阅读说明：本技术 一种运动磁屏蔽加异名磁极面式发电方法和感生发电机 (Motion magnetic shielding and synonym magnetic pole surface type power generation method and induced generator ) 是由 不公告发明人 于 2019-10-19 设计创作，主要内容包括：本发明、一种运动磁屏蔽加异名磁极面式发电方法和感生发电机,属于机械能发电,涉及电力能源领域。其避免了现在机械能动生发电机在输出电能过程中,发电机转子上存在相对巨大的磁阻力问题。本发明主要采用了机械能感生发电方法,通过磁屏蔽体在相对固定静止不动的定子磁铁和定子线圈之间做屏蔽磁场运动,让穿过线圈的磁场产生变化,在线圈中产生感应电动势,再在磁屏蔽体表面和导磁体表面垂直于运动方向交替平铺固定磁铁异名磁极面,通过这个磁铁异名磁极面磁场分别与定子磁铁磁场和线圈中感应电流磁场和定子铁芯线圈平面外侧的磁铁磁场之间,同时存在作用力相反的磁吸力和磁斥力相互作用,从而达到降低磁屏蔽体运动过程中所受到的磁阻力,达到节能发电目的。(The invention discloses a motion magnetic shielding and synonym magnetic pole surface type power generation method and an induced generator, belongs to mechanical energy power generation, and relates to the field of electric power energy. The problem that the rotor of the generator has relatively huge magnetic resistance in the process of outputting electric energy by the conventional mechanical energy-driven generator is solved. The invention mainly adopts a mechanical energy induced power generation method, a magnetic shielding body does a magnetic shielding field motion between a stator magnet and a stator coil which are relatively fixed and stationary, a magnetic field passing through the coil is changed, induced electromotive force is generated in the coil, then fixed magnet unlike magnetic pole faces are alternately paved on the surface of the magnetic shielding body and the surface of a magnetizer in a direction vertical to the motion direction, and the magnetic field of the magnet unlike magnetic pole faces respectively interacts with a magnetic field of a stator magnet and a magnetic field of a magnet induced current in the coil and a magnetic field of a magnet outside the plane of a stator iron core coil, and simultaneously magnetic attraction and magnetic repulsion with opposite acting forces exist, so that the magnetic resistance force applied in the motion process of the magnetic shielding body is reduced, and the purpose of energy.)

1. The utility model provides a motion magnetic shield adds different name magnetic pole face formula power generation method and induction generator, uses including magnet, coil, magnetizer, pivot, fixed axle, insulation board, nut, bearing, flange, fixed plate, glue, constitutes generator stator and rotor, its characterized in that: the stator is to stick and fix the magnet, bearing, magnetizer and coil separately on the insulating board with glue, form the panel of stator magnet and stator iron core coil panel, the panel of stator magnet includes sticking and making the panel of independent magnetic pole face (1) of stator magnet N-pole (1-3a), the panel of independent magnetic pole face (1-3b) of stator magnet S-pole (1) with glue on the insulating board, the stator iron core coil panel (2) is between the magnetic field of different magnetic poles of this stator magnet panel, iron core (2-4) formed by magnetizer, add the coil (2-5), add the magnet (2-10) and magnetizer (2-11) and stick and form the panel of stator iron core coil (2) on the insulating board, the rotor is to connect the fixed insulating board of guide flange through the spindle, and stick and fix the magnetic shield (3-4) formed by magnetizer separately on the insulating board with glue and add the magnetic pole face (3-5a, a, 3-5b, 3-5c, 3-5d), and sticking fixed magnetizer (3-6) and different magnetic pole surface (3-5e, 3-5f) of magnet.

2. The stator of claim 1, wherein: the stator magnet N pole (1-3a) independent magnetic pole face panel (1), the stator magnet S pole (1-3b) independent magnetic pole face panel (1) and the stator iron core coil panel (2) are mutually fixed through a thread fixing shaft (10) and a matched nut (11) and a base fixing plate (12).

3. A stator core coil panel (2) according to claim 1, characterized in that: and magnets (2-10) and magnetizers (2-11) are fixed on the outer side of the iron core coil plane in the stator iron core coil panel (2).

4. A stator core coil panel (2) according to claim 1, characterized in that: the stator iron core (2-4) is a high-permeability iron core (2-4).

5. A magnet according to claim 1, wherein: the magnet is a neodymium iron boron magnet.

6. Rotor magnetic shield panel (3) according to claim 1, characterized in that: the rotor magnetic shielding panel (3) is connected with guide flanges (4, 6) with the function of tightly fixing the rotating shaft and the rotating shaft (9) through the center of the panel to be fixed with each other.

7. Rotor magnetic shield panel (3) according to claim 1, characterized in that: the rotor magnetic shielding panel (3) is formed by fixing magnetic shielding bodies (3-4) and different magnetic pole faces (3-5a, 3-5b, 3-5c and 3-5d) of magnets at the corresponding positions on the front face and the back face of an insulating plate.

8. Rotor magnetic shield panel (3) according to claim 1, characterized in that: the unlike magnetic pole faces (3-5a, 3-5b, 3-5c and 3-5d) of the fixed magnets are alternately paved on the surface of the magnetic shielding body (3-4) perpendicular to the moving direction.

9. Rotor magnetic shield panel (3) according to claim 1, characterized in that: magnetizers (3-6) and different magnetic pole surfaces (3-5e, 3-5f) of the magnets are fixed on the rotor magnetic shielding panel (3) at the corresponding position on the side corresponding to the plane of the magnets (2-10) in the stator iron core coil panel.

10. The magnetizer of claim 1, wherein: the magnetizer is a silicon steel sheet.

Technical Field

The invention discloses a motion magnetic shielding and synonym magnetic pole surface type power generation method and an induced generator, belongs to mechanical energy power generation, and relates to the field of electric power energy.

Background

At present, mechanical energy generators used in the known power generation industry are mainly of a rotary magnetic pole type and a rotary armature type, and a magnet and a coil for power generation are fixed and rotate relative to each other, move relative to a vertical cutting magnetic line to generate electric energy, and are called as dynamic power generation. In the process of rotating and generating electricity of the two generators, the input mechanical energy mainly overcomes three aspects of resistance, (1) the resistance of the rotor self mass (weight); (2) mechanical friction resistance between the rotor rotating shaft and the bearing; (3) the reluctance force on the rotor opposite the input mechanical moment. In the power generation process of the high-power mechanical energy generator, the magnetic resistance force on the rotor is relatively maximum resistance force, and the magnetic resistance force is generated by the mutual magnetic attraction force resistance force and the magnetic repulsion force resistance force between the magnet magnetic field moving relatively and the induction current magnetic field in the coil. The existing high-power mechanical energy generator mainly adopts large facility equipment forms such as firepower, water power, nuclear energy, wind power and the like to generate high-power mechanical energy input torque so as to overcome and balance magnetic resistance on a rotor of the generator. In the operation process of the high-power generation modes such as firepower, water power, nuclear power, wind power and the like, some of the high-power generation modes can cause air and environmental pollution, and some of the high-power generation modes are easily influenced by geographical environment and climate environment. In the power generation industry, how to improve the power generation efficiency and reduce the power generation energy consumption, and avoid the pollution to the environment and the influence of the environment is a target sought by all countries in the world.

Disclosure of Invention

The invention relates to a method for generating electricity by moving magnetic shield and different name magnetic pole surface and an induced generator, wherein a magnet for generating electricity and a coil for generating electricity are mutually fixed to form a stator magnet and a stator coil of the generator, a rotor magnetic shield body is moved between the stator magnet and the stator coil, the stator magnet magnetic field passing through the stator coil is shielded by the movement of the rotor magnetic shield body, so that electromotive force (voltage) is induced and generated in the stator coil, meanwhile, different name magnetic pole plane different name magnetic pole magnetic fields are formed by fixing small magnets on the surface of the magnetic shield body and the surface of a magnetic conductor of a corresponding auxiliary balance magnet newly set up at this time, and the magnetic fields of the stator magnet magnetic field, the stator coil induced alternating current magnetic field and the auxiliary balance magnet magnetic field on the outer side of the stator coil respectively correspond to each other, and the mutual magnetic force of magnetic, the magnetic repulsion force is distributed to be larger than the magnetic attraction force through manual setting, and the lever action of the solid magnetic shielding panel is utilized, the magnetic repulsion force suspension distance between the magnetic repulsion force suspension distance and the magnetic shielding body is generated, the force balance is achieved at the tail end of the magnetic repulsion force suspension distance, the magnetic shielding body is moved to be in magnetic shielding motion relative to the suspension distance at one end of the magnetic repulsion force suspension distance, so that the magnetic attraction force resistance of the magnetic field of the stator magnet and the alternating current magnetic field in the stator coil is reduced in the magnetic shielding motion process of the magnetic shielding body, the rotor rotation resistance is reduced, the power generation power is increased through simple structure and convenience in series connection, the energy-saving power generation structure method relatively reduces the rotor magnetic resistance, optimizes the rotor input energy consumption, and supplements a new power generation.

