KR20100089465A - Permanent magnet force amotor - Google Patents

Abstract

PURPOSE: A permanent magnet force motor is provided to obtain rotary motion force generated when a rotor rotates continuously by fixing and arranging an outer permanent magnet and an inner permanent magnet. CONSTITUTION: According to a permanent magnet force motor(1), an outer permanent magnet is disposed and an inner permanent magnet is disposed inside to remain a rotor insertion space. A rotor rotates by generating repulsive force and attracting force with the outer permanent magnet. Only one among the binding bundle of a rotor passes through a magnetic force neutralization range.

Description

Permanent magnet prime mover: {Permanent magnet force amotor}

The present invention (1) by using the magnetic force of the outer permanent magnet (26, 27) and the inner permanent magnet (28, 29) without supplying energy from the outside, the bundle bundles 31, 32, 33, 34, 35 is constantly A fuel-free power field, which is distinguished from the conventional energy-consuming power field by a fuel-free permanent magnetic prime mover (1) in which a disposed rotor (2) continuously rotates.

The theory related to permanent magnetism thus far has been determined that the magnetic force of the permanent magnet is not an energy source, so there is no background technology in the invention of the permanent magnet prime mover (1) of the present invention.

Since the discovery of permanent magnets, many permanent magnets have been used. However, the inventors did not study the magnetic force of permanent magnets as an energy source at the discretion of scientists. However, there have been many times when a person who does not have basic knowledge about permanent magnet has applied for a patent and utility model that is a prime mover using permanent magnet, but all have failed because they are all wrong principles.

Until now, the magnetic force of the permanent magnet could not block the magnetic force without investing energy or change the polarity of N. S. instantaneously, and thus, did not invent the prime mover that generates the continuous rotational movement by using the magnetic force of the permanent magnet.

To solve these problems, only by creating a way to naturally control the magnetic force of the permanent magnet can develop a permanent magnetic motor (1) capable of continuous rotational movement without supplying external energy.

In order to obtain the continuous rotational motion of the rotor 2 by the magnetic force of the permanent magnet, the magnetic force of the permanent magnet must be created in a natural and rational control method without external energy supply.

With reference to the accompanying drawings, the important experiment process to create a method of naturally controlling the magnetic force of the permanent magnet to obtain a continuous rotational motion of the rotor (2) will be described in detail.

FIG. 2 is an exemplary diagram illustrating a stepwise experiment on magnetic force using three permanent magnets 39, 39 ', 40 and braided iron 36. FIG.

2a shows three permanent magnets 39, 39 ′, 40 and magnetization to test the variation of the braid 36 due to the magnetization of the braid 36 and the magnetic force of the magnetized braid 36. As a preparation made by using the non-magnetic material of the non-magnetic material, the insulating material (37), (38), (38 ') is fixed to install the braid (36) containing the appropriate amount of silicon as shown in b of FIG. When inserted into the insertion space 62, as shown in c of FIG. 2, the braid 36 which is in contact with the permanent magnet 40 is magnetized to S polarity, and the braided 36 which is magnetized to S polarity as shown in d of FIG. 2 is fixed to the right side. A repulsive force is generated with the S pole of the permanent magnet 39 ', and a mutual suction force is generated with the N pole of the permanent magnet 39 fixed to the left side to move to and attach to the N pole on the left side.

Thus, the left permanent magnet 39, the polarized magnets 36 magnetized to the north pole and the south pole is never separated without inputting physical energy larger than the attraction force.

As shown in FIG. 3A, if four pieces of braids 48 and 48 'are simultaneously attached to the centers of the polarities of the N and S polarities of the permanent magnet 50 made in a circle as shown in FIG. 3A, the braids 48 and 48' are shown in FIG. At the end, the magnetic force concentration phenomenon occurs and everyone magnetizes to the polarity of the magnets touching each other, so that the flat irons 48 and 48 'positioned on the same pole are unfolded in a fan shape by the occurrence of repulsive force. At this time, the permanent magnet 50 and the attached portion is also pushed by the repulsive force of each other to be separated by a predetermined interval.

