UA149014U - A method of obtaining a neutral reaction between sources of permanent magnetic fields - desactive magnetic interaction and a device for its realization. - Google Patents

Abstract

A method of obtaining a neutral reaction between sources of constant magnetic fields - inactive magnetic interaction - involves the rotation of moving sources of constant magnetic fields relative to stationary sources of constant magnetic fields. Rotation of moving sources of permanent magnets is carried out cyclically, by moving relative to stationary sources, sources of inactive magnetic interaction.

Description

The proposed useful model belongs to the field of energy and electrical engineering and can be used to improve the operating characteristics of electromagnetic motors.

It is designed to create a process of converting the reaction of permanent magnetic fields into a useful mechanical movement, which is used to ensure the operation of electromagnetic motors, the designs of which include the application of the principle of shielding and/or separation between moving and stationary sources of permanent magnetic fields.

The method combines the balanced interaction of multidirectional magnetic forces and the separating properties of magnetic materials created by the shielding device with respect to moving and stationary sources of a permanent magnetic field, which are designed to obtain useful mechanical work, creates a special type of reaction - deactivation magnetic interaction (the term deactivation is composed of the prefix "dez", which in French means: destruction, elimination, removal of something, in combination with the Latin word "assiimi5", i.e. "active" in the general sense means - removal of activity).

From the state of the art, a permanent magnet motor is known, described in the patent of the Russian Federation Mo KOZ4826Ц1, published on December 10, 2003, the design of which is able to most comprehensively explain the essence of the proposed method.

Permanent magnets are placed in the case of the magnetic motor. The first magnet is installed with the possibility of reciprocating movement under the influence of magnetic field forces. A shaft is also installed in the housing, connected to the first magnet by a means that allows converting the reciprocating movement of the first magnet into rotation of the shaft. The magnetic motor is equipped with a ferromagnetic screen designed to allow its movement in the gap between the magnets perpendicular to the lines of force of the magnetic field.

The ferromagnetic screen is equipped with a device that ensures its movement under the influence of shaft rotation. The ferromagnetic screen is also equipped with a device that ensures its reverse movement.

The mentioned means that ensures reciprocating movement of the magnet can be made in the form of a crank mechanism.

The means of moving the ferromagnetic screen can include a rotary lever and a cam mechanism, the cam of which is fixed on the shaft axis, and a pusher that interacts with

With a cam, fixed on one axis with a rotary lever. The shaft is equipped with a mechanical energy accumulator made in the form of a flywheel.

The described engine is problematic to use as a source of mechanical energy, since its design is made in the form of a closed-loop device and does not provide for the supply of energy from the outside.

Instead, the basic disadvantage of this engine, from a principled point of view, is the inappropriate characteristics of the ferromagnetic screen, the purpose of which is to create the potential difference necessary for the operation of the engine.

That is, in order to obtain optimal operational characteristics of this power plant, the ferromagnetic curtain, in addition to shielding the interaction of magnetic fields of permanent magnets, should not interact with these magnetic fields and create any relative resistance to movement.

This means that the material used in the design of the ferromagnetic curtain does not meet the necessary characteristics that should create conditions for continuous movement.

In addition, it is important to note the fundamentally low efficiency of energy conversion of sources of constant magnetic fields from a gradual type of movement to a rotary one, which potentially significantly reduces the operational characteristics of the engine.

The task of the proposed useful model is to significantly reduce the energy consumption of electrical installations due to the use of independent sources of permanent magnetic fields - permanent magnets.

The problem is solved by the fact that the method of obtaining a neutral reaction between sources of permanent magnetic fields is a deactivation magnetic interaction, which includes the rotation of moving sources of permanent magnetic fields relative to stationary sources of permanent magnetic fields, according to a useful model, the rotation of moving sources of permanent magnets is carried out cyclically, moving relative to stationary sources, sources of deactivating magnetic interaction.

Deactive magnetic interaction is implemented as a set of processes shielding permanent magnetic fields with soft magnetic materials and balanced multidirectional magnetic forces of compensating sources of permanent magnetic fields that compensate for the mechanical resistance created by soft magnetic materials relative to moving and stationary sources of permanent magnetic fields.

Balanced interaction between moving and stationary sources of permanent magnetic fields 60 and a source of deactivating magnetic interaction occurs at a constant distance between them.

The source of deactivating magnetic interaction relative to moving and stationary sources of a constant magnetic field is moved using electromagnetic induction.

Electromagnetic induction in electric machines of deactivating interaction is used as an auxiliary, preparatory process, in contrast to classic electric motors. That is, the direct process of obtaining mechanical movement on the motor shaft occurs due to the interaction of only the magnetic fields of the power permanent magnets, which was impossible with the known level of technology.