Technical scheme

The invention adopts a mechanical energy induced power generation structure method, which is a supplementary optimization function structure on the basis of the patent application technical data in the process of application by the inventor, and mainly adds and fixes a magnetizer (2-11) and a magnet (2-10) for auxiliary balance on the outer side of a stator coil plane to achieve auxiliary balance and further reduce the magnetic attraction resistance of a magnetic shielding body in magnetic shielding movement, and optimizes the width of a single magnetic pole surface in a different magnetic pole plane of the magnets corresponding to two planes of the stator coil to form the patent application data, wherein the invention patent application number is 201810153335.5; firstly, a power generation magnet and a power generation coil are relatively fixed and stationary to form a generator stator, then a magnetic shielding body is used for shielding magnetic field motion between the stator magnet and the stator coil, and the magnetic field passing through the stator coil is changed by shielding the magnetic field of the stator magnet passing through the stator coil, so that induced electromotive force (voltage) is generated in the stator coil;

magnetic shielding body (3-4) which is in magnetic shielding movement on the induced generator rotor magnetic shielding panel (3) mainly receives magnetic attraction resistance of stator magnet magnetic poles (1-3a, 1-3b) and magnetic attraction resistance mainly generated by induction alternating current in stator iron core coils (2-5), in order to reduce the two magnetic attraction resistances, the induced generator mainly specifically reduces the magnetic attraction resistance received by the magnetic shielding body (3-4) in the magnetic shielding movement by implementing six key steps:

a key step ①, fixing the generating iron core coil plane between the generating magnet magnetic pole N pole plane and S pole plane in the induced generator, wherein the planes are parallel to each other, keep the distance and are fixed to form the generator stator magnet and the stator iron core coil;

a key step ②, in the distance between the generator stator magnet magnetic pole plane (1-3a plane, 1-3b plane) and the stator core coil (2-5) plane, fixing a magnetic shielding rotor (3) rotating along the shaft, for shielding the magnetic field of the stator magnet magnetic pole passing through the stator core coil, the magnetic shielding rotor is fixed with a coaxially rotating insulating plate, and on the insulating plate front and back planes, the position corresponding to the stator magnet magnetic pole plane and the stator core coil plane is fixed with a coaxially rotating magnetic shielding body (3-4), and on the magnetic shielding body (3-4) plane is fixed with a coaxially rotating magnetic unlike magnetic pole plane to form a rotor magnetic shielding panel (3), wherein the magnetic shielding body (3-4) is a magnetic shielding body plane block made by the single high magnetic material oriented silicon steel sheet which is mutually insulated and tightly overlapped in the direction perpendicular to the moving direction, wherein the magnetic unlike magnetic pole plane is made by the single small magnet N pole plane and the single small magnet S pole plane, alternatively overlapped in the direction perpendicular to the moving direction and fixed on the magnetic shielding body (3-4) plane, and respectively:

the A surface of the rotor magnetic shielding panel, the magnetic shielding body (3-4) and the plane of the magnet unlike magnetic pole (3-5 a);

the B surface of the rotor magnetic shielding panel, the magnetic shielding body (3-4) and the plane of the magnet unlike magnetic pole (3-5B);

the rotor magnetic shielding panel C surface, the magnetic shielding body (3-4) and the magnet different magnetic pole (3-5C) plane;

the D surface of the rotor magnetic shielding panel, the magnetic shielding body (3-4) and the plane of the magnet different-name magnetic pole (3-5D);

a key step ③, in the generator, the plane of the N pole (1-3a) of the stator magnet corresponds to the A surface of the rotor magnetic shielding panel, the plane of the magnetic shielding body (3-4) and the unlike magnetic pole (3-5a) of the magnet, in the mutual corresponding process, the plane of the unlike magnetic pole (3-5a) of the magnet and the magnetic shielding body (3-4) which are relatively positioned in the same plane and the same direction of the magnetic shielding panel simultaneously receives two magnetic forces of magnetic repulsion force and magnetic attraction force from the plane of the N pole (1-3a) of the stator magnet in the same plane and the same direction of the magnetic repulsion force and the magnetic attraction force, and the directions of the magnetic repulsion force and the magnetic attraction force are opposite and the magnetic attraction force;

the magnetic shielding panel plays a lever role by taking a connecting point of the magnetic shielding panel and the rotating shaft as a fulcrum, simultaneously distributing the volume, the thickness and the magnetic pole area and the shape of the magnet of the N pole (1-3a) plane of the stator magnet and the small magnet in the (3-5a) plane, simultaneously distributing the relative distance between the two mutually corresponding planes, and simultaneously distributing to ensure that the quantity of the unlike magnetic poles in the (3-5a) plane adopts odd number (odd number) quantity, wherein the N pole is more than the S pole, and according to the principle that the like poles and the unlike poles attract each other between the magnetic poles, the magnetic repulsion force between the magnetic shielding body (3-4) and the unlike magnetic pole (3-5a) plane of the stator magnet and the N pole (1-3a) plane is larger than the magnetic attraction force, so that the magnetic repulsion force is generated among the magnetic poles and;

a key step ④, in the generator, the S pole (1-3b) plane of the stator magnet corresponds to the D surface of the rotor magnetic shielding panel, the magnetic shielding body (3-4) and the unlike magnetic pole (3-5D) plane of the magnet, in the mutual corresponding process, the magnetic shielding body (3-4) and the unlike magnetic pole (3-5D) plane in the same plane and the same direction of the magnetic shielding panel are simultaneously acted by two magnetic forces of magnetic repulsion and magnetic attraction from the S pole (1-3b) plane of the stator magnet in the same plane and the same direction of the magnetic repulsion and magnetic attraction, and the directions of the magnetic repulsion and the magnetic attraction are opposite and the magnetic attraction are acted on the same plane together;

the magnetic shielding panel plays a lever role by taking a connecting point of the magnetic shielding panel and the rotating shaft as a fulcrum, simultaneously distributing the size, the thickness and the magnetic pole area and the shape of the magnets on the S pole (1-3b) plane of the stator magnet and the small magnets on the (3-5d) plane, simultaneously distributing the relative distance between the two mutually corresponding planes, and simultaneously distributing to ensure that the quantity of the unlike magnetic poles in the (3-5d) plane adopts odd number (odd number) quantity, wherein the S pole is more than the N pole, and according to the principle that the like poles repel and the unlike poles attract among the magnetic poles, the magnetic repulsion force between the magnetic shielding body (3-4) magnetized unlike magnetic pole (3-5d) plane and the stator magnet S pole (1-3b) plane is larger than the magnetic attraction force, so that the magnetic repulsion force generated among the magnetic shielding body and the stator magnet S;

in the key step ⑤, two planes of a stator core coil (2-5) respectively correspond to a plane of a magnetic shielding body (3-4) and a magnetic unlike magnetic pole (3-5b) and a plane of the magnetic shielding body (3-4) and a magnetic unlike magnetic pole (3-5 c);

the optimized structure part is added, a group of magnetizers (2-11) and magnets (2-10) for auxiliary balance are respectively added and fixed on the outer sides of two planes of a stator iron core coil (2-5), a fixed magnetizer (3-6) and a magnet synonym magnetic pole (3-5e) plane are respectively added on the outer side of the (3-5b) plane and the outer side of the (3-5c) plane of two magnetic shielding panels and correspond to the auxiliary balance magnets (2-10), and a fixed magnetizer (3-6) and a magnet synonym magnetic pole (3-5f) plane are respectively added on the outer side of the (3-5b) plane;

wherein (3-5e) the plane corresponds to the N pole of the auxiliary balance magnet (2-10), and (3-5f) the plane corresponds to the S pole of the auxiliary balance magnet (2-10);

wherein the plane (3-5B) and the plane (3-5e) are on the same rotor magnetic shielding panel B surface to form the plane of the unlike magnetic pole (3-5B, 3-5e) of the magnet;

wherein the (3-5C) plane and the (3-5f) plane are positioned on the same rotor magnetic shielding panel C surface to form a magnet unlike magnetic pole (3-5C, 3-5f) plane;

in the process that a plane of a stator iron core coil (2-5) and an N pole plane of an outside auxiliary balance magnet (2-10) simultaneously correspond to the planes of the unlike magnetic poles (3-5b and 3-5e) of the magnets respectively, a magnetic shielding body (3-4) is added with the plane of the unlike magnetic poles (3-5b) of the magnets and simultaneously receives two magnetic forces of magnetic repulsion and magnetic attraction which are induced by alternating current magnetic fields in the stator iron core coil (2-5) from the same plane in the same direction, and the directions of the magnetic repulsion and the magnetic attraction are opposite and jointly act on the same plane;

meanwhile, the magnetizer (3-11) is added with a magnetic unlike magnetic pole (3-5e) plane, and the magnetizer is simultaneously subjected to two magnetic forces of magnetic repulsion and magnetic attraction of an N pole plane magnetic field of the auxiliary balance magnet (2-10) from the same plane in the same direction, and the directions of the magnetic repulsion and the magnetic attraction are opposite and the magnetic repulsion and the magnetic attraction act on the same plane together;

simultaneously, the number of the different magnetic poles of the planar magnet (3-5b) is distributed to be even number (even number), the even number is used for changing the magnetic polarity direction of the alternating current induced in the stator iron core coil (2-5) into an N pole or an S pole in the instant conversion, the number of the N pole and the S pole of the small magnetic pole in the different magnetic pole surface of the magnet in the corresponding plane is even number and equal, the number of the magnetic repulsion force surface and the magnetic attraction force surface is equal, and the relative distance between the two planes is distributed at the same time;

meanwhile, the connecting point of the same magnetic shielding panel and the rotating shaft is a fulcrum, and the magnetic shielding panel plays a lever role;

meanwhile, the volume, the thickness, the magnetic pole area and the shape of the small magnet in the N pole (2-10) and (3-5b, 3-5e) synonym magnetic pole planes of the auxiliary balancing magnets are distributed, and the corresponding distance between the mutually corresponding planes is distributed;

meanwhile, the number of the different-name magnetic poles in the (3-5e) plane is made to be odd number (odd number) through distribution, wherein the N pole is more than the S pole, and according to the principle that the homopolar repelling and the heteropolar attracting between the magnetic poles, the magnetic repulsion force between the magnetizer (3-6) and the magnet different-name magnetic pole (3-5e) plane and the N pole plane of the auxiliary balance magnet (2-10) is larger than the magnetic attraction force, so that the suspended space of the magnetic repulsion force is generated between the magnetizer and the auxiliary balance magnet;

a key step ⑥, in the process that the other plane of the stator core coil (2-5) and the S pole plane of the outside auxiliary balance magnet (2-10) simultaneously respectively correspond to the planes of the unlike magnetic poles (3-5c and 3-5f), the magnetic shielding body (3-4) is added with the plane of the unlike magnetic poles (3-5c) and simultaneously receives two magnetic forces of magnetic repulsion and magnetic attraction which are induced by alternating current magnetic fields in the stator core coil (2-5) from the same plane in the same direction, and the directions of the magnetic repulsion and magnetic attraction are opposite and jointly acted on the same plane;

meanwhile, the magnetizer (3-11) is added with a magnetic unlike magnetic pole (3-5f) plane, and is simultaneously subjected to two magnetic forces of magnetic repulsion and magnetic attraction of an S pole plane magnetic field of the auxiliary balance magnet (2-10) from the same plane in the same direction, and the magnetic repulsion and magnetic attraction are opposite in direction and jointly act on the same plane;

meanwhile, the number of the different magnetic poles of the planar magnet (3-5c) is distributed in an even number (even number), the even number is used for changing the magnetic polarity direction of the alternating current induced in the stator coil (2-5) into an N pole or an S pole in the instant conversion, the number of the N pole and the S pole of the small magnetic pole in the different magnetic pole surface of the corresponding planar magnet is equal to the even number, the number of the magnetic repulsion force surface and the magnetic attraction force surface is equal, and the relative distance between the two planes is distributed at the same time;

meanwhile, the connecting point of the same magnetic shielding panel and the rotating shaft is a fulcrum, and the magnetic shielding panel plays a lever role;

