阅读说明：本技术 一种稀土永磁动力逆向多转子发电机 (Rare earth permanent magnet power reverse multi-rotor generator ) 是由 林学优 于 2019-11-29 设计创作，主要内容包括：本发明适用于动力发电技术改进领域，提供了一种稀土永磁动力逆向多转子发电机，包括驱动电机，驱动电机设于定子上，第一感应线圈设于转轴上，多个永磁体通过第一转向器设于转轴上置于第一感应线圈的左侧，多个永磁体通过第二转向器设于转轴上置于第一感应线圈的右侧，第一转子设于转轴上置于第一转向器的左侧，第二转子通过第三转向器设于转轴上置于第二转向器的右侧，转轴的一端穿过驱动电机，转轴的两端分别通过轴承及第三转向器设于定子上，第二感应线圈设于第一转子上，多个永磁体分别设于第二转子及定子上。本稀士永磁动力逆向多转子发电机的原理以及结构为简单，可靠性高，投资成本也相对较低，同时完全杜绝了环境的污染。(The invention is suitable for the technical improvement field of power generation, and provides a rare earth permanent magnet power reverse multi-rotor generator which comprises a driving motor, wherein the driving motor is arranged on a stator, a first induction coil is arranged on a rotating shaft, a plurality of permanent magnets are arranged on the rotating shaft through a first steering gear and arranged on the left side of the first induction coil, a plurality of permanent magnets are arranged on the rotating shaft through a second steering gear and arranged on the right side of the first induction coil, a first rotor is arranged on the rotating shaft and arranged on the left side of the first steering gear, a second rotor is arranged on the rotating shaft through a third steering gear and arranged on the right side of the second steering gear, one end of the rotating shaft penetrates through the driving motor, two ends of the rotating shaft are respectively arranged on the stator through a bearing and the third steering gear, the second induction coil is arranged on the first rotor, and a plurality of permanent magnets. The rare-earth permanent-magnet power reverse multi-rotor generator has the advantages of simple principle and structure, high reliability, relatively low investment cost and complete prevention of environmental pollution.)

1. A rare earth permanent magnet power reverse multi-rotor generator is characterized by comprising a stator, a first rotor, a second rotor, a rotating shaft, a first steering gear, a second steering gear, a third steering gear, a first induction coil, a second induction coil, a driving motor, a bearing and a plurality of permanent magnets, wherein the driving motor is arranged on the stator, the first induction coil is arranged on the rotating shaft, the permanent magnets are arranged on the rotating shaft through the first steering gear and are arranged on the left side of the first induction coil, the permanent magnets are arranged on the rotating shaft through the second steering gear and are arranged on the right side of the first induction coil, the first rotor is arranged on the rotating shaft and is arranged on the left side of the first steering gear, the second rotor is arranged on the rotating shaft through the third steering gear and is arranged on the right side of the second steering gear, one end of the rotating shaft penetrates through the driving motor, two ends of the rotating shaft are arranged on the stator through a bearing and a third steering gear respectively, the second induction coil is arranged on the first rotor, and the permanent magnets are arranged on the second rotor and the stator respectively.

2. The rare earth permanent magnet power reverse multi-rotor generator according to claim 1, wherein the permanent magnets on the second rotor and the second induction coil on the second rotor realize reverse cutting magnetic induction line rotation through a third steering gear.

3. The rare earth permanent magnet power reverse multi-rotor generator according to claim 1 or 2, wherein the permanent magnet on the rotating shaft and the first induction coil realize reverse cutting magnetic induction line rotation through a first steering gear and a second steering gear.

4. A rare earth permanent magnet dynamic reverse multi-rotor generator according to any of claims 1 to 3, wherein the diameter of the outer ring of the first rotor rotation is smaller than the diameter of the inner ring of the second rotor rotation.

5. A rare earth permanent magnet power reverse multi-rotor generator according to any of claim 4, wherein the first and second rotors are N-shaped in cross section.

6. The rare earth permanent magnet power generator of any one of claims 1 to 5, further comprising a starting device, wherein the starting device is an electronic starting device or a mechanical starting device, an input end of the starting device is electrically connected to an electric energy output end of the rare earth permanent magnet power generator, and an output end of the starting device is connected to an input end of the driving motor.

