DE202022100863U1 - Linear inductive magnet motor - Google Patents

Abstract

A linear, inductive magnetic motor, comprising a rotor arrangement and a stator arrangement, characterized in that
that the rotor arrangement is fastened to a movable rotor base and consists of a strip-shaped permanent magnet having a rotor,
that the stator assembly is fixed on a fixed base and consists of a strip-shaped permanent magnet having stators and a linear silicon steel strip is placed on the strip-shaped permanent magnet having stators, the stator assembly serving to generate mutual attraction and repulsion force with the rotor assembly.

Description

field of invention

The present invention relates to a linear inductive magnet motor and more particularly to a linear inductive magnet motor using permanent magnets to provide stators and movers.

State of the art

In presently known magnetic motor devices (e.g. U.S. Patent 4151431A ) permanent magnets are used to generate magnetic kinetic energy, the structure of which is characterized in that a fixed stator magnet assembly is arranged on a fixed base and further a rotor magnet assembly with stationary magnets arranged is mounted on a shaft. The principle of generating kinetic energy is described below: When the rotors of the rotor magnet assembly and the stators of the stator magnet assembly alternately pass each other, a natural magnetic force is generated by the mutual repulsion or attraction of magnets of the same or different polarity, so that the motor can run by magnetic force is brought.

However, the magnetic motor described above is not optimal. Its basic principle is that a slight propulsion force is generated by the mutual cancellation of attractive and repulsive forces as the stators and rotors rotate. At the same time, the phenomenon of balance between the magnetic attraction and the repulsion occurs in the same time interval between the intersection of the stators and the movers of the previous stage and the intersection of the stators and the movers of the next stage. At this time, the magnet motor stops momentarily. This phenomenon is a frequently encountered deficiency in which so-called pulsations occur. According to the law of inertia of objects, the magnetic motor does not stop at this time, because the residual energy generated by the last interaction between the stators and the runners will propel the runners forward for a short distance into the area of the next interaction between the stators and be moved by the runners. So the next cycle of mutual repulsion and mutual attraction starts all over again so that the magnetic motor does not stop. However, the pulsation phenomenon described above occurs in the magnetic motor. As a result, there is a defect that the magnet motor does not run smoothly during operation, which affects the overall efficiency. Such a magnetic motor cannot therefore be used in industrial production.

object of the invention

The object of the present invention is to eliminate the above-mentioned disadvantages and to provide a magnet motor with good industrial applicability, which can prevent the pulsation phenomenon from occurring.

Technical solution

According to the invention, specially designed stators and runners are arranged in a special arrangement, so that with the present invention the objective of operation can be achieved with just a unidirectional propulsion force.

To achieve the above objects, the present invention provides a linear magnet inductive motor comprising a mover assembly and a stator assembly, the mover assembly being fixed on a movable mover base and composed of a strip-shaped permanent magnet having a mover fixing the stator assembly on a fixed base and consists of a strip-shaped permanent magnet having stators and a straight line silicon steel strip is arranged on the strip-shaped permanent magnet having stators, the stator assembly serving to generate mutual attraction and repulsion force with the rotor assembly.

In one embodiment, the moveable slider base is made of a non-magnetic material.

In one embodiment, the non-magnetic material is a zinc-aluminum alloy.

In one embodiment, the silicon steel strip is formed by a plurality of silicon steel sheets placed side by side, with the plurality of silicon steel sheets having one end of each silicon steel sheet facing forward and the other end facing rearward.

In one exemplary embodiment, the silicon steel strip is formed by a plurality of silicon steel sheets lying next to one another, with each silicon steel sheet being arrow-shaped in the plurality of silicon steel sheets.

