RU2403668C2 - Method and device for conversion of magnetic force interactions into mechanical energy - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: in method alternating or pulse current is sent to joined excitation coil with core and compensation coil. At the same time produced AC magnetic field acts at permanent magnet fixed on actuating mechanism with the possibility of displacement in zone of AC magnetic field action with operation. Device for method realisation comprises source of alternating or pulse current, excitation coil with core, compensation coil and actuating mechanism including permanent magnet, connected to each other and to specified source of current.

EFFECT: reduced weight and dimension characteristics and increased speed of permanent magnet motion, which results in increased pickup of mechanical energy.

4 cl, 1 dwg

Description

The invention relates to the field of energy, in particular to the field of conversion of one type of energy into another type of energy, and can be used both in systems intended for mechanical work and in energy conversion systems.

Known (RU, patent 2206170) is a linear electric generator comprising a housing of non-magnetic material, inside of which permanent magnets are mounted on shafts rotating from drives in the form of step motors, in the form of horizontal cylinders with bulges on the sides, inside the stator winding between these rotating permanent magnets is installed with the possibility moving between them a permanent magnet-slider in the form of a rectangle with bulges and with moving contacts on the sides, on the inner side of the stator winding fixed contacts are used to control the stepper motors of the drives of these permanent magnets depending on the location of the permanent magnet of the slide, while the control system of the stepper motors of the drives of rotating permanent magnets ensures the closure of the moving contacts with the fixed contacts when the permanent magnet of the slide moves to one dead point for signal transmission to the control system of said permanent magnet drives, depending on the position of the permanent magnet slide for such a rotation of the permanent magnets, so that the permanent magnet-slider rushes to another dead point, while the electromotive force induced in the stator winding enters the rectifier.

Known (RU, patent 2055236) is a method of generating mechanical energy, which includes creating a magnetic field in a generator with a vector potential oriented at an angle of 90-270 ° to the cosmological electromagnetic vector potential, and moving material bodies mechanically connected with consumers of mechanical energy in this field, in the region of reduced potential values equal to the sum of the indicated vector potentials, and material bodies are pre-untwisted around axes perpendicular to the planes in which us vector potential vectors of the magnetic field generator of mechanical energy and electromagnetic cosmological vector potential, to achieve each of the bodies of the regime of zero moment of external forces relative to the center of mass of the body, whereupon the preliminary unwinds impact is removed and the material to rotating bodies connected consumer of mechanical energy.

To implement this method, it is proposed to use a device that is a mechanical energy generator containing a magnetic field source and material bodies placed in it, and the magnetic field source is made in the form of a cylindrical axisymmetric magnetic system, and the material bodies are made in the form of disk rotors installed with the possibility of rotation, whose axes are parallel to the axis of symmetry of the magnetic system, are taken out of its limits, connected to consumers of mechanical energy and fur They are connected with systems of preliminary promotion of rotors.

Also known (RU, patent 2091976) is a method of generating mechanical energy, which includes creating a magnetic field source in a magnetic field with a vector potential oriented at an angle of 90-270 ° to the cosmological vector potential, placing and moving material bodies mechanically connected with consumers of mechanical energy , in the region of reduced values of the vector potential equal to the sum of the indicated vector potentials, and in the local zone of space in the region of reduced values of the vector sweat a potential equal to the sum of the vector potential of the magnetic field of the source of the magnetic field and cosmological vector potential, reduce the induction of the magnetic field of the source of the magnetic field, and material bodies, at least part of their mass, are placed in the specified local zone and, rotating them, pre-unwind around the axes, perpendicular to the planes in which the vectors of the vector potential of the magnetic field of the magnetic field source and the cosmological vector potential are located, until each of the bodies reaches the equal nstva zero moment of external forces relative to the center of mass of the body, whereupon the preliminary unwinds impact is removed and the material to rotating bodies connected consumer of mechanical energy.

To implement the method, it is proposed to use a mechanical energy generator containing a magnetic system and material bodies, the magnetic system being made in the form of an axisymmetric magnetic field source and a magnetic circuit made in the form of pole pieces mounted on poles of a magnetic field source developed in a direction radial relative to the axis of the magnetic field source and interconnected at the periphery, and material bodies are made in the form of rotors installed with the possibility of rotation, mechanically and associated with the systems of preliminary rotation of the rotors and with systems for connecting the rotors to consumers of mechanical energy and made in the form of bodies of revolution, at least part of the mass of which is located in the space between the side surface of the magnetic field source and the elements connecting the terminal tips of the generator magnetic system on the periphery while the axis of the rotors are parallel to the axis of symmetry of the source of the magnetic field.

All known technical solutions are not applicable to the solution of the task.

The technical problem solved by the developed technical solution is to develop a new method for converting magnetic energy into mechanical energy.

The technical result obtained by the implementation of the developed technical solution is to provide the possibility of converting magnetic energy into mechanical energy.

To achieve the specified technical result, it is proposed to use a method of converting electromagnetic force interactions into mechanical energy, characterized by the supply of alternating or pulsed current to interconnected excitation coils with a core and a compensation coil, the effect of the generated alternating magnetic field on a permanent magnet fixed to the actuator with the possibility of movement in the zone of action of an alternating magnetic field with the completion of work on the executive th mechanism with the generation of mechanical energy.

