JP2008029190A - Arrangement method of magnet in magnetic driving, and magnetic driving device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an arranging method of a magnet in magnetic driving, and a magnetic driving device. <P>SOLUTION: The driving device consists of a turn table equipped with a turn table shaft at the center, with a rotary magnet being fitted, and a fixed table to which a fixed magnet is fitted and the turn table shaft is rotatably fitted at the center so as to be connected to the turn table. The arrangement of the rotary magnet and the fixed magnet allows magnetic driving. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a magnet arrangement method and a magnetic drive device in magnetic drive.

  Conventionally, every device or device that exists in the world uses electricity, gas, gasoline, etc. to drive the drive, and electricity uses hydropower, thermal power, wind power, solar power, nuclear power, etc. to generate electricity. The stored electric power is used for the driving device.

However, in conventional drive devices that use electricity, gas, gasoline, etc., resources are limited, and the amount of water that generates electricity in electricity is not stable due to global warming. For wind, a vast wind power generation mechanism is required, and for solar power, a solar power generation device is required, and nuclear power is dangerous.
Japanese Unexamined Patent Publication No. 07-031128

  Therefore, the present invention can be driven without using resources such as electric power, and can further generate electric power therefrom, and can be used as power as it is. The object is to provide an apparatus.

  In order to solve the above-mentioned problems, the present invention is connected to a rotating disk by mounting a rotating magnet with a rotating disk shaft at the center of mounting the rotating magnet and rotatably mounting the rotating disk shaft at the mounting center of the stationary magnet. The arrangement method of the magnets and the configuration of the magnetic drive device in the drive device, which is configured by the fixed plate and is capable of magnetic driving by the arrangement relationship of the rotating magnet and the fixed magnet.

  The magnet arrangement method and the magnetic drive device in the magnetic drive device of the present invention can be driven without using resources such as electric power, gas, gasoline, etc., and therefore can always be driven without worrying about resources. Friendly.

  In addition, since it is possible to always generate a certain amount of power from the magnetic drive device, it is possible to supply a stable power and avoid a power shortage.

  The purpose of a driving device that can be driven without using gas, gasoline, and electric power generated from them, and that can generate electric power, has been realized by effectively arranging the magnets of the magnetic driving device.

  FIG. 1 is a diagram showing a magnet arrangement method in a magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention.

  As shown in FIG. 1, the magnet arrangement method 1 in the magnetic drive device according to the present invention is a semicircular shape on the fixed plate 2 so that the fixed magnet core 4a is slightly different from the rotating plate shaft 3a. The fixed plate 2 to which the fixed magnet 4 is attached, and the rotary plate 3 to which the substantially C-shaped rotary magnet 5 is cut off by about a quarter so that the rotary plate shaft 3a and the rotary magnet core 5a are slightly different positions. And a rotating plate 3 rotatably attached to the fixed plate 2, and one magnetic pole (for example, N pole) of the fixed magnet 4 is inside the rotating magnet 5 and one of the fixed magnets 4. Are located at the same height as the rotating magnet 5.

  The approximately C-shaped rotating magnet 5 cut off by about a quarter has different magnetic poles 5b and 5c from the center to the left and right, and the semicircular fixed magnet 4 has different magnetic poles from the center to the upper and lower sides. It has become. In FIG. 1 to FIG. 5 showing the present invention, the white magnetic pole is the S pole and the shaded magnetic pole is the N pole, but there is no particular limitation. That is, the white magnetic pole may be the N pole, and the magnetic pole painted with diagonal lines may be the S pole.

  FIG. 1 shows that only the N pole side of the fixed magnet 4 is positioned inside the rotating magnet 5 and further positioned at the same height as the rotating magnet 5. The fixed magnet 4 and the rotating magnet 5 are By making the positional relationship, the turntable 3 can continue to rotate counterclockwise. Further, when the fixed magnet 4 is only on the south pole side, the turntable 3 rotates clockwise.

  FIG. 2 is a view showing a second embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 2, the magnet arrangement method 1 a in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement method 1.

  That is, the magnet arrangement method 1a in the magnetic drive device according to the present invention includes a stationary platen 2 in which a stationary magnet 4b having a substantially elliptical shape and the same circumference and the same magnetic pole is attached to the central portion of the stationary platen 2, and a rotating disk shaft 3a. And the rotating plate 3 to which the rotating magnet 5 consisting of magnetic poles 5b and 5c different from each other on the left and right from the center is attached. 2, and a magnetic pole (for example, N pole) of the fixed magnet 4 b is inside the rotary magnet 5 and one magnetic pole (for example, the fixed magnet 4 b) N pole) is located at the same height as the rotating magnet 5.

  As shown in FIG. 2, only the N pole side of the fixed magnet 4b is positioned inside the rotating magnet 5, and further, is positioned at the same height as the rotating magnet 5. The fixed magnet 4b and the rotating magnet 5 are With such a positional relationship, the turntable 3 can continue to rotate counterclockwise. Further, when the fixed magnet 4b is only on the south pole side, the turntable 3 rotates clockwise.

  FIG. 3 is a view showing a third embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 3, the magnet arrangement method 1b in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 1 and 1a.

  That is, the magnet arrangement method 1b in the magnetic drive device according to the present invention includes a stationary platen 2 in which a stationary magnet 4c having a trapezoidal shape and the same magnetic pole is attached to the central portion of the stationary platen 2, and a rotary disk shaft 3a The fixed platen is provided with the rotary plate 3 to which the rotary magnet 5 consisting of magnetic poles 5b and 5c which are substantially C-shaped and are different from each other on the left and right sides is cut off by about a quarter so that the rotary magnet core 5a is slightly different. 2, and a magnetic pole (for example, N pole) of the fixed magnet 4 c is inside the rotating magnet 5 and one magnetic pole (for example, the fixed magnet 4 c) N pole) is located at the same height as the rotating magnet 5.

  As shown in FIG. 3, only the N pole side of the fixed magnet 4 c is positioned inside the rotating magnet 5, and further, is positioned at the same height as the rotating magnet 5, and the fixed magnet 4 c and the rotating magnet 5 are connected to each other. With such a positional relationship, the turntable 3 can continue to rotate counterclockwise. Further, when the fixed magnet 4c is only on the south pole side, the turntable 3 rotates clockwise.

  FIG. 4 is a view showing a fourth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 4, the magnet arrangement method 1c in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 1, 1a and 1b.

  That is, the magnet arrangement method 1c in the magnetic drive device according to the present invention includes a stationary platen 2 in which a stationary magnet 4d having a square shape and the same magnetic pole is attached to the central portion of the stationary platen 2, and a rotary disk shaft 3a. The fixed platen 2 is provided with a rotating plate 3 to which a rotating magnet 5 composed of magnetic poles 5b and 5c which are substantially C-shaped and are different from each other on the left and right sides from the center. And one magnetic pole (for example, N pole) of the fixed magnet 4d is inside the rotary magnet 5 and one magnetic pole (for example, N) of the fixed magnet 4d. Pole) is located at the same height as the rotating magnet 5.

  As shown in FIG. 4, only the N pole side of the fixed magnet 4d is positioned inside the rotating magnet 5, and further, is positioned at the same height as the rotating magnet 5. The fixed magnet 4d and the rotating magnet 5 are With such a positional relationship, the turntable 3 can continue to rotate counterclockwise. On the other hand, when the fixed magnet 4d is on the south pole side, the turntable 3 rotates clockwise.

  FIG. 5 is a view showing a fifth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 5, the magnet arrangement method 1d in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 1, 1a, 1b, and 1c.

  That is, the magnet arrangement method 1d in the magnetic drive device according to the present invention is such that the same periphery is the same by joining a plurality of fixed magnets 4e having the same shape and size in the center of the fixed plate 2 with the same magnetic poles joined together. The stationary platen 2 that is mounted in an evenly arranged configuration with magnetic poles, and a substantially C-shape that is cut off by about a quarter so that the rotary plate shaft 3a and the rotary magnet core 5a are slightly different positions, differ from the center to the left and right. The rotating disk 3 to which the rotating magnet 5 composed of the magnetic poles 5b and 5c is attached is composed of the rotating disk 3 rotatably attached to the fixed disk 2, and one magnetic pole (for example, N pole) of the fixed magnet 4e is One magnetic pole (for example, N pole) of the fixed magnet 4 e is located at the same height as the rotary magnet 5 inside the rotary magnet 5.

  As shown in FIG. 5, only the N pole side of the fixed magnet 4 e is located inside the rotating magnet 5, and further, is located at the same height as the rotating magnet 5, and the fixed magnet 4 e and the rotating magnet 5 are connected to each other. With such a positional relationship, the turntable 3 can continue to rotate counterclockwise. Further, when the fixed magnet 4e is only on the south pole side, the turntable 3 rotates clockwise.

  FIG. 6 is a view showing a sixth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIG. 6, the magnet arrangement method 6 in the magnetic drive device according to the present invention includes a fixed platen 7 to which a fixed magnet 9 having a hollow cylindrical interior and the same circumference and the same magnetic poles is attached. The rotating magnet core 10d is positioned between the rotating disk shaft 8a and the rotating magnet 10 in the rotating magnet 10 in which a plurality of magnets composed of magnetic poles 10a and 10b having different polarities are faced to each other and connected in a fan shape. The rotating magnet 10 is located inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is positioned at the same height as the rotating magnet 10. Yes.

  The fan-shaped rotating magnet 10 is formed by connecting a plurality of magnets composed of magnetic poles 10a and 10b having different polarities, and the inside of the fan is not concerned with the presence or absence of the magnetic poles 10a and 10b, but the outside is one side. The nonmagnetic material 10c is sandwiched between the magnet and the other magnet. The rotating magnet core 10d is equal to the center that appears when the rotating magnet 10 is connected in a circle, and the radius connecting the outer peripheral surface of the rotating magnet 10 and the rotating magnet core 10d is greater than the radius of the inner peripheral surface of the fixed magnet 9. Is also small.

  The fixed magnet 9 has magnetic poles that are different from each other from the top to the bottom. As described above, in FIGS. 6 to 21 showing the present invention, the white magnetic pole is the S pole, and the magnetic pole painted with diagonal lines is the N pole. However, there is no particular limitation. That is, the white magnetic pole may be the N pole, and the magnetic pole painted with diagonal lines may be the S pole.

