阅读说明：本技术 一种牵拉阻推永磁钢动力机 (Traction and push resistance permanent magnet steel power machine ) 是由 秦利 于 2021-08-24 设计创作，主要内容包括：本发明公开了一种牵拉阻推永磁钢动力机,涉及牵拉阻推永磁钢动力机的技术领域,本发明旨在解决新型能源的问题,本发明其包括壳体、定子和转子,所述壳体的内部周围安装有多个定子,且多个定子以壳体的轴线为中心呈圆周均匀分布在壳体的内部周围,所述壳体的内部安装有转子,且转子与壳体同轴,所述定子包括定子钢座、定子前部、定子中部和定子后部。无需人们所认知的或有待推广的新能源,如太阳能、地热能、风能、海洋能、生物质能和核聚变能等,仅通过磁回路原理,利用永磁钢的剩磁特性,只要永磁钢的剩磁没有衰减到原始饱和剩磁的60％以下,它就能够向外输出功率,对外就可以输出扭矩(做功),产生有利于人类所需要的动力。(The invention discloses a traction and thrust resistance permanent magnet steel power machine, which relates to the technical field of traction and thrust resistance permanent magnet steel power machines and aims to solve the problem of novel energy. The power generator does not need new energy sources which are recognized by people or need to be popularized, such as solar energy, geothermal energy, wind energy, ocean energy, biomass energy, nuclear fusion energy and the like, and only by utilizing the remanence characteristic of the permanent magnet steel through the principle of a magnetic loop, as long as the remanence of the permanent magnet steel is not attenuated to be below 60 percent of the original saturation remanence, the power generator can output power outwards and can output torque (doing work) outwards to generate power which is beneficial to human beings.)

1. The utility model provides a tractive hinders and pushes away permanent magnet steel engine, includes casing, stator (1) and rotor (2), install a plurality of stators (1) around the inside of casing, and a plurality of stators (1) use the axis of casing to be circumference evenly distributed around the inside of casing as the center, the internally mounted of casing has rotor (2), and rotor (2) and casing are coaxial, its characterized in that: the stator (1) comprises a stator steel seat, a stator front part (3), a stator middle part pushing-resistant permanent magnet steel body (4), a stator middle part traction permanent magnet steel body (6) and a stator rear part (5), wherein the top end of the stator steel seat is fixedly connected with the inner wall of the shell, the stator front part (3), the stator middle part pushing-resistant permanent magnet steel body (4), the stator middle part traction permanent magnet steel body (6) and the stator rear part (5) are respectively arranged below the stator steel seat, and the stator front part (3), the stator middle part pushing-resistant permanent magnet steel body (4), the stator middle part traction permanent magnet steel body (6) and the stator rear part (5) are mutually attached;

the rotor (2) is a two-head three-order permanent magnet steel rotor and comprises a main shaft, a plurality of first permanent magnet steel bodies and a plurality of second permanent magnet steel bodies, the first permanent magnet steel bodies and the second permanent magnet steel bodies are fixedly connected to the outer wall of the rotor in a trapezoidal spiral mode by taking the axis of the rotor as the center respectively, and the first permanent magnet steel bodies and the second permanent magnet steel bodies on the same plane are symmetrically distributed on the outer wall of the rotor.

2. The traction, resistance and push permanent magnet steel power machine according to claim 1, characterized in that: the first permanent magnet steel body comprises a first-end first-order permanent magnet steel body (7), a first second-end permanent magnet steel body (8) and a first third-order permanent magnet steel body (9), and the first-end first-order permanent magnet steel body (7), the first second-end permanent magnet steel body (8) and the first third-order permanent magnet steel body (9) are fixedly connected to the rotor (2) to form a complete magnet rotor component in the trapezoidal spiral.

3. The traction, resistance and push permanent magnet steel power machine according to claim 1, characterized in that: the second-head permanent magnet steel body comprises a second first-order permanent magnet steel body (10), a second-order permanent magnet steel body (11) and a second first-order third-order permanent magnet steel body (12), and the second first-order permanent magnet steel body (10), the second first second-order permanent magnet steel body (11) and the second first third-order permanent magnet steel body (12) are fixedly connected to the rotor (2) to form a complete magnetic rotor component in the trapezoidal spiral.