7. The rare earth permanent magnet power generator with multiple rotors according to claim 6, wherein when the starting device is an electronic starting device and the driving motor is a DC starting device, the starting device comprises a DC ballast, a rheostat R, a switch S1, a charging tube D1, a starting power supply B and a key switch S2, one end of the switch S1 and one end of the rheostat R are respectively connected with the input AC terminal of the DC ballast, the other end of the rheostat R is connected with the input neutral terminal of the DC ballast, the output + terminal of the DC ballast is respectively connected with the anode of the charging tube D1 and the input + terminal of the driving motor, the output-terminal of the DC ballast is respectively connected with one end of the starting switch S2 and the input-terminal of the driving motor, the cathode of the charging tube D1 is connected with the anode of the starting power supply B, the negative electrode of the starting power supply B is connected with the other end of the key switch S2.

8. The rare earth permanent magnet power reversing multi-rotor generator according to claim 6, wherein when the starting device is an electronic starting device and the driving motor is an ac starting, the driving motor is divided into a single-phase driving motor and a three-phase driving motor; when the driving motor is a three-phase driving motor, the starting device comprises a key switch S3, a key switch S4, a key switch S5, a starting switch S6, a starting switch S7, a starting switch S8, a rheostat R1, a rheostat R2 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected with an input a + end of the driving motor, one end of the key switch S4 and one end of the rheostat R2 are respectively connected with an input B + end of the driving motor, one end of the key switch S5 and one end of the rheostat R1 are respectively connected with an input C + end of the driving motor, an input-end of the driving motor is respectively connected with the other end of the rheostat R1, the other end of the rheostat R2 and the other end of the rheostat R3, one end of the starting switch S6 is connected with an input a + end of the driving motor, and the other end of the starting switch S6 is, one end of the starting switch S7 is connected with an input B + end of the driving motor, the other end of the starting switch S7 is connected with a B phase of a live line of a mains supply, one end of the starting switch S8 is connected with an input C + end of the driving motor, and the other end of the starting switch S8 is connected with a C phase of the live line of the mains supply;

when the driving motor is a single-phase driving motor, the starting device comprises a key switch S3 starting switch S6 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected with the input + end of the driving motor, the input-end of the driving motor is connected with the other end of the rheostat R3, one end of the starting switch S6 is connected with the input + end of the driving motor, and the other end of the starting switch S6 is connected with a live wire of a mains supply.

9. The rare earth permanent magnet power reversing multi-rotor generator according to claim 7, wherein when the starting device is a mechanical starting device; the front end of the rotating shaft is provided with a mechanical switching mechanism, when the driving motor is started by direct current, the starting device comprises a direct current ballast, a rheostat R, a switch S1 and a key switch S2, one end of the switch S1 and one end of the rheostat R are respectively connected with the input + end of the direct current ballast, the other end of the rheostat R is respectively connected with the input-end of the direct current ballast, the output + end of the direct current ballast is connected with the input + end of the driving motor, and the output-end of the direct current ballast is connected with the input-end of the driving motor;

when the driving motor is started by alternating current, the driving motor is divided into a single-phase driving motor and a three-phase driving motor; when the driving motor is a three-phase driving motor, the starting device comprises a key switch S3, a key switch S4, a key switch S5, a rheostat R1, a rheostat R2 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected with an input a + end of the driving motor, one end of the key switch S4 and one end of the rheostat R2 are respectively connected with an input B + end of the driving motor, one end of the key switch S5 and one end of the rheostat R1 are respectively connected with an input C + end of the driving motor, and the input-end of the driving motor is respectively connected with the other end of the rheostat R1, the other end of the rheostat R2 and the other end of the rheostat R3;

when the driving motor is a single-phase driving motor, the starting device comprises a key switch S3 starting switch S6 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected with the input + end of the driving motor, and the input-end of the driving motor is connected with the other end of the rheostat R3.

10. The rare earth permanent magnet power generator with multiple rotors according to claim 7, wherein the first and second induction coils, the permanent magnet on the second rotor and the permanent magnet on the rotating shaft are reversely cut by magnetic induction lines to generate electric energy, one part of the electric energy is connected in series with the DC motor through the DC ballast and is used for driving the driving motor installed on the stator to start kinetic energy, and the other part of the electric energy is output through three-phase AC;

the polarity of the magnet on the inner side of the permanent magnet on the stator is opposite to that of the magnet on the outer side of the permanent magnet on the second rotor.

Technical Field

The invention belongs to the field of power generation technology improvement, and particularly relates to a rare earth permanent magnet power reverse multi-rotor generator.