meanwhile, the sizes, thicknesses, magnetic pole areas and shapes of the small magnets in the S pole (2-10) and unlike magnetic pole planes (3-5c and 3-5f) of the auxiliary balancing magnets are distributed, and the corresponding distances between the mutually corresponding planes are distributed;

meanwhile, the number of the different-name magnetic poles in the (3-5f) plane is made to be odd number (odd number) by distribution, wherein S pole is more than N pole, and according to the principle that homopolar repulsion and heteropolar attraction between the magnetic poles, the magnetic repulsion force between the magnetizer (3-6) and the magnet different-name magnetic pole (3-5f) plane and the auxiliary balance magnet (2-10) S pole plane is larger than the magnetic attraction force, so that the suspended space of the magnetic repulsion force is generated between the magnetizer and the auxiliary balance magnet;

the magnetic repulsion force suspension space tail end is the balance position of the mutual force of the magnetic repulsion force and the magnetic attraction force, and the magnetic shielding body is moved in parallel in the direction perpendicular to the direction of the two forces to do magnetic shielding movement, so that the minimum relative magnetic resistance force is saved;

the magnetic shielding body (3-4) moves oppositely and parallelly at one end of the suspension distance of the magnetic repulsion force to perform magnetic shielding movement so as to reduce the resistance of magnetic attraction force, thereby achieving the purpose of saving labor and energy, and being similar to the principle that the resistance of the existing magnetic suspension train is reduced by magnetic suspension in the process of traveling, thereby reducing the resistance of magnetic attraction force received by the magnetic shielding body (3-4) in the process of performing magnetic shielding movement on four planes of an A surface, a B surface, a C surface and a D surface of the induced generator rotor magnetic shielding panel.

In the embodiment of the invention, high-permeability magnetic shielding body oriented silicon steel sheets with the width of 3 mm and the thickness of 0.25 mm are adopted, the high-permeability magnetic shielding body oriented silicon steel sheets are mutually insulated and are tightly superposed along the thickness direction to form a magnetic shielding body (3-4) plane block and a magnetizer (3-6) plane block, the thicknesses of the superposed magnetic shielding body plane block and the magnetizer plane block are 3 mm, the superposition direction of the silicon steel sheets is vertical to the movement direction, and the stator magnet, the magnet for auxiliary balance and the magnet with the different magnetic pole face adopt the NdFeB magnet N52.

Advantageous effects

The invention, in a moving magnetic shielding and different magnetic pole face type power generation method and an induced generator, the distance between a magnet for power generation and a coil is relatively larger than the distance between the magnet for power generation and the coil in the existing moving generator motor, so the utilization rate of the magnetic field intensity of the magnet for power generation is relatively low, for the weakness, the invention has simple structure, is convenient for modularized production and series assembly to increase the length of a stator coil, and is convenient for increasing the thickness of the stator magnet and the magnetic pole area, thereby achieving the purpose of increasing the power generation to make up the weakness, and simultaneously, by adopting the induced power generation structural method, the stator magnet and the stator coil are relatively fixed and fixed, the induced electromotive force (voltage) is obtained in the stator coil by moving a magnetic shielding body and the different magnetic pole face of the magnet between the stator magnetic pole and the stator coil, the whole power generation, the problem of relatively maximum motion resistance magnetic resistance in the power generation process of the high-power dynamic generator is avoided, and the method is also a beneficial supplement of a power generation structure and a method.

Drawings

An embodiment of the invention is illustrated by way of non-limiting example in the accompanying drawings, and some features and advantages of the invention will become apparent from the following detailed description. In the attached figures:

fig. 1 is a schematic diagram of the principle structure of induced power generation of a moving magnetic shield plus a different magnetic pole surface type power generation method and an induced generator of the present invention, and is a sectional view of a side view of a functional structure in a power generation structure.

In the induced power generation principle structure of fig. 1, the arrangement sequence and the relative position of the functional panels manufactured by using the insulating plate epoxy resin plate as the base plate are shown; in the fig. 1 notation:

(1) is two stator magnet panels;

(1-3a) is a stator magnet N-pole independent magnetic pole plane;

(1-3b) is the S-pole independent pole plane of the stator magnet;

(2) is a stator core coil panel;

(2-4) is the iron core in the stator core coil panel;

(2-5) are coils in the stator core coil panel;

(2-10) magnets for auxiliary balance fixed outside the coil plane in the coil panel of the stator core, wherein the magnetic pole corresponding to the B-side of the magnetic shield panel is the N-pole and the magnetic pole corresponding to the C-side of the magnetic shield panel is the S-pole;

(2-11) is a magnetizer fixed in the stator iron core coil panel, and is mutually stuck and fixed with the magnets (2-10) for auxiliary balance;

(3) two magnetic shielding panels of the rotor; the device is divided into a surface A, a surface B, a surface C and a surface D;

(3-4) magnetic shielding blocks which are made by overlapping magnetic shielding bulk silicon steel sheets in grooves on the front and back surfaces of the magnetic shielding panel;

(3-5a) is a magnet unlike magnetic pole surface fixed on the plane of the A-surface magnetic shielding block (3-4) of the magnetic shielding panel;

(3-5B) is a magnet synonym magnetic pole surface fixed on the plane of the magnetic shielding block (3-4) on the B surface of the magnetic shielding panel;

(3-5C) is a magnet synonym magnetic pole surface fixed on the plane of the magnetic shielding block (3-4) on the C surface of the magnetic shielding panel;

(3-5D) is a magnet synonym magnetic pole surface fixed on the plane of the magnetic shielding block (3-4) on the D surface of the magnetic shielding panel;

(3-5e) is a magnet unlike magnetic pole face fixed on the plane of the magnetic conductive body (3-6) on the B face of the magnetic shielding panel;

(3-5f) is a magnet unlike magnetic pole face fixed on the plane of the magnetic conductive body (3-6) on the C face of the magnetic shielding panel;

(3-6) magnetic conductors are formed by overlapping silicon steel sheets in grooves on the B surface and the C surface of the magnetic shielding panel;

in the structure of the principle of induced power generation in fig. 1, the relatively immovable functional panels are two magnet panels (1) and one iron core coil panel (2), and the three functional panels are collectively called as a generator stator.

In the induced power generation principle structure of fig. 1, the functional panels moving relative to the generator stator are collectively referred to as a generator rotor.

In the structure of the principle of induced power generation in fig. 1, the rotor function panels moving relative to the stators (1) and (2) of the generator are two magnetic shielding panels (3), the two magnetic shielding panels (3) move parallel relative to the stators at the same time, and the magnetic fields of the magnets (1-3a, 1-3b) in the two stator magnet panels (1) are shielded, so that the magnetic field passing through the stator core coil (2) is changed, and induced electromotive force is generated in the stator coils (2-5).

In the structure of the principle of induced power generation in fig. 1, the functional material for shielding the magnetic field of the magnet is the magnetic shielding bodies (3-4) on two magnetic shielding panels (3), the magnetic shielding bodies (3-4) in parallel motion relative to the stators (1) and (2) can be subjected to the magnetic field force of the stator magnets (1-3a and 1-3b) and the force of the induced current magnetic field in the stator core coils (2-5), the two magnetic field forces are applied to magnetic resistance force, in order to overcome the magnetic resistance force, the positions corresponding to the magnetic pole planes (1-3a and 1-3b) of the stator magnets and the magnetic pole planes (2-4 and 2-5) of the stator core coils on the surface plane of the magnetic shielding bodies (3-4) are alternatively fixed with the magnetic pole plane of the N pole and the magnetic pole plane of the S pole of the magnet vertical to the motion direction to form the magnetic pole plane (3-, 3-5b, 3-5c, 3-5d), wherein the number of the (3-5a) and (3-5d) plane synonym magnetic pole planes is odd number, wherein the number of the (3-5b) and (3-5c) plane synonym magnetic pole planes is even number, magnetic attraction and magnetic repulsion are generated by the synonym magnetic pole fields of the magnet synonym magnetic pole planes (3-5a, 3-5b, 3-5c, 3-5d), the magnetic field of the stator magnet magnetic poles (1-3a, 1-3b) and the induced current magnetic field in the stator core coil (2-5) simultaneously, the magnetic attraction and magnetic repulsion exist simultaneously in the same direction plane, the directions of the magnetic forces are opposite, and the number of the synonym magnetic pole of the corresponding stator magnet (1-3a) (1-3b) in the synonym magnetic pole plane is larger than the number of the synonym magnetic pole, magnetic repulsion force is larger than magnetic attraction force, magnetic attraction force resistance in movement of the magnetic shielding body (3-4) can be reduced through interaction between the magnetic repulsion force larger than the magnetic repulsion force and the magnetic shielding body (3-4), meanwhile, the optimized structure part is adopted, magnets (2-10) and magnetizers (2-11) are fixed on the outer sides of two planes of the stator iron core coil, the positions of the surfaces B and C on the magnetic shielding panel corresponding to the planes of the magnets (2-10) on the outer sides of the two planes of the stator iron core coil are respectively fixed with the magnetizers (3-6) and the two magnetic pole surfaces of the N poles and the S poles of the fixed magnets are alternately paved on the surfaces of the magnetizers (3-6) perpendicular to the movement direction to respectively form different-name magnetic pole surfaces (3-5e) and (3-5f) of the magnets, and then the same-name magnetic pole surfaces (3-5e) and the corresponding to the magnets (2-10) in the planes of the different-name magnetic poles The magnetic repulsion force is larger than the magnetic attraction force due to the fact that the number of the magnetic poles is larger than the number of the different magnetic poles, the magnetic repulsion force larger than the magnetic attraction force is interacted with the magnetic attraction force received by the moving magnetic shielding bodies (3-4) corresponding to the planes of the stator core coils (2-5) through the lever effect of the force transmitted by the magnetic shielding panel, and the magnetic attraction force resistance received by the moving magnetic shielding bodies in the moving process of the magnetic shielding bodies is reduced;

in the induced power generation principle structure shown in fig. 1, magnetic shielding bodies (3-4) and magnetizers (3-6) on two magnetic shielding panels (3) adopt high-permeability magnetic shielding body oriented silicon steel sheets with the width of 3 mm and the thickness of 0.25 mm, the high-permeability magnetic shielding bodies are mutually insulated and tightly overlapped along the thickness direction to form a block-shaped plane structure, a magnetic shielding block (3-4) plane and a magnetizer (3-6) plane are formed, the thicknesses of the magnetic shielding block plane and the magnetizer plane which are formed by overlapping are 3 mm, and the overlapping direction of the silicon steel sheets, the magnetic shielding block plane and the magnetizer plane are perpendicular to the movement direction. The fixed magnet different-name magnetic pole surfaces (3-5a, 3-5b, 3-5c and 3-5d) are alternately paved on the surface plane of the magnetic shielding block in the direction vertical to the motion direction, and the fixed magnet different-name magnetic pole surfaces (3-5e and 3-5f) are alternately paved on the surface plane of the magnetizer (3-6) in the direction vertical to the motion direction;

