TWI669887B - Magnetic motor structure - Google Patents

Abstract

The invention relates to a structure of a magnetic motor. The main structure comprises a seat body having a rotating component therein. The rotating component comprises a rotating output member pivoted in the seat body, a swinging member pivotally connected to the seat body, and a plurality of a magnetic seat assembly disposed on the oscillating member, and at least one magnetic disk member disposed on the rotary output member, wherein a plane of the magnetic disk member needs to form a predetermined angle with a plane of the rotary output member, and the swinging member is located At one side of the rotary output member, a plurality of magnetic spacers are disposed on the magnetic base assembly. With the above structure, a rotary power can be introduced into the rotary output member, the rotary output member can be rotated, and the magnetic disk member can be rotated to cooperate with the swinging member, the magnetic base assembly and the magnetic spacer to continuously rotate to retain the same. The power of rotation.

Description

Magnetic motor structure

The invention provides a structure of a magnetic motor, in particular a structure of a magnetic motor capable of retaining rotational power.

According to the industrial revolution, many machines have brought rapid progress to the people. Some people say that the speed of human progress in the past 100 years has been ten times that of the previous millennia, but relatively, due to the needs of various machinery. Energy has also led to the destruction of environmental damage and energy in the past 100 years, which is more than a dozen times in the past few thousand years.

For example, for a large amount of mining such as oil and natural gas, the stock is decreasing, and even some supply areas are approaching a depleted state. Burning oil and natural gas to generate electricity also causes quite serious air pollution and greenhouse effect. How to find alternative energy sources is currently a very popular topic.

At present, the most commonly mentioned alternative energy sources are solar energy, hydropower, and wind power. The above alternative energy sources have a certain degree of effect with the current research results, but in addition to the above several methods, There is a method of using magnetic energy as a substitute for energy, but in the current magnetic motor, the effect of preserving power is not complete enough, and how to use the magnetic motor to save power to achieve power generation, that is, it needs to be solved. problem.

Therefore, how to solve the above-mentioned problems and deficiencies of the above-mentioned applications is the applicant who is interested in researching and improving the direction of the applicants and related manufacturers engaged in the industry.

Therefore, the inventors of the present invention have collected the relevant materials in view of the above-mentioned deficiencies, and through multi-party evaluation and consideration, and through years of experience accumulated in the industry, through continuous trial and modification, the design of such a rotation power can be designed. The invention patent of the structure of the magnetic motor.

The main object of the present invention is to achieve the effect of retaining rotational power by using a rotating assembly and a magnetic shield.

In order to achieve the above object, the main structure of the present invention comprises: a body, a rotating component disposed in the body, the rotating component comprises a rotating output member pivoted in the body, a swinging member pivotally connected to the base, a plurality of magnetic seat assemblies disposed on the oscillating member, and at least one magnetic disk member disposed on the rotating output member, wherein each of the magnetic base assemblies further comprises a plurality of magnetic spacers; The plane of the rotating output member and the plane of the magnetic disk member form a predetermined angle, that is, the two are not parallel, and the swinging member is located at one side of the rotating output member, and the position of the magnetic seat assembly corresponds to the magnetic circle. The disk member, and the magnetic forces at one side of the magnetic seat assembly and the magnetic disk member adjacent to each other repel each other.

With the above structure, the user needs to first use the external power to rotate the rotary output member, and when the rotary output member rotates, the magnetic disk member is driven to rotate, because the plane of the magnetic disk member and the plane of the rotary output member form a The angle is predetermined, so that the magnetic disc member has a side that is closer to the swinging member, and the other side is farther away from the swinging member. When the magnetic disc member approaches the magnetic seat assembly provided on the swinging member, the magnetic seat assembly and the magnetic body The magnetic force of the disc member repels, and the magnetic force of the magnetic base assembly is adjusted by the magnetic spacer, so that a repulsive force is generated to be apart from each other, and since the magnetic disc member is in a rotating state, the repulsive force is matched with the rotation. The direction forms a thrust to push it to continue to rotate, and when one side of the oscillating member is pushed away from the magnetic disk member by the magnetic seat assembly, the other side thereof approaches the magnetic disk member due to the principle of the lever swinging. Therefore, when the magnetic disk member approaches the other side of the oscillating member again, a thrust is generated again by the above-described action via the magnetic seat assembly provided on the other side, so that the rotation continues, so that Via the interaction of the magnetic forces, the power stored in the rotation of the rotating assembly.