  FIG. 6 shows that the rotating magnet 10 has the same height as the position of the N pole inside the fixed magnet 9 and the N pole of the fixed magnet 9, and the fixed magnet 9 and the rotating magnet 10 are in such a positional relationship. By doing so, the turntable 8 can continue to rotate counterclockwise. When the inner circumference of the fixed magnet 9 is the south pole, the rotating disk 8 rotates clockwise.

  FIG. 7 is a view showing a seventh embodiment of the magnet placement method and the magnet placement state of the magnetic drive device according to the present invention. As shown in FIG. 7, the magnet arrangement method 6a in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement method 6.

  That is, the magnet arrangement method 6a in the magnetic drive device according to the present invention includes a fixed plate 7 to which a fixed magnet 9 having a hollow cylindrical interior and the same circumference and the same magnetic pole is attached, and magnetic poles having opposite polarities. The rotating disk shaft 8a is positioned between the rotating magnet core 10d and the rotating magnet 10 in the rotating magnet 10 in which a plurality of magnets 10a and 10b are connected in a fan shape with opposite poles facing each other with a non-magnetic material 10c. The rotating magnet 10 is located inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is positioned at the same height as the rotating magnet 10. .

  The fan-shaped rotating magnet 10 is formed by connecting a plurality of magnets having magnetic poles 10a and 10b having different polarities so that the different polarities face each other, and each fan is connected by a non-magnetic material 10c. On the outside, the non-magnetic body 10c is not adjacent between one magnet and the other magnet. The rotating magnet core 10d is equal to the center that appears when the rotating magnets 10 are connected in a circle, and the radius connecting the outer peripheral surface of the rotating magnet 10 and the rotating magnet core 10d is substantially the same as the radius of the fixed magnet 9.

  FIG. 7 shows that the rotating magnet 10 has the same height as the position of the N pole inside the fixed magnet 9 and the N pole of the fixed magnet 9, and the fixed magnet 9 and the rotating magnet 10 are in such a positional relationship. By doing so, the turntable 8 can continue to rotate clockwise. When the inner circumference of the fixed magnet 9 is the south pole, the rotating disk 8 rotates counterclockwise.

  FIG. 8 is a view showing an eighth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 8, the magnet arrangement method 6b in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 and 6a.

  That is, the magnet arrangement method 6b in the magnetic drive device according to the present invention includes a fixed platen 7 to which a fixed magnet 9 having the same cylindrical circumference and the same magnetic pole is attached, and a magnetic pole having different polarities on the front and back sides. A rotating magnet 10 in which a magnet composed of 10a and 10b is connected to both ends of a nonmagnetic body 10c curved with opposite poles facing each other is arranged such that the rotating magnet core 10d is positioned between the rotating disk shaft 8a and the rotating magnet 10. The rotating magnet 10 is located inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is positioned at the same height as the rotating magnet 10. Yes.

  The fan-shaped rotating magnet 10 is formed by connecting magnets composed of magnetic poles 10a and 10b having different polarities to both ends of a curved nonmagnetic material 10c. The rotating magnet core 10d is equal to the center that appears when the rotating magnets 10 are connected in a circle, and the radius connecting the outer peripheral surface of the rotating magnet 10 and the rotating magnet core 10d is smaller than the radius of the inner peripheral surface of the fixed magnet 9. .

  FIG. 8 shows that the rotating magnet 10 has the same height as the position of the north pole of the fixed magnet 9 and the fixed magnet 9, and the fixed magnet 9 and the rotating magnet 10 are in such a positional relationship. By doing so, the turntable 8 can continue to rotate counterclockwise. Further, when the inner circumference of the fixed magnet 9 is the south pole, the rotating disk 8 rotates clockwise.

  FIG. 9 is a view showing a ninth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 9, the magnet arrangement method 6c in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6, 6a, 6b.

  That is, the magnet arrangement method 6c in the magnetic drive device according to the present invention includes a fixed plate 7 to which a fixed magnet 9 having a hollow cylindrical interior and the same circumference is formed of the same magnetic pole, and a magnetic pole 10a having different polarities. A rotating magnet 10 in which a magnet composed of 10b is connected to both ends of a nonmagnetic body 10c curved with opposite poles facing each other is attached so that the rotating disk shaft 8a is positioned between the rotating magnet core 10d and the rotating magnet 10. The rotating magnet 10 is inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is located at the same height as the rotating magnet 10.

  The fan-shaped rotating magnet 10 is formed by connecting magnets composed of magnetic poles 10a and 10b having different polarities to both ends of a curved nonmagnetic material 10c. The rotating magnet core 10d is equal to the center that appears when the rotating magnets 10 are connected in a circle, and the radius connecting the outer peripheral surface of the rotating magnet 10 and the rotating magnet core 10d is substantially the same as the radius of the fixed magnet 9.

  FIG. 9 shows that the rotating magnet 10 has the same height as the position of the N pole inside the fixed magnet 9 and the N pole of the fixed magnet 9, and the fixed magnet 9 and the rotating magnet 10 are in such a positional relationship. By doing so, the turntable 8 can continue to rotate clockwise. When the inner circumference of the fixed magnet 9 is the S pole, the rotating disk 8 rotates counterclockwise.

  FIG. 10 is a view showing a tenth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 10, the magnet arrangement method 6d in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6c.

  In other words, the magnet arrangement method 6d in the magnetic drive device according to the present invention includes a fixed plate 7 on which a fixed magnet 9 having a hollow cylindrical interior and the same circumference and the same magnetic pole is mounted, and a magnetic pole 10a having a different polarity. The rotating magnet 10 in which the rotating magnet 10 and the rotating magnet core 10d are separated by the rotating shaft 8a is positioned in the same semicircle in which the rotating magnet 10 connected to both ends of the non-magnetic member 10c curved with the different poles curved. The rotating magnet 10 is located inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is positioned at the same height as the rotating magnet 10. Yes.

  The fan-shaped rotating magnet 10 is formed by connecting magnets composed of magnetic poles 10a and 10b having different polarities to both ends of a curved nonmagnetic material 10c. The rotating magnet core 10d is equal to the center that appears when the rotating magnets 10 are connected in a circle, and the radius connecting the outer peripheral surface of the rotating magnet 10 and the rotating magnet core 10d is smaller than the radius of the inner peripheral surface of the fixed magnet 9. .

  In FIG. 10, the rotating magnet 10 indicates that the inner side of the fixed magnet 9 and the height of the N pole of the fixed magnet 9 are the same, and the outer peripheral surface of the rotating magnet 10 is the center side of the rotating disk 8. The inner peripheral surface is attached so as to face the outside of the turntable 8. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate clockwise. When the inner circumference of the fixed magnet 9 is the south pole, the rotating disk 8 rotates counterclockwise.

  FIG. 11 is a view showing an eleventh embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 11, the magnet arrangement method 6e in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6d.

  In other words, the magnet arrangement method 6e in the magnetic drive device according to the present invention has a vertically different relationship with the fixed platen 7 to which the fixed magnet 9 having a cylindrical shape with the same circumference and the same magnetic pole is attached. The rotating magnet 10 includes a rotating disk 8 attached so that the left side of the rotating magnet 10 overlaps the diameter of the rotating disk 8 and one corner of the rotating magnet 10 is on the outer periphery of the rotating disk 8. The rotating magnet 10 is inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is positioned at the same height as the magnetic pole (for example, S pole) of the rotating magnet 10.

  In FIG. 11, the rotating magnet 10 indicates that the position and height of the S pole of the rotating magnet 10 and the N pole of the fixed magnet 9 are the same inside the fixed magnet 9. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate clockwise. Further, in FIG. 11, when the inner circumference of the fixed magnet 9 is the south pole, the rotating disk 8 rotates counterclockwise.

  FIG. 12 is a view showing a twelfth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 12, the magnet arrangement method 6f in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6e.

  That is, the magnet arrangement method 6f in the magnetic drive device according to the present invention includes a fixed plate 7 having a cylindrical shape with a hollow inside and a fixed magnet 9 having the same circumference and the same magnetic pole. The rectangular rotating magnet 10 having the magnetic poles 10a and 10b is overlapped on the diameter of the rotating disk 8 with the boundary lines of the magnetic poles 10a and 10b having different polarities on the rotating magnet 10, and the corners on both sides of the rotating magnet 10 having the different polarities are overlapped. , And the rotating magnet 10 is inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is rotated. It is located at the same height as the magnet 10.

  In FIG. 12, the rotating magnet 10 represents that the position and height of the N poles of the rotating magnet 10 and the fixed magnet 9 are the same inside the fixed magnet 9. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate counterclockwise. In addition, in FIG. 12, when the circumference inside the fixed magnet 9 is the south pole, the turntable 8 rotates clockwise.

  FIG. 13 is a diagram showing a thirteenth embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention. As shown in FIG. 13, the magnet arrangement method 6g in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6f.

  That is, the magnet arrangement method 6g in the magnetic drive device according to the present invention includes a fixed plate 7 to which a fixed magnet 9 having a hollow cylindrical interior and the same circumference and the same magnetic pole is attached, and magnetic poles having different polarities on the front and back sides. A rotating magnet 10 in which a plurality of flat magnets 10a and 10b are arranged in series with opposite poles facing each other is overlapped with the central portion of the rotating magnet 10 on the diameter of the rotating disk 8 so that the outer side of the rotating magnet 10 is different. The rotating disk 8 is mounted so that the corners on both sides of the poles are on the outer periphery of the rotating disk 8, the rotating magnet 10 is inside the fixed magnet 9, and one of the poles of the fixed magnet 9 (for example, N pole) is located at the same height as the rotating magnet 10.

  In FIG. 13, the rotating magnet 10 is inside the fixed magnet 9, and the position and height of the N poles of the rotating magnet 10 and the fixed magnet 9 are the same. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate counterclockwise. Further, in FIG. 13, when the circumference inside the fixed magnet 9 is the south pole, the turntable 8 rotates clockwise.

  FIG. 14 is a view showing a fourteenth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 14, the magnet arrangement method 6h in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6g.

