RU2264025C2 - Magnetoelectric machine - Google Patents

Abstract

FIELD: electromechanical engineering; transport, industry, and domestic applications.

SUBSTANCE: all magnetoelectric machines are characterized in absence of field coils and excitation loss is impossible in them. That is why they are much more economically efficient then electromagnetic machines, other conditions being equal. Proposed machine has its fixed part incorporating frame, removable sections constituting cylindrical part of frame designed for locating, fixing, and locking machine coils. Sections are screwed to frame to enhance stiffness of the latter. Coils are locked by means of holders and attached to removable section wall. Movable part of machine is rotor built of two plate-shaped disks provided with annular groove whose shape follows that of magnets installed therein. Rotor strength is enhanced by rigidly fixing its disks to cylindrical support passed near annular groove and to central bushing mounted on shaft through splined joint. Type of fixation may be different depending on mass and shape of magnets.

EFFECT: simplified design, facilitated regulation of output parameters.

1 cl, 4 dwg

Description

The technical field to which the invention relates.

The invention relates to the field of electrical engineering, is a single generator-engine design, and when the design of the generator or engine with a magnetic or combined excitation system is separately executed.

A magnetoelectric machine can be used in industry, transport and in everyday life, as a mechanical to electrical energy converter — a generator, and electric to mechanical — an engine.

The level of technology.

The invention of new magnetic alloys, the parameters of which are an order of magnitude greater than the existing ones, suggests that the design of magnetoelectric machines will be further developed.

The history of electrical engineering began with the invention of magnetoelectric machines.

So in 1832, the Pixie brothers built a model of a direct current generator, in which the switch rectified the alternating current induced in the fixed coils mounted on the U-shaped magnetic circuit, a change in the field direction was achieved by rotating the U-shaped magnet opposite.

This model is selected as an analogue as having the same characteristics with the proposed invention - magnetoelectric machine - the use of permanent magnets and coils.

As a prototype of the existing machines with magnetic excitation, a tachogenerator was selected. He has an anchor winding between the poles of the magnets mounted on the housing, the voltage is removed from the collector. The description of the Pixie brothers generator and tachogenerator can be found in the book Electrical Machines, author Ivanov-Smolensky A.V., Energia Publishing House, Moscow, 1980

Machines with magnetic excitation due to the absence of field windings and excitation losses have a higher efficiency than machines with electric excitation.

However, magnetic field machines have significant drawbacks:

1. The generator voltage and engine speed cannot be controlled by changing the field of excitation.

2. In the operating mode of the engine, poor starting properties are present.

3. Input and selection of direct current requires the use of contact devices.

SUMMARY OF THE INVENTION

The present invention is a magnetoelectric machine containing a rotor composed of permanent magnets and a stator formed from coils with steel cores fixed in removable sections of the housing, in which during rotation of the rotor there is a periodic change in the magnitude and direction of the magnetic flux penetrating the coil, i.e. . there is an electromagnetic interaction between magnets and coils, as a result of which an induced emf occurs in the coils.

The essence of the invention lies in the fact that permanent magnets of elongated shape, installed in pairs parallel to each other along the outer circumference of the rotor at a distance of the magnet length between each pair, with opposite poles of the same name, with a distance between the magnets in each pair equal to the height of the coil.

In the space between the magnets and perpendicular to them are coils with steel cores, fixedly mounted on the inside of the housing in removable sections. Coils are connected in magnetoelectric groups. When the rotor rotates near the coils of one group, the magnetic flux changes simultaneously in magnitude and direction, the same thing happens with coils of other groups, sequentially, in groups, there can be one or more such groups. The number of magnets and coils for one machine can be from two magnets and two coils, up to a lot depends on the power and dimensions of the machine. The coils of one group are located at a distance equal to the length of the magnet. Coils from different groups can be installed close to each other, maintaining the distance between each other in their group.

Significant differences are the following symptoms:

1. The housing has removable sections for installing coils.

2. Coils are installed in sections motionless.

3. Magnets of elongated shape, fixed in pairs with the possibility of rotation relative to the coils, form the rotor of the machine.

4. Coils are located in the space between the pairs of magnets and are divided into magnetoelectric groups.

5. The structural parts of the machine also have significant differences and are made of non-magnetic materials.

The present invention is a magnetoelectric machine allows you to:

1. Receive alternating current without contact devices.

2. To carry out step-by-step regulation by changing the connection of coils, groups.

When installing slip rings and a collector and installing 2 groups of coils, it is ensured:

3. Soft start in engine operation mode.

4. Obtaining direct current in the operating mode of the generator.

5. Regulation of speed and voltage.

6. Production and repair are simplified - no magnetic cores with grooves and laying windings in grooves are needed, the coils are easy to rewind and replace.

The disadvantages include the use of a collector.

Information confirming the possibility of carrying out the invention. A magnetoelectric machine, hereinafter referred to as a machine designed to convert energy, consists of two parts - fixed and mobile.