With the above technology, it is possible to break through the problem of the poor effect of the conventional magnetic motor for preserving power, and achieve the practical progress of the above advantages.

1, 1a‧‧‧ body

11‧‧‧ first piece

12‧‧‧Second body

13‧‧‧Base

14‧‧‧Power source parts

15a‧‧‧ brake components

16a‧‧‧Power output parts

161a‧‧‧Generator

162a‧‧‧ disc

163a‧‧‧ Tracks

17a‧‧‧pipe body

2‧‧‧Rotating components

21, 21a‧‧‧ Rotary output parts

22, 22a, 22b‧‧‧ swinging parts

221, 221a, 221b‧‧‧ magnetic seat assembly

222, 222a, 222b‧‧‧ oscillating magnetic components

223‧‧‧Flexible components

3, 3a, 3b‧‧‧ magnetic disc parts

31, 31a, 31b‧‧‧ fixed department

32, 32a, 32b‧‧‧Rotating magnetic components

321a‧‧‧Component fixing department

4, 4a, 4b‧‧‧ magnetic separator

The first figure is a perspective view of a preferred embodiment of the invention.

The second drawing is a schematic diagram of the power of the preferred embodiment of the invention.

The third drawing is a close-up view of a preferred embodiment of the invention.

The fourth figure is a schematic diagram of the repulsiveness of the preferred embodiment of the present invention.

Figure 5 is a schematic view of the thrust of a preferred embodiment of the present invention.

Figure 6 is a perspective view of still another preferred embodiment of the present invention.

Figure 7 is an exploded view of still another preferred embodiment of the present invention.

The eighth figure is a close-up schematic view of still another preferred embodiment of the present invention.

The ninth diagram is a schematic diagram of a repulsiveness of still another preferred embodiment of the present invention.

Figure 10 is a schematic view of the thrust of a further preferred embodiment of the present invention.

Figure 11 is a schematic view of a brake car according to still another preferred embodiment of the present invention.

Figure 12 is a schematic diagram of power generation in accordance with still another preferred embodiment of the present invention.

Figure 13 is a perspective perspective view of still another preferred embodiment of the present invention.

Figure 14 is a schematic view showing the rotation of a preferred embodiment of the present invention (1).

The fifteenth diagram is a schematic view of rotation (2) of still another preferred embodiment of the present invention.

Figure 16 is a schematic view (1) of a push of a further preferred embodiment of the present invention.

Figure 17 is a schematic view (1) of a swing of still another preferred embodiment of the present invention.

Figure 18 is a schematic view of a push of a further preferred embodiment of the present invention (2).

Figure 19 is a schematic view (2) of a swing of still another preferred embodiment of the present invention.

In order to achieve the above objects and effects, the technical means and the structure of the present invention will be described in detail with reference to the preferred embodiments of the present invention.