  That is, the magnet arrangement method 6h in the magnetic drive device according to the present invention includes a fixed plate 7 having a cylindrical shape with a hollow inside and a fixed magnet 9 having the same circumference and the same magnetic pole. The rotating magnet 10 having a horizontally long rectangular parallelepiped shape having the magnetic poles 10 a and 10 b is overlapped on the diameter of the rotating disk 8 by the boundary lines of the magnetic poles 10 a and 10 b of the rotating magnet 10 different from each other. The rotating magnet 8 is located at a position within one semicircle, the rotating magnet 10 is inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is connected to the rotating magnet 10. Located at the same height.

  In FIG. 14, the rotating magnet 10 is inside the fixed magnet 9 and indicates that the position and height of the N poles of the rotating magnet 10 and the fixed magnet 9 are the same. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate counterclockwise. Further, in FIG. 14, when the inner circumference of the fixed magnet 9 is the south pole, the turntable 8 rotates clockwise.

  FIG. 15 is a view showing a fifteenth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 15, the magnet arrangement method 6i in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6h.

  That is, the magnet arrangement method 6i in the magnetic drive device according to the present invention has a cylindrical shape with a hollow interior and a fixed plate 7 to which a fixed magnet 9 having the same magnetic pole is attached, and a left-hand side having a different polarity relationship in the vertical direction. The right side of the rotating magnet 10 overlaps the diameter of the rotating disk 8 and the two corners of the inclined surface of the rotating magnet 10 are positioned near the outer peripheral surface of the rotating disk 8. The rotating magnet 10 is inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is a magnetic pole (for example, S pole) of the rotating magnet 10. Located at the same height.

  In FIG. 15, the rotating magnet 10 is inside the fixed magnet 9, and the position and height of the S pole of the rotating magnet 10 and the N pole of the fixed magnet 9 are the same. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate clockwise. Further, in FIG. 15, when the circumference inside the fixed magnet 9 is the south pole, the rotating disk 8 rotates counterclockwise.

  FIG. 16 is a diagram showing a sixteenth embodiment of the magnet placement method in the magnetic drive and the magnet placement state of the magnetic drive device according to the present invention. As shown in FIG. 16, the magnet arrangement method 6j in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6i.

  That is, the magnet arrangement method 6j in the magnetic drive device according to the present invention has a vertically different relationship from the fixed platen 7 to which the fixed magnet 9 having a cylindrical shape with the same circumference and the same magnetic pole is attached. A rotating magnet 10 having an inclined surface 10e on the left side is attached so that the right side of the rotating magnet 10 overlaps the diameter of the rotating disk 8 and the acute angle of the rotating magnet 10 is positioned on the outer peripheral surface of the rotating disk 8. The rotating magnet 10 is inside the fixed magnet 9 and one pole (for example, N pole) of the fixed magnet 9 is at the same height as the magnetic pole (for example, S pole) of the rotating magnet 10. positioned.

  In FIG. 16, the rotating magnet 10 is inside the fixed magnet 9, and the position and height of the S pole of the rotating magnet 10 and the N pole of the fixed magnet 9 are the same. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate clockwise. Further, in FIG. 16, when the circumference inside the fixed magnet 9 is the south pole, the rotating disk 8 rotates counterclockwise.

  FIG. 17 is a view showing a seventeenth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 17, the magnet arrangement method 6k in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6j.

  In other words, the magnet arrangement method 6k in the magnetic drive device according to the present invention includes a fixed plate 7 having a cylindrical shape with a hollow inside and a fixed magnet 9 having the same circumference and the same magnetic pole. A substantially semicircular rotary magnet 10 having magnetic poles 10a and 10b is mounted with the central portion of the rotary magnet 10 overlapping the diameter of the rotary disk 8 and the inner side of the rotary magnet 10 facing the direction of the rotary disk axis 8a. The rotating magnet 10 is inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is located at the same height as the rotating magnet 10.

  The rotating magnet 10 is attached so that the rotating magnet core 10d when the rotating magnet 10 is circular is located between the rotating magnet 10 and the rotating disk shaft 8a.

  In FIG. 17, the rotating magnet 10 indicates that the position and height of the N poles of the rotating magnet 10 and the fixed magnet 9 are the same inside the fixed magnet 9. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate counterclockwise. Further, when the inner circumference of the fixed magnet 9 is the south pole, the rotating disk 8 rotates clockwise.

  FIG. 18 is a view showing an eighteenth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 18, the magnet arrangement method 6l in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6k.

  That is, the magnet arrangement method 6l in the magnetic drive device according to the present invention includes a fixed plate 7 having a cylindrical shape with a hollow inside and a fixed magnet 9 having the same circumference and the same magnetic pole. A substantially semicircular rotary magnet 10 having magnetic poles 10a and 10b is mounted with the central portion of the rotary magnet 10 overlapping the diameter of the rotary disk 8 and the inner side of the rotary magnet 10 facing the direction of the rotary disk axis 8a. The rotating magnet 10 is inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is located at the same height as the rotating magnet 10.

  The rotating magnet 10 is attached such that the rotating disk shaft 8a is between the rotating magnet core 10d and the rotating magnet 10 when the rotating magnet 10 is circular.

  In FIG. 18, the rotating magnet 10 is shown inside the fixed magnet 9 and the position and height of the N poles of the rotating magnet 10 and the fixed magnet 9 are the same. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate clockwise. When the inner circumference of the fixed magnet 9 is the south pole, the rotating disk 8 rotates counterclockwise.

  FIG. 19 is a view showing a nineteenth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 19, the magnet arrangement method 6m in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6l.

  That is, the magnet arrangement method 6m in the magnetic drive device according to the present invention includes a fixed plate 7 in which a fixed magnet 9 having a hollow cylindrical interior and the same circumference is formed of the same magnetic pole, and opposite poles at both ends. A state in which a substantially U-shaped rotating magnet 10 having magnetic poles 10a and 10b is overlapped with the central portion of the rotating magnet 10 close to the rotating disk shaft 8a, and both ends of the rotating magnet 10 face the inner periphery of the fixed magnet 9. The rotating magnet 10 is located inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is positioned at the same height as the rotating magnet 10. Yes.

  In FIG. 19, the rotating magnet 10 is inside the fixed magnet 9, and the position and height of the N poles of the rotating magnet 10 and the fixed magnet 9 are the same. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate clockwise. Further, in FIG. 19, when the inner circumference of the fixed magnet 9 is the south pole, the rotating disk 8 rotates counterclockwise.

  FIG. 20 is a diagram showing a twentieth embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention. As shown in FIG. 20, the magnet arrangement method 6n in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6m.

  That is, the magnet arrangement method 6n in the magnetic drive device according to the present invention has the same shape and the same size as the fixed platen 7 to which the fixed magnet 9 having a hollow cylindrical interior and the same circumference and the same magnetic pole is attached. The rotating magnets 10 are arranged in an arc so that the same number of circular magnets each having a different polarity of the magnetic poles 10a, 10b are arranged in such a way that the different polarity magnetic poles 10a, 10b are different from each other on the left and right. 8, the rotating magnet 10 is inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 has the same height as the rotating magnet 10. Is located.

  In FIG. 20, the rotating magnet 10 is inside the fixed magnet 9, and the position and height of the N poles of the rotating magnet 10 and the fixed magnet 9 are the same. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate counterclockwise. Further, in FIG. 20, when the circumference inside the fixed magnet 9 is the south pole, the rotating disk 8 rotates clockwise.

  FIG. 21 is a view showing a twenty-first embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 21, the magnet arrangement method 6o in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 6 to 6n.

  That is, the magnet arrangement method 6o in the magnetic drive device according to the present invention includes a fixed plate 7 to which a fixed magnet 9 having a hollow cylindrical interior and the same circumference and the same magnetic pole is attached, and the same circumference from the same magnetic pole. A line connecting the both ends of the substantially semicircular rotating magnet 10 is parallel to a meridian that is vertically lowered from the rotating disk shaft 8a, and a meridian that is vertically lowered from the rotating disk shaft 8a. Is a rotating disk 8 attached to the left side of the rotating magnet 10, the rotating magnet 10 is inside the fixed magnet 9, and one pole (for example, N pole) of the fixed magnet 9 is a rotating magnet. It is located at the same height as 10 magnetic poles (for example, S pole).

  FIG. 21 shows that the rotating magnet 10 is inside the fixed magnet 9 and the position and height of the N poles of the rotating magnet 10 and the fixed magnet 9 are the same. By setting the fixed magnet 9 and the rotating magnet 10 in such a positional relationship, the rotating disk 8 can continue to rotate counterclockwise. Further, in FIG. 21, when the circumference inside the fixed magnet 9 is the south pole, the rotating disk 8 rotates clockwise.

  FIG. 22 is a view showing a twenty-second embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIG. 22, the magnet placement method 11 in the magnetic drive device according to the present invention includes a fixed disk 12 to which a fixed magnet 14 having a flat plate and one surface made of the same magnetic pole is attached. The rotating magnet core 15d is connected between the rotating disk shaft 13a and the rotating magnet 15 with a plurality of plate magnets made of magnetic poles 15a and 15b facing each other with a plurality of different poles facing each other in a fan shape via a nonmagnetic material 15c. The rotating magnet 15 is positioned below the fixed magnet 14.

  The fan-shaped rotating magnet 15 is formed by connecting a plurality of plate-shaped magnets composed of magnetic poles 15a and 15b having different polarities on the front and back sides in a fan shape with the different polarities facing each other through a non-magnetic material 15c. The space is not adjacent by the nonmagnetic material 15c. The rotating magnet core 15d is equal to the center appearing when the rotating magnet 15 is connected in a circle, and the radius connecting the outer peripheral surface of the rotating magnet 15 and the rotating magnet core 15d is smaller than the radius of the fixed magnet 14.

  The fixed magnet 14 is a magnetic pole whose top and bottom are different from each other. Accordingly, one surface of the fixed magnet 14 has the same magnetic pole, and in FIGS. 22 to 38 showing the present invention, for the rotating magnet 15, the white magnetic pole is the S pole, and the magnetic pole painted with diagonal lines is the N pole. The surface of the fixed magnet 14 facing the rotating magnet 15 is an N pole, but is not particularly limited. That is, the white magnetic pole of the rotating magnet 15 may be regarded as the N pole, the magnetic pole painted with diagonal lines as the S pole, and the surface of the fixed magnet 14 facing the rotating magnet 15 as the S pole.