4. The traction, resistance and push permanent magnet steel power machine according to claim 1, characterized in that: the front part (3) of the stator adopts a traction pulling force step-shaped permanent magnet steel body.

5. The traction, resistance and push permanent magnet steel power machine according to claim 1, characterized in that: and the middle part of the stator is a transition combination body formed by combining a middle part pushing-resistant permanent magnet steel body (4) of the stator and a middle part traction permanent magnet steel body (6) of the stator.

6. The traction, resistance and push permanent magnet steel power machine according to claim 1, characterized in that: the tail part (5) of the stator adopts an arc-shaped structure resistance thrust permanent magnet steel body.

Technical Field

The invention relates to the technical field of traction and push resistance permanent magnet steel power machines, in particular to a traction and push resistance permanent magnet steel power machine.

Background

The magnetic steel power machine is different from new energy sources which are recognized by people or need to be popularized, such as solar energy, geothermal energy, wind energy, ocean energy, biomass energy, nuclear fusion energy and the like. The energy of the energy source is completely derived from the self characteristics of the neodymium iron boron high-magnetic-force permanent magnet steel body and more than 60 percent of residual magnetism, the energy source is scientifically placed through the magnetic loop principle, finally, the outward output power is generated, in addition, the fact that the outward output power is achieved only by one neodymium iron boron high-magnetic-force permanent magnet steel is emphasized, the new energy source is called magnetic energy, along with the social progress and the high-speed development of scientific technology, particularly, the energy source is rapidly developed in the field of the neodymium iron boron high-magnetic-force permanent magnet steel, various product series appear, and the neodymium iron boron which is commonly used in the market is like N series N30-N52; NM series N30M-N48M; NH series N30H-N45H; NSH series N30 SH-N45 SH; NUH series N25 UH-N42 UH; NEH series N28 EH-N35 EH; NAH series N28 EH-N35 AH, and the like, some of which have high remanence; some emphasis is placed on high coercivity or high intrinsic coercivity; there are some high-side working temperatures (i.e. curie temperature), in short, different ndfeb series products have penetrated into various fields of the world, no matter military industry or civil use, but there is no major breakthrough in the power generated by the ndfeb permanent magnet steel power machine (which is completely composed of a single ndfeb permanent magnet steel body).

Disclosure of Invention

In order to solve the problems, namely the problems of the background art, the invention provides a traction and thrust permanent magnet steel power machine, which comprises a shell, a stator and a rotor, wherein a plurality of stators are arranged around the inside of the shell, the plurality of stators are uniformly distributed around the inside of the shell in a circumferential manner by taking the axis of the shell as the center, the rotor is arranged inside the shell and is coaxial with the shell, the stator comprises a stator steel seat, a stator front part, a stator middle part and a stator rear part, the top end of the stator steel seat is fixedly connected with the inner wall of the shell, the stator front part, the stator middle part and the stator rear part are respectively arranged below the stator steel seat, and the stator front part, the stator middle part and the stator rear part are mutually attached;

the rotor is a two-head three-order permanent magnet steel rotor and comprises a main shaft, a plurality of first permanent magnet steel bodies and a plurality of second permanent magnet steel bodies, the first permanent magnet steel bodies and the second permanent magnet steel bodies are fixedly connected to the outer wall of the rotor in a trapezoidal spiral mode by taking the axis of the rotor as the center respectively, and the first permanent magnet steel bodies and the second permanent magnet steel bodies on the same plane are symmetrically distributed on the outer wall of the rotor.

The invention is further provided with: the first permanent magnet steel body comprises a first-end first-order permanent magnet steel body, a first second-end permanent magnet steel body and a first third-end permanent magnet steel body, and the first-end first-order permanent magnet steel body, the first second-end permanent magnet steel body and the first third-end permanent magnet steel body are fixedly connected to the rotor to form a complete magnet rotor part in the trapezoidal spiral.