Deactive magnetic interaction is a set of shielding properties of magnetic materials with balanced multidirectional magnetic forces of compensating sources of permanent magnetic fields, which are combined in shielding devices, and provide mechanical control of magnetic interactions between sources of powerful permanent magnetic fields.

Taking into account some fundamental differences from the traditional method of converting electromagnetic energy into mechanical energy, which makes it possible to obtain extraordinary technical characteristics of electric motors. It makes sense to reasonably explain the factors that allow you to combine the reasons and the final technical result of the proposed useful model.

Therefore, the deactivating magnetic interaction (DEM), as a set of magnetic effects, is used in combination with the well-known and scientifically substantiated magnetic, electromagnetic and physical properties of materials, as well as principles, the combination of which allows building highly efficient electromagnetic power plants based on them.

To understand the processes that occur during the DMV, it is advisable to use some specific terms:

Attraction (Аиг) is a force that arises between different poles of sources of a constant magnetic field, which ensures their mutual attraction.

Repulsion (Cree) is a force arising between the same poles of sources of a constant magnetic field, which ensures their mutual repulsion.

Deactive magnetic interaction, as a set of properties, has practical applicability when used in appropriate conditions and with corresponding well-known electromagnetic effects and properties.

Properties on the basis of which deactivating magnetic interaction is implemented:

Zo - the existence in nature of a material that is capable of maintaining a permanent magnetic field around itself for a long time, without supplying it with energy from the outside - the properties of permanent magnets. - mutual attraction and repulsion (force of attraction and repulsion) that occurs between the poles of permanent magnetic fields and creates conditions for potential performance of work. - the property of soft magnetic materials to separate (shield) the interaction between the lines of force of permanent magnetic fields, due to the low coercive force. - the possibility of balanced action of multipolar magnetic forces, relative to the poles of permanent magnetic fields, which reduces the total resistance to movement of one system relative to another to minimum values.

The combination of the specified properties in one interacting complex allows you to get an atypical reaction, in which the amount of work performed by strong permanent magnetic fields is much greater than the amount of work required to maintain its cyclic action.

The deactivating magnetic shutter, which is used to create a potential difference between moving and stationary sources of a constant magnetic field, is a structure that combines two main components: - magnetic field separators (MFS); - magnetic field compensators (MFC).

Magnetic field separators are a stacked set of parts made of magnetic material, which is able to effectively delay the propagation of magnetic lines of force of permanent magnetic fields, and directly separate their interaction.

Magnetic field compensators are sources of permanent magnetic fields that create magnetic forces equal in strength and opposite in direction relative to the magnetic lines of the permanent magnetic fields with which they interact.

That is, the design of the deactivation shutter, when it moves between strong permanent magnetic fields, simultaneously stops their direct interaction, and balances its negative resistance forces arising in the SMP with the help of the KMP.

The size, overlapping area and ratio of the separation and compensatory systems of the deactivation shutter depend on the value of the magnitude of the strong permanent magnetic fields with which they interact.

The list of forces and characteristics that ensure the creation of a deactivating magnetic interaction reaction (Fig. 5, 6):

E1 is the force of attraction of a moving source of a permanent magnetic field;

E2 - attraction force of a stationary source of a constant magnetic field;

EZ - the force of attraction of the SMP, the deactivation shutter relative to the moving source of the constant magnetic field;

E4 - the force of attraction of the SMP, the deactivation shutter relative to the stationary source of the constant magnetic field;

E5 - force of repulsion of the KMP, the deactivating shutter relative to the moving source of the constant magnetic field;

Eb is the force of attraction of the magnetic field, the deactivation shutter relative to the moving source of the constant magnetic field;

E7 - the force of attraction of the magnetic field, the deactivation shutter relative to the stationary source of the constant magnetic field;

E8 - force of repulsion of the KMP, the deactivating shutter relative to the stationary source of the constant magnetic field;

Et - the external force introduced into the system to move the deactivation shutter relative to the moving and stationary sources of the constant magnetic field; 951 - the distance between the deactivating shutter and the moving source of the permanent magnetic field; 52 is the distance between the deactivation shutter and the stationary source of the constant magnetic field.

The active magnetic field equation (07) has the following form:

Beer I ve ZA) Sho 51, 52-sopvi. AND

Therefore, the interaction between the stationary source of the permanent magnetic field 5, with the force of attraction E2, and the moving source of the permanent magnetic field 1, with the force of attraction E1, becomes deactivated under the condition that the sum of the attraction forces ЕЗ, Е4, Еб, Е7 and the sum of the repulsion forces Е5 and E8 of the SE deactivation shutter is greater than or equal to zero, subject to constant Zita 52 distances between the interacting elements.