Referring to the first embodiment, which is a perspective view of a preferred embodiment of the present invention, it is apparent that the present invention includes a body 1 having a first body 11 and a first a second body 12 at one side of the body 11 and a base 13 simultaneously connecting the first body 11 and the second body 12; a rotating assembly 2, the rotating assembly 2 includes a rotating output member 21, a swing The member 22, the two magnetic base assembly 221, and a magnetic disc member 3, wherein the rotary output member 21 is pivotally disposed in the base body 1 and located between the first sheet body 11 and the second sheet body 12, and the swinging member 22 The magnetic base assembly 221 is disposed on the swinging member 22 and is respectively located at two opposite sides of the swinging member 22, and the magnetic disc member 3 is disposed on the rotating output member 21, and the magnetic disc is disposed. The plane of the member 3 and the plane of the rotary output member 21 form a predetermined angle, so that the two are not parallel to each other; each of the magnetic base assembly 221 includes an elastic member 223 and a swinging magnetic member 222, The magnetic element 223 is disposed between the oscillating member 22 and the seat body 1, and the oscillating magnetic member 222 is disposed on the side of the oscillating member 22 adjacent to the magnetic disk member 3; the magnetic disk member 3 includes a rotating output member The fixing portion 31 on the 21, and the plurality of rotating magnetic members 32 disposed in the fixing portion 31, and the magnetic material 32 and the swinging magnetic member 222 are adjacent to each other, the magnetic forces thereof repel each other, for example, the rotating magnetic member 32 is adjacent to each other. When the side of the swinging magnetic element 222 is N pole, the side of the swinging magnetic element 222 adjacent to the rotating magnetic element 32 is also N pole, and vice versa; and each magnetic pole assembly 221 is provided with a magnetic shield 4 The magnetic lines of force generated by the oscillating magnetic element 222 can be adjusted, and in the embodiment, the material of the magnetic spacer 4 is sheet metal.

With the above description, the structure of the present technology can be understood, and according to the corresponding cooperation of this structure, the rotational kinetic energy can be stored in the rotating assembly 2, and the detailed explanation will be described below.

Please refer to the first to fifth figures at the same time, which is a perspective view to a thrust diagram of a preferred embodiment of the present invention. When the above components are assembled, it can be clearly seen from the figure that the user must first rotate. The rotary output member 21 of the assembly 2 is connected to a power source member 14. The power source member 14 can be an electric motor or other tool that can rotate it, which is not limited, thereby rotating the rotary output member 21 when rotating output. When the member 21 rotates, the magnetic disc member 3 is rotated, and since the magnetic disc member 3 forms a predetermined angle with the rotary output member 21, and the swinging member 22 is not oscillated and unstressed, it will rotate with the output member 21 The planes are parallel, and the two oscillating magnetic elements 222 are disposed at a side adjacent to the second body 12, so that the magnetic disk member 3 has a side closer to the oscillating magnetic member 222, and the other side is farther away. When the magnetic member 222 is swung, when the magnetic disc member 3 approaches the swinging member 22 at the side adjacent to the swinging member 22, the rotating magnetic member 32 located on the magnetic disc member 3 is brought close to the swinging magnetic member 222 on the swinging member 22, Rotating magnetic element The magnetic force between the 32 and the oscillating magnetic member 222 repels each other, so that a repulsive force is generated. The power of the magnetic disc member 3 itself rotates, and the magnetic force of the oscillating magnetic member 222 is adjusted in conjunction with the magnetic shield 4 to break the repulsive force. When they are close to each other, the repulsive force will push the swinging member 22 and the magnetic disc member 3 away from each other, and the repulsive force will form a thrust in accordance with the direction of rotation, thereby pushing the magnetic disc member 3 and the rotary output member 21 to continue to rotate.

When the force of the oscillating member 22 is oscillated via the force given by the oscillating magnetic member 222, the elastic member 223 is pressed to generate an elastic force transmitted to the oscillating member 22, whereby the oscillating member 22 is swung and continuously pushed away from the magnetic disk. At the same time, when one end of the swinging member 22 is away from the magnetic disc member 3, the other side of the swinging member 22 is close to the magnetic disc member 3 by the principle of the lever, and the magnetic disc member is 3 when the side adjacent to the oscillating member 22 is rotated to the other side of the oscillating member 22, the oscillating magnetic member 222, the rotating magnetic member 32, and the magnetic shield 4 will be passed through the other side via the above-described actuation mode. The repulsive force is converted into a thrust force, thereby pushing the magnetic disc member 3 and the rotary output member 21 to continuously rotate, so that the rotational power can be retained in the rotating assembly 2, and if the power is quickly lost, the power source member 14 can be used to replenish the power. To extend the time of rotation.