Background

A generator is currently the most common type of energy conversion device used to convert other forms of energy into electrical energy. In the prior art, the engine generally comprises a turbine generator, a hydraulic generator, a diesel generator, a gasoline generator and the like. Therefore, the current power generator mainly converts chemical energy into mechanical energy directly or indirectly, and therefore a large amount of energy is consumed in the conversion process, so that pollution to the environment is inevitably caused, and therefore more and more technicians begin to consider the power generator which develops new energy, such as using water conservancy, wind power, solar energy, nuclear energy and the like as a driving machine, but the nuclear energy threshold is higher, and the problems of nuclear leakage and nuclear waste treatment need to be considered; water conservancy and wind power generation are relatively environment-friendly, but the investment cost is too high, and improvement is urgently needed; and the solar power generation is greatly influenced by natural factors and has poor stability.

Disclosure of Invention

The invention aims to provide a rare earth permanent magnet power reverse multi-rotor generator, which aims to solve the technical problems in the prior art.

The invention is realized in such a way that the rare earth permanent magnet power reverse multi-rotor generator comprises a stator, a first rotor, a second rotor, a rotating shaft, a first steering gear, a second steering gear, a third steering gear, a first induction coil, a second induction coil, a driving motor, a bearing and a plurality of permanent magnets, wherein the driving motor is arranged on the stator, the first induction coil is arranged on the rotating shaft, the permanent magnets are arranged on the rotating shaft on the left side of the first induction coil through the first steering gear, the permanent magnets are arranged on the rotating shaft on the right side of the first induction coil through the second steering gear, the first rotor is arranged on the rotating shaft on the left side of the first steering gear, the second rotor is arranged on the rotating shaft on the right side of the second steering gear through the third steering gear, one end of the rotating shaft penetrates through the driving motor, two ends of the rotating shaft are arranged on the stator through a bearing and a third steering gear respectively, the second induction coil is arranged on the first rotor, and the permanent magnets are arranged on the second rotor and the stator respectively.

The further technical scheme of the invention is as follows: and the permanent magnet on the second rotor and the second induction coil on the second rotor realize reverse cutting magnetic induction line rotation through a third steering gear.

The further technical scheme of the invention is as follows: the permanent magnet and the first induction coil on the rotating shaft realize reverse cutting magnetic induction line rotation through the first steering gear and the second steering gear.

The further technical scheme of the invention is as follows: the diameter of the outer race of the first rotor rotation is smaller than the diameter of the inner race of the second rotor rotation.

The further technical scheme of the invention is as follows: the cross sections of the first rotor and the second rotor are in an N shape.

The further technical scheme of the invention is as follows: the rare earth permanent magnet power reverse multi-rotor generator further comprises a starting device, the starting device is divided into an electronic starting device or a mechanical starting device, the input end of the starting device is electrically connected with the electric energy output end of the rare earth permanent magnet power reverse multi-rotor generator, and the output end of the starting device is connected with the input end of the driving motor.

The further technical scheme of the invention is as follows: when the starting device is an electronic starting device and the driving motor is started by direct current, the starting device comprises a direct current ballast, a rheostat R, a switch S1, a charging tube D1, a starting power supply B and a key switch S2, one end of the switch S1 and one end of the rheostat R are respectively connected with an input AC end of the direct current ballast, the other end of the rheostat R is connected with an input zero line end of the direct current ballast, an output + end of the direct current ballast is respectively connected with an anode of the charging tube D1 and an input + end of the driving motor, an output-end of the direct current ballast is respectively connected with one end of the starting switch S2 and an input-end of the driving motor, a cathode of the charging tube D1 is connected with an anode of a starting power supply B, and a cathode of the starting power supply B is connected with the other end of the key switch S2.

The further technical scheme of the invention is as follows: when the starting device is an electronic starting device and the driving motor is started in an alternating current mode, the driving motor is divided into a single-phase driving motor and a three-phase driving motor; when the driving motor is a three-phase driving motor, the starting device comprises a key switch S3, a key switch S4, a key switch S5, a starting switch S6, a starting switch S7, a starting switch S8, a rheostat R1, a rheostat R2 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected with an input a + end of the driving motor, one end of the key switch S4 and one end of the rheostat R2 are respectively connected with an input B + end of the driving motor, one end of the key switch S5 and one end of the rheostat R1 are respectively connected with an input C + end of the driving motor, an input-end of the driving motor is respectively connected with the other end of the rheostat R1, the other end of the rheostat R2 and the other end of the rheostat R3, one end of the starting switch S6 is connected with an input a + end of the driving motor, and the other end of the starting switch S6 is, one end of the starting switch S7 is connected with an input B + end of the driving motor, the other end of the starting switch S7 is connected with a B phase of a live line of a mains supply, one end of the starting switch S8 is connected with an input C + end of the driving motor, and the other end of the starting switch S8 is connected with a C phase of the live line of the mains supply;