The invention is further provided with: the second head permanent magnet steel body comprises a second first-order permanent magnet steel body, a second-order permanent magnet steel body and a second third-order permanent magnet steel body, and the second first-order permanent magnet steel body, the second-order permanent magnet steel body and the second third-order permanent magnet steel body are fixedly connected to the rotor to form a complete magnetic rotor part in the trapezoidal spiral.

The invention is further provided with: the front part of the stator adopts a traction pulling force stepped permanent magnet steel body. The invention is further provided with: and the middle part of the stator is a transition combination body formed by combining a resistance thrust permanent magnet steel body and a traction tension permanent magnet steel body.

The invention is further provided with: the tail of the stator adopts an arc-shaped structure resistance thrust permanent magnet steel body.

The beneficial technical effects of the invention are as follows: the power generator does not need new energy sources which are recognized by people or need to be popularized, such as solar energy, geothermal energy, wind energy, ocean energy, biomass energy, nuclear fusion energy and the like, and only by utilizing the remanence characteristic of the permanent magnet steel through the principle of a magnetic loop, as long as the remanence of the permanent magnet steel is not attenuated to be below 60 percent of the original saturation remanence, the power generator can output power outwards and can output torque (doing work) outwards to generate power which is beneficial to human beings.

Drawings

Fig. 1 shows a working schematic diagram of the magnetic power part and the rotor which are uniformly distributed integrally.

Fig. 2 shows a single magnetomotive element working schematic.

Fig. 3 shows a schematic view of a transition combination formed by combining the middle push-resisting and pulling working units.

Fig. 4 shows a schematic structural diagram of a two-head three-order resistance-push permanent magnet steel step spiral arrangement rotor.

Fig. 5 shows a schematic cross-sectional view of a two-head three-order thrust permanent magnet steel step spiral arrangement rotor.

Fig. 6 shows a working principle diagram of the push-resisting magnetic steel rotor close to the front part of the push-resisting magnetic steel stator.

Fig. 7 shows a working principle diagram of the push-resisting magnetic steel rotor close to the middle of the push-resisting magnetic steel stator.

Fig. 8 shows a working principle diagram of the push-resisting magnetic steel rotor close to the rear part of the push-resisting magnetic steel stator.

Fig. 9 shows the working principle diagram of the push-resisting magnetic steel rotor approaching the front part of the pull magnetic steel stator.

Fig. 10 shows a schematic diagram of the operation of the push-resistant magnetic steel rotor near the middle of the pull magnetic steel stator.

Fig. 11 shows a working principle diagram of the push-resisting magnetic steel rotor approaching the rear part of the pull magnetic steel stator.

Fig. 12 shows a partially enlarged schematic view of a two-head three-step thrust permanent magnet steel step spiral arrangement rotor structure.

Reference numeral 1, a stator, 2, a rotor, 3, a front part of the stator, 4, a middle part of the stator, a push-resistant permanent magnet steel body, 5, a rear part of the stator, 6, a middle part of the stator, a traction permanent magnet steel body, 7, a first-end first-order permanent magnet steel body, 8, a first-end second-order permanent magnet steel body, 9, a first-end third-order permanent magnet steel body, 10, a second-end first-order permanent magnet steel body, 11, a second-end second-order permanent magnet steel body, 12 and a second-end third-order permanent magnet steel body.

Detailed Description

Preferred embodiments of the present invention are described below with reference to the accompanying drawings. It should be understood by those skilled in the art that these embodiments are only for explaining the technical principle of the present invention, and are not intended to limit the scope of the present invention.

The invention provides a traction and push resistance permanent magnet steel power machine, which comprises a shell, a stator 1 and a rotor 2, wherein a plurality of stators 1 are arranged around the inside of the shell, the plurality of stators 1 are uniformly distributed around the inside of the shell in a circumference manner by taking the axis of the shell as the center, the rotor 2 is arranged inside the shell, the rotor 2 is coaxial with the shell, the stator 1 comprises a stator steel seat, a stator front part 3, a stator middle part 4, a stator middle part 6 and a stator rear part 5, the top end of the stator steel seat is fixedly connected with the inner wall of the shell, the stator front part 3, the stator middle part 4, the stator middle part 6 and the stator rear part 5 are respectively arranged below the stator steel seat, and the stator front part 3, the stator middle part 4, the stator middle part 6 and the stator rear part 5 are mutually attached;

referring to the schematic diagram of the working principle of a single magnetomotive component, namely fig. 2, the permanent magnet steel body fixed and placed on the stator can be divided into three basic working units according to the characteristics of the push-resistant permanent magnet steel body and the traction permanent magnet steel body:

