RU98645U1 - AUTONOMOUS MAGNETOELECTRIC GENERATOR (OPTIONS) - Google Patents

Abstract

 1. Autonomous magnetoelectric generator containing a stator, a rotor with permanent magnets, including a shaft, and a collector, characterized in that the stator is made with a field coil located on the permanent magnets installed inside the stator winding, both windings are closed by a magnetic screen, the rotor is rigidly radially mounted cores mounted on a telescopic shaft with a winding and with permanent magnets of various sizes of semicircular shape mounted on their ends, which are directed by the same name E poles towards the poles of the stator magnets, the reciprocating motion of the rotor is carried displacement mechanism fixed to the movable frame moving along the bed. ! 2. The generator according to claim 1, characterized in that the movement mechanism is a rack-and-pinion mechanism and consists of a gear gear meshed with a gear rack mounted on a movable frame that moves on rollers along the generator frame, while the gear gear is fixed on the shaft mounted in the bed. ! 3. The generator according to claim 1 or 2, characterized in that the magnetic screen is made of two magnets mounted to each other by opposite poles. !four. The generator according to claim 1 or 2, characterized in that the permanent magnets of the rotor are closed with a protective cover. ! 5. An autonomous magnetoelectric generator containing a stator, a rotor with permanent magnets, including a shaft, and a collector, characterized in that the stator is made with a field winding located on permanent magnets, the rotor is radially distributed rigidly mounted on a telescopic shaft

Description

The utility model relates to electrical engineering and energy, namely, to the field of alternative energy by converting the energy of permanent magnets into mechanical energy to produce electrical energy, and can be used in industry and in everyday life. The utility model can also be used as a drive for existing generators.

Synchronous permanent magnet generators and generator sets based on them are known, including the generator itself and the inverter controlling it, the DC-to-DC converter to the output three-phase AC voltage, and the regulating and stabilizing elements (capacitors, voltage regulators or saturation chokes). The generator usually consists of a stator and a rotor mounted on the shaft. These generators are characterized by high efficiency and low energy consumption, smaller mass and overall dimensions and differ in special designs of both the rotor and stator, as well as the composition of magnetic alloys. According to these schemes, such foreign manufacturers as SDMO (France) and Newage AVK SEG (Stamford, USA) manufacture electrical equipment. Permanent magnet generators are widely known in Russia (Balagurov V.A., Galteev F.F. Electric generators with permanent magnets. M., Energoatomizdat, 1988, 280 p.), Mainly used in wind energy, aviation and motor vehicles with power up to 2 kW The magnetic system of the generators is a cross-in-ring radial system, where one of the crossbeams of the cross is a permanent magnet and the other is a control electromagnet, the coil of which can be divided into 2 parts or used as a single coil. The ring is a magnetic circuit on which there are 4 working windings (output windings) with a pair connection. These generators are used only in machines with power up to 2 kW and are practically not used in various autonomous power supply systems.

Known linear permanent magnet generator according to the patent of the Russian Federation for invention No. 2206170 dated 10.07.2001, comprising a housing of non-magnetic material, inside of which are installed two permanent magnets rotating from the drives in the form of horizontal cylinders with spherical bulges on the sides. The third slider magnet in the form of a rectangle with convexities is installed in the middle part of the housing inside the stator winding between two rotating magnets on the rails with the possibility of reciprocating movement from one rotating magnet to another. With the reciprocating movement of the slider inside the coil, an EMF occurs, the resulting electricity enters the rectifier. The disadvantage of this generator is the presence of stepper motors as drives of rotating permanent magnets and the inability to use it as an autonomous source of electricity.

A synchronous alternating-pole generator is known (patent for utility model No. 50059 dated January 20, 2005), comprising a stator with a multiphase winding and a multi-pole rotor inductor with an excitation winding located along its axis, as well as a brushless excitation machine. The stator windings of both machines are made in the form of coils with cores placed inside the rotation figure, and the inductors form rotation figures covering the stator windings. The generator is difficult to manufacture.

The inventive generator (options), as well as known, contains a stator, a rotor with permanent magnets, including a shaft, and a collector.

The objective of the claimed utility model is to expand the scope of application of permanent magnet generators.

The technical result of an autonomous generator is to increase the EMF, power and reliability of the generator. The technical result is also the possibility of using this generator as a drive to power other generators.