Figure 1 shows a machine in the embodiment with motionlessly mounted coils 3 and movably mounted magnets 13, acting as active parts of the machine. In this case, a machine made using 3 pairs of permanent magnets will be considered.

The stationary part of the machine consists of a housing 1, removable sections 2, forming a cylindrical part of the housing and playing the role of the location, fastening and fixing of the coils 3. Sections 2 with screws 4 are attached to the housing 1, giving it additional rigidity. The coils 3 with the help of holders 5 are fixed and attached to the wall of the removable section 2. The holders 5 are a U-shaped structure of three planes, two have grooves for the core 6 of the coil 3, the middle plane is used to fasten the holder 5 to the inner wall of the section 2 with screws 8. The number of turns and the cross section of the wire in the coils are selected depending on the magnets used and the power of the machine. The core 6 of the coil 3 from longitudinal movements in the grooves 7 of the holder 5 are fixed with screws 9.

The movable part of the machine, the rotor 10, is made of two disk-shaped disks 11, an annular groove 12 is made along the edges of the disks in the form of installed magnets 13. To give the rotor a structural strength, the disks 11 are rigidly connected by a cylindrical support 14, which extends adjacent to the annular groove 12, and in the center a sleeve 15, which is mounted on the shaft 16 by means of a spline connection. The fasteners, depending on the mass and shape of the magnets, are different, but reliable.

Figure 1 shows a set of ring magnets worn on a tube 17, which is attached to the disk with bolts 18, pressing magnets 13 in the groove 12.

The collector assembly is shown in FIG. 2, consisting of two slip rings 19 and their current collection brushes 20, collector 21 with two current collection brushes 22, a rotary beam 23 with a control lever 24, a profile washer 25, a supporting washer 26, a protective cap 27. Contact rings 19 made of textolite with a copper rim using slots mounted on the shaft 16, through the brushes 20 are connected by wiring to the terminal block 28. The collector 21 is a shallow bowl with a spline sleeve in the center and cylindrical edges, machined from plastic. On the outer cylindrical surface, copper lamellas 29 are mounted using screws 30 welded to the ends of the lamellas. Six current lamellas are separated by six neutral lamellas 31, insulated with micanite insulation 32 from current lamellas 29. A necessary condition, the brushes of the collector 22 should not close the current lamellas at the same time, i.e. their thickness should be less than the length of the neutral lamella. The current lamellas inside the bowl are interconnected, alternating on plus and minus, and are connected by two wires with slip rings 19, the wires are attached to the screws 30 of the lamellas 29. The yoke 23 is a cylindrical sleeve with a flange 33 that can be rotated in the profile washer 25 on the supporting washer 26 by means of the control lever 24. The vertical walls of the traverse are divided into 4 parts, two parts are removed, the collector brushes, slip rings and control lever are attached to the remaining opposite.

The length of the current lamellas ≈ equal to the length of the magnet when calculated by angular degrees. The length of the neutral lamella 31 is ≈ 1/7 of the current lamella, depending on the diameter of the collector, there may be other sizes.

The work of the magnetoelectric machine.

By the term work for an electric machine is meant the process of converting energy from one type to another, in the active parts of the machine. For example, in a generator this is the conversion of mechanical energy into electrical energy, in the engine - electrical into mechanical energy.

Consider the conversion process in a machine made of three pairs of movably mounted magnets and two groups of six fixedly mounted coils, which are the active parts of the machine. It is necessary that when assembling the brushes 22 of the collector 21 were on neutral slats 31, the coils in the zone of the poles of the magnets 13, the internal connection diagram corresponded to the diagram shown in figure 3. Current lamellas 29 must run onto the brushes 22 from the rotation side, which is set by the control lever 24, by supplying brushes 22, turning the beam 23.

Work in the generator mode occurs under the action of mechanical forces from outside, the rotor of the machine starts to rotate, the magnets 13 mounted on the rotor also rotate, as a result of this, coils 3 with cores 6 will be affected by magnets periodically changing in magnitude and direction. As a result, an EMF variable appears in the coils, and in the coils of one pair of one group, an EMF of the opposite direction appears simultaneously. In order for the total EMF to be in one direction, the coils must be connected according to the scheme of Fig. 3. The AC voltage is selected directly from the terminal block 28 from the terminals of the coils. Constant voltage is obtained due to the collector along the chain - coils - terminal block - collector brushes - lamellas - contact rings - terminal block.

When the rotor (magnets) rotate, the coils of one group simultaneously experience a change in the direction of the magnetic flux, then also occurs with the coils of the second group, etc. successively in 1/3 of a revolution, two changes in the direction of flow will occur with 3 pairs of magnets installed. For 1 revolution there will be 6 changes in the direction of the magnetic flux. To obtain a frequency of 50 Hz, a rotation speed of 500 rpm is needed 500 × 6: 60 = 50 period / sec.

The work of the magnetoelectric machine in engine mode.