  FIG. 22 shows that the rotating magnet 15 is at a lower position of the fixed magnet 14, and the rotating disk 13 rotates counterclockwise by setting the fixed magnet 14 and the rotating magnet 15 in this positional relationship. Can continue.

  FIG. 23 is a view showing a twenty-third embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 23, the magnet arrangement method 11a in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement method 11.

  As shown in FIG. 23, the magnet arrangement method 11a in the magnetic drive device according to the present invention has a flat disk shape and a fixed plate 12 to which a fixed magnet 14 having one surface of the same magnetic pole is attached. A rotating magnet shaft 15a is formed between a rotating magnet core 15d and a rotating magnet 15, and a rotating magnet shaft 15a and 15b are connected to each other in a fan shape through a non-magnetic material 15c. The rotary magnet 15 is positioned below the fixed magnet 14.

  The fan-shaped rotating magnet 15 is formed by connecting a plurality of plate magnets composed of magnetic poles 15a and 15b having different polarities on the front and back sides to face each other with a non-magnetic material 15c in a fan shape. The magnets are not adjacent to each other by the nonmagnetic material 15c. The rotating magnet core 15d is equal to the center that appears when the rotating magnet 15 is connected in a circle.

  FIG. 23 shows that the rotating magnet 15 is at the lower position of the fixed magnet 14, and the rotating disk 13 rotates counterclockwise by setting the fixed magnet 14 and the rotating magnet 15 in this positional relationship. Can continue.

  FIG. 24 is a view showing a twenty-fourth embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention. As shown in FIG. 24, the magnet arrangement method 11b in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 and 11a.

  As shown in FIG. 24, the magnet arrangement method 11b in the magnetic drive device according to the present invention is a flat disk-shaped fixed plate 12 to which a fixed magnet 14 having one surface of the same magnetic pole is attached, and the front and back are different polarities. The rotating magnet 15 is composed of a plate-shaped magnet composed of magnetic poles 15a and 15b facing opposite poles and attached to both ends of a fan-shaped non-magnetic body 15c. The rotating magnet 15 is located on the lower side of the fixed magnet 14.

  The fan-shaped rotating magnet 15 has a shape in which plate magnets composed of magnetic poles 15a and 15b having different polarities on the front and back sides are attached to both ends of a substantially fan-shaped nonmagnetic material 15c so that the opposite polarities face each other. The rotating magnet core 15d is equal to the center appearing when the rotating magnet 15 is connected in a circle, and the radius connecting the outer peripheral surface of the rotating magnet 15 and the rotating magnet core 15d is smaller than the radius of the fixed magnet 14.

  FIG. 24 shows that the rotating magnet 15 is at a lower position of the fixed magnet 14, and the rotating disk 13 rotates counterclockwise by setting the fixed magnet 14 and the rotating magnet 15 in this positional relationship. Can continue.

  FIG. 25 is a view showing a twenty-fifth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 25, the magnet arrangement method 11c in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11b.

  As shown in FIG. 25, the magnet arrangement method 11c in the magnetic drive device according to the present invention includes a fixed disk 12 having a flat disk shape and a fixed magnet 14 having one surface having the same magnetic pole, A rotating magnet shaft 15a is formed between a rotating magnet core 15d and a rotating magnet 15, and a rotating magnet 15 is formed by attaching plate magnets made of magnetic poles 15a and 15b to both ends of a fan-shaped nonmagnetic material 15c with opposite poles facing each other. The rotary magnet 15 is positioned below the fixed magnet 14.

  The fan-shaped rotating magnet 15 has a shape in which plate magnets composed of magnetic poles 15a and 15b having different polarities on the front and back sides are attached to both ends of a substantially fan-shaped nonmagnetic material 15c so that the opposite polarities face each other. The rotating magnet core 15d is equal to the center that appears when the rotating magnet 15 is connected in a circle.

  FIG. 25 shows that the rotating magnet 15 is at the lower position of the fixed magnet 14, and the rotating disk 13 rotates counterclockwise by setting the fixed magnet 14 and the rotating magnet 15 in this positional relationship. Can continue.

  FIG. 26 is a diagram showing a twenty-sixth embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention. As shown in FIG. 26, the magnet arrangement method 11d in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11c.

  As shown in FIG. 26, the magnet arrangement method 11d in the magnetic drive device according to the present invention includes a fixed disk 12 having a flat disk shape and a fixed magnet 14 having one surface having the same magnetic pole, A rotating magnet 15 is formed between a rotating magnet core 15d and a rotating disk shaft 13a. The rotating magnet 15 is formed by attaching plate magnets made of magnetic poles 15a and 15b to opposite ends of a fan-shaped non-magnetic body 15c. The rotary magnet 15 is positioned below the fixed magnet 14.

  The fan-shaped rotating magnet 15 has a shape in which plate magnets composed of magnetic poles 15a and 15b having different polarities on the front and back sides are attached to both ends of a substantially fan-shaped nonmagnetic body 15c so that the opposite polarities face each other. The rotating magnet core 15d is equal to the center appearing when the rotating magnet 15 is connected in a circle, and the radius connecting the outer peripheral surface of the rotating magnet 15 and the rotating magnet core 15d is smaller than the radius of the fixed magnet 14.

  FIG. 26 shows that the rotating magnet 15 is at a lower position of the fixed magnet 14, and the rotating disk 13 rotates counterclockwise by setting the fixed magnet 14 and the rotating magnet 15 in this positional relationship. Can continue.

  FIG. 27 is a view showing a twenty-seventh embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention. As shown in FIG. 27, the magnet arrangement method 11e in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11d.

  As shown in FIG. 27, the magnet arrangement method 11e in the magnetic drive device according to the present invention includes a fixed disk 12 to which a fixed magnet 14 having a flat disk shape and one surface made of the same magnetic pole is attached, and a different polarity up and down. A rotating disk 13 having a rectangular parallelepiped-shaped rotating magnet 15 provided with a relationship so that the left side of the rotating magnet 15 overlaps the meridian of the rotating disk 13 and one corner of the rotating magnet 15 is positioned on the outer periphery of the rotating disk 13. The rotating magnet 15 is located below the fixed magnet 14.

  The rectangular parallelepiped rotating magnet 15 includes different magnetic poles 15 a and 15 b on the upper and lower sides. In the magnetic pole arrangement method 11 e, the rotating magnet 15 on the rotating disk 13 has an S pole on the upper side and is closest to the N pole of the fixed magnet 14. In position.

  FIG. 27 shows that the rotating magnet 15 is at the lower position of the fixed magnet 14, and the rotating disk 13 rotates clockwise by setting the fixed magnet 14 and the rotating magnet 15 in such a positional relationship. You can continue.

  FIG. 28 is a view showing a twenty-eighth embodiment of a magnet arrangement method in magnetic driving and a magnet arrangement state of the magnetic driving apparatus according to the present invention. As shown in FIG. 28, the magnet arrangement method 11f in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11e.

  As shown in FIG. 28, the magnet arrangement method 11f in the magnetic drive device according to the present invention includes a fixed disk 12 to which a fixed magnet 14 having a flat disk shape and one surface having the same magnetic pole is attached, and both ends on a plane. A rectangular parallelepiped rotating magnet 15 having magnetic poles 15a and 15b having different polarities is overlapped on the meridian of the rotating disk 13 so that the magnetic pole boundary at the center of the rotating magnet 15 overlaps the magnetic poles of the different polarities outside the rotating magnet 15. The rotating magnet 15 is positioned below the fixed magnet 14, and the rotating magnet 15 is positioned so that the corners on both sides are positioned on the outer periphery of the rotating disk 13.

  FIG. 28 shows that the rotating magnet 15 is at a lower position of the fixed magnet 14, and the rotating disk 13 rotates clockwise by setting the fixed magnet 14 and the rotating magnet 15 in such a positional relationship. You can continue.

  FIG. 29 is a view showing a twenty-ninth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 29, the magnet arrangement method 11g in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11f.

  As shown in FIG. 29, the magnet arrangement method 11g in the magnetic drive device according to the present invention has a flat disk shape and a fixed plate 12 to which a fixed magnet 14 having one surface of the same magnetic pole is attached, and the front and back are different polarities. The rotating magnet 15 having a plurality of plate-like magnets having the magnetic poles 15 a and 15 b facing each other and facing each other is arranged so that the center of the rotating magnet 15 overlaps the meridian of the rotating disk 13. The rotating magnet 15 is located on the lower side of the fixed magnet 14. The rotating magnet 15 is mounted so that the corners on both sides of the magnetic poles of different polarities are positioned on the outer periphery of the rotating disc 13.

  FIG. 29 shows that the rotating magnet 15 is at the lower position of the fixed magnet 14, and the rotating disk 13 rotates clockwise by setting the fixed magnet 14 and the rotating magnet 15 in this positional relationship. You can continue.

  FIG. 30 is a view showing a thirtieth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 30, the magnet arrangement method 11h in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11g.

  As shown in FIG. 30, the magnet arrangement method 11h in the magnetic drive device according to the present invention includes a fixed disk 12 with a fixed disk 14 having a flat disk shape and one surface having the same magnetic pole, and different polarities on both sides. The rotating magnet 15 having a horizontally long rectangular parallelepiped shape including the magnetic poles 15a and 15b is overlapped with the meridian of the rotating disk 13, and the rotating magnet 15 is positioned in one semicircle of the rotating disk 13. The rotating magnet 15 is positioned below the fixed magnet 14.

  FIG. 30 shows that the rotating magnet 15 is at a lower position of the fixed magnet 14, and the rotating disk 13 rotates clockwise by setting the fixed magnet 14 and the rotating magnet 15 in such a positional relationship. You can continue.

  FIG. 31 is a view showing a thirty-first embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 31, the magnet arrangement method 11i in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11h.

  As shown in FIG. 31, the magnet arrangement method 11 i in the magnetic drive device according to the present invention includes a fixed disk 12 to which a fixed magnet 14 having a flat disk shape and one surface made of the same magnetic pole is attached, and a different polarity up and down. The rotating magnet 15 having a relationship and having the left side as the inclined surface 15e is overlapped with the right side of the rotating magnet 15 close to the diameter of the rotating disk 13, and two angles of the inclined surface 15e of the rotating magnet 15 are on the outer peripheral surface of the rotating disk 13. The rotating magnet 15 is positioned below the fixed magnet 14.

