SU598139A1 - Ratio transformer - Google Patents

Description

(54) TRLNSTFOT LTOR OG1 OSHB: NIY

The invention relates to electrical measuring equipment and can be used in ac bridges for measuring capacitance, inductance and resistance, as well as in other devices where it is required to have an exactly known ratio of two or more voltages. A relationship transformer is known, consisting of a magnetic conductor, a primary winding, secondary windings and a permalle screen between the primary and secondary windings 1. The toroidal magnetic pipe is made of a permallo tape, thermally processed and induced in a protective housing. The primary winding is placed on a protective case. The magnetic core with the primary winding razmepde) in the screen of permallo. Secondary windings are placed on top of the screen. The coils of the secondary windings are connected in series and together form the secondary windings. The disadvantage of the device is its considerable complexity of verification. The transformer of relations is known, which contains the magnetic core, the primary and sectional secondary windings, shielded along the entire length of the windings, the screens of which are connected to the collar lO-iKi.iii of the secondary windings 2. accuracy of calibration. The purpose of the invention is 11 (1: p51 verification accuracy. For this purpose, the ratio transformer is equipped with a protective voltage transformer with one primary and secondary secondary windings, a switch, an adjustable voltage divider and an additional secondary winding of a transformer with two concentric screens) which is located on the magnetic circuit of the transformer of relations, the middle point of the outer screen is connected to the common point of the secondary windings of the transformer. The primary winding of the transformer The protective voltage transformer is connected in parallel to the primary winding of the transformer, the common point of the two secondary windings of the protective voltage transformer is connected to the common point of the secondary transformer windings one output of the third secondary winding, between

the second output of which is the common point of the first two secondary windings of the protective voltage transformer. And the adjustable voltage divider is turned on, the midpoint of which is connected to the middle of the internal screen of the additional winding of the transformer ratio; the number of turns of the secondary secondary winding of the transformer relations is equal to the number of turns of the sections of the two first secondary windings of the transformer relations; the number of sections of the secondary windings of the protective voltage transformer is equal to the number of sections of the secondary windings of the transformer ratio; The third secondary winding of the protective voltage transformer contains the number of turns equal to half the number of turns of the sections of the first two secondary windings of the same transformer, and the ratio of the numbers of turns of the secondary windings of the protective voltage transformer to the number of turns of its primary winding is greater than the same ratio for the transformer ratios; An adjustable voltage divider contains conL M and T resistors together.

The mache () tezhe is given a schematic of the proposed transformer of fumes.

The proposed transistor relation with; The magnetic conductor I, on which the winding 2 and the secondary windings 3 and 4 are located, is located on the windings of the latter but of the entire length, for example, they are made of shielded wire and partitioned. All sections have the same number of turns. Screens 5 and 6 are connected to the common point 7 of secondary windings 3 and 4. With this switch on, screens 5 and b form the windings of equipotential protection for windings 3 and 4, which allows to significantly reduce the error of windings 3 and 4 from inter-turn capacitive currents. From all sections of windings 3 and 4 and from the screens conclusions 8-14 were made.

Relationship transformer contains six sections. On the magnetic core I there is also a section of the reference voltage with the number of turns equal to the number of turns of the sections of the secondary windings 3 and 4, the section consists of an internal wire 15 and two concentric shields 16 and 17 protecting the wire 15 along its entire length.

The protective voltage transformer consists of a magnetic circuit 18, a primary winding 19 connected to the primary winding 2 of the transformer ration, and three secondary windings 20, 21 and 22. The secondary windings 20 and 21 have the same number of sections as the secondary windings 3 and 4 of the transformer . The number of turns in all sections of the windings 20 and 21 is the same. The common point of the windings 20 and 21 is connected to the circuit; the point 7 of the windings 3, 4 and 5, 6 is connected to it. The third secondary winding 22 has the number of turns equal to half the number of turns of the sections of the windings 20 and 21, which have pins 23-29. The switch 30 is connected to the winding 22, and its movable contact is connected to the terminals 23-29 of the secondary windings 20-21. The second terminal of the winding 22 is connected to a voltage divider consisting of a constant capacitor 31 and

a resistor 32 connected in series with a variable capacitor 33 and a resistor 34. The middle point of the divider is connected to the middle of the inner screen 16, and the middle of the outer screen 17 and pins 33 and 34 are connected to a common point 7.

In addition, the transformer contains a generator 35 and the indicator 36.

Transformer relations works as follows.

When the generator 35 is turned on, all the windings 20, 21 and 22 of the transformer of the ratios and the windings 3-6, 15, 16 and 17 of the protective voltage transformer appear. To calibrate the transformer relations, it is necessary to connect the winding 15 oppositely to each section of windings 3 and 4 through the indicator 36, which shows the voltage difference. Knowing the voltage difference between all sections of windings 3 and 4 and winding 15, determine the ratios of the voltages of all sections to the voltage of the winding 15. After that, determine the ratios of the voltages of any sections, for which it is sufficient to exclude the ratios from the resulting expressions to winding voltage 15.

In order to ensure a strictly constant voltage of the winding 15 when connected to different sections of the windings 3 n 4, a protective voltage from the windings 18-29 is applied through the divider 31-34 to the internal screen 16. The protective voltage excludes any capacitive currents from the winding 15 that may cause a change in the voltage of the winding 15. The switch 30 is set to the position corresponding to the tested section of the windings 3 and 4 (winding 23 for pin 8-9, winding 24 for pin 9 -10 and so on) and using variable capacitor 33 and resistor 34 set the voltage on the internal screen 16 in the same way that there is no voltage difference between the terminals of screen 16 and the terminals of the winding section 3. Such a setting is made t only once: for extreme position and switch 30 - withdrawal position 23.

For different frequencies, different values of the capacitor 33 and the resistor 34 are set, for which they are provided with a frequency scale. If there is a voltage divider, there is no need to achieve strict compliance with the voltages on the windings 3, 4 and 20, 21, but it is enough to ensure the proportionality of the voltages on these windings. The winding 22 provides voltages proportional to the voltage of the middle of the screens of the winding sections 5 and 6. In addition, the divider eliminates phase shifts between the voltages of the windings 3, 4 and 20, 21. The supply of protective voltage to the middle of the internal screen 16 and the connection of the middle of the screen 17 with a common point of 77 secondary windings significantly reduces the effect of capacitive currents between screens 16 and 17 on the voltages of windings 15, 3 and 4, since the capacitive currents are directed towards each other, therefore compensation of the effect occurs.