When applying direct current to the terminals "+" and "-" of the terminal block 28, the current will flow through the brushes 20 of the contact rings 19 to the lamellas 29 of the collector 21 through the brushes 22 to the terminal block 28 and to the coils 3.

It is theoretically possible for the machine to operate when applying alternating voltage to the coils, having previously unwound the machine to a synchronous frequency.

Continuing further with direct current, for the selected direction of rotation, it is necessary that the lamellas 29 of the collector run onto the brushes 22 from the side of rotation. In this case, a current of the corresponding direction will enter the coils 3. This is done by means of the control lever 24. As a result of the passage of current, a magnetic field of the coils 3 in the opposite direction to the field of permanent magnets 13 is generated, and the cores 6 of the coils 3 are magnetized with the poles of the magnets of the same name 13, as a result of which the magnets 13 are ejected, since the opposite directions of the fields and the same poles repel . The rotor will move, the magnets 13 are repelled from the fixed coils 3. After passing half the length of the magnet, the magnets 13 fall into the range of other coils, see figure 4, in which the magnetic fields are aligned in the direction of the fields of the magnets 13, and the cores 6 are magnetized opposite to the poles of the magnets, flux linkage and attraction of the magnets 13 occurs. As soon as the magnets, rotating the rotor, approach their poles 3, the brushes 22 will be on the neutral slats 31. The current flow will stop, the inertia of the rotor will continue be rotated, and current slat 29, but with a different direction of the current, suited to the brushes 22, and the process starts over again until the current is shut off.

Regulation.

Changing the magnitude of the alternating voltage in steps is possible by connecting the coils in series or in parallel, if several groups of coils are installed, then by switching the groups. If there is an installed collector, it is possible to install several electromagnets, controlling which you can get the necessary parameters. Upon receipt of direct current regulation is carried out using the lever 24 of the traverse 23, turning the traverse, we change the angle of switching to early or late. Speed control also takes place by changing the switching angle. The principle of regulation by the lever 24 is that the normal switching of the current supply to the coils from one direction to another should occur when the coils are in the zone of the poles of the magnets. At this time, the brushes 22 of the collector 21 should be on the neutral lamellas 31. If left or right is deflected, current will flow to the coils in the opposite direction from the current lamellas 29 and either attraction or repulsion will occur. Given the speed of rotation of the machine, it is better to set the necessary parameters during operation of the machine, when the lever moves, you can immediately see the change in the voltage or speed of the machine.

Connecting a machine.

In engine mode.

Mount jumpers between terminals

2. Apply DC current to terminals 5K-6K

In generator mode.

Averaged DC voltage is obtained from terminals 5K-6K with the above jumpers. For DC separately from each group of coils need to connect one of the groups through the rectifier unit, for example terminal ₁ 2H -10K _1, the second terminal through the collector 1H -3SH _{2 2 2} 9K -7SH ₂ - shorted. The current is removed from the terminals 5K-6K. To obtain alternating current, the first group is connected to the terminals 2H ₁ -10K ₁ ; 1H ₂ -9K ₂ - the second group. If necessary, it is possible to obtain rectified voltage from one group and alternating voltage from the other. The numbers after the letter indicate the coils belong to the group:

H ₁ -W ₁ -K ₁ - 1st group

H ₂ -W ₂ -K ₂ , - 2nd group

The list of figures drawings.

1. The drawing of figure 1 shows a magnetoelectric machine.

2. The drawing of figure 2 shows the node of the collector in cross section along the longitudinal axis and the ring of the collector 21 in general terms.

3. Figure 3 shows a schematic diagram of an internal electric. network machine. The numbers 1 and 2 indicate the coils belong to the first or second groups.

4. Figure 4 shows a diagram of the interaction between the active parts - magnets and coils.

The arrows resting on the magnets show the direction of movement of the magnets in the interaction of the fields of coils and magnets. Inclined arrows with one direction ← show the moment of mutual attraction of coils and magnets. The arrows with two directions ↔ indicate the moment where the magnets repel from the coils or the magnets repel the coils. For reduction, FIG. 4 shows the interaction with two pairs of magnets and two groups of eight coils.

Claims (1)

A magnetoelectric machine, characterized in that it has a housing formed by two disks and removable sections, with machine parts installed therein, which are a collector, a stator, a rotor formed by two disks interconnected by a sleeve connected to a shaft on the inner sides of the disks along circles of equal radius, magnets are paired in parallel in parallel at a distance from each other equal to their length, with the poles of the same name pointing on one disk in one direction, on the other in the opposite direction, with the stator is formed by coils with steel cores installed in removable sections located in the space between and perpendicular to the longitudinal axis of the magnets at a distance from each other equal to the length of the magnet, covering the bifurcated magnets between the magnets mounted on different disks with the ends of the cores, the cross section of the magnets with a minimum gap, the collector is formed by two slip rings and a ring with alternating plus and minus current lamellas E separated lamellae and neutral pivot crosspiece with a control lever which provides repositioning current brushes relative sipes.

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