  FIG. 31 shows that the rotating magnet 15 is at a lower position of the fixed magnet 14, and the rotating disk 13 rotates clockwise by setting the fixed magnet 14 and the rotating magnet 15 in such a positional relationship. You can continue.

  FIG. 32 is a view showing a thirty-second embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 32, the magnet arrangement method 11j in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11i.

  As shown in FIG. 32, the magnet arrangement method 11j in the magnetic drive device according to the present invention includes a fixed disk 12 to which a fixed magnet 14 having a flat disk shape and one surface made of the same magnetic pole is attached, and a different polarity up and down. The right side of the rotating magnet 15 is overlapped near the diameter of the rotating disk 13 and the acute angle forming the inclined surface 15e of the rotating magnet 15 is on the outer peripheral surface of the rotating disk 13. The rotating magnet 15 is positioned below the fixed magnet 14.

  FIG. 32 shows that the rotating magnet 15 is at the lower position of the fixed magnet 14, and the rotating disk 13 rotates clockwise by setting the fixed magnet 14 and the rotating magnet 15 in this positional relationship. You can continue.

  FIG. 33 is a diagram showing a thirty-third embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 33, the magnet arrangement method 11k in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11j.

  As shown in FIG. 33, the magnet arrangement method 11k in the magnetic drive device according to the present invention includes a fixed disk 12 to which a fixed magnet 14 having a flat disk shape and one surface having the same magnetic pole is attached, and both sides on a plane. A rotating magnet 15 having a semicircular shape having magnetic poles 15a and 15b having different polarities is overlapped on the diameter of the rotating disk 13, and the inner side of the rotating magnet 15 faces the rotating disk shaft 13a. The rotating magnet 15 is positioned below the fixed magnet 14.

  Further, the positions of the rotary magnet core 15d and the rotary disk shaft 13a are shifted so that the rotary magnet core 15d of the rotary magnet 15 is positioned between the rotary magnet 15 and the rotary disk shaft 13a.

  FIG. 33 shows that the rotating magnet 15 is at the lower position of the fixed magnet 14, and the rotating disk 13 rotates clockwise by setting the fixed magnet 14 and the rotating magnet 15 in this positional relationship. You can continue.

  FIG. 34 is a view showing a thirty-fourth embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 34, the magnet arrangement method 11l in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11k.

  As shown in FIG. 34, the magnet arrangement method 11l in the magnetic drive device according to the present invention includes a fixed disk 12 to which a fixed magnet 14 having a flat disk shape and one surface having the same magnetic pole is attached, and both sides on a plane. A rotating magnet 15 having a semicircular shape having magnetic poles 15a and 15b having different polarities is overlapped on the diameter of the rotating disk 13, and the inner side of the rotating magnet 15 faces the rotating disk shaft 13a. The rotating magnet 15 is positioned below the fixed magnet 14.

  Further, the positions of the rotary magnet core 15d and the rotary disk shaft 13a are shifted so that the rotary disk shaft 13a is positioned between the rotary magnet 15 and the rotary magnet core 15d.

  FIG. 34 shows that the rotating magnet 15 is at the lower position of the fixed magnet 14, and the rotating disk 13 rotates clockwise by setting the fixed magnet 14 and the rotating magnet 15 in this positional relationship. You can continue.

  FIG. 35 is a diagram showing a thirty-fifth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 35, the magnet arrangement method 11m in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11l.

  As shown in FIG. 35, the magnet arrangement method 11m in the magnetic drive device according to the present invention is different from the fixed plate 12 in which the fixed magnet 14 having a flat disk shape and one surface having the same magnetic pole is attached. A substantially U-shaped rotating magnet 15 provided with pole magnetic poles 15 a and 15 b is overlapped with the central portion of the rotating magnet 15 close to the rotating disk shaft 13 a, and both ends of the rotating magnet 15 face the circumference of the fixed magnet 9. The rotating magnet 15 is positioned below the fixed magnet 14.

  FIG. 35 shows that the rotating magnet 15 is at a lower position of the fixed magnet 14, and the rotating disk 13 rotates counterclockwise by setting the fixed magnet 14 and the rotating magnet 15 in this positional relationship. Can continue.

  FIG. 36 is a view showing a thirty-sixth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 36, the magnet arrangement method 11n in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11m.

  As shown in FIG. 36, the magnet arrangement method 11n in the magnetic drive device according to the present invention is the same shape and size as the fixed plate 12 to which the fixed magnet 14 having the same surface and the same magnetic pole is attached. An even number of circular magnets composed of magnetic poles 15a and 15b having different polarities on the front and back are arranged on the rotating disk 13 so that the same number of rotating magnets 10 are arranged on the left and right in an arc shape so as to become magnetic poles 15a and 15b of different polarities on the left and right. The rotating magnet 15 is located near the outer peripheral surface, and the rotating magnet 15 is positioned below the fixed magnet 14.

  FIG. 36 shows that the rotating magnet 15 is at a lower position of the fixed magnet 14, and the rotating disk 13 rotates clockwise by setting the fixed magnet 14 and the rotating magnet 15 in such a positional relationship. You can continue.

  FIG. 37 is a view showing a thirty-seventh embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. As shown in FIG. 37, the magnet arrangement method 11o in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11n.

  As shown in FIG. 37, the magnet arrangement method 11o in the magnetic drive device according to the present invention is different from the fixed plate 12 in which the fixed magnet 14 having the same surface and the same magnetic pole is attached to the fixed plate 12 in the up and down direction. A line connecting the both ends of the substantially semicircular rotary magnet 15 provided with is parallel to a meridian that is vertically lowered from the rotary disk shaft 13a, and is vertically lowered downward from the rotary disk shaft 13a. The rotating magnet 15 is located on the lower side of the fixed magnet 14, and the rotating magnet 15 is positioned on the lower side of the fixed magnet 14.

  FIG. 37 shows that the rotating magnet 15 is at the lower position of the fixed magnet 14, and the rotating disk 13 rotates clockwise by setting the fixed magnet 14 and the rotating magnet 15 in such a positional relationship. You can continue.

  FIG. 38 is a view showing a thirty-eighth embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 11p in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 11 to 11o.

  As shown in FIG. 38, the magnet arrangement method 11p in the magnetic drive device according to the present invention includes a stationary disk 12 having a flat disk shape and a stationary magnet 14 having the same surface and the same magnetic pole, and both ends on the plane. A horizontally-oriented rotating magnet 15 having different polar poles 15a, 15b is placed so that the center of the rotating magnet 15 overlaps the meridian of the rotating disk 13, and the different pole pole 15a outside the rotating magnet 15 is overlapped. , 15b and the rotating disk 13 mounted so that the corners on both sides are positioned on the outer periphery of the rotating disk 13, and the rotating magnet 15 is positioned below the fixed magnet 14.

  FIG. 38 shows that the rotating magnet 15 is at the lower position of the fixed magnet 14, and the rotating disk 13 rotates clockwise by setting the fixed magnet 14 and the rotating magnet 15 in such a positional relationship. You can continue.

  FIG. 39 is a view showing a 39th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIG. 39, the magnet arrangement method 16 in the magnetic drive device according to the present invention includes a fixed plate 17 to which a fixed magnet 19 having a disk shape and the same circumference and the same magnetic pole is attached, and a magnetic pole 20a having a different polarity. The boundary line of the magnetic poles 20a and 20b overlaps the extension of the meridian of the rotating disk 18, and the corners on both sides of the magnetic poles 20a and 20b with different polarities outside the rotating magnet 20 are rotated. The rotating disk 18 is mounted so as to be positioned on the outer periphery of the disk 18.

  The diameter of the rotating plate 18 is larger than the diameter of the fixed platen 17, and the diameter of the rotating plate 18 is larger than the diameter of the fixed magnet 19. Since the rotating magnet 20 mounted on the rotating plate 18 and the fixed magnet 19 mounted on the fixed plate 17 are located at the same height, the rotating magnet 20 rotates and moves outside the fixed magnet 19.

  The rotating magnet 20 includes magnetic poles 20a and 20b having different polarities on both sides. In FIGS. 39 to 48 showing the present invention, the rotating magnet 20 has a white magnetic pole as an S pole and a magnetic pole painted with diagonal lines. Although the N pole is used and the fixed magnet 19 is an N pole, there is no particular limitation. That is, the white magnetic pole of the rotating magnet 20 may be regarded as the N pole, the magnetic pole painted with diagonal lines as the S pole, and the fixed magnet 19 as the S pole.

  In FIG. 39, it is shown that the rotating magnet 20 is located outside the fixed magnet 19, and the rotating disk 18 rotates counterclockwise by setting the fixed magnet 19 and the rotating magnet 20 in this positional relationship. You can continue.

  FIG. 40 is a view showing a 40th embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 16 a in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement method 16.

  As shown in FIG. 40, the magnet arrangement method 16a in the magnetic drive device according to the present invention includes a fixed plate 17 to which a fixed magnet 19 having a disk shape and the same circumference and the same magnetic pole is attached, and a magnetic pole having opposite polarities. The center of the rotating magnet 20 formed by connecting a plurality of flat magnets 20a and 20b with the opposite poles facing each other overlaps the meridian of the rotating disk 18, and magnetic poles 20a and 20b having different poles outside the rotating magnet 20 are overlapped. The rotating disk 18 is attached so that the corners on both sides are located on the outer periphery of the rotating disk 18.

  The diameter of the rotating plate 18 is larger than the diameter of the fixed platen 17, and the diameter of the rotating plate 18 is larger than the diameter of the fixed magnet 19. Since the rotating magnet 20 mounted on the rotating plate 18 and the fixed magnet 19 mounted on the fixed plate 17 are located at the same height, the rotating magnet 20 rotates and moves outside the fixed magnet 19.

  FIG. 40 shows that the rotating magnet 20 is located outside the fixed magnet 19, and the rotating disk 18 rotates counterclockwise by setting the fixed magnet 19 and the rotating magnet 20 in this positional relationship. You can continue.

  FIG. 41 is a diagram showing a forty-first embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention. The magnet arrangement method 16b in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 16 and 16a.