To implement the method, it is proposed to use a device containing an alternating or pulsed current source, at least one core excitation coil, at least one compensation coil, the coils being interconnected and connected to the specified current source, and an actuator containing a constant magnet mounted on the actuator with the ability to move in the area of action of an alternating magnetic field with the work on the actuator with the generation of fur nical energy. It is preferable to use an even number of field coils and / or an even number of compensation coils.

In the future, the essence and advantages of the developed technical solution will be disclosed using examples of its implementation.

The developed technical solution can be implemented using a device, a block diagram of which is shown in the drawing.

The device comprises an electronic circuit 1 for controlling currents in coil windings, a phase matching unit 2 for switching the direction of currents of coils with the movement of a permanent magnet, a shaft 3 for selecting mechanical power, a crank mechanism 4, a rod 5, a shell 6 of a permanent magnet 7, made of magnetically transparent and non-conductive material rigidly connected to the rod 5 and the permanent magnet 7, the excitation coil 8 and the compensation coil 9. The electronic control circuit is an AC rectifier with an electron control using thyristors (in particular, triacs), capable of generating the voltage potential of the required polarity, amplitude, shape and duration, the matching unit is an electronic circuit that operates at the right time and sends an electrical signal in the form of a pulse, unlocking or locking thyristors of an electronic control circuit, the shell can be made of solid insulating material, in particular ceramics or a polymer based on phenol-formaldehyde resin.

The above device operates as follows. When the permanent magnet 7 is placed in the extreme right position relative to the coils 8 and 9, the electronic circuit 1 supplies a current of the direction and amplitude to the winding of the excitation coil 8, at which the permanent magnet 7 moves to its extreme left position with the generation of a certain amount of mechanical energy during movement. In the process of movement, the rod 5 transmits the movement of the permanent magnet 7 to the crank mechanism 4, the movement of which causes the shaft 3 to rotate 180 °. When the permanent magnet 7 reaches the indicated extreme left position, the position of the shaft 3 gives a signal to the matching unit 2, which generates a control signal for the electronic control circuit 1 to change the polarity of the supply voltage. In this case, accordingly, its polarity and magnetic field flux, covering the excitation coil 8, change. The specified field of the coil 8 acts on a permanent magnet, providing its movement from the extreme left to the extreme right position with the transmission of the shaft 3 by means of the rod 5 and the crank mechanism 4 of the shaft 3. Changing the polarity of the magnetic field of the excitation coil 8 provides cyclic movement of the permanent magnet and, ultimately account, rotation of the shaft.

When the permanent magnet 7 is rapidly moving in the winding of the excitation coil 8, according to the law of electromagnetic induction, an electromotive force is induced that prevents the creation of a magnetic field accelerating the permanent magnet in the winding, i.e. directed against the amperage coming from the electronic control circuit 1. To prevent the indicated action of the electromotive force, a compensation coil 9 is additionally introduced into the device, electrically connected to the excitation coil so that when the permanent magnet 7 moves in high speed, the electromotive force is also induced, directed in the same direction as the main supply current. The parameters of the compensation coil 9 are selected so that the main accelerating permanent magnet 7 magnetic flux generated by the coil 9, with a high-speed movement of the magnet is somewhat enhanced.

Coil 9 introduces, by its magnetic flux, an inhibitory effect on the movement of the permanent magnet 7, but since it is made without a core, the negative magnetic component in the resulting magnetic flux from it will be substantially smaller compared to the flux of the magnetic field that arises from coil 8. The excitation coil 8 not only does not decrease its main magnetic flux during high-speed movement of a permanent magnet, but, on the contrary, even increases it, since its core is in an unsaturated state.

Devices made on the basis of the developed method can be used in the engines of various vehicles, as well as as an electric generator drive for autonomous power supply.

To reduce losses in the compensating part of the device, it is possible to reduce the geometric dimensions of the compensation coil 9 and install two of these compensation coils 9 perpendicular to the axis of the core of the coil 8 and its ends, while the permanent magnet 7 will move between these compensation coils 9 parallel to the excitation coil.

Other embodiments of the developed method are also possible.

In particular, to reduce the overall dimensions of the device while increasing the speed of the permanent magnet and, consequently, the shaft, leading to an increase in the removal of mechanical energy, it is advisable to replace the reciprocating movement of the magnet with a rotational one.

Using the developed technical solution allows us to provide the possibility of converting magnetic energy into mechanical energy.

Claims (4)

1. A method of converting magnetic force interactions into mechanical energy, characterized by the supply of alternating or pulsed current to interconnected excitation coils with a core and a compensation coil, the effect of the resulting alternating magnetic field on a permanent magnet, mounted on the actuator with the possibility of movement in the area of the alternating magnetic field with the work on the actuator with the generation of mechanical energy. 2. A device for converting electromagnetic force interactions into mechanical energy, characterized by the presence of an alternating or pulsed current source of at least one excitation coil with a core of at least one compensation coil, the coils being interconnected and connected to the specified current source, and an actuator containing at least one permanent magnet mounted on the actuator with the ability to move in the area of action of an alternating magnetic Olya with work on the actuator with the generation of mechanical energy. 3. The device according to claim 2, characterized in that it contains an even number of field coils. 4. The device according to claim 2, characterized in that it contains an even number of compensation coils.

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