By arranging the stators and runners of the present invention in this manner, the interpolar repulsion and attraction force between The stator and rotor are reinforced, which generates operating energy, and thus no pulsation phenomenon occurs when a magnet motor is operated, and the magnet motor can rotate smoothly and stably. As a result, the invention has better industrial applicability compared to the prior art.

character list

• 1 Fig. 13 is a schematic side sectional view showing the relative positions of a mover and a stator of a first embodiment of the present invention;
• 2 Fig. 14 is a side view showing the relative positions of a mover and a stator of the first embodiment of the present invention;
• 3 Fig. 14 is a view showing the distribution of magnetic induction areas of the stators of the first embodiment of the present invention;
• 4 Fig. 14 is a cross-sectional view of the magnetic induction between the mover and the stator of the first embodiment of the present invention;
• 5 Fig. 14 is a sectional front view of the first embodiment of the present invention in which the invention is applied to an annular inductive magnet motor;
• 6 Fig. 12 is a sectional side view of the first embodiment of the present invention, in which the invention is applied to an annular inductive magnet motor;
• 7 Fig. 14 is a side view showing the relative positions of a mover and a stator of a second embodiment of the present invention;
• 8th Fig. 12 shows a cross-sectional view of the stators of the second embodiment of the present invention;
• 9 Fig. 12 is a view showing the distribution of magnetic induction areas of the stators of the second embodiment of the present invention.

Detailed description of the preferred embodiments

It will be on the 1 and 2 referenced. Each stator assembly 1 consists primarily of a strip-shaped permanent magnet 11 having stators and a silicon steel strip 12 consisting of a plurality of silicon steel sheets 13. The characteristic of a silicon steel sheet 13 is that each sheet is formed into a shape in which the center is forward and both ends are backward point behind. Therefore, the silicon steel strip 12 composed of the plurality of silicon steel sheets 13 also has a shape in which the center faces forward and both ends face backward. With the composite silicon steel sheets 13, the two different magnetic poles, S-pole and N-pole, of the strip-shaped permanent magnet 11 having stators can be used for conducting and concentrating magnetism (the principle will be described later). The rotor arrangement 2 of the linear, inductive magnet motor 100 is a strip-shaped permanent magnet 21 having a rotor.

It will be on the 3 and 4 10, which respectively show a magnetic induction area distribution view of the stators of the first embodiment according to the present invention and a cross-sectional view of the magnetic induction between the mover and the stator of the first embodiment according to the present invention. In 3 a first stator arrangement 1a and a second stator arrangement 1b adjacent thereto are shown. It can be seen that the N pole of the rotor 2a faces the first stator arrangement 1a. Since a first silicon steel strip 12a arranged in parallel and serving to conduct and concentrate magnetism is provided on the first stator assembly 1a, a strong N' magnetic field can be induced in the segment 121a of the first silicon steel strip 12a, so that there is a repulsive force on the N pole of the runner 2a exerts. The attractive and repulsive forces cause a strong propelling force to be generated by the N pole of the mover 2a.

Furthermore, the S-pole of the rotor 2b faces the second stator arrangement 1b. Since a second silicon steel strip 12b arranged in parallel and serving to conduct and concentrate magnetism is provided on the second stator assembly 1b, a strong S' magnetic field can be induced in the segment 121b of the second silicon steel strip 12b, so that there is a repulsive force on the S pole of the runner 2b exerts. The attractive and repulsive forces cause a strong propelling force to be generated by the S pole of the mover 2b.

It will be on at the same time 4 Referring now to FIG. 1, which shows a magnetic field line distribution diagram of the N-pole of the rotor 2a and the first stator assembly 1a viewed from one side. In the N-pole of the rotor 2a and the N-pole of the first stator assembly 1a, the induced magnetic pole phenomenon occurs. The repulsion and attraction relationship between the runner's S pole 2b and the second stator assembly 1b can also be explained in the same way.

It will be on the 5 and 6 referenced. The rotor assembly 2 of the present invention is attached to a movable rotor base 20, the movable rotor base 20 is attached to a rotor shaft 10, there is a small gap 3 between the movable rotor base and the stator assembly 1, and the stator assembly 1 is fixed to the fixed base 4 of the magnetic motor of the present invention is. Both the movable slider base 20 and the fixed base 4 are made of a non-magnetic material such as zinc-aluminum alloy.

In the upper section of 6 Fig. 12 is a schematic view showing the operating area 61 and the non-operating area 62 of the present invention. The slider assembly 2 of the present invention is a moving part that can move back and forth and allows the user to select whether to control the magnetic motor of the present invention in the stopped or running state. When the rotor assembly 2 is moved so that the rotor assembly 2 is in the non-operational region 62, the stator assembly 1 and the rotor assembly 2 are in a static state due to a lack of magnetic interaction. At the same time, when the mover assembly 2 is moved to the position of the operating region 61, the above-mentioned mutual repulsive and attractive force may be generated between the stator assembly 1 and the mover assembly 2 due to magnetic induction at close range. In this case, operating energy can also be generated in the case of the rotor arrangement 2 .