  As shown in FIG. 41, in the magnetic drive device according to the present invention, the arrangement method 16b of magnets with different polarities is a fixed plate 17 to which a fixed magnet 19 having a disk shape and the same circumference is composed of the same magnetic pole, Is composed of a rotating disk 18 in which flat magnets composed of magnetic poles 20a and 20b having different polarities are attached to both ends of a fan-shaped non-magnetic body 20c with opposite polarities facing each other.

  The diameter of the rotating plate 18 is larger than the diameter of the fixed platen 17, and the diameter of the rotating plate 18 is larger than the diameter of the fixed magnet 19. Since the rotating magnet 20 mounted on the rotating plate 18 and the fixed magnet 19 mounted on the fixed plate 17 are located at the same height, the rotating magnet 20 rotates and moves outside the fixed magnet 19.

  FIG. 41 shows that the rotating magnet 20 is located outside the fixed magnet 19, and the rotating disk 18 rotates counterclockwise by setting the fixed magnet 19 and the rotating magnet 20 in such a positional relationship. You can continue.

  FIG. 42 is a diagram showing a forty-second embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 16c in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 16 to 16b.

  As shown in FIG. 42, the magnet arrangement method 16c in the magnetic drive device according to the present invention includes a fixed plate 17 to which a fixed magnet 19 having a disk shape and the same circumference and the same magnetic pole is attached, and a magnetic pole having different polarities on the front and back sides. A rectangular parallelepiped rotary magnet 20 composed of 20a and 20b is positioned so that the right side of the rotary magnet 20 overlaps the meridian of the rotary disk 18, and the surface of one magnetic pole of the rotary magnet 20 (for example, 20b) is the fixed magnet 19. It consists of a rotating disk 18 which is disposed and attached at a position facing an inclined surface toward the circumferential surface.

  The diameter of the rotating plate 18 is larger than the diameter of the fixed platen 17, and the diameter of the rotating plate 18 is larger than the diameter of the fixed magnet 19. Since the rotating magnet 20 mounted on the rotating plate 18 and the fixed magnet 19 mounted on the fixed plate 17 are located at the same height, the rotating magnet 20 rotates and moves outside the fixed magnet 19.

  FIG. 42 shows that the rotating magnet 20 is located outside the fixed magnet 19, and the rotating disk 18 rotates counterclockwise by setting the fixed magnet 19 and the rotating magnet 20 in this positional relationship. You can continue.

  FIG. 43 is a diagram showing a forty-third embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 16d in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 16 to 16c.

  As shown in FIG. 43, the magnet arrangement method 16d in the magnetic drive device according to the present invention includes a fixed plate 17 to which a fixed magnet 19 having a disk shape and the same circumference and the same magnetic pole is attached, and a magnetic pole having different polarities on the front and back sides. A plurality of rectangular parallelepiped magnets 20a and 20b facing each other with different poles connected to each other at equal intervals through a non-magnetic member 20c to form a fan-shaped rotating magnet 20, and the core of the rotating magnet 20 is a fixed plate shaft It consists of the turntable 18 attached so that it may become the same position as 18a.

  The diameter of the rotating plate 18 is larger than the diameter of the fixed platen 17, and the diameter of the rotating plate 18 is larger than the diameter of the fixed magnet 19. Since the rotating magnet 20 mounted on the rotating plate 18 and the fixed magnet 19 mounted on the fixed plate 17 are located at the same height, the rotating magnet 20 rotates and moves outside the fixed magnet 19.

  FIG. 43 shows that the rotating magnet 20 is at a position outside the fixed magnet 19, and the rotating disk 18 rotates counterclockwise by setting the fixed magnet 19 and the rotating magnet 20 in this positional relationship. You can continue.

  FIG. 44 is a view showing a forty-fourth embodiment of a magnet arrangement method in a magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention. The magnet arrangement method 16e in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 16 to 16d.

  As shown in FIG. 44, the magnet arrangement method 16e in the magnetic drive device according to the present invention includes a fixed plate 17 to which a fixed magnet 19 having a disk shape and the same circumference and the same magnetic pole is attached, and magnetic poles having opposite polarities on both sides. A rotating disk 18 in which an arcuate rotating magnet 20 having 20a and 20b is mounted so that the boundary line between the magnetic poles 20a and 20b is located on the meridian of the rotating disk 18 and the inner side of the rotating magnet 20 faces the rotating disk shaft 18a. It consists of.

  The diameter of the rotating plate 18 is larger than the diameter of the fixed platen 17, and the diameter of the rotating plate 18 is larger than the diameter of the fixed magnet 19. Since the rotating magnet 20 mounted on the rotating plate 18 and the fixed magnet 19 mounted on the fixed plate 17 are located at the same height, the rotating magnet 20 rotates and moves outside the fixed magnet 19.

  FIG. 44 shows that the rotating magnet 20 is located outside the fixed magnet 19, and the rotating disk 18 rotates counterclockwise by setting the fixed magnet 19 and the rotating magnet 20 in this positional relationship. You can continue.

  FIG. 45 is a diagram showing a 45th embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 16f in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 16 to 16e.

  As shown in FIG. 45, the magnet arrangement method 16f in the magnetic drive apparatus according to the present invention includes a fixed plate 17 to which a fixed magnet 19 having a disk shape and the same circumference and the same magnetic pole is attached, and a magnetic pole having opposite polarities. The poles 20a and 20b of the plate-shaped magnet 20e made of 20a and 20b are arranged at equal intervals with the opposite poles facing each other so that the boundary lines of the magnetic poles 20a and 20b are located on the meridian of the rotating disk 18. In order to prevent the different poles from being in direct contact with each other, a non-magnetic body 20c is provided between the respective different poles, and a rotating disk 18 having a circular rotating magnet 20 attached thereto is attached.

  The diameter of the rotating plate 18 is larger than the diameter of the fixed platen 17, and the diameter of the rotating plate 18 is larger than the diameter of the fixed magnet 19. Since the rotating magnet 20 mounted on the rotating plate 18 and the fixed magnet 19 mounted on the fixed plate 17 are located at the same height, the rotating magnet 20 rotates and moves outside the fixed magnet 19.

  45 shows that the rotating magnet 20 is located outside the fixed magnet 19, and the rotating disk 18 rotates counterclockwise when the fixed magnet 19 and the rotating magnet 20 are in such a positional relationship. You can continue.

  FIG. 46 is a view showing a magnet placement method in a magnetic drive and a 46th embodiment of a magnet placement state of the magnetic drive device according to the present invention. The magnet arrangement method 16g in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 16 to 16f.

  As shown in FIG. 46, the magnet arrangement method 16g in the magnetic drive device according to the present invention includes a fixed disk 17 to which a fixed magnet 19 having the same circumference and the same magnetic pole is attached, and the front and back surfaces are different from each other. The flat magnets 20a and 20b are arranged at equal intervals with the opposite poles facing each other so that the boundary lines of the magnetic poles 20a and 20b of the flat magnet 20e are located on the meridian of the rotating disk 18. Rotation with a rotating magnet 20 attached with a non-magnetic material 20c connected to each other with a non-magnetic material 20c in a circular shape so that the different polarities of 20e are not in direct contact with each other, and at least one of the circular shapes being more widely spaced. It consists of a board 18.

  The arrangement method of the rotating magnet 20 used in the magnet arrangement method 16g is substantially the same as the arrangement method of the rotating magnet 20 arranged in the magnet arrangement method 16f. That is, in a state in which the rotating magnets 20 are arranged at equal intervals with the different polarities of the flat magnets 20e facing each other, at least one of the flat magnets 20e is removed at least one of them, and the one nonmagnetic The body 20d is made wider than the width of the other nonmagnetic body 20c.

  The diameter of the rotating plate 18 is larger than the diameter of the fixed platen 17, and the diameter of the rotating plate 18 is larger than the diameter of the fixed magnet 19. Since the rotating magnet 20 mounted on the rotating plate 18 and the fixed magnet 19 mounted on the fixed plate 17 are located at the same height, the rotating magnet 20 rotates and moves outside the fixed magnet 19.

  46 shows that the rotating magnet 20 is located outside the fixed magnet 19, and the rotating disk 18 rotates counterclockwise when the fixed magnet 19 and the rotating magnet 20 are in such a positional relationship. You can continue.

  FIG. 47 is a view showing a 47th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 16h in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 16 to 16g.

  As shown in FIG. 47, the magnet arrangement method 16h in the magnetic drive device according to the present invention includes a fixed plate 17 to which a fixed magnet 19 having a disk shape and the same circumference and the same magnetic pole is attached; The inside of the rotating magnet 20 arranged in a circular shape at equal intervals so that the different poles face each other so that the boundary line of the magnetic poles 20a, 20b of the flat magnet 20e composed of 20a, 20b is located on the meridian of the rotating disk 18 Has a configuration in which the flat magnets 20e are in contact with different poles, and the outer side of the rotating magnet 20 is formed in a circular shape by connecting each other with a non-magnetic material 20c, and at least one of the circular shapes is wider. It consists of a rotating disk 18 to which a rotating magnet 20 provided continuously with a nonmagnetic material 20d at an interval is attached.

  The arrangement method of the rotating magnet 20 used in the magnet arrangement method 16h is that a plurality of flat magnets 20e are arranged in a circular shape at equal intervals, and at least one of the magnets 20e is arranged at at least one of them. The nonmagnetic body 20d at one location is made wider than the width of the other nonmagnetic body 20c. At this time, the inside of the rotating magnet 20 is in a state where the magnetic poles 20a and 20b are in contact with each other except the place through the non-magnetic body 20d.

  The diameter of the rotating plate 18 is larger than the diameter of the fixed platen 17, and the diameter of the rotating plate 18 is larger than the diameter of the fixed magnet 19. Since the rotating magnet 20 mounted on the rotating plate 18 and the fixed magnet 19 mounted on the fixed plate 17 are located at the same height, the rotating magnet 20 rotates and moves outside the fixed magnet 19.

  47 shows that the rotating magnet 20 is at a position outside the fixed magnet 19, and the rotating disk 18 continues to rotate clockwise by setting the fixed magnet 19 and the rotating magnet 20 in this positional relationship. be able to.

  FIG. 48 is a view showing a 48th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 16i in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 16 to 16h.