1. a head working unit: the traction magnetic steel body is adopted, the traction force of the traction magnetic steel body is reserved, and useless tension of the traction magnetic steel body is abandoned.

2. And the tail working unit adopts the push-resistant magnetic steel body, retains the thrust of the push-resistant magnetic steel body and abandons the useless resistance of the push-resistant magnetic steel body.

3. And the middle working unit adopts a combination of the push-resisting magnetic steel body and the traction magnetic steel body, and finally aims to reduce the useless tension in the head traction magnetic steel body and reduce the useless resistance in the tail push-resisting magnetic steel body.

Rotor 2 is first three-order permanent magnet steel body rotor of two, including main shaft, a plurality of first permanent magnet steel bodies and a plurality of second permanent magnet steel bodies, and a plurality of first permanent magnet steel bodies and a plurality of second permanent magnet steel bodies use the axis of rotor to be trapezoidal spiral rigid coupling on the outer wall of rotor as the center respectively, and first permanent magnet steel bodies and the first permanent magnet steel body symmetric distribution of second on the coplanar are on the outer wall of rotor.

The first permanent magnet steel body comprises a first-end first-order permanent magnet steel body 7, a first second-end permanent magnet steel body 8 and a first third-end permanent magnet steel body 9, and the first-end first-order permanent magnet steel body 7, the first second-end permanent magnet steel body 8 and the first third-end permanent magnet steel body 9 are fixedly connected to the rotor 2 to form a complete magnet rotor component in the trapezoidal spiral.

The second-head permanent magnet steel body comprises a second first-order permanent magnet steel body 10, a second-head second-order permanent magnet steel body 11 and a second-head third-order permanent magnet steel body 12, and the second first-order permanent magnet steel body 10, the second-head second-order permanent magnet steel body 11 and the second-head third-order permanent magnet steel body 12 are fixedly connected to the rotor 2 to form a complete magnetic rotor component in the trapezoidal spiral.

The first complete magnetic rotor part and the second complete magnetic rotor part are arranged at the first end, and the two magnetic rotor parts uniformly distributed on the rotor body are taken as basic units to form a trapezoidal spiral structure of the permanent magnet steel body. See fig. 4, fig. 5, fig. 12.

The invention relates to a traction resistance-push permanent magnet steel power machine, which aims to provide a new environment-friendly neodymium iron boron permanent magnet steel power energy source, and defines two basic characteristics mainly aiming at a stator neodymium iron boron permanent magnet steel body according to different forces generated by the power machine:

and the resistance thrust permanent magnet steel body (namely, the resistance thrust permanent magnet steel body).

And (3) pulling the permanent magnet steel body (namely, the traction force pulling permanent magnet steel body).

The purpose of the invention is realized based on the following thought: the permanent magnet steel power machine has two parts (or two parts), namely:

1. and the rotor body part (assuming that N stages of each magnetic unit of the rotor are outward), each magnetic unit is arranged and installed according to the sequence of a first stage, a second stage and a third stage, a first complete magnetic rotor part at the first end and a second complete magnetic rotor part at the second end are formed, and finally, a trapezoidal spiral structure of the permanent magnet steel body is formed. See fig. 4, fig. 5, fig. 12.

2. Stator body part, according to the permanent magnet steel body state of producing different power at the during operation, defines two names, promptly: the push-resistant permanent magnet steel body and the traction permanent magnet steel body are connected in series. Through the magnetic loop principle, various different push-resistant magnetic steel bodies and pull-off magnetic steel bodies are scientifically fixed and placed.

The front part 3 of the stator is a head working unit and adopts a traction force and tension step-shaped permanent magnet steel body, namely traction magnetic steel for short.