in the induced power generation principle structure of fig. 1, the magnet N pole and S pole directions of the magnet are marked in the stator magnet panel (1); the character patterns in the iron cores (2-4) and the coils (2-5) are marked on the stator iron core coil panel (2) to facilitate visual observation and understanding, and meanwhile, the magnetic polarity directions of the magnets (2-10) of the optimized structure part are also clearly marked; and the magnetic polarity sequence of the unlike magnetic pole faces (3-5a, 3-5B, 3-5C and 3-5D) of the magnets which are alternatively tiled and fixed and vertical to the moving direction is marked on the surface planes of the magnetic shielding blocks (3-4) of the A face, the B face, the C face and the D face of the magnetic shielding panel (3); and the magnetic polarity sequence of the unlike magnetic pole faces (3-5e, 3-5f) of the magnets which are alternatively tiled and fixed in a way of being vertical to the movement direction is marked on the surface planes of the magnetizers (3-6) on the B face and the C face of the magnetic shielding panel (3);

fig. 2 is a cross-sectional view of a side view of a functional structure in a preferred embodiment of the present invention, in which main functional panels are labeled, based on a structural diagram of the principle of induced power generation in fig. 1, and induced power generation is performed by a relative parallel rotational motion mode, in the following drawings, a front diagram shows a more complete manner of the structure of the main functional panel in fig. 2, and in fig. 2, the labels are as follows:

(1) the two stator magnet panels are an N-pole independent magnetic pole plane panel and an S-pole independent magnetic pole plane panel;

(2) is a stator core coil panel;

(3) the rotor is provided with two magnetic shielding panels which are divided into an A surface, a B surface, a C surface and a D surface;

(4) is a guide flange male type (welded with screws);

(5) the guide flange is a male type (welded with screws) guide part with 2 fastening hole sites and matched fastening screws; the 2 fastening holes are vertical to each other:

(6) is a guide flange female type (with a corresponding round hole);

(7) the guide flange is a female type (with corresponding round holes) with 2 fastening hole sites at the guide part and matched fastening screws; the 2 fastening hole positions are vertical to each other;

(8) the guide flange is a male type (welded with screws) matched nut and gasket;

(9) is a rotating shaft;

(10) is a threaded fixed shaft;

(11) is a matched nut of a threaded fixed shaft;

(12) the stator panel base fixing plate is a metal plate;

in the two stator magnet panels N pole independent magnetic pole planar panel (1) and S pole independent magnetic pole planar panel (1) in fig. 2:

(1-3a) is a stator magnet N-pole independent magnetic pole plane;

(1-3b) is the S-pole independent pole plane of the stator magnet;

(1-4) a cylindrical roller bearing in the central hole of the stator magnet panel;

and (1-5) are cylindrical roller bearings (1-4) fastening hole positions and matched fastening screws.

Fig. 3 is a front elevational view of the individual pole planar panel (1) of the stator magnet panel N-poles (1-3a) of fig. 2, in fig. 3:

(1-1) a central hole of a stator magnet panel;

(1-2) stator magnet panel fixing holes;

(1-3a) is a stator magnet N-pole independent magnetic pole plane;

and (1-6) are stator panel base fixing holes.

Fig. 4 is a front elevational view of the individual pole planar panel (1) of the stator magnet panel S-poles (1-3b) of fig. 2, in fig. 4:

(1-1) a central hole of a stator magnet panel;

(1-2) stator magnet panel fixing holes;

(1-3b) is the S-pole independent pole plane of the stator magnet;

and (1-6) are stator panel base fixing holes.

Fig. 5 is a schematic diagram of a pattern manufacturing process of the N-pole and S-pole independent magnetic pole plane panels of the stator magnet panels of fig. 3 and 4, the diagram of fig. 5 is divided into 10 isosceles trapezoid areas, the 10 isosceles trapezoids are represented by 1a to 10a, and the N-pole and S-pole independent magnetic pole planes of the stator magnet are respectively and correspondingly adhered and fixed on the 10 isosceles trapezoids on the two stator magnet panels by using epoxy resin glue.

Fig. 6 is a front elevational view of the stator core coil panel (2) of fig. 2, in fig. 6:

(2-1) is the center hole of the stator core coil panel:

(2-2) stator core coil panel fixing holes;

(2-3) iron core fixing holes in the stator iron core coil panel;

(2-4) is the iron core in the stator core coil panel;

(2-5) are coils in the stator core coil panel;

(2-6) the binding posts are formed by connecting the positive pole and the negative pole of the coil on each iron core on the two sides of the panel in series;

(2-7) the wiring terminal is a wiring terminal formed by connecting coils on 10 iron cores on the panel in series with the positive electrode and the negative electrode;

(2-8) the terminal is a power line output terminal led out after coils on 10 iron cores on the panel are mutually connected in series in positive and negative poles;

(2-9) stator panel base fixing holes;

(2-10) are magnets in the stator core coil panel;

and (2-11) are magnetizers in the stator iron core coil panel.

Fig. 7 is a schematic diagram of a graphical fabrication of the stator core coil panel (2) of fig. 6; in the graph of FIG. 7, 10 isosceles trapezoids are marked by using 1a to 10a as equal parts, namely, the 10 equal parts of the isosceles trapezoids are cut into isosceles trapezoid holes, then the isosceles trapezoid iron cores are inserted and pasted and fixed by using epoxy resin glue, then the fixed magnets (2-10) and the magnetizers (2-11) are pasted and fixed, and then coils are wound on the iron cores; 5 straight equal lines are arranged among the 10 equal parts, and the figure indicated by the arrow in figure 7 is that the 5 straight equal lines among the 10 equal parts are sequentially and gradually trimmed and shortened along the clockwise direction to display the fixed position structures of the isosceles trapezoid holes (2-3) of the iron core and the magnetizers (2-11) of the magnet (2-10), so that the stator iron core coil panel is uniformly manufactured.

Fig. 8 is a front elevational view of the bottom plate and the recesses of two magnetic shield panels (3) of the rotor of fig. 2; wherein FIG. 8-1 in FIG. 8 is a pattern of recesses of the bottom plate of the A-side and D-side of the magnetic shield panel and a pattern of fixing the magnetic shield blocks in the recesses; wherein FIG. 8-2 in FIG. 8 is a pattern of grooves of the bottom plate of the B-side and C-side of the magnetic shield panel, and a pattern of fixing the magnetic shield block (3-4) and the magnetizer (3-6) in the grooves; in fig. 8:

(3-1) is a central hole of a bottom plate of the magnetic shielding panel;

(3-2) fixing holes for guide flanges of the bottom plate of the magnetic shielding panel;

(3-3) the grooves on the bottom plate of the magnetic shielding panel are divided into grooves of magnetic shielding blocks (3-4) and grooves of magnetizers (3-6), wherein the front and back surfaces of each panel are provided with 10 same grooves for the isosceles trapezoid magnetic shielding blocks (3-4); wherein only the bottom plates of the B surface and the C surface of the magnetic shielding panel in the figure 8-2 are provided with relatively small isosceles trapezoid small grooves for magnetizers (3-6);

(3-4) the isosceles trapezoid magnetic shielding block is fixed in the isosceles trapezoid groove (3-3) on the bottom plate of the magnetic shielding panel;

and (3-6) are magnetizers fixed in small grooves on the B surface and the C surface of the bottom plate of the magnetic shielding panel.

FIG. 9 is a diagrammatic pictorial representation of a front elevational view of the bottom panel and recess of the magnetic shield panel of FIG. 8; in the graph, 10 isosceles trapezoid equal parts are respectively marked by 1 to 10, namely, equal parts at the same equal parts on the front surface and the back surface of the panel are alternately selected from 1, 3, 5, 7 and 9, and then the 5 corresponding isosceles trapezoid equal parts are cut into grooves for isosceles trapezoid magnetic shielding blocks, wherein the graph of fig. 9-1 in fig. 9 is a schematic graph for manufacturing grooves of the bottom plates of the A surface and the D surface of the magnetic shielding panel in fig. 8-1 in fig. 8, and the graph of fig. 9-2 in fig. 9 is a schematic graph for manufacturing grooves of the bottom plates of the B surface and the C surface of the magnetic shielding panel in fig. 8-2 in fig. 8.

FIG. 10 is a front plan view of the A-side (3-5a) of the rotor magnetic shield panel (3) of FIG. 2; the magnet unlike magnetic pole faces which are alternately tiled and fixed and vertical to the moving direction are added on the plane of an isosceles trapezoid magnetic shielding block (3-4) on the bottom plate of the magnetic shielding panel (3) in the figure 8-1 in the figure 8; in fig. 10:

(3-1) is a center hole of the magnetic shield panel;

(3-2) fixing holes for guide flanges of the magnetic shielding panels;

and (3-5a) small isosceles trapezoid magnet N pole S pole magnetic pole faces are alternately tiled and fixed on the isosceles trapezoid magnetic shielding block (3-4) plane on the A face bottom plate of the magnetic shielding panel perpendicular to the motion direction to form isosceles trapezoid magnet unlike magnetic pole faces.