With the children of ANYA, Nd AVM, and here is KACHA, the head of mighty forks:

At the same time, the value Et of the external force, which is brought into the system for movement

From the deactivation shutter, relative to the moving 1 and stationary 5 sources of constant magnetic fields, there will be less force created by the attraction between the moving and stationary sources of constant magnetic fields.

Thus, the difference between the magnitude of the forces created by the sources of constant magnetic fields and the external force that must be brought into the system to ensure motion

C5 of the deactivating shutter is a solution with the help of which a significant increase in energy efficiency is realized in electromagnetic motors using the deactivating magnetic interaction.

Depending on the design of the engine, the deactivation valve can be made as a "Cascade" translational action mechanism or a "Quazar" rotary action mechanism.

The description of the devices that reasonably confirm the functionality of the proposed method and the possibility of its implementation as a work cycle for power plants is provided.

Fig. 1, 2 depict the basic magnetic properties, namely: attraction (attraction) and repulsion (repulsion), which are characteristic interactions between permanent magnetic fields, provide useful work and for which a deactivating magnetic interaction is used.

At the same time, useful work is the result of magnetic interactions of a moving source of constant magnetic fields 1, which creates a force E, which is applied through the arm of the force Y to the axis of rotation, and moves to a distance "4, creating a moment of force M, relative to a stationary source of a constant magnetic field 5.

Fig. 3, 4 depict the general essence of the method of deactivating magnetic interaction, namely: fig. C depicts the position of different polar interacting elements, in which the mechanical movement of the constant magnetic field source 1 occurs due to the attraction of the relatively stationary source of the constant magnetic field 5, while the deactivation shutter is in the open position.

Fig. 4 shows the relative position of the elements, directly at the moment of the deactivating magnetic interaction, when the separation of the interaction of the sources of constant magnetic fields occurs, with the simultaneous balanced counteraction of the compensating sources of the magnetic fields of the deactivating shutter. At the same time, the attraction between the sources of constant magnetic fields and the deactivation gate 60 is close to zero, so that the moving source of the constant magnetic field and the deactivation gate can continue to move without hindrance.

Fig. 5, 6 illustrate in more detail the simplest example of deactivating magnetic interaction between different sources of a constant magnetic field. 071 - deactivation shutter assembly; 1 - moving source of constant magnetic field; 2 - variable compensator of the magnetic field of the moving source of the magnetic field; Z - magnetic field separator; 4 - magnetic field compensator of the same name of a stationary magnetic field source; 5 - stationary source of permanent magnetic field; b - magnetic field compensator of the same name of a moving magnetic field source; 7 - variable compensator of the magnetic field of the stationary source of the magnetic field.

As an example of the work of the proposed method, the design of the electromagnetic engine of the rotary action of the "Quazar" system, as well as the experimental energy installation of the translational action of the "Cascade" system is presented.

The electromagnetic engine of the "Quazar" system contains a housing with immovably fixed permanent magnets forming a stator, which houses a rotor formed by permanent magnets fixed on a non-magnetic core, and a deactivation shutter (DZ) with magnetic windows. The rotor and DZ are made with the possibility of mutually opposite rotation relative to the stator with the help of the drive electric motor of the deactivation shutter.

The rotor is designed to receive the reaction force of permanent magnets and transmit it to the main shaft of the engine. The rotor mechanism is mounted on support bearings and consists of a core on which permanent magnets with radial magnetization are located, forming a rotor package.

A deactivation shutter (DZ) is a cylindrical mechanism that consists of magnetic field separators (MFS) made of ferromagnetic and soft magnetic material, and magnetic field compensators (MFC), which are compensating sources of permanent magnetic fields. The mechanism is installed on support bearings, in which there are magnetic windows of structurally specified sizes and shapes, and is set in motion with the help of an electric motor. The design of the DZ ensures the maintenance of two basic properties (separation and compensation), relative to the magnetic fields of the stator and rotor, ensures the timely transition of the rotor from the reaction of attractions (repulsion) to the reaction of overlap, which contributes

From the continuity of the work cycle.

The stator is a stationary part of the motor that is responsible for creating a magnetic moment between the rotor. The stator includes permanent magnets of radial magnetization located in the engine housing.

The reaction distribution system consists of a deactivation shutter with magnetic windows and a drive electric motor, which together ensure the necessary sequence of interaction between the gate and the rotor.

The engine control system consists of a drive electric motor of the deactivation valve and a device for changing the parameters of the electric current. The system provides start, stop and adjustment of the speed of rotation of the engine shaft.