The stator tail part 5 is a tail part working unit and adopts an arc-shaped structure resistance thrust permanent magnet steel body, namely resistance thrust magnetic steel for short.

The middle part of the stator is a transition combination body formed by combining a resistance thrust permanent magnet steel body 4 and a traction tension permanent magnet steel body 6, and is a middle working unit, and a combination body of the resistance thrust magnetic steel body and the traction tension magnetic steel body is adopted, and the combination body is a combination body of a resistance thrust magnetic steel body and a traction magnetic steel body for short.

The working principle of the push-resisting magnetic steel is as follows: see FIG. 6: when the N-level of the rotor permanent magnet steel is outward, the rotor rotates clockwise around O, the stress analysis schematic diagram of the central axis BB ' of the rotor before the resistance-push boundary of the rotor central axis BB ' and the stator resistance-push magnetic steel body BB ' are collinear is shown, and the resistance part (useless resistance), the thrust part (useful thrust) and the magnetic steel body on the rotor do not have thrust around the O point and only have resistance.

The working principle of the push-resisting magnetic steel is as follows: see FIG. 7: when the N-level of the rotor permanent magnet steel is outward, the rotor rotates clockwise around O, the stress analysis schematic diagram of the central axis BB ' of the rotor when the central axis BB ' is collinear with the thrust boundary of the stator thrust magnetic steel body BB ' is shown, and the magnetic steel body on the rotor has no thrust or resistance around the O point and is a balance position.

The working principle of the push-resisting magnetic steel is as follows: see fig. 8: when the N-level of the rotor permanent magnet steel faces outwards, the rotor rotates clockwise around O, the stress analysis schematic diagram of the central axis BB 'of the rotor after being collinear with the thrust boundary of the stator thrust magnetic steel body BB' shows that the resistance part (useless resistance), the thrust part (useful thrust) and the magnetic steel body on the rotor have no resistance around the O point and only have thrust.

The working principle of the traction magnetic steel is as follows: see FIG. 9: when the N-level of the rotor permanent magnet steel is outward, the rotor rotates clockwise around the O, and the front end of the stator generates an attack force (useless resistance) before the front end AA 'of the rotor and the front end AA' of the stator traction magnet steel body are collinear. When the front end AA 'of the rotor and the front end AA' of the stator pulling magnetic steel body are collinear, the pulling magnetic steel can generate traction (useful traction) on the rotor magnetic steel, and until the rear end CC 'of the rotor and the rear end CC' of the stator are collinear, tension (useless traction) can be generated.

The working principle of the traction magnetic steel is as follows: see fig. 10: when the N-level of the rotor permanent magnet steel is outward, the rotor rotates clockwise around O, when the middle BB 'of the rotor is collinear with the middle BB' of the stator traction magnet steel body, the traction magnet steel continues to generate traction (useful traction) on the rotor magnet steel until the rear end CC 'of the rotor is collinear with the rear end CC' of the stator, and then the traction (useless traction) is generated.

The working principle of the traction magnetic steel is as follows: see FIG. 11: when the N-level of the rotor permanent magnet steel faces outwards, the rotor rotates clockwise around the O until the rear end CC 'of the rotor and the rear end CC' of the stator traction magnet steel body are collinear, and then pulling force (useless pulling force) is generated.

While the invention has been described with reference to a preferred embodiment, various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention, and particularly, features shown in the various embodiments may be combined in any suitable manner without departing from the scope of the invention. It is intended that the invention not be limited to the particular embodiments disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

In the description of the present invention, the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", and the like, which indicate directions or positional relationships, are based on the directions or positional relationships shown in the drawings, which are for convenience of description only, and do not indicate or imply that the devices or elements must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

The terms "comprises," "comprising," or any other similar term are intended to cover a non-exclusive inclusion, such that a process, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, article, or apparatus.

So far, the technical solutions of the present invention have been described in connection with the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Equivalent changes or substitutions of related technical features can be made by those skilled in the art without departing from the principle of the invention, and the technical scheme after the changes or substitutions can fall into the protection scope of the invention.