Please also refer to the sixth to twelfth drawings, which are schematic diagrams of power generation according to still another preferred embodiment of the present invention. It can be clearly seen from the figure that the embodiment is similar to the above embodiment. In this embodiment, the number of the magnetic disc members 3a is two, and the one side of the two adjacent to the swinging member 22a is located on the same side of the rotating output member 21a, that is, when the two magnetic disc members 3a are rotated, Close to the oscillating member 22a, the rotating magnetic member 32a of the magnetic disk member 3a further has a plurality of component fixing portions 321a, which are fixed perforations in the embodiment, and the fixing portion 31a is a groove, so that the rotating magnetic component can be 32a is inserted into the recess, and the screw is locked into the component fixing portion 321a to be fixed to the fixing portion 31a, and each of the magnetic base assemblies 221a includes two swinging magnetic members 222a, which are respectively located on both sides of the swinging member 22a. The position is respectively corresponding to the two magnetic disc members 3a, and then the brake body 15a and the power output member 16a are disposed on the seat body 1a, and the brake component 15a and the power output member 16a are connected to the rotary output member 21a.

When the rotational output member 21a is rotated to rotate it to rotate, the two magnetic disc members 3a are rotated, and when the two magnetic disc members 3a are rotated, the two sides of the vibrating member 22a are adjacent to each other at the same time. The member 22a simultaneously uses the repulsive force given by the magnetic disk member 3a and the oscillating magnetic member 222a provided on the oscillating member 22a, and the repulsion force is converted into thrust by the adjustment and rotation power of the magnetic spacer 4a to push The magnetic disk member 3a and the rotary output member 21a are continuously rotated.

The rotary output member 21a extends out of a tubular body 17a, and the tubular body 17a rotates in synchronization with the rotary output member 21a, and the brake member 15a is disposed on the tubular body 17a. When the user needs to stop the rotary output member 21a, The brake element 15a can be used to stop the tubular body 17a to drive the rotary output member 21a to stop rotating synchronously, and the brake component 15a can be one of a drum brake or a disc brake, which is not limited, and can be other types. The way of driving.

In the present embodiment, the power output member 16a includes a generator 161a, a disk 162a connecting the power output member 16a, and a crawler belt 163a capable of simultaneously rotating the generator 161a and the disk 162a, thereby rotating the output. The rotational power of the piece 21a is transmitted to the generator In 161a, to achieve the effect of power generation.

Please also refer to the thirteenth to nineteenth drawings, which are a perspective view to a schematic view (2) of another preferred embodiment of the present invention. It can be clearly seen from the figure that the present embodiment and the present embodiment The above embodiment is similar. In the present embodiment, each of the magnetic base assemblies 221b includes two swinging magnetic elements 222b, which are respectively located at two sides of the swinging member 22b, and the magnetic disc member 3b is located between the two swinging magnetic elements 222b. The rotating magnetic members 32b are respectively located at two sides of the fixing portion 31b to respectively correspond to the swinging magnetic members 222b at the two sides, and the magnetic spacer 4b is disposed on the swinging magnetic member 222b, and is located at the swinging magnetic member 222b and rotated. Between the magnetic elements 32b.

As the moving time, first referring to the fourteenth to sixteenth drawings, the power is first given to rotate the magnetic disk member 3b, and as shown in the sixteenth figure, when the magnetic disk member 3b is rotated to the angle The rotating magnetic element 32b on one side is close to the oscillating magnetic element 222b on one side thereof, and the magnetic line of the oscillating magnetic element 222b is adjusted via the magnetic spacer 4b, thereby converging the repulsive force and converting the power of the rotation. It is a thrust to push the magnetic disc member 3b to rotate.