If a large number of uneven irons 49 and 49 'are attached to the center of each pole of the N and S anodes of the circular magnet 50 as shown in FIG. 4A, the magnetized uneven irons 49 and 49' are circular due to magnetic concentration. The permanent magnet 50 is spread out in a fan shape, and the braids (49, 49 ') near the magnetic neutralization range (61) between the N and S anodes are attached to the braids with different magnetisms. It is a phenomenon caused by the action of the same polar repulsive force of the braided iron attached to the same pole as the attraction force of, so that it can be dropped only by applying an external force larger than the attraction force attached to each other. Although the silicon-containing braids 36, 48, 48 ', 49 and 49' used in this experiment were forcibly separated from the permanent magnets 39, 39 'and 40, The magnetized magnetism is almost lost.

In this state, the magnetic force of the permanent magnet is not naturally controlled. As shown in Fig. 5, the external permanent magnets 26 and 27 are fixedly arranged, leaving a space for inserting the bundles of waffles 31 therein to the inside. When the center of the magnetic neutralization range (30), (31 ') of the permanent magnets (28), (29) N, S anodes is fixedly arranged so as to coincide with the center of polarity of the external permanent magnets (26), (27), FIG. The two mutual suction zones 66, 68, and the mutual repulsion zones 67 and 69, which are divided into quadrants around the virtual crosshairs, are formed. The thickness of the bundle 31 to be inserted into the space between the outer permanent magnets 26, 27 and the inner permanent magnets 28, 29 exceeds 70% of the magnetic neutralization range 30, 30 '. As illustrated in FIG. 6, a bundle of braids 60 larger than the magnetic neutralization ranges 30 and 30 'matches the suction force of the N and S polarities of the internal permanent magnets 28 and 29. Since it does not fall off and becomes an absolute obstacle of rotational movement, the bundle 31 is made to be within 70% of the magnetic neutralization ranges 30 and 30 'as illustrated in FIG. 7A, and the outer permanent magnet N pole as shown in FIG. 8A. (27) is bonded to the experimental disc located in the space between the inner magnetic pole S pole 29, but if the inner end of the bundle (31) bundle attached to the inner permanent magnet S pole (29) as shown in Figure 8b bundle (31) bundle Is magnetized to the S pole toward the center of the external permanent magnet N pole 26 by generating a mutual repulsion force with the external permanent magnet S pole 29 and mutual attraction force with the external permanent magnet N pole 26. Jeonhadaga a portion of the bind-in 31 bundle is stopped by neutralization somewhat enters the magnetic force range (30) of the inner permanent magnet S pole 29 and the N pole inside the permanent magnet 28 as shown in Figure 8c.

This phenomenon is because the partial contact of the bundle 31 into the magnetic neutralization range 30, the area of contact with the internal permanent magnet S pole 28 is reduced, the S polarity is weakened to become an unmanned state. This is because the mutual attraction force action with the external permanent magnet N pole 26 is weakened. In this state, if one additional bundle of braided bundles 32 is added to the experimental disk as shown in FIG. 9A, the braided bundles 32 are self-rotated and rotated by attraction and repulsion by magnetization. The braided bundle 31 of the attractive state is rotated together. When the center of magnetic force neutralization range (30) coincides with the center of bundle (31) bundle, when the line is in line with the external permanent magnet N pole 26, S pole 27, the force is lost due to magnetic neutralization, but additionally The magnetized bundle bundles 32 added in the magnetic neutralization ranges 30 and 30 'as shown in FIGS. 9B, 9C, 9F, and 9G while being magnetized again out of the magnetic neutralization range 30 by the rotation force of the combined bundle bundles 32. Mutually assist and rotate. In particular, resistance is hardly generated when it is magnetized again out of the magnetic neutralization ranges 30 and 30 '.

The cause is that the bundle 31 is magnetized to the same polarity as the outer permanent magnet N pole 26 but rotates outward from the center of the outer permanent magnet N pole 26 to the outside of the outer permanent magnet N pole 26. Because the repulsive force of the outer permanent magnet N pole 26 pushes the bundle of iron (31), magnetization is accelerated to the N pole of the bundle of iron (31), and the suction force with the outer pole of the permanent magnet S is also strong. Rotation of the bundle 31 is rapid.

In this principle, as shown in Figs. 10, 11, 14, and 15, when the rotor 2 is composed of a plurality of bundle bundles 31, 32, 33, 34, and 35, the external permanent The rotor 2 continues to rotate by the magnetic force of the magnet N pole 26, the S pole 27, the internal permanent magnet N pole 28, and the S pole 29.

