sensor.