Referring again to the seventeenth figure, when the repulsive force is converted into a thrust to thereby drive the magnetic disc member 3b to rotate, the rotating magnetic member 32b on the other side will squeeze the corresponding swinging magnetic force with a repulsive force. The element 222b thereby urges the oscillating member 22b to swing in conjunction with the rotational direction of the magnetic disk member 3b.

Referring again to the eighteenth figure, when the magnetic disk member 3b is rotated thereto, the magnetic force given by the oscillating magnetic member 222b at the other side is adjusted by the magnetic spacer 4b to convert the repulsive magnetic force. For the thrust, the magnetic disk member 3b is again pushed to rotate continuously, and as shown in Fig. 19, when the magnetic disk member 3b is rotated, the swinging member 22b is further swung in accordance with the direction in which the magnetic disk member 3b rotates, thereby Returning to the aspect as in the sixteenth diagram, and repeating the action, the rotational power is retained therein.

However, the above description is only the preferred embodiment of the present invention, and thus it is not intended to limit the scope of the present invention. Therefore, the simple modification and equivalent structural changes of the present specification and the drawings should be treated similarly. It is included in the scope of the patent of the present invention and is combined with Chen Ming.

Therefore, the key to improving the structure of the magnetic motor of the present invention is to convert the mutually repulsive magnetic force into thrust via the magnetic base assembly 221, the magnetic disc member 3, and the magnetic shield 4, thereby acting on The rotational power on the rotary output member 21 is stored in the rotary assembly 2, and if the power is quickly lost, the power source member 14 can be used to replenish the power.

In summary, the structure of the magnetic motor of the present invention can achieve its efficacy and purpose when used. Therefore, the invention is an invention with excellent practicability, in order to meet the application requirements of the invention patent, and to apply in accordance with the law, and hope that the trial committee will grant the invention as soon as possible to protect the applicant's hard work, if the bureau has Any suspicion, please do not hesitate to give instructions, the applicant will try his best to cooperate, and feel really good.

Claims (9)

A magnetic motor structure mainly comprises: a body, the base body comprising a first body, a second body disposed at one side of the first body, and a first body coupled to the first body a base of the second piece; a rotating component disposed between the first piece and the second piece, and the rotating component comprises a rotating output member, a swinging member, a plurality of magnetic seat assemblies, And at least one magnetic disc member, the rotary output member is pivotally disposed in the housing, the magnetic disc member is disposed on the rotary output member, and a plane of the magnetic disc member and a plane of the rotary output member form a predetermined The oscillating member is pivotally connected to the seat body, and the oscillating member is located at one side of the rotating output member, and the magnetic seat assembly is disposed on the oscillating member and corresponding to the magnetic disk member; The magnetic isolation sheets are respectively disposed on the magnetic seat assemblies and located adjacent to one side of the magnetic disc members. The structure of the magnetic motor according to claim 1, wherein each of the magnetic base assemblies includes an elastic member and a swinging magnetic member, the elastic member is disposed between the swinging member and the base, and the swinging magnetic The component is disposed on the oscillating member and is positioned corresponding to the magnetic disk member. The structure of the magnetic motor of claim 1, wherein the magnetic base assembly comprises a plurality of swinging magnetic elements respectively disposed at two sides of the swinging member and corresponding to the magnetic disc Pieces. The structure of a magnetic motor according to claim 1, wherein the magnetic disk member comprises a fixing portion and a plurality of rotating magnetic members disposed on the fixing portion. The structure of the magnetic motor of claim 4, wherein the rotating magnetic element is provided with at least one component fixing portion for fixing the rotating magnetic component in the fixing portion. The structure of the magnetic motor of claim 1, wherein the rotary output member is for connecting a power source member. The structure of the magnetic motor of claim 1, wherein the rotary output member is for connecting to a power output member. The structure of the magnetic motor according to claim 1, wherein the base body is provided with a brake component connected to the rotary output member. The structure of the magnetic motor of claim 8, wherein the brake component is one of a drum brake or a disc brake.