BG112970A - Magnetic modulation method and a system thereof - Google Patents

Abstract

The invention relates to a method and a system for magnetic modulation which find application in the field of electrical engineering for increasing the efficiency of power supplies, control, drive, and other hybrid electromagnetic systems. The method of magnetic modulation is characterized by the fact that to the output energy generated during the supply pulse from the bifilarly wound input and output winding coils is added additionally generated electricity, that has been generated after the end of the supply pulse (during the current pause) in additional output windings and due to magnetic fluxes created by permanent magnets, redirected by specially selected moments of on and off modes of the input winding and the output windings. The moment of switching on the bifilarly wound input and output windings located on the upper yoke of the middle nuclear magnetic core coincides with the beginning of the supply pulse to the input winding, and the moment of switching off the bifilarly wound input and output windings coincides with the end of the supply winding. . The moment of switching on the additional output windings located on the two cores of the middle nuclear magnetic core coincides with the moment of switching off the bifilarly wound input and output windings, and the moment of switching off the additional output windings coincides with the moment of switching on the input winding. The magnetic modulation system implementing the method consists of a magnetic core, an air gap, two permanent magnets, an input winding and output windings. The magnetic core is quad-core with three windows, forming three connected nuclear magnetic cores, and in the lower part (yokes) of the two end nuclear magnetic cores there are permanent magnets built-in. An air gap is located in the yoke of the middle nuclear magnetic core and the input coil is located on the upper yoke of the middle nuclear magnetic core. One output coil is bifilarly wound with the input coil, and the other output coils are located on both cores of the middle nuclear magnetic core.

Description

The invention relates to a method and system for magnetic modulation with applications in the field of electrical engineering to increase the efficiency of power supplies, control, drive and others. hybrid electromagnetic systems.

BACKGROUND OF THE INVENTION

Methods and designs of hybrid electromagnetic systems are known in which the magnetic fluxes excited by permanent magnets are redistributed by a suitable supply to the input windings, whereby more power is generated in the respective output windings [EP 1446862 Bl, US 20060163971 A1] .

The main disadvantages of these methods and constructions are the complex magnetic system, the difficult adjustment of its operating modes, the large number of air gaps, the use of a large number of permanent magnets and supply windings, and the failure to use all areas where magnetic fluxes change.

TECHNICAL ESSENCE

The object of the invention is to provide a method of magnetic modulation system in which to achieve higher energy efficiency, as a result of which to reduce the energy consumed by the respective current source.

The problem is solved by a method and system for magnetic modulation to achieve higher energy efficiency of hybrid electromagnetic systems.

The method of magnetic modulation is characterized by the fact that to the output energy generated during the supply pulse from the bifilarly wound input and output windings is added additionally generated electricity generated after the end of the supply pulse (during the current pause) in additional outputs. windings and due to magnetic fluxes created by permanent magnets, redirected by specially selected moments of switching on and off of the input winding and the output windings. The moment of switching on the bifilarly wound input and output windings located on the upper yoke of the middle nuclear magnetic circuit coincides with the beginning of the supply pulse to the input winding and the moment of switching off the bifilarly wound input and output windings coincides with the end of the supply winding. The moment of switching on the additional output windings located on the two cores of the middle nuclear magnetic circuit coincides with the moment of switching off the bifilarly wound input and output windings, and the moment of switching off the additional output windings coincides with the moment of switching on the input winding.

The magnetic modulation system implementing the method consists of a magnetic conductor, an air gap, two permanent magnets, an input winding and output windings. The magnetic conductor is quad-core with three windows, forming three connected nuclear magnetic conductors and in the lower part (yokes) of the two end nuclear magnetic conductors are permanent magnets. An air gap is located in the yoke of the middle nuclear magnetic conductor and the input coil is located on the upper yoke of the middle nuclear magnetic conductor. One output coil is bifilarly wound with the input coil, and the other output coils are located on both cores of the middle nuclear magnetic circuit. ^d

For different applications of the magnetic modulation system, the magnetic conductor can be made of different materials such as amorphous, ferrite and nanocrystalline magnetic materials, and the air gap is from 0.2 to 3 mm.

The permanent magnets are arranged in such a way that the magnetic fluxes created by them in the lower yokes of the two final nuclear magnetic conductors in the absence of power from an external current source are in the same direction, and in the presence of power from an external current source the direction of the total magnetic flux. created by the permanent magnets in the final nuclear magnetic conductors, coincides with the direction of the magnetic flux excited in the middle nuclear magnetic conductor by the input winding and the output windings.

An advantage of the method and the hybrid electromagnetic system configured in this way is that thanks to the additionally generated electricity, higher energy efficiency is achieved.

DESCRIPTION OF THE ATTACHED FIGURES

Figure 1 shows the location of the individual elements;

Figure 2 shows the distribution of magnetic fluxes and their directions without power from an external current source;

Figure 3 shows the distribution of magnetic fluxes and their directions with power from an external current source.