FIG. 11 is a front plan view of the B face (3-5B) (3-5e) of the rotor magnetic shield panel (3) of FIG. 2; the magnet unlike magnetic pole faces which are alternately tiled and fixed and perpendicular to the moving direction are added on the plane of an isosceles trapezoid magnetic shielding block (3-4) on the bottom plate of a magnetic shielding panel (3) of a graph 8-2 in a graph 8 and on the plane of an isosceles trapezoid magnetizer (3-6): in fig. 11:

(3-1) is a center hole of the magnetic shield panel;

(3-2) fixing holes for guide flanges of the magnetic shielding panels;

(3-5B) small isosceles trapezoid magnet N pole S pole magnetic pole faces are alternately tiled and fixed on the plane of the isosceles trapezoid magnetic shielding block (3-4) on the B face bottom plate of the magnetic shielding panel perpendicular to the motion direction to form isosceles trapezoid magnet unlike magnetic pole faces;

(3-5e) small isosceles trapezoid magnet N pole S pole magnetic pole faces are alternately tiled and fixed on the small isosceles trapezoid magnetic shielding block (3-6) plane on the bottom plate of the B face of the magnetic shielding panel perpendicular to the motion direction to form isosceles trapezoid magnet unlike magnetic pole faces;

FIG. 12 is a front plan view of the rotor magnetic shield panel (3) at the C-plane (3-5C) (3-5f) of FIG. 2; the magnet unlike-name magnetic pole surfaces which are alternately tiled and fixed and vertical to the moving direction are added on the plane of an isosceles trapezoid magnetic shielding block (3-4) on the bottom plate of the magnetic shielding panel (3) of the figure 8-2 in the figure 8 and on the plane of an isosceles trapezoid magnetizer (3-6); in fig. 12:

(3-1) is a center hole of the magnetic shield panel;

(3-2) fixing holes for guide flanges of the magnetic shielding panels;

(3-5C) small isosceles trapezoid magnet N pole S pole magnetic pole faces are alternately tiled and fixed on the isosceles trapezoid magnetic shielding block (3-4) plane on the C face bottom plate of the magnetic shielding panel perpendicular to the motion direction to form isosceles trapezoid magnet unlike magnetic pole faces;

(3-5f) small isosceles trapezoid magnet N pole S pole magnetic pole faces are alternately tiled and fixed on the small isosceles trapezoid magnetic shielding block (3-6) plane on the bottom plate of the C face of the magnetic shielding panel perpendicular to the motion direction to form isosceles trapezoid magnet unlike magnetic pole faces;

FIG. 13 is a front plan view of the D-face (3-5D) of the rotor magnetic shield panel (3) of FIG. 2; the magnet unlike magnetic pole faces which are alternately tiled and fixed and vertical to the moving direction are added on the plane of an isosceles trapezoid magnetic shielding block (3-4) on the bottom plate of the magnetic shielding panel (3) in the figure 8-1 in the figure 8; in fig. 13:

(3-1) is a center hole of the magnetic shield panel;

(3-2) fixing holes for guide flanges of the magnetic shielding panels;

(3-5D) small isosceles trapezoid magnet N pole S pole magnetic pole faces are alternately tiled and fixed on the plane of the isosceles trapezoid magnetic shielding blocks (3-4) on the D face bottom plate of the magnetic shielding panel perpendicular to the motion direction to form isosceles trapezoid magnet unlike magnetic pole faces;

fig. 14 is a manufacturing schematic view of a front view of the a-side (3-5a) plane of the magnetic shield panel (3) of fig. 10 and the D-side (3-5D) plane of the magnetic shield panel (13); the pattern is manufactured on the basis of the bottom plate of the magnetic shielding panel in fig. 8-1, equal parts at the same positions as the isosceles trapezoid magnetic shielding blocks (3-4), five equal parts of 1, 3, 5, 7 and 9 are selected on ten equal parts planes of 1 to 10 in the diagram in fig. 14, 14 concentric circles are drawn by taking the center of the panel as the center of a circle, and 13 small isosceles trapezoids are respectively reserved between the adjacent distances of the 14 concentric circles on the five equal parts planes, namely the pattern of the unlike-name magnetic pole faces of the magnets which are alternately tiled and fixed in a direction perpendicular to the moving direction.

Fig. 15 is a manufacturing schematic view of a front view of the B face (3-5B) (3-5e) plane of the magnetic shield panel (3) of fig. 11 and the C face (3-5C) (3-5f) plane of the magnetic shield panel (3) of fig. 12, the pattern is completed on the basis of the bottom plate of the magnetic shield panel of fig. 8-2 in fig. 8, on ten equal parts of planes 1 to 10 in the diagram of fig. 15, equal parts of positions same as the isosceles trapezoid magnetic shielding blocks (3-4), five equal parts of 1, 3, 5, 7 and 9 are selected, 19 concentric circles are drawn by taking the center of the panel as the center of a circle, on the five equal planes, 17 small isosceles trapezoids are respectively left between the adjacent distances of 19 concentric circles, namely the plane patterns of the synonym magnetic pole faces (3-5b) (3-5e) of the magnets which are alternately tiled and fixed in a way of being vertical to the moving direction.

FIG. 16 is a view of the guide flange (4, 6) of FIG. 2; in fig. 16:

(4) is a guide flange male type (welded with screws);

(5) the guide flange is a male type (welded with screws) guide part with 2 fastening hole sites and matched fastening screws; the 2 fastening hole positions are mutually vertical by 90 degrees;

(6) is a guide flange female type (with a corresponding round hole);

(7) the guide flange is a female type (with corresponding round holes) with 2 fastening hole sites at the guide part and matched fastening screws; the 2 fastening hole positions are mutually vertical by 90 degrees;

(8) is a guide flange male type (welded with screws) matched nut and gasket.

Fig. 17 is a front elevational view of the stator plate base mounting plate (12) of fig. 2, which is a metal plate; in fig. 17:

(12-1) welding and fixing pins of a stator panel base fixing plate;

(12-2) vertical fixing holes are formed in welding fixing pins of a stator panel base fixing plate;

and (12-3) are parallel fixing holes on the fixing plate of the stator panel base, and are mutually fixed with the stator panel for use.

Fig. 18 is a cross-sectional view of a top view of the stator plate base retainer plate (12) of fig. 17; in fig. 18:

(12-1) welding and fixing pins of a stator panel base fixing plate;

(12-2) vertical fixing holes are formed in welding fixing pins of a stator panel base fixing plate;

and (12-3) are parallel fixing holes on the fixing plate of the stator panel base, and are mutually fixed with the stator panel for use.

Fig. 19 is a diagram of the power generation structure of fig. 2, which is based on the series connection of 4 groups of power generation structures, and is duplicated in the coaxial direction, so as to show the advantage trend of the invention that the structure is simple, and the series connection is easy to increase the power generation power.

Detailed Description

The following detailed description of the preferred embodiments of the present invention, taken in conjunction with the accompanying drawings, will make the advantages and features of the invention easier to understand by those skilled in the art, and thus will clearly and clearly define the scope of the invention.

The assembly materials used in one embodiment of the invention are respectively:

(I): 3 square 2 round epoxy boards were used; wherein the side length of the square is 840 mm, the thickness of the square is 40 mm, and the thickness of the square is 20 mm; the diameters of the 2 circles are 680 mm, and the thicknesses of the 2 circles are 20 mm; 2 epoxy resin plate panels with square thickness of 40 mm are used for manufacturing the stator magnet panel (1); another square panel with the thickness of 20 mm is used for manufacturing a stator iron core coil panel (2); 2 circular epoxy resin plate panels with the thickness of 20 mm are used for manufacturing the rotor magnetic shielding panel (3).

(II): 20 stator magnets (1-3a, 1-3b) are used, each stator magnet is an isosceles trapezoid neodymium iron boron magnet N52, the thickness of each stator magnet is 20 mm, the isosceles height is 90 mm, the angle between the isosceles magnets is 24 degrees, the length of an upper base arc is 58.64 mm, the length of a lower base arc is 96.34 mm, and two magnetic poles are respectively arranged on two planes in the thickness direction; the stator magnet plan views, including the epoxy board plan views used in combination, are shown in figures 3 and 4, respectively, in the accompanying drawings; the schematic diagram of the planar dimension manufacturing method is shown in the attached drawing and is figure 5.

(III): 20 magnetic shielding bodies (3-4) and magnet different-name magnetic pole faces (5 blocks of 3-5a planes, 5 blocks of 3-5b planes, 5 blocks of 3-5c planes and 5 blocks of 3-5d planes) are used; using 10 magnetizers and magnet unlike magnetic pole planes (5 planes 3-5e and 5 planes 3-5 f);

1. the magnetic shielding bodies (3-4) and the magnetizers (3-6) are isosceles trapezoid magnetic shielding block (3-4) planes and magnetizer (3-6) planes which are formed by mutually insulating and closely superposing high-permeability magnetic shielding body oriented silicon steel sheets along the thickness direction, the width of each oriented silicon steel sheet is 3 mm, the thickness of each oriented silicon steel sheet is 0.25 mm, and the thickness of each isosceles trapezoid magnetic shielding block (3-4) plane and magnetizer (3-6) plane is 3 mm; the plane of the magnetic shielding block (3-4), the plane graph of the magnetizer (3-6) and the plane graph of the bottom plate of the magnetic shielding panel (3) are manufactured together, and the attached drawing is figure 8; a schematic diagram of a method of making a plan view is shown in fig. 9;

2. the magnet unlike the magnetic pole face 5 pieces 3-5a plane, 5 pieces 3-5b plane, 5 pieces 3-5c plane, 5 pieces 3-5d plane, each thickness 10 mm, two magnetic poles in the thickness direction, also isosceles trapezoid, and isosceles trapezoid magnetic shielding block (3-4) the same size, all isosceles height 130 mm, the angle between the isosceles 36 degrees, the upper base arc length 75.4 mm, the lower base arc length 157.08 mm, the arc length direction is parallel to the direction of motion, two isosceles trapezoids in the thickness direction through epoxy resin glue to coincide with each other and paste fixedly; each of 5 unlike magnetic pole faces of the magnet is 10 mm thick, the two magnetic poles are isosceles trapezoids in the thickness direction, the sizes of the 5 unlike magnetic pole faces are the same as those of the isosceles trapezoid magnetizers (3-6), the isosceles heights of the two magnetic poles are 30 mm, the angles among the isosceles trapezoids are 36 degrees, the length of an upper base arc is 188.5 mm, the length of a lower base arc is 207.35 mm, the arc length direction is parallel to the movement direction, and the two isosceles trapezoids are overlapped and stuck fixedly in the thickness direction through epoxy resin glue;

3. wherein 5 (3-5a) plane magnet synonyms magnetic pole faces, every 13 small isosceles trapezoid magnet magnetic poles N pole S pole and isosceles height order that from the isosceles trapezoid lower bottom to the upper bottom circle center direction tiling fixed are: 1. n pole 10 mm; 2. 10 mm for the S pole: 3. n pole 10 mm; 4. s pole 10 mm; 5. n pole 10 mm; 6. s pole 10 mm; 7. n pole 10 mm; 8. s pole 10 mm; 9. n pole 10 mm; 10. s pole 10 mm; 11. n pole 10 mm; 12. s pole 10 mm; 13. n pole 10 mm; the graphic plane structure is fig. 10 in the drawings;