As described above, the outer permanent magnet N pole 26 and the S pole 27, the fixed arrangement and the fixed arrangement of the inner permanent magnet N pole 28 and the S pole 29 and the structure and function of the rotor (2) Pure water contained in permanent magnets 26, 27, 28, and 29 without the supply of energy from the outside due to the configuration of braided bundles 31, 32, 33, 34, and 35 Rotation in which the rotor 2 continues to rotate by supplying and losing its own magnetic force to the braided bundles 31, 31, 33, 34, and 35 of the rotor 2 naturally. It produces the effect of gaining exercise power.

In constructing the permanent magnet prime mover 1 of the present invention, as shown in FIGS. 5, 17, and 18, the external permanent magnet N pole 26 and the S pole 27 are fixedly disposed and a space into which the rotor 2 is inserted. The center of the magnetic neutralization range 30 of the inner permanent magnet N-pole 28 and the inner permanent magnet S-pole 29 is left inside so as to coincide with the exact center of the outer permanent magnet N-pole 26 and the opposite magnetic neutralization. The exact center of the range 30 'is fixed so as to coincide with the center of the outer permanent magnet S-pole 27 to form two suction zones 66, 68 and two mutually repulsive zones 67, 69. The rotor (2) is made with reference to Figs. 14 and 15 by using a bundle of bundles 31, 32, 33, 34, and 35 in a bundle of several sheets of iron. 7, the bundle thickness of the bundles 31, 32, 33, 34, and 35 is made within 70% of the magnetic neutralization range 30, 30 'as shown in FIG. The distance between and the bundle is about 1.5 times the magnetic neutralization range (30), (30 ') It will be fixedly arranged on the rotor (2).

The inner bundles 6, 6 ′ of the braided bundles 31, 32, 33, 34, and 35 of the rotor 2 are internal permanent magnets N pole 28 and S poles. It is made with reference to Fig. 11 to make fine contact with the outer surface of (29). As illustrated in FIG. 11, the friction surface 42 between the braided bundles 31, 32, 33, 34, and 35 and the inner permanent magnet N pole 28 and the S pole 29 is illustrated. ), 42 'must be kept in such fine contact that there is no energy loss due to friction.

As described above, the rotor 2 and the outer permanent magnet N pole 26, the S pole 27, the inner permanent magnet N pole 28, and the S pole 29 are arranged and configured as shown in FIG. (7) and the rotor (2) is coupled to the rotor coupling plate (9) and other components are combined as shown in Figure 13, 19, 20, 21 shown in Fig. 18), 18 ', the permanent magnet prime mover 1 of the present invention having a lubricating oil chamber for wear protection is completed.

The rotational motion of the permanent magnet prime mover 1 thus completed will be described with reference to FIG.

As a step-by-step process of the rotational motion from Fig. 23 a to k in Fig. 23, N out of the five bundle bundles 31, 32, 33, 34, and 35 of the rotor 2 is always N. Two braided bundles magnetized to polarity and having N-polarity magnetic force, Two braided bundles magnetized to S-polarity and S-polarized, and one braided bundle that loses magnetism within the magnetic neutralization range (30) or (30 ') This quantity is always the same so that the rotor 2 continues to rotate. Braided bundles (31), (32), (33), (34), and (35) containing appropriate amounts of silicon to remove residual magnetism are outside the internal permanent magnets (28) and (29). (30 ') and there is no resistance to the rotational force of the rotor (2) when the magnetism disappears, the center of the magnetic neutralization range (30), (30') and the outer permanent magnet (26), (27) Even when the magnet is re-magnetized while touching the inner permanent magnets (28) and (29), the center of the iron-clad bundle is slightly out of the center of the outer permanent magnet N pole (26) and the center of the S pole (27). The resistance against the rotational force of the rotor 2 due to the magnetic force of the permanent magnets 26 and 27 does not occur, and the inner permanent magnets 28 and 29 touch the internal magnets 28 and 29 so that the braid of the magnetized rotor 2 is reduced. Bundles (31), (32), (33), (34), and (35) act as repulsion and attraction, and again lose their magnetism through the neutralization range (30) and (30 '), and again the internal permanent magnet Magnetization while touching 28, 29 By continuously repeating the process, the external permanent magnets 26, 27 and is the retained attractive force and repulsive force of the rotational force continues with Features without any external energy supply permanent magnetic motor (1).