when the driving motor is a single-phase driving motor, the starting device comprises a key switch S3 starting switch S6 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected with the input + end of the driving motor, the input-end of the driving motor is connected with the other end of the rheostat R3, one end of the starting switch S6 is connected with the input + end of the driving motor, and the other end of the starting switch S6 is connected with a live wire of a mains supply.

The further technical scheme of the invention is as follows: when the starting device is a mechanical starting device; the front end of the rotating shaft is provided with a mechanical switching mechanism, when the driving motor is started by direct current, the starting device comprises a direct current ballast, a rheostat R, a switch S1 and a key switch S2, one end of the switch S1 and one end of the rheostat R are respectively connected with the input + end of the direct current ballast, the other end of the rheostat R is respectively connected with the input-end of the direct current ballast, the output + end of the direct current ballast is connected with the input + end of the driving motor, and the output-end of the direct current ballast is connected with the input-end of the driving motor;

when the driving motor is started by alternating current, the driving motor is divided into a single-phase driving motor and a three-phase driving motor; when the driving motor is a three-phase driving motor, the starting device comprises a key switch S3, a key switch S4, a key switch S5, a rheostat R1, a rheostat R2 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected with an input a + end of the driving motor, one end of the key switch S4 and one end of the rheostat R2 are respectively connected with an input B + end of the driving motor, one end of the key switch S5 and one end of the rheostat R1 are respectively connected with an input C + end of the driving motor, and the input-end of the driving motor is respectively connected with the other end of the rheostat R1, the other end of the rheostat R2 and the other end of the rheostat R3;

when the driving motor is a single-phase driving motor, the starting device comprises a key switch S3 starting switch S6 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected with the input + end of the driving motor, and the input-end of the driving motor is connected with the other end of the rheostat R3.

The further technical scheme of the invention is as follows: the first induction coil and the second induction coil are connected with the permanent magnet on the second rotor and the permanent magnet on the rotating shaft in series to reversely cut the magnetic induction line to generate electric energy, one part of the electric energy is connected with the direct current motor in series through the direct current ballast and is used for driving the driving motor installed on the stator to start kinetic energy, and the other part of the electric energy is output through three-phase alternating current;

the polarity of the magnet on the inner side of the permanent magnet on the stator is opposite to that of the magnet on the outer side of the permanent magnet on the second rotor.

The invention has the beneficial effects that: the rare earth permanent magnet rotor rotates by utilizing the magnetic force of the permanent magnets which are continuously repelled by the magnetic matching and combining the mutual matching of the direct current driving motor and the steering gear, so that the permanent magnets and the induction coil generate continuous electric energy, therefore, the principle and the structure of the rare earth permanent magnet power reverse multi-rotor generator are simple, the reliability is high, the investment cost is relatively low, and the environmental pollution is completely avoided. Meanwhile, the driving power supply is in an intermittent and instantaneous working state, so that the consumption of electric energy is very little, and an excellent energy-saving effect is achieved.

Drawings

FIG. 1 is a front view of a rare earth permanent magnet power counter-rotating multi-rotor generator provided by an embodiment of the invention.

FIG. 2 is a schematic circuit diagram of a rare-earth permanent magnet power reverse multi-rotor generator according to an embodiment of the invention;

FIG. 3 is a schematic diagram of a mechanically-actuated magnetomotive generator circuit provided by an embodiment of the invention.