4. wherein 5 (3-5b) plane magnet synonyms magnetic pole faces, every one from isosceles trapezoid go to bottom to upper base centre of circle direction tiling fixed 14 little isosceles trapezoid magnet magnetic pole N utmost point S utmost point and isosceles height order of magnet are: 1. n pole 10 mm; 2. s pole 10 mm; 3. the N pole is 9 mm; 4. the S pole is 9 mm; 5. the N pole is 9 mm; 6. the S pole is 9 mm; 7. the N pole is 9 mm; 8. the S pole is 9 mm; 9. the N pole is 9 mm; 10. the S pole is 9 mm; 11. the N pole is 9 mm; 12. the S pole is 9 mm; 13. n pole 10 mm; 14. s pole 10 mm; wherein 5 (3-5e) plane magnet synonyms magnetic pole faces, every 3 little isosceles trapezoid magnet magnetic pole N utmost point S poles and isosceles height order that from the isosceles trapezoid lower bottom to the upper base centre of a circle direction tiling fixed are: 1. n pole 10 mm; 2. s pole 10 mm; 3. n pole 10 mm; the graphic plane structure is fig. 11 in the accompanying drawings;

5. wherein 5 (3-5c) plane magnet synonyms magnetic pole faces, every one from isosceles trapezoid go to bottom to upper base centre of circle direction tiling fixed 14 little isosceles trapezoid magnet magnetic pole N utmost point S utmost point and isosceles height order of magnet are: 1. s pole 10 mm; 2. n pole 10 mm; 3. the S pole is 9 mm; 4. the N pole is 9 mm; 5. the S pole is 9 mm; 6. the N pole is 9 mm; 7. the S pole is 9 mm; 8. the N pole is 9 mm; 9. the S pole is 9 mm; 10. the N pole is 9 mm; 11. the S pole is 9 mm; 12. the N pole is 9 mm; 13. s pole 10 mm; 14. n pole 10 mm; wherein 5 (3-5f) plane magnet synonyms magnetic pole faces, every 3 little isosceles trapezoid magnet magnetic pole N utmost point S poles and isosceles height order that from the isosceles trapezoid lower bottom to the upper base centre of a circle direction tiling fixed are: 1. s pole 10 mm; 2. n pole 10 mm; 3. s pole 10 mm; the graphic plane structure is fig. 12 in the accompanying drawings;

6. wherein 5 (3-5d) plane magnet synonyms magnetic pole faces, every 13 small isosceles trapezoid magnet magnetic poles N pole S pole and isosceles height order that from the isosceles trapezoid lower bottom to the upper base centre of a circle direction tiling fixed are: 1. s pole 10 mm; 2. n pole 10 mm; 3. s pole 10 mm; 4. n pole 10 mm; 5. s pole 10 mm; 6. n pole 10 mm; 7. s pole 10 mm; 8. n pole 10 mm; 9. s pole 10 mm; 10. n pole 10 mm; 11. s pole 10 mm; 12. n pole 10 mm; 13. s pole 10 mm; the graphic plane structure is fig. 13 in the accompanying drawings;

7. wherein the (3-5a) plane is the A plane of the magnetic shield panel;

wherein the (3-5B) plane is the B-plane of the magnetic shield panel;

wherein the (3-5C) plane is the C-plane of the magnetic shield panel;

wherein the (3-5D) plane is the D-plane of the magnetic shield panel.

(IV): using 10 stator cores (2-4) which comprise two layers of insulating cloth required to be wound at the winding part of each stator core, wherein each stator core is made of a high-permeability magnetic-permeability material, single oriented silicon steel sheets with the length of 90 mm and the thickness of 0.25 mm are adopted, and are mutually insulated and tightly overlapped along the thickness direction to form an isosceles trapezoid, each isosceles trapezoid stator core has the thickness of 90 mm, the angle between the isosceles trapezoid is 24 degrees, the isosceles height is 90 mm, the upper bottom arc length is 58.64 mm, and the lower bottom arc length is 96.34 mm; the plan view of the stator core and the plan view of the epoxy resin plate panel used in combination are shown in fig. 6 and the plan view size figure forming method is shown in fig. 7.

(V): the stator coil is used for 20 groups (2-5) and is wound on an isosceles trapezoid iron core to form a stator core coil, the coils on each iron core are divided into two groups on two sides of a panel, the outer planes of the coils and the iron core planes are on the same plane and are connected in series through binding posts, and the wire used by the coils is an enameled round copper wire with the diameter of 1 mm.

(VI): 20 magnets (2-10) and 20 magnetizers (2-11) are used on a stator iron core coil panel, the magnets (2-10) are isosceles trapezoid neodymium iron boron magnets N52, the thickness of each magnet is 35 mm, the equivalent height is 30 mm, the angle between the isosceles trapezoids is 30 degrees, the length of an upper bottom arc is 157.08 mm, and the length of a lower bottom arc is 172.79 mm; the magnetizer (2-11) is formed by tightly overlapping single silicon steel sheets along the thickness direction to form a thickness of 5 mm, the angle between the isosceles angles is 30 degrees, the upper bottom arc length is 154.46 mm, the lower bottom arc length is 157.08 mm, and the magnetizer is mutually stuck and fixed with the magnet (2-10) to play a role of a magnetic conduction path.

(seventh): 4 circular guide flanges (4 and 6) with a function of fixing a rotating shaft by fastening screws are used, the inner diameter of each guide flange is 30 mm, the length of each guide flange is 38 mm, and the diameter of the outer circle of each flange is 100 mm, wherein 6 screws are uniformly and symmetrically welded on the plane of each flange at a position which is 85 mm apart around the circle center symmetrically, the distance between the symmetrical centers of the screws is 85 mm, the length of each screw is 65 mm, the diameter of each screw is 8 mm, each screw is matched with 1 gasket and 2 nuts, and the same positions of the other two guide flanges respectively correspond to 6 circular holes with the diameter of 9 mm; the circular guide flange configuration is illustrated in figure 16 of the drawings.

(eighth): 2 cylindrical roller bearings are used, and can be fixed on a rotating shaft through a set screw, wherein the inner diameter of each cylindrical roller bearing is 30 mm, and the outer diameter of each cylindrical roller bearing is 62 mm.

(nine): one rotating shaft is used, the length of the rotating shaft is 700 mm, and the diameter of the rotating shaft is 30 mm.

(ten): 10 threaded fixing shafts are used, 60 matched nuts are used, and the length of each threaded fixing shaft is 500 mm, and the diameter of each threaded fixing shaft is 20 mm.

(eleven): fixing 3 stator panel bases and 18 matched screws and nuts; is a metal base fixing plate;

the stator panel base fixing plate is 840 mm in length, 60 mm in width and 10 mm in thickness, 5 parallel circular fixing holes are formed in the horizontal line of the center of the stator panel base fixing plate panel, the diameter of each circular fixing hole is 20 mm, one circular fixing hole is located in the center of the panel, and the distance between the 5 parallel adjacent circular centers of the circular fixing holes is 180 mm;

fixing feet are welded on two sides of the bottom of the fixing plate of the stator panel base, the plane of each fixing foot is perpendicular to the plane of the fixing plate of the stator panel base, and the length, the width and the thickness of each fixing foot are 100 mm, 60 mm and 30 mm respectively; a rectangular vertical fixing hole is respectively arranged on the plane central points of the two fixing legs along the length directions of the two sides, the length of the rectangular fixing hole is 50 mm, and the width of the rectangular fixing hole is 20 mm;

the stator face plate base retainer plate plan view is in the attached figures fig. 17; the cross-sectional view of the top view is fig. 18.

(eleven): 1 kg of epoxy glue was used.

The first step is as follows: uniformly manufacturing parts with the same function; firstly, manufacturing the parts with the same graph structures of a stator magnet panel (1) and a stator iron core coil panel (2); in the accompanying drawings are figures 5 and 7 respectively;

1. on 6 planes of 3 square epoxy resin plates, 4 concentric circles are drawn respectively by taking the center of the plane of the panel as the center of a circle, wherein the diameter of one circle is 500 mm, the diameter of one circle is 460 mm, the diameter of one circle is 280 mm, and the diameter of one circle is 240 mm.

2. Then respectively drawing 3 concentric circles with the circle center as the center, wherein the diameter of one concentric circle is 840 mm, then respectively cutting the half side length of the square panel as the boundary into a semicircle along the half circumference of the circle, and keeping the other half plane right angle of the 3 square panels as the bottom of the generator stator panel;

another concentric circle is 760 mm in diameter, then a small circle with the diameter of 20 mm is respectively drawn by taking the intersecting position of the central vertical line of the plane at the bottom of the right angle of the plane of the panel and the circumferential line as the center, then 10 small circles with the diameter of 20 mm are uniformly drawn on the circumferential line with the diameter of 760 mm at equal intervals by taking the small circle as the starting point, and then 10 small circular holes with the diameter of 20 mm are respectively cut out to be used as fixing holes (1-2 and 2-2) of the stator magnet panel (1) and the stator iron core coil panel (2);

the third concentric circle has a diameter of 62 mm and is then cut into circular holes having a diameter of 62 mm, respectively.

3. Then drawing 5 straight equal lines passing through the center of a circle at the same position on a circumference line with the diameter of 840 mm in 6 planes of the 3 panels respectively, equally dividing the concentric circles with the diameter of 840 mm and the diameter of 240 mm into 10 uniform isosceles trapezoids, wherein the isosceles height between the concentric circles with the diameter of 500 mm and the diameter of 240 mm is 130 mm, the angle between the isosceles trapezoids is 36 degrees, the length of the upper base arc of the isosceles trapezoid is 75.4 mm, and the length of the lower base arc is 157.08 mm; for easy understanding and operation, the 10 isosceles trapezoids on the same position of each panel are respectively numbered identically, namely 1 equal part, 2 equal parts, 3 equal parts, 4 equal parts, 5 equal parts, 6 equal parts, 7 equal parts, 8 equal parts, 9 equal parts and 10 equal parts; the area positions of the 10 isosceles trapezoids are used as magnetic shielding areas;

then drawing 10 straight lines at equal intervals on two sides of the 10 isosceles trapezoid equal lines to pass through the circle center, respectively and uniformly leaving 12-degree included angle distances between the adjacent isosceles trapezoids of the 10 identical equal lines, forming 10 identical small isosceles trapezoids with 12-degree included angles at intervals among concentric circles with the diameters of 460 millimeters and 280 millimeters, wherein the small isosceles trapezoids are uniformly distributed around the circle center, are arranged in the middle of the large isosceles trapezoid, and for convenience of understanding and operation, the small isosceles trapezoids are respectively added with new numbers on the basis of the numbering of the large preceding isosceles trapezoid equal lines, and then respectively form new same numbers from the new equal numbers together; 1a aliquot, 2a aliquot, 3a aliquot, 4a aliquot, 5a aliquot, 6a aliquot, 7a aliquot, 8a aliquot, 9a aliquot, 10a aliquot; these small isosceles trapezoids are 90 mm in isosceles height, 24 degrees between the isosceles, 58.64 mm in upper base arc length, and 96.34 mm in lower base arc length.