1 is a permanent force prime mover

Figure 2 is an example of the braided movement by the magnetic force

Figure 3a, Figure 3b is a test of the braided motion by the magnetic force

Figure 4a, Figure 4b is a test of the braided motion by the magnetic force

5 is an illustration of the magnetic field formed by the magnetic force of the external permanent magnet and the internal permanent magnet

Figure 6 is an illustration of the problem of the deviation is greater than the magnetic neutralization range

7 is an illustration of the effect of the segregation smaller than the magnetic neutralization range

8a, 8b, 8c is a test diagram of the segregation rotational motion by the magnetic force

9A, 9B, 9C, 9D, 9E, 9F, 9G, 9H, and 9I are diagrams for establishing a rotational motion by increasing the iron deviation.

Fig. 10 is a schematic arrangement diagram of rotors

11 is an exemplary view showing the precision of the internal stator magnet and the rotor and sequins

Figure 12 is a perspective view of the bundle of iron

Figure 13 is a perspective view of the rotor coupling plate and the rotating shaft

14 is a perspective view showing a part symbol of the rotor;

Fig. 15 is a perspective view showing part symbols of the rotor;

Figure 16 is a perspective view showing the coupling of the rotor and the rotor coupling plate

17 is a perspective view of a permanent magnet coupling body showing a permanent magnet

18 is a perspective view of a permanent magnet coupling body showing a permanent magnet

Figure 19 is a perspective view of the permanent magnet coupling body showing the pulley coupling direction

20 is a perspective view showing the bearing coupling

Figure 21 is a perspective view showing the coupling of the rotor, pulley, permanent magnet coupling body

22 is a sectional view of a completed permanent magnet prime mover

Figure 23 is an exemplary diagram showing the rotation principle by the permanent magnetic induction of the permanent magnetic prime mover

* Description of Symbols for Major Parts of Drawings *

1: permanent magnet prime mover 2: rotor

3,3 ': Pulley 4,4': Bolted screw hole

5: nonferrous metal of rotor

6,6 ': part in contact with the internal stator magnet

7: axis of rotation 8,8 ': bolt

9: rotor coupling plate 10: washer

11,11 ': braided bundle coupling groove 12: bearing coupling position

13,13 ': Bolted hole 14: Screw shaft part

15: fixed key coupling groove

16: External Permanent Magnet and Internal Permanent Magnet

17,17 ': screw hole 18,18': bearing

19: Spacer ring 20: Bearing support plate

21,21 ': Washer 22,22': Bolt

23: bearing coupling hole 24: washer

25: nut 26: external fixed permanent magnet N pole

27: External fixed permanent magnet S pole 28: Internal fixed permanent magnet N pole

29: Internal fixed permanent magnet S pole

30,30 ': Magnetic neutralization between magnet poles 31: Bundle bundle 1

32: Bundle Bundle 2 33: Bundle Bundle 3

34: Twine Bundle 4 35: Twine Bundle 5

36: fixed key 37,37 ': nonmagnetic isolation

38: permanent magnet 39: permanent magnet

40: permanent magnet 41,41 ': spacing line

42,42 ': Partial line where the internal fixed permanent magnet touches the rotor bundle bundle

43,43 ': Bolted hole 44,44': Bolted hole

45,45 ': Nonferrous metal coupling hole 46,46': Mechanical cell

47: Rotor compartment protective cover 48,48 ': Multiple iron

49,49 ': Multiple stitches 50: Circular magnet

51: square permanent magnet

52,52 ': Positions where the ends of the braids face each other by magnetic force

53,53 ': Permanent magnet and braided end positions

54,54 ': Indicator line 55.55': Bolt

56,56 ': washer 57,57': bolted screw hole

58,58 ': Bolted hole 59: Bonding plate

60: bundles larger than neutralization range between stimuli

61: neutralization range between stimulus 62: iron insertion space

63,63 ': Neutralizing range between stimuli

64: Experimental disc for attaching braided iron bundles (31), (32), (33), (34) and (35)

65: rotation shaft insertion hole

66: mutual attraction force range between the outer permanent magnet N pole 26 and the inner permanent magnet S pole 29