  As shown in FIG. 48, the magnet arrangement method 16i in the magnetic drive device according to the present invention includes a fixed plate 17 to which a fixed magnet 19 having a disk shape and the same circumference and the same magnetic pole is attached, and a magnetic pole having opposite polarities. Several flat magnets 20e composed of 20a and 20b are circularly arranged on the rotating disk 18 at positions where different polarities face each other with a considerable gap therebetween, and a nonmagnetic property is provided between the flat magnets 20e. The rotating disk 18 is provided with a rotating magnet 20 provided continuously with a body 20c.

  The diameter of the rotating plate 18 is larger than the diameter of the fixed platen 17, and the diameter of the rotating plate 18 is larger than the diameter of the fixed magnet 19. Since the rotating magnet 20 mounted on the rotating plate 18 and the fixed magnet 19 mounted on the fixed plate 17 are located at the same height, the rotating magnet 20 rotates and moves outside the fixed magnet 19.

  FIG. 48 shows that the rotating magnet 20 is located outside the fixed magnet 19, and the rotating disk 18 rotates counterclockwise by setting the fixed magnet 19 and the rotating magnet 20 in this positional relationship. You can continue.

  FIG. 49 is a diagram showing a 49th embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention.

  As shown in FIG. 49, the magnet arrangement method 21 in the magnetic drive device according to the present invention includes a fixed plate 22 having a fixed magnet 24 having one surface made of the same magnetic pole near the outer peripheral surface, and magnetic poles having opposite polarities. The magnetic poles 25a and 25b of the flat plate-shaped magnet 25d made of 25a and 25b are arranged at a position where the boundary line has an angle of about 90 ° with respect to the meridian of the rotating disk 23. It is composed of a rotating disk 23 on which rotating magnets 25 arranged in a circular shape at equal intervals are arranged, and one magnetic pole of the fixed magnet 24 and the rotating magnet 25 are located at the same height. Reference numeral 23a denotes a rotating disk shaft.

  49 to 51 showing the present invention, the fixed magnet 24 has a white magnetic pole as the S pole and the shaded magnetic pole as the N pole in FIGS. 49 to 51 showing the present invention. Although 24 is assumed to be an N pole, there is no particular limitation. In other words, the white magnetic pole of the rotating magnet 25 may be regarded as the N pole, the magnetic pole painted with diagonal lines as the S pole, and the fixed magnet 24 as the S pole.

  In FIG. 49, the diameter of the rotating plate 23 is smaller than the diameter of the fixed platen 22, and the rotating magnet 25 attached on the rotating plate 23 rotates inside the fixed magnet 24 attached on the fixed platen 22. It is made. By disposing the fixed magnet 24 and the rotating magnet 25 in such a positional relationship, the rotating disk 23 can continue to rotate counterclockwise.

  FIG. 50 is a view showing a fiftyth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 21 a in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement method 21.

  As shown in FIG. 50, the magnet arrangement method 21a in the magnetic drive device according to the present invention includes a stationary platen 22 having a fixed magnet 24 having one surface made of the same magnetic pole near the outer peripheral surface, and magnetic poles having different polarities on the front and back sides. The magnetic poles 25a and 25b of a flat plate-shaped magnet 25d made of 25a and 25b have a plurality of magnets 25d at opposite ends at positions where the boundary line of the magnetic poles 25a and 25b has an angle of about 90 ° with respect to the meridian of the turntable 23. It consists of a rotating disk 23 on which rotating magnets 25 are arranged in a circular shape at equal intervals. The diameter of the fixed plate 22 is smaller than the rotary plate 23 and is located in the rotary plate 23.

  In FIG. 50, the diameter of the rotating plate 23 is larger than the diameter of the fixed platen 22, and the rotating magnet 25 attached on the rotating plate 23 is outside the one magnetic pole of the fixed magnet 24 attached on the fixed platen 22. Is made to rotate. By disposing the fixed magnet 24 and the rotating magnet 25 in such a positional relationship, the rotating disk 23 can continue to rotate counterclockwise.

  FIG. 51 is a diagram showing a 51st embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention. The magnet arrangement method 21b in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 21 and 21a.

  As shown in FIG. 51, the magnet arrangement method 21b in the magnetic drive device according to the present invention includes a fixed plate 22 having a disk-shaped fixed magnet 24 having the same circumference and the same magnetic pole, and magnetic poles having different polarities on the front and back sides. The magnetic poles 25a and 25b of the flat magnet 25d composed of 25a and 25b have a plurality of magnets 25d at opposite ends at positions where the boundary line of the magnetic poles 25a and 25b has an angle of about 90 ° with respect to the meridian of the rotating disk 23. It consists of a rotating disk 23 on which rotating magnets 25 are arranged in a circular shape at equal intervals. The diameter of the fixed plate 22 is smaller than the rotary plate 23 and is located in the rotary plate 23.

  In FIG. 51, the diameter of the rotating plate 23 is larger than the diameter of the fixed plate 22, and the rotating magnet 25 attached on the rotating plate 23 is outside the one magnetic pole of the fixed magnet 24 attached on the fixed plate 22. Is made to rotate. By disposing the fixed magnet 24 and the rotating magnet 25 in such a positional relationship, the rotating disk 23 can continue to rotate counterclockwise.

  FIG. 52 is a view showing a 52nd embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIG. 52, the magnet placement method 26 in the magnetic drive according to the present invention has a substantially elliptical shape in which two substantially crescent-shaped fixed magnets 29 and 29a are joined face to face and the same circumference is composed of the same magnetic poles. From the fixed plate 27 attached, and the rotary plate 28 in which a rectangular parallelepiped rotary magnet 30 having magnetic poles 30a, 30b of different polarity is attached near the outer periphery at a position where the boundary line of the different polarity overlaps the meridian of the rotary plate 28. Thus, the fixed plate 27 is located in the rotary plate 28.

  The fixed magnet core 29c that appears when the fixed magnet 29 is circular is located on the back side of the fixed magnet 29a and near the outer peripheral surface of the fixed platen 27, and the fixed magnet core 29b of the fixed magnet 29a is fixed. It is located on the back side of the magnet 29 and near the outer peripheral surface of the fixed platen 27.

  The fixed magnets 29 and 29a are provided with magnetic poles different from each other on the upper and lower sides. For the rotating magnet 30, the white magnetic pole 30a is the S pole, the magnetic pole 30b painted with diagonal lines is the N pole, and the fixed magnets 29 and 29a are N. Although it was a pole, there is no particular limitation. That is, the white magnetic pole 30a of the rotating magnet 30 may be regarded as the N pole, the magnetic pole 30b painted with diagonal lines as the S pole, and the fixed magnets 29 and 29a as the S pole.

  In FIG. 52, the diameter of the rotating plate 28 is larger than the diameter of the fixed plate 27, and the rotating magnet 30 attached on the rotating plate 28 is outside the one magnetic pole of the fixed magnet 29 attached on the fixed plate 27. Is made to rotate. By disposing the fixed magnet 29 and the rotating magnet 30 in such a positional relationship, the rotating disk 28 can continue to rotate counterclockwise.

  FIG. 53 is a view showing a 53rd embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 26 a in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement method 26.

  As shown in FIG. 53, in the magnet arrangement method 26a in the magnetic drive according to the present invention, the center of the line connecting both ends of the substantially crescent shaped fixed magnet 29d having the same circumference and the same magnetic pole is the center of the fixed platen 27. A fixed plate 27 having a fixed magnet 29d and a rectangular parallelepiped rotary magnet 30 having different poles 30a and 30b are attached near the outer periphery at a position where the boundary of the different poles overlaps the meridian of the rotary plate 28. The fixed plate 27 is located in the rotary plate 28.

  The fixed magnet 29d has magnetic poles that are different from each other in the vertical direction. For the rotating magnet 30, the white magnetic pole 30a is an S pole, the shaded magnetic pole 30b is an N pole, and the fixed magnet 29d is an N pole. There is no particular limitation. That is, the white magnetic pole 30a of the rotating magnet 30 may be regarded as the N pole, the magnetic pole 30b painted with diagonal lines as the S pole, and the fixed magnet 29d as the S pole.

  In FIG. 53, the diameter of the rotary plate 28 is larger than the diameter of the fixed plate 27, and the rotary magnet 30 mounted on the rotary plate 28 is outside the one pole of the fixed magnet 29 d mounted on the fixed plate 27. Is made to rotate. By arranging the fixed magnet 29d and the rotating magnet 30 in such a positional relationship, the rotating disk 28 can continue to rotate counterclockwise.

  FIG. 54 is a diagram showing a 54th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 26b in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 26 and 26a.

  As shown in FIG. 54, the magnet arrangement method in the magnetic drive according to the present invention and the magnet arrangement state 26b of the magnetic drive device are obtained by aligning the apexes of the curved portions with two substantially crescent-shaped fixed magnets 29f and 29g. A fixed plate 27 that is joined and attached in a substantially X shape with the same circumference and the same magnetic pole, and a rectangular parallelepiped rotary magnet 30 having magnetic poles 30a and 30b of different polarities, the boundary line of different polarities is on the meridian of the rotary disc 28. The fixed platen 27 is located in the rotary plate 28. The rotary plate 28 is mounted near the outer periphery at a position overlapping with the rotary plate 28.

  The fixed magnet core 29h that appears when the fixed magnet 29f is circular is located near the outer peripheral surface of the fixed platen 27, and the fixed magnet core 29i of the fixed magnet 29g is also close to the outer peripheral surface of the fixed platen 27. positioned.

  The fixed magnets 29f and 29g are provided with magnetic poles different from each other on the upper and lower sides. For the rotating magnet 30, the white magnetic pole 30a is the S pole, the magnetic pole 30b painted with diagonal lines is the N pole, and the fixed magnets 29f and 29g are N. Although it was a pole, there is no particular limitation. That is, when the white magnetic pole 30a of the rotating magnet 30 is an N pole and the magnetic pole 30b painted with diagonal lines is an S pole, the fixed magnets 29f and 29g may be viewed as an S pole.

  In FIG. 54, the diameter of the rotating plate 28 is larger than the diameter of the fixed plate 27, and the rotating magnet 30 mounted on the rotating plate 28 is one of the magnetic poles of the fixed magnets 29f and 29g mounted on the fixed plate 27. It is made to rotate outside. By disposing the fixed magnets 29f and 29g and the rotating magnet 30 in such a positional relationship, the rotating disk 28 can continue to rotate counterclockwise.