The technical result is achieved by the fact that according to the first embodiment of the generator, its stator is made with an excitation winding located on permanent magnets installed inside the stator winding, both windings are closed by a magnetic screen. The rotor is a radially arranged cores rigidly fixed on a telescopic shaft with a winding and with permanent magnets of various sizes of semicircular shape mounted on their ends, which are directed by the same poles towards the poles of the stator magnets. The reciprocating movement of the rotor is carried out by a movement mechanism mounted on a movable frame moving along the bed.

The technical result is achieved by the fact that in the second embodiment of the generator, its stator is made with an excitation winding located on permanent magnets. The rotor is a radially arranged cores rigidly fixed on a telescopic shaft with a winding and with permanent magnets of various sizes of semicircular shape mounted on their ends, which are directed by the same poles towards the poles of the stator magnets. The reciprocating motion of the stator is carried out by a movement mechanism mounted on a movable frame moving along the bed.

The movement mechanism can be a rack-and-pinion mechanism and consist of a gear gear meshing with a gear rack mounted on a movable frame moving on rollers along the generator bed, while the gear gear is mounted on a shaft mounted in the frame. The magnetic screen can be made of two magnets mounted to each other by opposite poles. Permanent rotor magnets can be covered with a protective cover.

The utility model is illustrated with the help of the drawings, in which: FIG. 1 is a perspective view of an autonomous generator according to claim 1 with a longitudinal section, FIG. 2 is a cross-sectional view of a stator with a rotor, and FIG. 3 is a side view of a generator according to 1 point. formula, figure 4 is a General view of an autonomous generator according to paragraph 5 of the formula with a longitudinal section.

An autonomous generator (see FIGS. 1, 2) according to 1 independent claim consists of a stator 1, a rotor 2 and a moving mechanism 3. Stator 1 is a few (six in this embodiment) radially arranged cores 4 with a winding 5, inside of which Permanent magnets 6 are installed with an excitation winding 7, forming inductors. They provide permanent magnetization of the stator winding 5, create a magnetic field inside the stator and the primary voltage of the field winding 7, which, when it is increased, supplies power to the rotor cores 8. The voltage is removed from the stator winding 5. The stator windings 5 and 7 are closed by a magnetic screen 9, which is permanent magnets mounted by opposite poles to each other. The magnetic screen 9 provides an increase in the efficiency of using the stator magnetic field by creating counter magnetic fields to achieve maximum magnetic field concentration on the stator windings and magnetization 1, which increases the electromagnetic induction of the generator. The stator 1 is installed in the housing 10 and is mounted on a fixed frame 11.

The rotor 2 (see figure 1, 2) is three rigidly fixed to the shaft 12 of the core 8 with windings 13 located radially at an angle of 120 ° to each other. The connection of the windings is serial. At the end sections of each core 8, permanent magnets 14 are semicircular in shape. Permanent magnets 14 can be covered with a protective cover 15, preventing them from destruction at high speeds of the rotor 2 of the generator with high power. The magnets 14 can be made of different sizes and, accordingly, areas, for example, one large and two smaller, and installed by the same poles towards the poles of the stator magnets 6. The shaft 12 is installed in the bearing assembly 16 mounted on the movable frame 17, and from the stator 1 made telescopic and installed in the bearing assembly 18, mounted on the frame 11. At the other end of the shaft 12 is a collector 19, through which power is transmitted to the windings 13 of the rotor 2.

The rotor 2 is moved into the magnetic field of the stator 1 using the movement mechanism 3 (see Figs. 1, 3), which is a rack-and-pinion mechanism and consists of a gear gear 20 that engages with a gear rack 21 mounted on a movable frame 17 The gear 20 is mounted on a shaft 22 installed in the frame 11. The movable frame 17 moves on rollers 23 along the frame 11, thereby moving the rotor 2 into the stator area. When docking the casing 24 with the housing 10, the casing 24 is attached to the housing 10 by a latch (not shown). The initial movement of the frame 17 is given manually by a handle, or by a flywheel or an electric motor (not shown in the drawing), the power of which can be carried out from the battery or from the excitation winding of the generator itself.

The generator control panel (not shown in the drawings) is, for example, a dashboard with a step-up transformer, a rectifier diode bridge, electrical devices that record the parameters of the generator itself, and a variable resistor.