EXAMPLE OF IMPLEMENTATION

Magnetic modulation method in which to the output energy generated during the supply pulse from the bifilarly wound input coil 5 and the output coil 6 is added additionally generated electrical energy generated after the end of the supply pulse during the current pause in the additional 7 output coils and 8 and due to magnetic fluxes created by the permanent magnets 3 and 4, redirected by specially selected moments of switching on and off of the input winding 5 and the output windings 6, 7 and 8. The moment of switching on the input winding 5 and the output winding 6 located on the upper yoke of the middle nuclear magnetic circuit coincides with the beginning of the supply pulse to the input coil 5, and the moment of disconnection of the input coil 5 and the output coil 6 coincides with the end of the supply pulse to the input coil 5. The moment of inclusion of additional outputs windings 7 and 8 located on the two cores of the middle nuclear magnetic circuit coincide with the moment of switching off the input winding 5 and the output winding 6, and the moment of switching off the additional output windings 7 and 8 coincides with the moment of switching on the input winding 5.

The magnetic modulation system consists of magnetic conductor 1, air gap 2, permanent magnets 3 and 4, input coil 5 and output coils 6, 7 and 8. The magnetic conductor 1 is quad-core with three windows, forming three connected nuclear magnetic conductors, and is realized by amorphous magnetic material. In the lower part (yokes) of the two end nuclear magnetic conductors are permanent magnets 3 and 4 as in the yoke of the middle nuclear magnetic conductor is located the air gap 2 with a size of 0.5 mm, and the input coil 5 is located on the upper yoke of the middle nuclear magnetic circuit. The output coil 6 is bifilarly wound with coil 5, and the output coils 7 and 8 are located on both cores of the middle core magnetic core.

The permanent magnets are arranged in such a way that the magnetic fluxes created by them in the lower yokes of the two final nuclear magnetic conductors in the absence of power from an external current source are in the same direction, and in the presence of power from an external current source the direction of the total magnetic flux. created by the permanent magnets (3) and (4) in the terminal nuclear magnetic conductors, coincides with the direction of the magnetic flux excited in the middle nuclear magnetic conductor by the input winding (5) and the output windings (6), (7) and (8).

USE OF THE INVENTION

The invention is carried out as follows. When the input winding 5 is disconnected from the power supply, the magnetic fluxes excited by the permanent magnets 3 and 4 are closed through the magnetic sections under the windings 7 and 8, respectively. magnets 3 and 4, whereby they are redirected through the section of the magnetic conductor located below the input winding 5 and thus summed with the excited magnetic flux from the input winding. This causes an increase in the magnetic flux covered by the output coil 6, as a result of which an electrical signal is generated at its terminals. At the same time, due to the redirection of the magnetic fluxes created by the permanent magnets 3 and 4, the corresponding fluxes in the sections of the magnetic circuit where the output windings 7 and 8 are located decrease to 0, which excites electrical signals in the output windings 7 and 8. signals are summed with the signal excited in the output winding 6, resulting in a resultant output signal greater than that in the input winding 5. When the power supply of the input winding 5 is interrupted, the magnetic fluxes excited by the permanent magnets 3 and 4 , are redirected through the magnetic sections respectively under the windings 7 and 8, as a result of which similar output signals are generated in the output windings 6, 7 and 8.

Claims (7)

Magnetic modulation method, characterized in that additionally generated electrical energy generated after the end of the supply pulse during the current pause in the additional output windings (7) and (2) is added to the generated output energy during the supply pulse 8) and due to the magnetic fluxes created by permanent magnets (3) and (4), redirected by appropriately selected on and off moments of the input winding (5) and the output windings (6), (7) and (8) . Magnetic modulation system consisting of a magnetic conductor, an air gap, permanent magnets, an input coil and an output coil, characterized in that the magnetic conductor (1) is quad-core with three windows forming three connected nuclear magnetic conductors, as in the lower part (yokes) of the two end nuclear magnetic conductors are permanent magnets (3) and (4), where in the lower yoke of the middle nuclear magnetic conductor is an air gap (2), the input coil (5) is located on the upper yoke of the middle nuclear magnetic conductor, the output coil (6) is bifilarly wound with a coil (5), and the additional output coils (7) and (8) are located on both cores of the middle nuclear magnetic conductor. Magnetic modulation method according to claims 1 and 2, characterized in that the moment of switching on the input winding (5) and the output winding (6) coincides with the beginning of the supply pulse to the input winding (5), and the switching off moment of the input winding (5) and the output winding (6) coincide with the end of the supply pulse to the input winding (5). Magnetic modulation method according to claims 1 and 2, characterized in that the moment of switching on the additional output windings (7) and (8) coincides with the moment of switching off the input winding (5) and the output winding (6), and the moment of switching off of the additional output windings (7) and (8) coincides with the moment of switching on of the input winding (5). Magnetic modulation system according to claims 1 and 2, characterized in that the magnetic conductor can be realized from materials such as amorphous, ferrite and nanocrystalline magnetic materials. Magnetic modulation system according to claims 1 and 2, characterized in that the air gap is 0.2 to 3 mm in size. Magnetic modulation system according to claims 1 and 2, characterized in that the permanent magnets (3) and (4) are arranged in such a way that the magnetic fluxes created by them in the lower yokes of the two end nuclear magnetic conductors in the absence of of power supply from an external current source are in the same direction, and in the presence of power supply from an external current source the direction of the total magnetic flux created by the permanent magnets (3) and (4) in the final nuclear magnetic conductors coincides with the direction of the magnetic flux in the middle nuclear magnetic conductor from the input winding (5) and the output windings (6), (7) and (8).