RU184270U1 - THREE-PHASE TRANSFORMER OF DC SUPPLY SUBSTANCES - Google Patents

Abstract

The invention relates to the field of electrical engineering, in particular to transformers designed to supply three-phase power consumers. As the current flowing through sections (7) and (8) increases, the alternating magnetic flux increases, the material of the second section (4) goes into a state of magnetic saturation, its magnetic resistance increases, the alternating magnetic flux of the second section (4) decreases, and therefore decreases EMF of the second section (6) of the secondary winding. The eddy currents in the body of a non-magnetic electrically conductive core (9) increase and have a demagnetizing effect on the material of the first section (3), the magnetic resistance of which decreases and most of the alternating magnetic flux created by the primary winding current branches to the first section (3). When the voltage of the first section (5) increases and the voltage of the second section (6) decreases, the voltage on the entire secondary winding remains at the required level. When the primary current decreases, the magnetic flux decreases. This means that the material of the second section (4) goes out of the state of magnetic saturation, its magnetic resistance decreases. The alternating magnetic flux created by the current of the primary winding is redistributed between sections (3) and (4) of the rod (2) so that a smaller part of it branches to section (3) and a large part branches off to section (4). As a result, the voltage generated on section (5) decreases, the voltage formed on section (6) increases, and the voltage on the entire secondary winding of the transformer does not change. The technical result is to increase the efficiency of a transformer by reducing its electrical losses. 1 il.

Description

The invention relates to the field of electrical engineering, in particular to transformers designed to supply three-phase power consumers.

A three-phase transformer of direct current traction substations is used, which is used in a transformer unit for electrified AC railways (RU # 146074, H01F 30/12, 09/27/2014) and contains a three-core magnetic core, the rods of which are split into two sections, which in the upper part are connected by ferromagnetic feet, the phases of the secondary winding, which is connected to the load, are wound onto the rods, and the phases of the primary winding connected to the supply mains are wound on top of the phases of the secondary winding. The sections of the rod in the lower part are connected by ferromagnetic stops, with the first section of the secondary winding being wound on the first section of the rod, the second section of the secondary winding having a larger number of turns as compared to the first section of the secondary winding is wound on the second section, and the end of the first section of the secondary winding is connected to the beginning of the second section of the secondary winding, short-circuited turns are mounted on the first section of the rod.

The disadvantage of the proposed design is the fact that in short-circuited coils with low electrical resistance under the action of alternating magnetic flux, additional electrical losses occur that exceed the losses in the coils of the secondary winding sections. An increase in the total electrical losses leads to a decrease in the efficiency of the transformer.

Known three-phase transformer traction substations DC (RU # 172859, H01F 30/12, 07.28.2017), designed to power three-phase energy converters at the traction DC substations, selected as a prototype, and containing a three-core magnetic core, the rods of which are split into two sections , the phases of the secondary winding, which is connected to the load, are wound on the rods; the phases of the primary winding connected to the supply mains are wound on top of the phases of the secondary winding, and the first sec is wound on the first section of the rod secondary winding, a second section of the secondary winding is wound to the second section, the end of the first section of the secondary winding is connected to the beginning of the second section of the secondary winding, short-circuited coils are mounted on the first section of the rod, the second section of the secondary winding has a smaller number of turns than the first section of the secondary winding , the primary winding is divided into two sections with the same number of turns, with the first section of the primary winding winding over the first section of the secondary winding, the second section of the primary winding amotana over the second section of the secondary winding, the primary winding first end section is connected with the beginning of the second primary winding sections.

The eddy currents flowing in the short-circuited coils of the prototype design introduce additional electrical losses into the total losses of the transformer, as a result of which its efficiency decreases.

The task of the utility model is to increase the efficiency of a three-phase transformer of a direct current substation by using the demagnetizing action of eddy currents induced in an open continuous non-magnetic core located inside the magnetic core.

The technical result is achieved by the fact that in a three-phase transformer of traction DC substations containing a three-core magnetic core, the rods of which are split into two sections, the phases of the secondary winding are wound on the rods, which is connected to the load, and the phases of the primary winding connected to the mains while the first section of the secondary winding is wound on the first section of the rod, the second section of the secondary winding is wound on the second section, and the end of the first section of the secondary coating is ki connected to the beginning of the second section of the secondary winding, the second section of the secondary winding has a smaller number of turns compared with the first section of the secondary winding, the primary winding is divided into two sections with the same number of turns, the first section of the primary winding is wound over the first section of the secondary winding, the second the secondary section is wound over the second section of the secondary, the end of the first section of the primary winding is connected to the beginning of the second section of the primary, the first section of the split rod It has a transverse bore in which is located an unlocked nonmagnetic electrically conductive core.