In the manufacture of the inventive stand-alone generator for driving the existing generators according to the second independent claim - claim 5 (see Fig. 4), the stator 25 consists of a housing 26 and permanent magnets 27 with field windings 28. The stator is mounted on a movable frame 29. The rotor 30 is made similarly to the rotor of an autonomous generator, its shaft 31 is mounted on a fixed bed 32 in the bearing units 33 and 34. The rotation of the rotor 30 in this embodiment of the utility model occurs by moving the stator 25. The movement mechanism 35 also represents th gear-rack mechanism and consists of a gear gear 36, which engages with a gear rack 37, mounted on a movable frame 29. The movable frame 29 on the rollers moves along the frame 32. The connection of the inventive generator (engine) to the shaft 38 of the main generator 39 is carried out, for example, using two coupling halves or gearbox 40.

The principle of operation of the generator. The permanent magnets 6 laid out inside the stator 1 form a balanced balanced magnetic field. The rotor 2 has an unbalanced unbalanced magnetic field, which is achieved by different sizes of magnets 14. When moving the rotor 2 in the field of the stator 1, the larger magnet of the rotor 2 is more repelled by the magnetic field of the stator 1, and two smaller ones increase the movement, thereby creating a torque of the rotor 2 That is, when moving the unbalanced magnetic field of the rotor 2 into the balanced magnetic field of the stator 1, the magnetic field of the rotor 2 due to the continuous magnetic repulsion will cause the rotor 2 to rotate Finding balance. When rotating, the rotor 2 has its own magnetic field, while the two unipolar fields do not mix, a rigid boundary and constant continuous friction arise between them, which creates a static voltage that continuously accumulates on the stator windings, which increases the efficiency of the generator. Considering that the cores in the field coil are permanent magnets, there is a minimum voltage at the terminals of the field coil. When creating a rotor 2 torque and the occurrence of an EMF, it enhances the electromagnetic induction on the field windings 7 in accordance with the law on electromagnetic induction. The voltage thus obtained on the field winding 7 is supplied to the winding 13 of the cores 8 of the rotor 2, the cores 8 become electromagnets, increasing the rotation speed of the rotor 2. This enhances the magnetic flux of the generator, and accordingly, increases its efficiency or efficiency. A bipolar magnetic screen 9, which prevents magnetic fields from extending beyond the stator winding 5, also increases the concentration of magnetic fields on the stator winding 5 and improves the efficiency of the generator.

In addition, during the operation of the generator there is a constant magnetization of its permanent magnets 6, 9, 14 by electromagnets. The magnetic screen 9 is magnetized by the stator cores 4 with the winding 5. The magnets 6 of the field winding 7 themselves become electromagnets during operation. The permanent magnets 14 of the rotor 2 are magnetized by the rotor cores 8 with a winding 13. This increases the life of the generator (options) and increases the reliability of the permanent magnets.

The principle of operation of the inventive generator used as a drive for other more powerful generators is the same.

The inventive utility model (options) is a small-sized power plant and can be used both as stand-alone power sources for powering detached buildings, objects, villages, cottages, cottages, remote from power lines, and to drive existing generators.

Claims (6)

1. Autonomous magnetoelectric generator containing a stator, a rotor with permanent magnets, including a shaft, and a collector, characterized in that the stator is made with a field coil located on the permanent magnets installed inside the stator winding, both windings are closed by a magnetic screen, the rotor is rigidly radially mounted cores mounted on a telescopic shaft with a winding and with permanent magnets of various sizes of semicircular shape mounted on their ends, which are directed by the same name E poles towards the poles of the stator magnets, the reciprocating motion of the rotor is carried displacement mechanism fixed to the movable frame moving along the bed. 2. The generator according to claim 1, characterized in that the movement mechanism is a rack-and-pinion mechanism and consists of a gear gear meshed with a gear rack mounted on a movable frame that moves on rollers along the generator frame, while the gear gear is fixed on the shaft mounted in the bed. 3. The generator according to claim 1 or 2, characterized in that the magnetic screen is made of two magnets mounted to each other by opposite poles. 4. The generator according to claim 1 or 2, characterized in that the permanent magnets of the rotor are closed with a protective cover. 5. An autonomous magnetoelectric generator comprising a stator, a rotor with permanent magnets, including a shaft, and a collector, characterized in that the stator is made with an excitation coil located on permanent magnets, the rotor is a radially arranged core with a winding and with mounted at their ends with permanent magnets of various sizes of a semicircular shape, which are directed by the same poles towards the poles of the stator magnets, reciprocating The motion of the stator carried displacement mechanism fixed to the movable frame moving along the bed. 6. The generator according to claim 5, characterized in that the movement mechanism is a rack-and-pinion mechanism and consists of a gear gear meshed with a gear rack mounted on a movable frame that moves on rollers along the generator frame, while the gear is mounted on shaft installed in the bed.