RU71443U1 - DEVICE FOR DETERMINING INSTANT VALUES OF SINGLE-PHASE TRANSFORMER MAGNETIZATION INDUCTIVITY - Google Patents

Abstract

The utility model relates to the field of electromechanics, namely the use of information processing tools in electromechanics, and can be used to determine the instantaneous values of the magnetization inductance of a single-phase transformer in operating mode or in idle mode. The objective of the utility model is to create a device for determining the instantaneous values of the magnetization inductance of a single-phase transformer in operating mode or in idle mode. The task is achieved in that a reduction unit is connected to the control object, which is connected to a difference calculation unit and an averaging unit, the outputs of which are connected to a resistance determination unit, to which a voltage calculation unit, a differentiation unit and an average inductance unit are connected, the outputs of which are connected to an inductance calculation unit, wherein the resistance determination unit is connected to the inductance calculation unit.

Description

The utility model relates to the field of electromechanics, namely to the use of information processing tools in electromechanics, and can be used to determine the instantaneous values of the magnetization inductance of a single-phase transformer in operating mode or in idle mode.

No known device for determining the instantaneous values of the magnetization inductance of a single-phase transformer.

The objective of the utility model is to create a device for determining the instantaneous values of the magnetization inductance of a single-phase transformer in operating mode or in idle mode.

The task is achieved in that a reduction unit is connected to the control object, which is connected to a difference calculation unit and an averaging unit, the outputs of which are connected to a resistance determination unit, to which a voltage calculation unit, a differentiation unit and an average inductance unit are connected, the outputs of which are connected to an inductance calculation unit, wherein the resistance determination unit is connected to the inductance calculation unit.

Due to the fact that the claimed device contains a reduction unit, a difference calculation unit, an averaging unit, a resistance determination unit, a voltage calculation unit, a differentiation unit, an average inductance unit and an inductance calculation unit, it allows determining instantaneous values of the magnetization inductance of a single-phase transformer.

Figure 1 - shows a hardware diagram of a device for determining instantaneous values of the magnetization inductance of a single-phase transformer.

A device for determining the instantaneous values of the magnetization inductance of a single-phase transformer (Fig. 1) contains a reduction unit 1 (BPR), a difference calculation unit 2 (BVR), an averaging unit 3 (BUS), a resistance determination unit 4 (BFB), a voltage calculation unit 5 ( BVN), differentiation block 6 (DB), medium inductance block 7 (BSI) and inductance calculation block 8 (BVI).

The input of the cast unit 1 (BPR) is connected to a transformer (not shown in FIG. 1). The corresponding outputs of the casting unit 1 (BPR) are connected to the input of the difference calculation unit 2 (BWR) and to the input of the averaging unit 3 (BCF), the outputs of which are connected to the input of the resistance determination unit 4 (BFB). To block calculation of resistance 4 (BFB)

in parallel, a voltage calculation unit 5 (BVN), a differentiation unit 6 (DB) and a medium inductance unit 7 (BSI) are connected, the outputs of which are connected to the inductance calculation unit 8 (BVI). In this case, the resistance determination unit 4 (BFB) is also connected to the inductance calculation unit 8 (BVI). The output of the inductance calculation unit 8 (BVI) is connected to a segment indicator not shown in FIG.

Reduction unit 1 (BPR), difference calculation block 2 (BVR), averaging block 3 (BUS), resistance determination block 4 (BFB), voltage calculation block 5 (BVN), differentiation block 6 (DB), medium inductance block 7 ( BSI) and inductance calculation unit 8 (BVI) can be performed on the atmel AT89S53 series 51 microcontroller.

The primary winding W _{1 of a} single-phase transformer is supplied with an input voltage u _BX (t) with a frequency f, and the secondary winding W _{2 is} connected to a load Z _H. The current i ₂ (t) - In this case the current i ₁ (t), on the secondary flows in the primary winding of the transformer. The voltage on the secondary winding is u _H (t).