67: The outer permanent magnet N-pole (26) and the inner permanent magnet N-pole (28) and mutually repulsive power

68: mutual attraction force between the outer permanent magnet S pole (27) and the inner permanent magnet N pole (28)

69: the repulsive force of the outer permanent magnet S pole (27) and the inner permanent magnet S pole (29)

70: lubricating oil seal

71: magnetic field separator crosshair

Claims (5)

The inside of the main body 16 having the lubricating oil chamber as the bearing 18, 18 'wear-preventing means has a circular shape and is formed through the insertion hole 65 into which the rotating shaft 7 is inserted. The inner permanent magnet N pole 28 and the S pole 29 is fixedly disposed on the outer surface of the rotor and the outer permanent magnet N pole 26 and the S pole 27 are fixed to the outside of the space into which the rotor 2 is to be inserted. The center of the magnetic neutralization range (30) and (30 ') between the inner permanent magnet N pole 28 and the S pole 29 coincides with the center of the outer permanent magnet N pole 26 and the center of the S pole 27 respectively. And mutually attracting force zones 66 and 68 divided into four by the magnetic force of the outer permanent magnet N pole 26, the S pole 27, the inner permanent magnet N pole 28, and the S pole 29. The outer perimeter of the silicon-containing braided bundles 31, 32, 33, 34, and 35 of the rotor 2 The gap is maintained so as not to contact the permanent magnet N pole (26), S pole (27), and the inner surfaces (6) and (6 ') Fine contact with the magnet N pole 28, S pole 28, and fixedly coupled to the rotating shaft (7) with a nonmagnetic metal or plastic to the rotor (2) external permanent magnet N pole (26) S pole (27) By inserting and coupling into the space between the internal permanent magnet N pole 28 and the S pole 29, the inner side of the permanent magnet N pole (31), (32), (33), (34), (35) 28), magnetized by the S pole 29 and rotated with the external permanent magnet N pole 26, S pole 27 to generate mutual repulsion and attraction force, and the bundle of magnetic neutralization range (30), (30 ') Permanent magnetic prime mover, characterized in that the magnetic force is lost only at each passing moment and is magnetized again when it touches the inner permanent magnet N pole 28 and the S pole 29 so that the rotor 2 continues to rotate without external energy supply. One). The thickness of the braided bundles 31, 32, 33, 34, and 35 of the rotor 2 is set between the inner permanent magnet N pole 28 and the S pole 29. The magnetic neutralization range (30, (30 ') is within 70% of the size and the spacing between the braided bundle and the braided bundle arrangement of the rotor 2 is the magnetic neutralization range between the inner permanent magnet N pole 28, S pole 29 Permanent magnetic prime mover (1) characterized by minimizing interference with the rotational force of the rotor (2) by fixedly placing the rotor (2) at intervals of about 1.5 times greater than (30) (30 '). The permanent magnet prime mover (1) according to claim 1, wherein the permanent magnet prime mover (1) maintains the rotational force appropriately by increasing or decreasing the number and size of the braided bundles of the rotor (2) according to the specifications of the permanent magnet prime mover (1). According to claim 1, wherein the outer permanent magnet N pole 26 and the S pole 27 is fixedly disposed inside the main body 16, and the rotor 2 has an insertion space therein, and the inner permanent magnet N pole 28 is provided. The center of the magnetic force neutralization range 30 between the poles and S poles 29 coincides with the center of the N pole 26 of the external permanent magnet, and the center of the magnetic pole neutralization range 30 'between the poles is the S pole 27 of the external permanent magnet. In accordance with), the internal permanent magnets 28 and 29 are fixedly disposed so that the magnetic attraction force of the external permanent magnets 26 and 27 and the magnetic force of the internal permanent magnets 28 and 29 are mutually attracted. Permanent magnet prime mover (1) characterized by forming (66), (68) mutually repulsive forces (67), (69). The magnetization bundles 31, 32, 33, 34, and 35 of the rotor 2 are magnetized only when they touch the inner permanent magnets 28 and 29, respectively. If you have magnetic force and completely enter the magnetic neutralization range (30), (30 '), the magnetic force is lost and the bundles 31, 32, 33, 34, and 35 are attracted. Permanent magnet prime mover (1) characterized in that the rotor (2) rotates within the range (66), (68) and the range of repulsion range (69).

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