Detailed Description

As shown in fig. 1-3, the rare earth permanent magnet power reverse multi-rotor generator provided by the present invention includes a stator 1, a first rotor 9, a second rotor 8, a rotating shaft 10, a first steering gear 22, a second steering gear 23, a third steering gear 24, a first induction coil 6, a second induction coil 4, a driving motor 7, a bearing 21, and a plurality of permanent magnets 2, 3, 5, wherein the driving motor 7 is disposed on the stator 1, the first induction coil 6 is disposed on the rotating shaft 10, the plurality of permanent magnets 5 are disposed on the rotating shaft 10 through the first steering gear 22 and disposed on the left side of the first induction coil 6, the plurality of permanent magnets 5 are disposed on the rotating shaft 10 through the second steering gear 23 and disposed on the right side of the first induction coil 6, the first rotor 9 is disposed on the rotating shaft 10 and disposed on the left side of the first steering gear 22, the second rotor 8 is arranged on the rotating shaft 10 through a third steering gear 24 and is arranged on the right side of the second steering gear 23, one end of the rotating shaft 10 penetrates through the driving motor 7, two ends of the rotating shaft 10 are arranged on the stator 1 through a bearing 21 and the third steering gear 24 respectively, the second induction coil 4 is arranged on the first rotor 9 and is multiple, and the permanent magnets 2 and 3 are arranged on the second rotor 8 and the stator 1 respectively.

The permanent magnet 3 on the second rotor 8 and the second induction coil 4 on the second rotor 8 realize reverse cutting magnetic induction line rotation through a third steering gear 24.

The permanent magnet 5 and the first induction coil 6 on the rotating shaft 10 realize reverse cutting magnetic induction line rotation through the first steering gear 22 and the second steering gear 23.

The diameter of the outer ring of rotation of the first rotor 9 is smaller than the diameter of the inner ring of rotation of the second rotor 8.

The first rotor 9 and the second rotor 8 have N-shaped cross sections.

The rare earth permanent magnet power reverse multi-rotor generator 11 further comprises a starting device, the starting device is divided into an electronic starting device or a mechanical starting device, the input end of the starting device is electrically connected with the electric energy output end of the rare earth permanent magnet power reverse multi-rotor generator 11, and the output end of the starting device is connected with the input end of the driving motor 7.

When the starting device is an electronic starting device, and the driving motor 7 is started by direct current, the starting device includes a direct current ballast, a rheostat R, a switch S1, a charging tube D1, a starting power supply B and a key switch S2, one end of the switch S1 and one end of the rheostat R are respectively connected to an input AC end of the direct current ballast, the other end of the rheostat R is connected to an input neutral end of the direct current ballast, an output + end of the direct current ballast is respectively connected to an anode of the charging tube D1 and an input + end of the driving motor, an output-end of the direct current ballast is respectively connected to one end of the starting switch S2 and an input-end of the driving motor, a cathode of the charging tube D1 is connected to an anode of the starting power supply B, and a cathode of the starting power supply B is connected to the other end of the key switch S2.

When the starting device is an electronic starting device and the driving motor 7 is started by alternating current, the driving motor 7 is divided into a single-phase driving motor and a three-phase driving motor; when the driving motor is a three-phase driving motor, the starting device comprises a key switch S3, a key switch S4, a key switch S5, a starting switch S6, a starting switch S7, a starting switch S8, a rheostat R1, a rheostat R2 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected with an input a + end of the driving motor, one end of the key switch S4 and one end of the rheostat R2 are respectively connected with an input B + end of the driving motor, one end of the key switch S5 and one end of the rheostat R1 are respectively connected with an input C + end of the driving motor, an input-end of the driving motor is respectively connected with the other end of the rheostat R1, the other end of the rheostat R2 and the other end of the rheostat R3, one end of the starting switch S6 is connected with an input a + end of the driving motor, and the other end of the starting switch S6 is, one end of the starting switch S7 is connected with an input B + end of the driving motor, the other end of the starting switch S7 is connected with a B phase of a live line of a mains supply, one end of the starting switch S8 is connected with an input C + end of the driving motor, and the other end of the starting switch S8 is connected with a C phase of the live line of the mains supply;

when the driving motor 7 is a single-phase driving motor, the starting device includes a key switch S3 starting switch S6 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected to the input + end of the driving motor, the input-end of the driving motor is connected to the other end of the rheostat R3, one end of the starting switch S6 is connected to the input + end of the driving motor, and the other end of the starting switch S6 is connected to a live wire of a commercial power.