Arrays of instantaneous values of the input and output currents i ₁ (t) and i ₂ (t) and voltages u _BX (t) and u _H (t) with time discreteness Δt, which corresponds to the number of samples on the period N, obtained for time instants

t _j = t _j-1 + Δt,

arrive at the input of the cast unit 1 (BPR). In the block unit 1 (BPR), the secondary current and output voltage lead to the primary circuit

Then simultaneously arrays of instantaneous values of the input current | i ₁ (t _j ) | and reduced output current the difference calculation unit 2 (BVR) is input and the arrays of instantaneous values of the input and reduced output voltages | u _BX (t _j ) | and arrive at the input of the averaging block 3 (BUS).

In the block for calculating the difference 2 (BVR) calculate the array of instantaneous values of the magnetization current of the transformer, shown in table 1

In the block averaging 3 (BC) determine the array of instantaneous values of the magnetization voltage

An array of instantaneous values of the magnetization voltage | u ₀ (t _j ) | and an array of instantaneous values of the magnetization current | i ₀ (t _j ) | simultaneously enter the input of the resistance determination unit 4 (BOS).

In the block for determining the resistance 4 (BOS) determine the active loss of magnetization

Then determine the effective value of the magnetization current

and calculate the resistance of the magnetizing branch

Arrays | u ₀ (t _j ) |, | i ₀ (t _j ) | together with the value of the active resistance R ₀ simultaneously enter the input of the voltage calculation unit 5 (BVN), the inductance calculation unit 8 (BVI), the differentiation unit 6 (DB) and the medium inductance unit 7 (BSI).

Then, simultaneously, in the voltage calculation unit 5 (BVN), the instantaneous values of the inductive component of the magnetization voltage of the transformer are determined

u _L (t _j ) = u ₀ (t _j ) -i ₀ (t _j ) R ₀ ,

and the array | u _L (t _j ) | arrives at the input of the inductance calculation unit 8 (BVI). In the differentiation unit 6 (DB), the magnetization current i ₀ (t _j ) is differentiated and an array of instantaneous values of the derivative of the specified current with respect to time is obtained

which goes to the input of the inductance calculation unit 8 (BVI). In the block of medium inductance 7 (BSI) determine the loss of reactive magnetization power

Where - the area of the current-voltage characteristics u ₀ (i ₀ ), determine the value of the inductive magnetization

and the corresponding value of the average magnetization inductance

where ω = 2πf is the cyclic frequency of the alternating current. The obtained value L _{0CP is} fed to the input of the inductance calculation unit 8 (BVI).

Then, in the block for calculating the inductance 8 (BVI), the instantaneous values of the magnetization inductance are determined by the formula

using numerical differentiation. In this case, the following numerical integration algorithm can be used. First find an intermediate array | m (t _j ) | values of the integral at points 1 ... N, whose constant component is not equal to zero. For this, it is assumed that | m (t _j ) | = 0. Values | m (t _j ) | at other points calculated by the formula:

Where - integrand. This array has some constant component. Therefore, they then find an array of instantaneous values of the magnetization inductance L ₀ (t _j ) at points 1 ... N, subtracting from the array | m (t _j ) | its constant component M and adding L _0CP :

L ₀ (t _j ) = m (t _j ) -M + L _0CP ,

Where is the average value of the array | m (t _j ) | over a period.

Thus, the proposed method made it possible to determine the instantaneous values of the magnetization inductance L ₀ (t _j ) of a single-phase transformer in operating mode.

Claims (1)

A device for determining the instantaneous values of the magnetization inductance of a single-phase transformer, characterized in that a reduction unit is connected to the transformer, which is connected to a difference calculation unit and an averaging unit, the outputs of which are connected to a resistance determination unit, to which a voltage calculation unit, a differentiation unit and a unit are connected in parallel medium inductance, the outputs of which are connected to the inductance calculation unit, and the resistance determination unit is connected to the calculation unit induction.