BG67031B1 - Electromagnetic device - Google Patents

Abstract

The device is intended for use in instrumentation and machine building as a component and as a separate device. It has increased functionalities. It consists of a carrier (1) connected to a torsional mechanism (2) and a magnet (4) with coils (5) coupled to a current source (6). Into a carrier is formed a longitudinal profile channel (7) in a diametrical plane, perpendicular to which by bearings is mounted a transverse axis (8) by a holder (9) connected to a magnet (4) whose coils (5) are connected to the current source 6) through a collector (3), with a control unit (10). The control unit (10) is connected to the torsional mechanism (2) and with a slewing mechanism (11) around the transverse axis (8) which coincides with the centre of gravity of the magnet (4). Between the holder (9) of the magnet (4) and the carrier (1) there is a spring (12) in which carrier (1) are mounted switchers (13) of the direction of slew of the magnet (4). The torsional (2) and slewing (11) mechanisms form an area (14) of the electromagnetic field of the device.

Description

Field of technology

The invention relates to an electromagnetic device used in instrumentation as a component and as a stand-alone device.

BACKGROUND OF THE INVENTION

An electromagnetic device is known, consisting of a rotating body connected to a rotating mechanism and a collector connecting wires from the body to a current source. The rotating body is located between the poles of a fixed magnet, whose windings are connected by the current source / 1 /.

This solution does not allow the creation of an extended zone of the magnetic field and its change in size, shape and intensity, which limits its functionality.

The object of the invention is to provide an electromagnetic device with increased functionality.

Technical essence of the invention

The problem is solved by means of a drive device including a carrier, a rotating mechanism and a collector are connected, and a magnet is a coil connected to a current source. According to the invention, a longitudinal profile channel is formed in the support in a diametrical plane, perpendicular to which a transverse axis of a holder is mounted, a magnet is connected. The windings of the magnet are connected to the current source through the collector is a control unit, which is connected to the rotating mechanism and to a rotating (magnet) mechanism around the transverse axis, coinciding with the center of gravity of the magnet. There is a spring between the magnet holder and the holder, and switches for the direction of rotation of the magnet are mounted in the holder. The rotating and rotating mechanism form a zone of the electromagnetic field of the device.

A cylindrical surface is formed along the longitudinal axis of the magnet, through which it is mounted in the holder, on the transverse axis of which a gear is mounted, a magnet is engaged, a second gear is mounted on the axis of the carrier and is connected externally. drive wheel.

The magnet is formed by two adjacent segments is the same shape and corresponding poles and windings, and a common bearing axis, coinciding is the transverse axis of the holder, which segments are hinged are one ends of the arms, the other ends of which are hinged to each other and to the piston of the rotating mechanism.

At the end of the magnet is located transversely at least one tangential magnet, whose windings are connected by the current source.

An axial electromagnet is mounted on the axis of the carrier, the winding of which is connected to the current source by means of the collector.

The control units of adjacent devices, is contacting magnetic zones, are connected by a common synchronization unit.

An advantage of the invention is its increased functionality due to the creation of an extended zone of its magnetic field and its change in size, shape and intensity, as well as its program control.

Explanation of the attached figures

Figure 1 is a longitudinal section of the device;

Figure 1a is a section along AA of Figure 1;

figure 1c - longitudinal section of the carrier is an axial magnet;

Figure 1k is a longitudinal section of an electrically driven rotating mechanism;

Figure 2 - magnet is a peripheral tangential magnet;

Figure 2a - a magnet is a rotating tangential magnet;

Figure 2c is a view B of Figure 2a;

FIG. 2c is a B view of FIG. 2a in another embodiment;

105

Descriptions of issued patents for inventions № 04.2 / 30.04.2020 figure 3 - section on CC from figure 1 with a rotating magnet; Figure 4 - longitudinal section of the carrier is a magnet of segments; Figure 4.1 is a section along EE of Figure 4;

Figure 5 - coaxial adjacent devices; Figure 6 - adjacent devices with parallel axes.