4. Then respectively drawing 2 circles in the left and right directions of the horizontal line of the center of the stator panel of the right-angle side at the bottom of the 3 panels respectively, wherein the diameters of the 4 circles are respectively 20 mm, the distance between the centers of the 5 adjacent circles is 180 mm, then cutting the circles into circular holes with the diameters of 20 mm, and the 5 circular holes on the horizontal line are simultaneously used as the fixing holes of the stator panel base.

The second step is that: manufacturing 2 stator magnet panels (1); in the drawings are figures 3 and 4;

1. firstly, respectively installing a cylindrical roller bearing with a bearing tightening function in 2 panel center holes with the thickness of 40 mm, wherein the bearing tightening holes are exposed out of the plane of the panel to facilitate the bearing tightening; and then coating epoxy resin glue to ensure that the outer shaft diameter of the bearing and the epoxy resin plate are mutually adhered and fixed.

2. Fixing stator magnets on the back planes of the panels, which are exposed out of the bearing fastening hole positions, respectively, smearing epoxy resin glue on 10 isosceles trapezoid planes, which are equal in number from 1a to 10a, on the back planes, then respectively pasting all isosceles trapezoid neodymium-iron-boron magnet S-pole magnetic pole planes on one of the panels, wherein the labels in attached figures 2 and 3 are (1-3a), and manufacturing a stator magnet N-pole independent magnetic pole plane panel (1); and (3) adhering the other panel to the N-pole magnetic pole plane of the isosceles trapezoid neodymium-iron-boron magnet, wherein the N-pole magnetic pole plane is marked with (1-3b) in attached figures 2 and 4, and manufacturing the S-pole independent magnetic pole plane panel (1) of the stator magnet.

The third step: 1 stator iron core coil panel (2) is manufactured;

1. optionally selecting 1 plane on 1 stator panel plane with the thickness of 20 mm, taking the center of the original concentric circle as the center, and drawing 5 concentric circles, wherein the diameter of the first circle is 200 mm, the diameter of the second circle is 540 mm, the diameter of the third circle is 590 mm, the diameter of the fourth circle is 600 mm, and the diameter of the fifth circle is 660 mm.

2. Then, on a circumference line with the diameter of 200 mm, 10 small round holes are drilled on the intersection points of 5 equal lines of the isosceles trapezoid with 1 equal line to 10 equal lines, the diameter of each small round hole is 5 mm, and 10 matched copper screw nuts are installed and fixed to serve as binding posts, wherein the binding posts are used as binding posts (2-6 in attached figure 6) for connecting the positive and negative electrodes of two groups of coils on each iron core on two sides of the panel in series.

3. Then, on a circumference line with the diameter of 540 mm, at the intersection point position of the extension lines at the two ends of 5 equal lines of an isosceles trapezoid with the diameter of 1 equal line to 10 equal lines, 10 small round holes with the diameter of 5 mm are drilled, and 10 matched copper screw nuts are installed and fixed to serve as binding posts, wherein the binding posts are used as binding posts for connecting the positive and negative electrodes of coils on 10 iron cores in series (2-7 in attached figure 6).

4. Then, on the intersection point of the equal lines on the left side and the right side of the 9a equal part and the circumference line with the diameter of 760 mm, 2 round holes are drilled, the diameter of each round hole is 5 mm, and 2 matched copper screw nuts are installed and fixed to serve as binding posts, wherein the binding posts are used as power line output binding posts (2-8 in attached figure 6) led out after coils on 10 iron cores are mutually connected in series in the positive and negative poles.

5. Then two straight lines passing through the center of the circle are drawn on two sides of the equal division line between the 1 equal division line and the 10 equal division line, included angles between the two straight lines and the middle equal division line are respectively 3 degrees, an included angle between the two included angle lines is 30 degrees in a region from 1 equal part to 10 equal parts, a concentric circle with the diameter of 590 mm and the diameter of 600 mm, a narrow equal part between the region from 1 equal part to 10 equal parts and an intersection point of the two included angle lines is a position of the magnetizer (2-11), a concentric circle with the diameter of 600 mm and the diameter of 660 mm, an equal part between the region from 1 equal part to 10 equal parts and an intersection point of the two included angle lines is a position of the magnet (2-10), the magnet (2-10) and the magnetizer (2-11) are mutually stuck and fixed at the position of the region of the panel, and the magnet (2-10) and the magnetizer (2-11) are on the same plane; the graphical production schematic is in appended fig. 7.

6. Then, the 10 small isosceles trapezoids are formed by equally dividing the 1a into 10a, 10 isosceles trapezoid apertures (2-3) are cut along the edge lines of the isosceles trapezoids, the isosceles trapezoid iron cores (2-4) are correspondingly inserted, 35 mm long iron cores (2-4) respectively extend out of the planes of the two sides of the panel, and epoxy resin glue is smeared at the junction of the panel and the iron cores to be fixed mutually.

7. And then, two layers of insulating cloth are wound on the 35 mm long iron cores (2-4) extending out of the two sides of the panel respectively, and then coils (2-5) are wound, wherein the coils can be directly wound, or can be wound on a die with the same size in advance and then directly sleeved.

8. Then, the positive and negative poles of two groups of coils on each iron core on two sides of the panel are connected in series through binding posts (2-6 in the attached figure 6).

9. Then, the coils on the 10 iron cores are mutually connected in series by positive and negative poles through binding posts (2-7 in attached figure 6); and two power lines are led out to connect two power output terminals (2-8 in the attached figure 6).

10. Then coating epoxy resin glue to adhere the coil, the iron core and the epoxy resin plate to form a whole.

The fourth step: manufacturing 2 rotor magnetic shielding panel (3) bottom plates; in the accompanying figures is the figure 8 diagram; the schematic of the graphic fabrication method is fig. 9;

1. firstly, drawing 4 concentric circles, one circle with the diameter of 500 mm, one circle with the diameter of 240 mm, one circle with the diameter of 85 mm and one circle with the diameter of 30 mm on 4 planes of two circular epoxy resin plate panels by taking the center of the panels as the center of a circle; and then drawing 2 concentric circles, one circle with the diameter of 600 mm and one circle with the diameter of 660 mm, on one plane of each panel by taking the center of the panel as the center of a circle, manufacturing bottom plates of the B surface and the C surface of the magnetic shielding panel, and manufacturing the A surface and the D surface of the magnetic shielding panel on the other two planes.

2. Then, circular holes having a diameter of 30 mm were cut into the circular holes, respectively.

3. Then respectively drawing 6 small circles at the same positions on the circumference line with the diameter of 85 mm on the two panels, uniformly and symmetrically drawing the 6 small circles around the circle center, wherein the distance between the symmetrical circle centers of the small circles is 85 mm, the diameter of each small circle is 8 mm, and then respectively cutting the small circles into 6 small holes with the diameter of 8 mm to be used as fixing holes of the guide flange.

4. Then respectively drawing 5 straight lines passing through the center of a circle at the same position on a circumference line with the diameter of 500 mm on 4 planes of the two circular magnetic shielding panels, and equally dividing concentric circles with the diameters of 500 mm and 240 mm into 10 uniform equal isosceles trapezoids, wherein the isosceles heights are 130 mm, the angles between the isosceles trapezoids are 36 degrees, the upper base arc length of the isosceles trapezoid is 75.4 mm, and the lower base arc length is 157.08 mm; the isosceles trapezoids on the two planes of each panel correspond in position, and for convenience of understanding and operation, 10 corresponding isosceles trapezoids on the two planes of each panel are numbered identically, namely 1 equal part, 2 equal parts, 3 equal parts, 4 equal parts, 5 equal parts, 6 equal parts, 7 equal parts, 8 equal parts, 9 equal parts and 10 equal parts.

5. Then, equal lines are respectively extended to the intersection point of the diameter of the circle 600 mm and the diameter of the circle 660 mm on the B surface and the C surface of the two circular magnetic shielding panels, a relatively small isosceles trapezoid is formed between the diameter of the circle 600 mm and the diameter of the circle 660 mm, and the equal lines are the positions of the grooves (3-3) for the magnetizers (3-6).

6. Then, on 4 planes of the two circular magnetic shielding panels, 1 equal part, 3 equal parts, 5 equal parts, 7 equal parts and 9 equal parts are alternately selected from 1 equal part to 10 equal parts respectively, and then, 20 magnetic shielding blocks selected on the 4 planes are cut into isosceles trapezoid grooves (3-3) according to isosceles trapezoid shape marginal lines by using isosceles trapezoids, wherein the depth of each isosceles trapezoid groove (3-3) is 8 mm; then the B-surface and C-surface magnetic conductive bodies (3-6) are cut into 8 mm in depth by the grooves (3-3).