It will be on the 7 and 8th Reference is made to Fig. 1 showing a second embodiment according to the present invention. The main difference between the first embodiment and the second embodiment can be seen at the same time from the 3 and 4 be compared. The plural silicon steel sheets 13 are arrow-shaped (V-shaped). The feature of a silicon steel sheet 13 is that each sheet is formed into a shape in which the center faces forward and both ends face backward. Therefore, the silicon steel strip 12 composed of the plurality of silicon steel sheets 13 also has a shape in which the center faces forward and both ends face backward. With the composite silicon steel sheets 13, the two different magnetic poles, S pole and N pole, of the strip-shaped permanent magnet 11 having stators for conducting and concentrating magnetism can be used to obtain the effect of excellent conducting and concentrating magnetism to achieve.

In 9 a first stator arrangement 1a and a second stator arrangement 1b adjacent thereto are shown. The N pole of the rotor 2a and the S pole of the rotor 2b face the different segments of the first stator assembly 1a and the second stator assembly 1b, respectively. Since an arrow-shaped first silicon steel strip 12a and an arrow-shaped second silicon steel strip 12b, which serve to conduct and concentrate magnetism, are arranged on the first stator assembly 1a and the second stator assembly 1b, respectively, the first silicon steel strip 12a and the second silicon steel strip 12b can have a strong N ' magnetic field can be induced by the N pole of the rotor 2a to exert a repulsive force on the N pole of the rotor 2a. Since an arrow-shaped first silicon steel strip 12a and an arrow-shaped second silicon steel strip 12b, which serve to conduct and concentrate magnetism, are disposed on the first stator assembly 1a and the second stator assembly 1b, respectively, the first silicon steel strip 12a and the second silicon steel strip 12b can have a stronger S ' magnetic field can be induced by the S pole of the mover 2b to exert a repulsive force on the S pole of the mover 2b.

In summary, the present invention relates to a linear magnetic inductive motor, and more particularly to a linear magnetic inductive motor that uses permanent magnets to create stators and rotors, the stators and rotors being specifically arranged to generate associated magnetic moments such that in the present invention, magnetic kinetic energy can be generated without any power supply to ensure smooth and stable rotation.

Reference List

100

linear, inductive magnet motor

1

stator assembly

1a

first stator

1b

second stator

11

Strip-shaped permanent magnet having stators

12

silicon steel strips

12a

first silicon steel strip

121a

segment

122b

segment

13

silicon steel sheet

2

runner arrangement

10

rotor shaft

20

moveable runner base

2a

N pole of the rotor

2 B

S pole of the rotor

21

Strip-shaped permanent magnet having runners

3

gap

4

solid base

QUOTES INCLUDED IN DESCRIPTION

This list of the documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• US4151431A [0002]

Claims (5)

A linear inductive magnet motor comprising a rotor assembly and a stator assembly, characterized in that the rotor assembly is mounted on a moveable rotor base and consists of a strip-shaped permanent magnet having rotors, that the stator assembly is mounted on a fixed base and consists of a strip-shaped permanent magnet having stators and a rectilinear silicon steel strip is arranged on the strip-shaped permanent magnet having stators, the stator assembly serving to generate a mutual attraction and repulsion force with the rotor assembly. Linear inductive magnet motor claim 1 , in which both the movable slider base and the fixed base are made of a non-magnetic material. Linear inductive magnet motor claim 2 , in which the non-magnetic material is a zinc-aluminum alloy. Linear inductive magnet motor claim 1 wherein the silicon steel strip is formed by juxtaposing a plurality of silicon steel sheets, wherein in the plurality of silicon steel sheets, one end of each silicon steel sheet faces forward and the other end faces rearward. Linear inductive magnet motor claim 1 wherein the silicon steel strip is formed by a plurality of silicon steel sheets placed side by side, wherein in the plurality of silicon steel sheets, each silicon steel sheet is arrow-shaped.

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