Examples of the invention

The device consists of a carrier 1 connected to a rotating mechanism 2 and a collector 3 attached to the housing 44, and a magnet 4 with windings 5 connected to a current source 6. A longitudinal profile channel 7 is formed in the carrier 1 in a diametrical plane perpendicular to which it is mounted. transverse axis 8 of a holder 9 connected to the magnet 4, whose windings 5 are connected to the current source 6 by a collector 3 with a control unit 10, which is connected to the rotating mechanism 2 and a rotating (magnet 4) mechanism 11 around the transverse axis 8, which coincides with the center of gravity of the magnet 4. Between the holder 9 of the magnet 4 and the carrier 1 there is a spring 12, in which the carrier 1 are mounted switches 13 for the direction of rotation of the magnet 4. The rotating 2 and the rotating 11 mechanism form the zone 14 of the electromagnetic field .

In one embodiment, FIG. 1, the magnet 4 is fixedly attached to the holder 9. The rotating mechanism 11 in one embodiment, FIG. 1, is a hydraulic piston 15, hinged by levers 43 is the holder 9. The chambers 16 of the piston 15 are connected by a collector 17 is a hydraulic unit 18, which is connected to the control unit 10. In another embodiment, the drive mechanism 11 is an electric drive of known type. The rotating mechanism 2 in one embodiment, FIG. 1, the carrier 1 is connected, and in another embodiment, FIG. 1k, is formed by a cage rotor winding 19 in a section 41 of the carrier 1, enclosed by a stator 20 generating a rotating electromagnetic field. The switch 13 for the direction of rotation of the magnet 4 is included in the circuit of the rotating mechanism 11. In one embodiment, FIG. 1, the carrier 1 is made of non-ferromagnetic material, and in another, FIG. 1k, at least its section 41 is of ferromagnetic material.

In another embodiment shown in Figure 3, the magnet 4 has a cylindrical surface 21 formed along its longitudinal axis 42, through which it is mounted in the holder 9, on the transverse axis 8 of which a gear 22 is mounted, engaged with a gear 23 attached to the magnet. and is a second gear 24 mounted on the axis of the carrier 1, and an external drive wheel 25 is connected.

In one embodiment, the drive wheel 25 is stationary relative to the housing 44, and in another, an external drive device of a known type is connected.

In another embodiment shown in Figure 4, the magnet 4 is formed by two adjacent segments 26, 27 of the same shape, poles and coils 39, 40, and a common bearing axis 28 coinciding with the transverse axis 8, which segments 26, 27 are hinged to one end of the arms 29, 30, the other ends of which are hinged to each other and to the piston 15 of the rotating mechanism 11.

The windings 39 and 40 of the segments 26, 27 are connected to the current source 6.

In another embodiment shown in Figure 2, at least one tangential magnet 31 is arranged transversely at the end of the magnet, the windings 32 of which are connected to the current source 6.

In one embodiment, FIG. 2, the tangential magnet 31 is fixedly attached to the bearing magnet 4, and in another embodiment, FIG. 2a, at least one tangential magnet 31 is mounted on a disk 33, which is mounted on the bearing magnet 4. A collector 34 is provided between the magnet 4 and the disk 33. In one embodiment, FIG. 2c, the magnets 31 of the disk 33 are arranged radially therein, and in another embodiment, FIG. 2c, are located frontally on the disk 33.

In another embodiment shown in Figure 1c, an axial magnet 35 is mounted on the axis of the carrier 1, the winding 36 of which is connected to the current source 6 by means of a collector 3.

The control units 10, in another embodiment, FIG. 5,6, of adjacent devices, is contacting magnetic zones 14, are connected by a common synchronizing unit 37.

In one embodiment, FIG. 5, the adjacent devices are coaxially arranged, and in another embodiment, FIG. 6, axes 38 are arranged in parallel.

106

Descriptions of issued patents for inventions № 04.2 / 30.04.2020

Use of the invention

When the carrier 1 rotates, the poles of the magnet 4 create a rotating electromagnetic field, in a circular zone 14, with a different diameter depending on the angle of inclination a of the magnet 4 relative to the axis of the carrier

1. When simultaneously rotating the carrier 1, rotating the magnet 4 around the transverse axis 8, the trajectory of the magnetic poles changes, significantly expanding the area of the magnetic field 14. This area 14 is formed by the combination between the rotation of the support body 1 and the rotation / the swing / of the magnet 4, as well as their directions of rotation and rotation / swing /. The intensity of the magnetic field in the zone 14, and the change of its polarity depends on the current in the windings 5 of the magnet 4, varying in size and direction from the control unit 10, which controls the rotating mechanism 11 and the rotation of the carrier 1. The magnetic zone 14 changes and when the magnet 4 rotates about its longitudinal axis 42, FIG. 3, by means of the drive gear 25 by an external mechanism or by the rotation of the carrier 1 with the drive wheel 25 stationary (relative to the housing 44).

