SU864149A1 - Current-to-voltage converter - Google Patents

Description

The invention relates to a measuring technique and can be used in automation devices for converting alternating current into alternating voltage. A current to voltage converter is known, which contains an amplifier and a transformer with two secondary windings, one of which is connected to the input of the amplifier, and the second secondary winding of the transformer is connected to the output of the amplifier in parallel l. The disadvantage of this converter is the galvanic connection of the output to the power supply of the amplifier, which reduces the conversion accuracy due to the presence in the output signal of the voltage fluctuation of the power supply. A current-to-voltage converter is known, which contains a first transformer, the primary winding of which is connected to the input buses, the first amplifier, one input of which is connected to another input and to the common bus through the first secondary winding of the first transformer, and the output is connected to the common bus through serially connected the resistor and the secondary winding of the first transformer and through the first primary winding of the second transformer with the first input of the second amplifier, the second input of which is connected to the common bus, and the output from union of the common bus through a second primary winding of the second ransformatora m, the first terminal of the secondary winding of which is connected to the first output line 2. The disadvantage of this converter is the low conversion accuracy due to a decrease in the output voltage as the load current increases. The purpose of the invention is to improve the accuracy of the current-to-voltage converter. The goal is achieved by the fact that, in the current-voltage converter, the content of the first transformer, the primary winding of which is connected to the input buses, the first amplifier, one input of which is connected to the other input and the common bus through the first secondary winding of the first transformer, and the output co. it is uniform with the common bus through series-connected resistor and the second secondary winding of the first transformer and through the first primary winding of the second transformer with the first input of the second amplifier, the second input of which is connected to. common bus and the output is connected to the common bus through the second primary winding of the second transformer, the first output of the secondary winding of which (connected to the first output bus, the second output bus connected to the second output of the secondary winding of the second transformer through the additional secondary winding additionally to the first transformer .

The drawing shows a current to voltage converter circuit,

 The current-to-voltage converter contains a transformer 1 with secondary windings 2-4 and primary winding 5 connected to input buses, an amplifier 6, one input of which is connected to another input and a common bus through a secondary winding 2, amplifier 7, transformer 8, with the primary windings 9 and 10 and the secondary winding 11, one output of which is connected to the first output bus, and the second output to the second output bus through the secondary winding 4, the output of the amplifier 7 is connected to the common bus through the primary winding 9, one input - with the common bus and another entrance - with the output of the amplifier 6 through the primary winding 10, the output of the amplifier b is connected to the common bus through a series-connected resistor 12 and the secondary winding 3,

The current-to-voltage converter operates as follows.

Convertible current (supplied to the primary winding 5, transformer 1. Magnetic-motive signal (MDS) is generated by the current in the core of the transformer 1, Difference (MDS) in the core of the transformer 1 creates a magnetic flux error. This magnetic flux induces an emf in the winding 2 of transformer 1, which is connected at the input of amplifier 6. The voltage of the honey clamps of winding 2, amplified by amplifier 6, creates a current in the circuit consisting of series-connected windings 3 and resistor 12. With a high gain factor of amplifier 6, MDS created by currents windings 2 and 3 are almost equal. And the current in the compensation winding 3 follows the law of current variation in steady state 3. The output voltage of amplifier 6 is equal to the sum of the voltage drops on the resistance of winding 3 and on the resistance of resistor 12. With a large gain factor of 6 in steady state, the magnetic flux in the core of the transformer 1 is negligible. If we ignore this magnetic flux and parasitic parameters of the winding 3, the output voltage of the amplifier b is equal to the sum of the voltage drops across the active resistance winding 3 and the resistance of the resistor 12. Therefore, the voltage U follows the law of change of current I. Thus, the cascade assembled on transformer 1 and amplifier 6, works as a current converter I to voltage and. The voltage difference U and EMF induced in the winding 10 of the transformer 8 is fed to the input of the amplifier 7, the output of which is connected to the winding 9. The current in this winding creates a magnetic flux in the core of the transformer 8, which induces an emf in the winding 10. At enough

5, the high gain of the amplifier 7, the emf induced in the winding 10, practically balances the voltage and and the error voltage supplied to the input of the amplifier 7 will be negligible. In this case, the EMF in the winding 10 and the same in the winding 11 follows the law of voltage variation. And the EMF in the winding 11 forms the output signal of the Converter. Consequently, a cascade consisting of amplifier 7 and transformer 8 converts voltage 0 into electromotive voltage, driven in winding 11. To compensate for the dependence of the output voltage on the load current in series with winding 11 of transformer 8

BJ (switch 4 winding of transformer 1. This winding forms positive current feedback: MDS created by currents in windings 5 and 4 have

5 in the same direction. As a result, an increase in the load current leads to an increase in the current in the compensation winding 3, and thus to an increase in the voltage tf. And this

0 causes an increase in emf in the winding

11. Therefore, in the presence of winding 4, depending on the magnitude of the load current, the current transfer ratio — the electromotive voltage of the winding 11 — varies. By selecting the number of turns of the winding 4,

 to fully compensate for the effect of the load impedance on the output voltage of the converter Tsz ..

The use of a converter in 0 automation devices and measuring equipment allows to increase the accuracy of conversion when changing over a wide range of load current.

Claims (2)

1. Author's certificate of the USSR 1 721755, cl. 6 01 R 19/10, 1977. 2. Measuring equipment, 1975, No. 1, s, 73 (prototype).