Declared a three-phase transformer traction substations DC is illustrated in the drawing. The transformer contains a three-core magnetic core consisting of yoke 1 and rods 2. Rods 2 are split into two parallel sections 3 and 4. The first section 3 of the rod 2 is wound with the first section 5 of the secondary winding, the second section 6 of the secondary winding is wound with the second section 4, having a smaller number of turns than the first section 5 of the secondary winding, with the end of the first section 5 of the secondary winding connected to the beginning of the second section 6 of the secondary winding. The primary winding is divided into two sections with the same number of turns, with the first section 7 of the primary winding winding over the first section 5 of the secondary winding, the second section 8 of the primary winding winding over the second section 6 of the secondary winding so that the end of the first section 7 of the primary winding is connected with the beginning the second section 8 of the primary winding. The phases of the secondary winding are connected according to the “delta” scheme, the phases of the secondary winding are connected according to the “star” scheme. In the transverse hole, which may be through or deaf, of the first section 3 of the split rod 2 is inserted an unclosed non-magnetic electrically conductive core 9 made of copper or aluminum. Unclosed non-magnetic electrically conductive core 9 can be made either solid or diagonal.

The work of the three-phase transformer traction substations DC is as follows.

Voltage is applied to the primary winding of a three-phase three-rod transformer, consisting of series-connected first 7 and second 8 sections, through which alternating electric current begins to flow. This current creates an alternating magnetic flux interlocking with the turns of the first 5 and second 6 sections of the secondary winding and inducing in the turns of the first 5 and second 6 sections of the secondary winding an alternating electric current creating a counter magnetic flux. The resulting variable magnetic flux, which is the sum of the variable magnetic fluxes from the currents of the primary and secondary windings, flows along the yokes 1, the first section 3 and the second section 4 of the rod 2, engages the coils of the first section 5, inducing in it the EMF of the first section 5. In addition the resulting alternating magnetic flux flowing through the first section induces in the body an open non-magnetic electrically conductive core 9 eddy currents creating a magnetic flux directed towards the resulting magnetic perspiration Ku, currents created by the primary and secondary windings and flows through the first portion 3 of the rod 2. The resulting magnetic flux flowing through the first portion 3 of the rod 2 is decreased, thus decreasing the voltage of the first section 5 of the secondary winding. The magnetic flux flowing through the second section 4 of the rod 2 is larger than the magnetic flux flowing through the first section 3 of the rod 2. The magnetic flux of section 4 interlocks with the turns of the second section 6 of the secondary winding and forms the voltage of the second section 6 on it. The resulting voltage of the secondary winding is composed of the voltage on the first section 5 and the voltage on the second section 6 of the secondary winding.

Since the core 9 is open, the loss of electrical energy introduced by the eddy currents flowing in it is smaller compared to the prototype, where short-circuited coils are used - the cores, and the efficiency of the transformer is higher.

As the voltage on the primary winding increases, the current flowing through sections 7 and 8 increases, the alternating magnetic flux increases, the material of the second section 4 goes into a state of magnetic saturation, the magnetic resistance of the second section 4 of the split rod 2 increases. As a result, the variable magnetic flux flowing through the second section 4 of the rod 2 decreases, consequently, the EMF of the second section 6 induced by this flow decreases. The magnetic flux flowing through the first section 3 of the rod 2 increases, the eddy currents induced by it in the body of the open non-magnetic electrically conductive core 9 increase and have a demagnetizing effect on the material of the first section 3 of the rod 2. The magnetic resistance of the first section 3 of the rod 2 decreases and most of the variable magnetic flux created by the current of the primary winding, branches off into the first section 3 of the rod 2. This part of the magnetic flux interlocks with the turns of the first section 5 of the secondary winding and nav dit therein EMF first section 5. Thus, by increasing the voltage of the first section 5 of the secondary winding and the voltage drops of the second section 6 of the secondary winding the resulting voltage generated across the secondary winding is at the desired level.

When reducing the voltage on sections 7 and 8 of the primary winding, the current flowing in the primary winding decreases. The alternating magnetic flux created by this current is also reduced. This means that the material of the second section 4 of the rod 2 leaves the state of magnetic saturation and its magnetic resistance decreases. Then the alternating magnetic flux created by the primary current is redistributed between the first 3 and second 4 sections of the rod 2 so that a smaller part of this stream branches off to the first section 3, a large part to the second section 4 of the rod 2. As a result, the voltage generated in the first section 5 of the secondary winding wound on the first section 3 of the rod 2 decreases, the voltage generated on the second section 6 wound on the second section 4 of the rod 2 increases, and the voltage on the entire secondary winding of the transformer does not change.

Thus, the three-phase transformer of the direct current substation differs from its prototype by high efficiency, due to the fact that the losses in the body of an open non-magnetic conductive core are small compared to the losses from eddy currents in short-circuited turns.

Claims (1)

A three-phase transformer of direct current dc substations containing a three-core magnetic core, the rods of which are split into two sections, the phases of the secondary winding are wound on the rods, which is connected to the load, and the phases of the primary winding connected to the supply mains are wound from the top of the secondary windings the first section of the secondary winding is wound, the second section of the secondary winding is wound on the second section, and the end of the first section of the secondary winding is connected to the beginning of the second section of the secondary windings, the second section of the secondary winding has a smaller number of turns compared with the first section of the secondary winding, the primary winding is divided into two sections with the same number of turns, the first section of the primary winding is wound over the first section of the secondary winding, the second section of the secondary winding is wound over the second section secondary winding, while the end of the first section of the primary winding is connected with the beginning of the second section of the primary winding, characterized in that the first section of the split rods has a transverse hole The term, which is unlocked nonmagnetic electrically conductive core.

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