The axial magnet 35, FIG. 1c, also changes the magnetic zone 14.

In the case of magnet 4 of two segments 26, 27, FIG. 4, their synchronous rotation is achieved by their hinged arms 29, 30 of the rotating mechanism 11. The zone 14 and the intensity of the magnetic field are changed depending on the polarity of the segments 26,27, the distance between them, a function of the angle a of the inclination them, and by the strength of the current in their windings 39, 40.

The use of tangential magnets, fig. 2 changes the magnetic field zone 14, as in the case of a bearing disk 33 with magnets 31, FIG. 2a, it can be rotated by the action of inertial forces, of the axial magnet 35 and of magnetic zones of adjacent devices.

In close adjacent devices, FIG. 5, their magnetic zones 14 interact through rotating and corresponding axial / torsional / magnetic fields. In this case, one device can drive an adjacent device. This interaction takes place both at the same and at different angles of inclination of their magnets.

When contiguous devices are connected in a closed loop, their energy circulates in the loop and can synchronize their rotation.

In the case of adjacent devices with parallel axes 38, FIG. 6, their magnetic zones 14 interact according to the polarity of their magnets 4, which rotate (by attracting, repelling), forming a common electromagnetic field.

The change of the angle of inclination a of the magnets 4 is related to the emission / reception / of energy from the devices, with a corresponding decrease / increase / of the angle of their inclination, corresponding to the rotation of their poles by different diameters. When the axis of rotation of the carrier 1 coincides with the axis of rotation of the magnetic field of the magnet 4, the action of their inertial and torsional fields and the forces on them during their flow (Magnus effects) are summed, depending on their direction of rotation. . This is also achieved by rotating the carrier 1 / from its rotor section 41 / and the rotating magnetic field generated by the stator 20.

As the angle of inclination of the magnet 4 decreases, the inertial moment of the carrier 1 decreases and its angular velocity increases accordingly.

Claims (6)

Patent claims An electromagnetic device comprising a carrier connected to a rotating mechanism and a collector, as well as a magnet with windings connected to a current source, characterized in that a longitudinal profile channel (7) is formed in the carrier (1) in a diametrical plane perpendicular to which is a bearing transverse axis (8) of a holder (9), is connected to the magnet (4), whose windings (5) are connected to the current source (6) through the collector (3) is a control unit (10), which is connected to the rotating mechanism (2) and with a rotating / magnet (4) / mechanism (11) around the transverse axis (8), which coincides with the center of gravity of the magnet (4), between whose holder (9) and the carrier (1) there is a spring (12), switches (13) for the direction of rotation of the magnet (4) are mounted in the carrier (1), whereby the rotating (2) and the driving (11) mechanism form a zone (14) of the electromagnetic field of the device. Electromagnetic device according to claim 1, characterized in that the magnet (4) has a cylindrical surface (21) is a longitudinal axis (42) by means of which it is mounted in the holder (9) on whose transverse axis (8) it is mounted. a gear (22) engaged with a magnet (4) attached to the magnet (4) and is a second gear (24) mounted on the axis of the carrier (1), and an external drive wheel (25) is connected. Electromagnetic device according to claim 1, characterized in that the magnet (4) is formed by two adjacent segments (26,27) is of the same shape, poles and windings (39,40), is a common axis (28) of bearing , the transverse axis (8) coincides, as the segments (26, 27) are hinged to one end of the arms (29,30), the other ends of which are hinged to each other and to the piston (15) of the rotating mechanism (11). ). Electromagnetic device according to claims 1 to 3, characterized in that at least one tangential magnet (31) is arranged transversely at the end of the magnet (4), the windings (32) of which are connected to the current source (6). Electromagnetic device according to Claims 1 to 4, characterized in that an axial magnet (35) is arranged / mounted on the axis of the carrier (1), the winding (36) of which is connected to the current source (6) by means of a corrector. 3). Electromagnetic device according to claims 1 to 5, characterized in that the control units (10) of adjacent devices are contacting magnetic zones (14), connected to a common synchronizing unit (37).