When the starting device is a mechanical starting device; the front end of the rotating shaft is provided with a mechanical switching mechanism, when the driving motor 7 is started by direct current, the starting device comprises a direct current ballast, a rheostat R, a switch S1 and a key switch S2, one end of the switch S1 and one end of the rheostat R are respectively connected with the input + end of the direct current ballast, the other end of the rheostat R is respectively connected with the input-end of the direct current ballast, the output + end of the direct current ballast is connected with the input + end of the driving motor, and the output-end of the direct current ballast is connected with the input-end of the driving motor;

when the driving motor 7 is started by alternating current, the driving motor is divided into a single-phase driving motor and a three-phase driving motor; when the driving motor is a three-phase driving motor, the starting device comprises a key switch S3, a key switch S4, a key switch S5, a rheostat R1, a rheostat R2 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected with an input a + end of the driving motor, one end of the key switch S4 and one end of the rheostat R2 are respectively connected with an input B + end of the driving motor, one end of the key switch S5 and one end of the rheostat R1 are respectively connected with an input C + end of the driving motor, and the input-end of the driving motor is respectively connected with the other end of the rheostat R1, the other end of the rheostat R2 and the other end of the rheostat R3;

when the driving motor 7 is a single-phase driving motor, the starting device includes a key switch S3 starting switch S6 and a rheostat R3, one end of the key switch S3 and one end of the rheostat R3 are respectively connected to the input + end of the driving motor, and the input-end of the driving motor is connected to the other end of the rheostat R3.

The first induction coil 6 and the second induction coil 4 rotate with the permanent magnet on the second rotor 8 and the permanent magnet on the rotating shaft 10 in a reverse cutting magnetic induction line to generate electric energy, one part of the electric energy is connected with the driving motor 7 in series through the direct current ballast 12 and is used for driving the driving motor 7 arranged on the stator 1 to start kinetic energy, and the other part of the electric energy is output through three-phase alternating current;

the polarity of the magnet at the inner side of the permanent magnet on the stator 1 is opposite to the polarity of the magnet at the outer side of the permanent magnet on the second rotor 8.

The mechanical rotation mechanism may be a rope tensioner or a coupling.

The like-pole repulsive magnetic force of the permanent magnet stator 2 and the permanent magnet rotor 3 is used as a power source, the rotor permanent magnet 3 and the rotor induction coil 4 of the generator rotate reversely through increasing the power generation torque of the generator by multiple times, and the rotor permanent magnet 5 and the rotor induction coil 6 rotate reversely. Compared with the traditional generator with the stator and the rotor rotating in one direction to cut the magnetic flux of the magnetic lines, the generator has the advantage that the efficiency is doubled and the generated energy is output. Meanwhile, the volume of the generator is reduced, and materials are saved.

This reverse many rotors of rare earth permanent magnetism power generator includes tombarthite permanent magnet stator and rotates tombarthite permanent magnet rotor and the induction coil who sets up in tombarthite permanent magnet stator, its characterized in that: the permanent magnet motor comprises a rare earth permanent magnet stator, a rare earth permanent magnet rotor, a direct current driving power supply, a direct current ballast, an induction coil and a direct current driving motor, wherein the rare earth permanent magnets are uniformly arranged on the outer periphery of the rare earth permanent magnet stator, the rare earth permanent magnets are uniformly arranged on the outer periphery of the rare earth permanent magnet rotor, the induction coil is arranged in the middle of a rare earth permanent magnet rotating shaft, the rare earth permanent magnets are arranged on the left side and the right side, the induction coil is arranged on the left side.

The generator device is provided with a starting power supply of a driving motor, and when the generator normally runs, the starting power supply is closed. The like-pole repulsive magnetic force of the permanent magnet rotor 3 and the permanent magnet stator 2 of the generator is used as power, and the power of the generator is generated by the rotor induction coil 4 and the rotor induction coil 6 and is more than several times larger than that of the driving motor 7. The induction coils 4 and 6 of the generator are connected with the direct current ballast 12 in series to form a loop with the driving motor 7, so that the permanent magnet and the induction coils generate uninterrupted electric energy to be output outwards. The generator has the advantages of simple structure and low cost.

The magnetic force with like poles repelling each other serves as the power of the generator, the generating torque of the generator is increased by multiple times, the power of the generator is enabled to be generated and is more than several times larger than the 7 times of the power of the driving motor, and therefore after the generator is started, the generator can continuously generate electric energy and output the electric energy outwards.

The rare earth permanent magnet power reverse multi-rotor generator utilizes the magnetic force continuously repulsed by the magnetic matching of the permanent magnets and combines the mutual matching of the direct current driving motor and the steering gear, so that the rare earth permanent magnet rotor rotates, and the permanent magnets and the induction coils generate continuous electric energy. Meanwhile, the driving power supply is in an intermittent and instantaneous working state, so that the consumption of electric energy is very little, and an excellent energy-saving effect is achieved.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.