The principle of operation of the rotary electromagnetic engine of the "Kvazar" system with a deactivating shutter.

The rotational movement of the main shaft of the engine is ensured by the forces of attraction (repulsion) that arise between different (identical) poles of permanent magnets of the stator and rotor, the directional interaction between which is provided by a deactivation gate (DZ).

The operating cycle of the electromagnetic engine "Quazar"' includes a complex of successive mutually complementary processes based on a set of its features.

These processes occur during the mutual reaction of the rotor-DZ-stator system, the interaction of which creates two working phases: - Attraction phase (repulsion phase). - overlapping phase.

The phase of attraction (repulsion) is the basic working process of the engine, which is provided by the interaction and radial convergence (removal) of the permanent magnets of the rotor 4 of different (same) polarity to the stator 2.

The permanent magnets of the stator and rotor, between which the phase of attraction (repulsion) occurs at a given time, are called a magnetic pair.

The overlap phase is an auxiliary work process, during which the deactivation shutter (DZ), actuated by an auxiliary electric motor, converts the interaction between the magnetic pair into the interaction between the rotor-DZ-stator system.

At the same time, the deactivating properties of the shutter ensure the unhindered movement of the sources of the constant magnetic field of the rotor to the position in which the conditions are created for 60 repetitions of the basic work process, and ensuring its cyclicity.

Together, these two reactions form a workflow.

The operating cycle of an electromagnetic motor based on deactivating magnetic interaction.

To describe the interactions that occur in the engine, the processes that take place between an individual magnetic pair are given below.

As a sample, a configuration is presented in which the attraction that occurs between the opposite poles of permanent magnets is used.

The permanent magnet of the rotor is placed perpendicularly to the permanent magnet of the stator, which corresponds to the position of the conditional starting point (STP) of the engine's operating cycle and is equal to 0".

At the 0" position, the magnetic window of the DZ is placed in such a way relative to the rotor and the stator that corresponds to the beginning of the phase of attraction between them, as a result of which the rotor moves in the direction of the permanent magnet of the stator. At the same time, the auxiliary electric motor drives the deactivation shutter with the magnetic window

When the rotor is moved 30" from the UST, the initial stage of the attraction phase change to the overlapping phase occurs, which corresponds to the maximum torque between the stator and the rotor.

After the rotor position is 30", the radial force of the attraction phase begins to decrease in accordance with the decrease in the reaction area between the magnetic pair due to the overlapping of the magnetic window of the DZ and its creation of a deactivating magnetic interaction.

At the position of the rotor corresponding to 60", its reaction is due to deactivating forces

DZ, during which there is a gradual decrease in the radial force and further movement is due to the inertial forces of the mechanisms.

The position of the rotor, which is equal to 90" from the UT, is the final point of the attraction phase, at this position there is a complete overlap of the magnetic window and the end of the action of the radial force between the permanent magnets of the stator and the rotor.

The movement of the rotor from 90" to 180" occurs due to the repetition of the work process between other magnetic pairs of the motor.

At the position of the rotor equal to 180", the phase of attraction to the permanent magnet of the stator begins and the work process is repeated.

As a device, the characteristics of which directly confirm the efficiency of the proposed method, an experimental, demonstration installation is presented, in which the deactivation mechanism of the translational action of the "Cascade" system is used in combination with the translational movement of a dynamic source of a permanent magnetic field.

The device repeats the principle diagram described according to fig. 3-6.

A demonstration of this device is available at the link: pere: /уоши.ре/7ТМ Огемикм.

Claims (4)

35 USEFUL MODEL FORMULA 1. The method of obtaining a neutral reaction between sources of permanent magnetic fields is a deactivating magnetic interaction, which includes the rotation of moving sources of permanent magnetic fields relative to stationary sources of permanent magnetic fields, which is distinguished by the fact that the rotation of moving 40 sources of permanent magnets is carried out cyclically, moving relative to stationary sources, sources of deactivating magnetic interaction. 2. The method according to claim 1, which is distinguished by the fact that the deactivating magnetic interaction is implemented as a set of processes that shield permanent magnetic fields with soft magnetic materials and balanced multidirectional magnetic forces of compensating sources of permanent magnetic fields that compensate for the created by soft magnetic materials mechanical resistance relative to moving and stationary sources of permanent magnetic fields. Q. The method according to claim 2, which is characterized by the fact that the balanced interaction between the moving and stationary sources of permanent magnetic fields and the source of deactivating magnetic interaction occurs at a constant distance between them. 50 4. The method according to claim 3, which differs in that the source of deactivating magnetic interaction relative to moving and stationary sources of a permanent magnetic field is moved using electromagnetic induction.