The fifth step: 2 rotor magnetic shielding panels (3) are manufactured, wherein the A surface is B surface, and the C surface is D surface; among the accompanying drawings are fig. 10, 11, 12, 13, respectively; the schematic diagrams of the graphic production method are respectively fig. 14 and fig. 15;

1. firstly, coating epoxy resin glue at the bottom of an isosceles trapezoid groove on the A surface of one magnetic shielding panel (3), correspondingly placing 5 adhered and fixed magnetic shielding body planes (3-4) and a magnet unlike magnetic pole plane (3-5a) plane, placing the magnetic shielding blocks (3-4) plane into the groove bottom for adhering and fixing, enabling the 5 magnet unlike magnetic pole planes (3-5a) to be on the same plane, and coating the epoxy resin glue between the magnet unlike magnetic pole plane and the epoxy resin plate for mutual fixation to form the A surface of the magnetic shielding panel; in the drawings is FIG. 10;

2. then coating epoxy resin glue at the bottom of the groove on the other surface B of the surface A, and then pasting and fixing 5 magnetic shielding bodies (3-4) plane with a magnet unlike magnetic pole surface (3-5B) plane and 5 magnetizers (3-6) plane with a magnet unlike magnetic pole surface (3-5e) plane, wherein the magnetic shielding blocks (3-4) plane and the magnetizers (3-6) plane are placed at the bottom of the groove for pasting and fixing; the planes (3-5e) of the 5 magnet unlike magnetic pole faces (3-5B) are on the same plane, and then epoxy resin glue is coated between the magnet unlike magnetic pole faces and the epoxy resin plate and fixed with each other to form a B surface of the magnetic shielding panel; among the accompanying figures is figure 11;

3. then coating epoxy resin glue on the bottom of an isosceles trapezoid groove on the C surface of the other magnetic shielding panel (3), then correspondingly placing 5 fixed magnetic shielding bodies (3-4) plane and magnet unlike magnetic pole surface (3-5C) plane and 5 magnetic conductor (3-6) plane and magnet unlike magnetic pole surface (3-5e) plane which are well stuck, placing the magnetic shielding blocks (3-4) plane and the magnetic conductor (3-6) plane into the groove bottom to be stuck and fixed, placing the 5 magnet unlike magnetic pole surfaces (3-5C) plane (3-5f) plane on the same plane, and coating epoxy resin glue between the magnet unlike magnetic pole surfaces and the epoxy resin plate to be mutually fixed to form the C surface of the magnetic shielding panel; in the accompanying drawings is figure 12;

4. then, coating epoxy resin glue at the bottom of the groove on the D surface, correspondingly placing 5 bonded and fixed magnetic shielding bodies (3-4) plane and a magnet unlike magnetic pole surface (3-5D) plane, and placing the magnetic shielding blocks (3-4) plane into the bottom of the groove for bonding and fixing; the planes of the 5 different-name magnetic pole faces (3-5D) of the magnets are on the same plane, and then epoxy resin glue is smeared between the different-name magnetic pole faces of the magnets and the epoxy resin plate and fixed with each other to form a D surface of the magnetic shielding panel; in the accompanying drawings is figure 13.

The fifth step: assembling the stator and the rotor of the generator:

1. firstly, 3 stator panel base fixing plates (12) are respectively installed on the bottom right-angle edges of 2 stator magnet panels (1) and 1 stator iron core coil panel (2), wherein a fixing screw is not used in 1 fixing hole in the middle of 5 parallel fixing holes, the center hole is coincided with the fixing hole of the stator panel to penetrate into the thread fixing shaft (10), and then the matched nut (11) of the thread fixing shaft is screwed down.

2. Then, 10 thread fixing shafts (10) penetrate into 10 fixing holes (2-2) on the stator iron core coil panel (2) and penetrate in the center distance of the thread fixing shafts, 2 nuts (11) are screwed into two ends of each thread fixing shaft (10), the stator iron core coil panel (2) and the thread fixing shafts (10) are screwed and fixed through two nuts (11), the other two nuts (11) are not screwed and keep the distance of 100 mm, and the purpose is that the nuts (11) are screwed into the inner side for standby when the stator magnet panels (1) at two ends are adjusted in distance and fixed in the later step.

3. Then 2 guide flange male types (welded with screws) (4) penetrate into panel guide flange fixing holes (3-2) from the B surface and the C surface of the magnetic shielding panel (3), then another two guide flange female types (provided with corresponding round holes) (6) are correspondingly inserted into the A surface and the D surface respectively, and a gasket nut (8) is threaded on the guide flange male types and the D surface, so that the guide flange male types are not screwed temporarily, and the guide flange male types are fixed temporarily without being screwed so as to penetrate into a rotating shaft (9).

4. Then, 4 planes of 2 magnetic shield panels were arranged in the order of A plane, B plane, C plane, and D plane.

5. Then, two magnetic shielding panels (3) are used for temporarily shielding and fixing hard wood boards or other hard plane materials on the 4 plane magnet synonym magnetic pole faces to serve as the gap distance between the panels and prevent displacement, collision and friction caused by magnetic attraction in the installation process;

6. the distance between the stator and the rotor is between millimeters according to the quality of materials and the precision of a manufacturing and installing process, and the distance is 5 millimeters and the distance is 10 millimeters respectively in the embodiment;

the distance between the plane of the A surface (3-5a) of the magnetic shielding panel and the corresponding plane (1-3a) of the independent magnetic pole of the N pole of the stator magnet is 5 mm;

the distance between the B surface (3-5B) plane of the magnetic shielding panel and the corresponding stator core coil plane (2-4) (2-5) is 10 mm; the distance between the plane (3-5e) and the plane of the N pole of the magnet (2-10) is 10 mm;

wherein, the distance between the plane of the C surface (3-5C) of the magnetic shielding panel and the corresponding plane (2-4) (2-5) of the stator core coil is 10 mm; the distance between the plane (3-5f) and the S pole plane of the magnet (2-10) is 10 mm;

the distance between the plane of the D surface (3-5D) of the magnetic shielding panel and the corresponding plane (1-3b) of the independent magnetic pole of the S pole of the stator magnet is 5 mm.

7. Then, a 90-degree right-angle line is drawn on the plane of one end of a rotating shaft (9) with the length of 700 mm and the center of the plane of the rotating shaft is taken as a center point, two lines of the 90-degree right-angle line extend in parallel on the straight rotating shaft to draw marks to the other end, and the two parallel lines are used as positioning reference marks of two mutually perpendicular fastening holes (5) and (7) on guide flanges (4) and (6) in subsequent operation.

8. Then a rotating shaft (9) penetrates into guide flanges (4) and (6) at the centers of 2 magnetic shielding panels (3), for the convenience of understanding and operation, the outer end of the guide flange (6) at the D plane of the magnetic shielding panel (3) is selected to extend out of the rotating shaft (9) by a long distance of 150 mm, the 150 mm is the installation distance of the independent magnetic pole plane panel (1) of the S pole (1-3b) of the stator magnet panel, then the guide flange male type (4) on the D plane of the magnetic shielding panel (3) (C plane) and the fastening hole positions (5) and (7) of the guide flange female type (6) are reserved, two parallel line traces carved on the rotating shaft (9) are aligned, then a guide flange matching nut (8) is temporarily screwed, the fastening hole positions (5) and (7) are positioned and marked on the rotating shaft (9), then the magnetic shielding panel (3) (C plane D plane) and the guide flanges (4) and (6), and drilling a counter bore 10 mm deep at the marked position, tapping to facilitate the tightening and fixing of the set screw, resetting the magnetic shielding panel (3) (C surface and D surface) and the guide flanges (4) (6), and then tightening and fixing the matched set screw in the counter bore.

9. Then the guide flange male type (4) and the guide flange female type (6) on the other magnetic shielding panel (3) (A surface B surface) are fastened at the hole positions (5) and (7) corresponding to two parallel lines carved on the rotating shaft (9), meanwhile, the different name magnetic pole surfaces of the plane magnets (3-5B) and the different name magnetic pole surfaces of the plane magnets (3-5c) on the two magnetic shielding panels (3) are mutually corresponding, the distance between the two planes is kept to be 110 mm, the distance of 110 mm is reserved for the stator iron core coil panel (2), which is exactly equal to the sum of the thickness of the stator iron core (2-4) and the distance of 10 mm between two side gaps, then the matched nut (8) of the guide flange is screwed, and the guide flange fastening hole positions (5) and (7) on the magnetic shielding panel (3) (A surface B surface) are positioned and marked on the rotating shaft (9), then, the guide flange mating nut and the spacer (8) are temporarily removed, and the magnetic shield panel (3) (a-side and B-side) together with the two guide flanges (4) (6) are temporarily removed from the rotary shaft (9), followed by drilling a counterbore 10 mm deep and tapping at the mark.

10. Then, the stator iron core coil panel (2) is selected to be in a plane direction, a rotating shaft (9) penetrates from the direction in which the magnetic shielding panel (3) (A surface and B surface) just exits in the previous step to be close to the C surface of the magnetic shielding panel (3), and the distance of 10 mm between the planes of the stator iron core coils (2-4 and 2-5) and the plane of the C surface (3-5C) of the magnetic shielding panel (3) is kept; then, the guide flange male type (4) is firstly penetrated into the rotating shaft (9) from the new position, 2 fastening screws are screwed on the corresponding fastening counter bores on the rotating shaft (9), then the magnetic shielding panel (3) (the surface B of the A) and the guide flange female type (6) are newly installed, and then the guide flange matching nut (8) and the guide flange female type (6) are screwed on the 2 fastening screws, so that the generator rotor is formed.

11. Then, the N-pole independent magnetic pole plane panel (1) of the stator magnet panel is penetrated into the rotating shaft (9) on the side of the A surface of the magnetic shielding panel (3) and 8 thread fixing shafts (10) on the stator iron core coil panel (2).

12. A stator magnet panel S pole independent magnetic pole plane panel (1) penetrates through a rotating shaft (9) on one side of a D surface of a magnetic shielding panel (3) and 8 thread fixing shafts (10) on a stator iron core coil panel (2).

13. Then adjusting the distance between the standby matched nuts (11) at the inner sides of the 10 thread fixing shafts (10) to ensure that the distance between the plane of the synonym magnetic pole surface (3-5a) of the magnet and the corresponding plane (1-3a) of the independent magnetic pole of the N pole of the stator magnet is kept at 5 mm; keeping a distance of 5 mm between the plane of the unlike magnetic pole surface (3-5d) of the magnet and the corresponding independent magnetic pole plane (1-3b) of the S pole of the stator magnet; and the stator core coil panel (2) is at a median distance.

14. Then, the positions of tightly fixing hole positions (1-5) of cylindrical roller bearings (1-4) at the centers of 2 stator magnet panels (1) are marked and positioned on a rotating shaft (9), then the 2 stator magnet panels (1) are temporarily dismounted, counter bores are drilled to be 10 mm deep and tapped, after tapping is completed, the 2 stator magnet panels (1) are newly installed, matched nuts (11) on the outer sides of the thread fixing shafts (10) are installed firstly, matched nuts (11) on the two sides of the stator magnet panels (1) on the 8 thread fixing shafts (10) are screwed, matched tightly fixing screws (1-5) of the cylindrical roller bearings (1-4) are screwed, and finally boards or other hard plane materials for temporarily shielding and fixing the unlike magnetic pole faces of the magnets are dismounted. Thus, the matching assembly of the stator and the rotor of the generator is completed.

The generator is placed in two states during power generation and use, wherein one state is fixed in a metal protective cover shell which can simultaneously perform metal heat dissipation and cold (cool) air circulation heat dissipation, and the other state is directly fixed in a relatively large closed type circulation cold (cool) air independent factory building environment which can be inspected through electronic monitoring and has a larger relative space.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications of equivalent structures and equivalent processes, which are made by using the contents of the present specification and the accompanying drawings, or directly or indirectly applied to other related technical fields, are included in the scope of the present invention.