  FIG. 55 is a view showing a 55th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIG. 55, the magnet arrangement method 31 in the magnetic drive according to the present invention has a rectangular parallelepiped fixed magnet 34 provided with magnetic poles 34a and 34b of different polarities, and the boundary line of different polarities is on the meridian of the rotating disk 28. A fixed plate 32 attached near the outer periphery at a position overlapping with the rotary plate 33 and two rotary magnets 35, 35a having a substantially crescent shape and facing each other, and attached to a substantially elliptical shape having the same circumference composed of the same magnetic poles. Become.

  The rotating magnet core 35c that appears when the rotating magnet 35 is circular is located on the back side of the rotating magnet 35a and near the outer peripheral surface of the rotating disk 33, and the rotating magnet core 35b of the rotating magnet 35a is rotated. It is located on the back side of the magnet 35 a and near the outer peripheral surface of the rotating disk 33.

  The rotating magnets 35 and 35a are provided with magnetic poles that are different from each other on the upper and lower sides. For the fixed magnet 34, the white magnetic pole 34a is an S pole, the magnetic pole 34b painted with diagonal lines is an N pole, and the rotating magnets 35 and 35a are N. Although it was a pole, there is no particular limitation. That is, the white magnetic pole 34a of the fixed magnet 34 may be regarded as the N pole, the magnetic pole 34b painted with diagonal lines as the S pole, and the rotating magnets 35 and 35a as the S pole.

  In FIG. 55, the diameter of the rotating plate 33 is smaller than the diameter of the fixed plate 32, and one of the magnetic poles of the rotating magnets 35 and 35 a mounted on the rotating plate 33 is the same height as the fixed magnet 34 on the fixed plate 32. It is made to rotate the inside of the fixed magnet 34 at the position. By disposing the fixed magnet 34 and the rotating magnets 35 and 35a in such a positional relationship, the rotating disk 33 can continue to rotate clockwise.

  FIG. 56 is a view showing a fifty-sixth embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 31 a in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement method 31.

  As shown in FIG. 56, in the magnet arrangement method 31a in the magnetic drive according to the present invention, the center of the line connecting the ends of the substantially crescent-shaped rotating magnet 35d having the same circumference and the same magnetic pole is the center of the rotating disk 33. A rotating plate 33 provided with a rotating magnet 35d and a rectangular parallelepiped fixed magnet 34 provided with magnetic poles 34a and 34b having different polarities so as to overlap with each other are arranged at the outer periphery at a position where the boundary line of the different polarity overlaps the meridian of the rotating plate 33. The rotating plate 33 is located in the fixed platen 32.

  The rotating magnet 35d has magnetic poles that are different from each other in the vertical direction. For the fixed magnet 34, the white magnetic pole 34a is an S pole, the shaded magnetic pole 34b is an N pole, and the rotating magnet 35d is an N pole. There is no particular limitation. That is, the white magnetic pole 34a of the fixed magnet 34 may be regarded as the N pole, the magnetic pole 34b painted with diagonal lines as the S pole, and the rotating magnet 35d as the S pole.

  In FIG. 56, the diameter of the rotating plate 33 is smaller than the diameter of the fixed plate 32, and one magnetic pole of the rotating magnet 35 d attached on the rotating plate 33 is positioned at the same height as the fixed magnet 34 on the fixed plate 32. Thus, it is made to rotate inside the fixed magnet 34. By disposing the fixed magnet 34 and the rotating magnet 35d in such a positional relationship, the rotating disk 33 can continue to rotate clockwise.

  FIG. 57 is a view showing a 57th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention. The magnet arrangement method 31b in the magnetic drive device according to the present invention is substantially the same as the magnet arrangement methods 31 and 31a.

  As shown in FIG. 57, the magnet arrangement method 31b in the magnetic drive according to the present invention is made by joining two substantially crescent-shaped rotating magnets 35f and 35g with the vertices of the curved portions aligned to each other, and the same periphery is composed of the same magnetic pole. A rotating plate 33 attached in a substantially X shape and a rectangular parallelepiped fixed magnet 34 having magnetic poles 34a and 34b of different polarities are attached near the outer periphery at a position where the boundary line of the different polarities overlaps the meridian of the rotating disc 33. The rotary plate 33 is located in the fixed plate 32.

  The rotating magnet core 35h that appears when the rotating magnet 35f is circular is located near the outer peripheral surface of the rotating disk 33, and the rotating magnet core 35i of the rotating magnet 35g is also close to the outer peripheral surface of the rotating disk 33. positioned.

  The rotating magnets 35f and 35g are provided with magnetic poles that are different from each other on the upper and lower sides. For the fixed magnet 34, the white magnetic pole 34a is the S pole, the magnetic pole 34b painted with diagonal lines is the N pole, and the rotating magnets 35f and 35g are N. Although it was a pole, there is no particular limitation. That is, the white magnetic pole 34a of the fixed magnet 34 may be regarded as the N pole, the magnetic pole 34b painted with diagonal lines as the S pole, and the rotating magnets 35f and 35g as the S pole.

  In FIG. 57, the diameter of the rotating plate 33 is smaller than the diameter of the fixed plate 32, and one of the magnetic poles of the rotating magnets 35 f and 35 g attached on the rotating plate 33 is the same height as the fixed magnet 34 on the fixed plate 32. It is made to rotate the inside of the fixed magnet 34 at the position. By disposing the fixed magnet 34 and the rotating magnet 35 in such a positional relationship, the rotating disk 33 can continue to rotate clockwise.

  FIG. 58 is a view showing a 58th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIG. 58, the magnet arrangement method 36 in the magnetic drive according to the present invention is a substantially donut in which the same circumference is formed of the same magnetic pole with the four sides rounded outward and the inside formed a substantially circular hole. A fixed plate 37 having a fixed magnet 39 and a rectangular parallelepiped rotary magnet 40 having magnetic poles 40a and 40b of different polarities are mounted near the outer periphery at a position where the boundary line of the different polarities overlaps the meridian of the rotary disc 38. The fixed plate 37 is located inside the rotary plate 38.

  The fixed magnet cores 39a appearing when the sides of each of the rounded sides of the fixed magnet 39 are circular are present in the fixed magnet 39, and all the fixed magnet cores 39a are the same from the rotating disk shaft 38a. A distance away.

  The fixed magnet 39 has the same circumference and the same magnetic pole and has different magnetic poles in the upper and lower sides. For the rotating magnet 40, the white magnetic pole 40a is the S pole, and the magnetic pole 40b painted with diagonal lines is the N pole. Although it was set as N pole about, it does not specifically limit. That is, the white magnetic pole 40a of the rotating magnet 40 may be regarded as an N pole, the magnetic pole 40b painted with diagonal lines as an S pole, and the fixed magnet 39 as an S pole.

  In FIG. 58, the diameter of the rotating plate 38 is larger than the diameter of the fixed plate 37, and the rotating magnet 40 mounted on the rotating plate 38 is positioned at the same height as one of the magnetic poles of the fixed magnet 39 on the fixed plate 37. Thus, the outer side of the fixed magnet 39 is rotated. By disposing the fixed magnet 39 and the rotating magnet 40 in such a positional relationship, the rotating disk 38 can continue to rotate counterclockwise.

  FIG. 59 is a view showing a 59th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIG. 59, the magnet arrangement method 41 in the magnetic drive according to the present invention has a rectangular parallelepiped fixed magnet 44 having magnetic poles 44a and 44b of different polarities, and the boundary line of different polarities is on the meridian of the rotating disk 43. And a stationary platen 42 attached near the outer periphery in a position overlapping with the outer periphery, and a substantially donut-shaped rotating magnet 45 having four sides that are rounded outward and a substantially circular hole inside, and the same circumference comprising the same magnetic pole. The rotary plate 43 is located inside the fixed plate 42.

  The rotating magnet cores 45a appearing when the sides of the rotating magnet 45 are rounded are present in the rotating magnet 45, and all the rotating magnet cores 45a are the same from the rotating disk shaft 43a. A distance away.

  The rotating magnet 45 has the same circumference and the same magnetic pole and has different magnetic poles. The fixed magnet 44 has the white magnetic pole 44a as the S pole, and the shaded magnetic pole 44b as the N pole. Although it was set as N pole about, it does not specifically limit. That is, the white magnetic pole 44a of the fixed magnet 44 may be regarded as the N pole, the magnetic pole 44b painted with diagonal lines as the S pole, and the rotating magnet 45 as the S pole.

  In FIG. 59, the diameter of the rotating plate 43 is smaller than the diameter of the fixed platen 42, and one magnetic pole of the rotating magnet 45 mounted on the rotating plate 43 is positioned at the same height as the fixed magnet 44 on the fixed platen 42. Thus, the inner side of the fixed magnet 44 is made to rotate. By disposing the fixed magnet 44 and the rotating magnet 45 in such a positional relationship, the rotating disk 43 can continue to rotate clockwise.

  FIG. 60 is a diagram showing a 60th embodiment of a magnet arrangement method in magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention.

  As shown in FIG. 60, the magnet arrangement method 59 in the magnetic drive device according to the present invention includes a stationary platen 60 to which a stationary magnet 62 having one surface made of the same magnetic pole is attached, and magnetic poles 63a and 63b whose front and back are different polarities. Are arranged at equal intervals so that the boundary lines of the magnetic poles 63a and 63b of the plate-shaped magnet 63d are located on the meridian of the turntable 61, and the non-magnetic material 63c is provided between each 63. It is composed of a rotating disk 61 which is continuously arranged and configured in a circular shape.

  The diameter of the rotating plate 61 is smaller than the diameter of the fixed platen 60, and the rotating magnet 63 attached on the rotating plate 61 and the fixed magnet 62 attached on the fixed platen 60 are located at the same height, so the rotating magnet 63 will rotate inside the fixed magnet 62.

  In FIG. 60, the rotating magnet 63 represents that it is inside the fixed magnet 62, and the rotating disk 61 can continue to rotate clockwise by making the positional relationship between the fixed magnet 62 and the rotating magnet 63. it can.

    61, 62, and 63 are diagrams showing a magnet arrangement method and a magnetic driving device of the magnetic driving device according to the present invention.

  As shown in FIG. 61, the magnetic drive device 46 according to the present invention includes a rotating disk 48 in which a rotating magnet 50 is vertically suspended and a rotating disk shaft 48a is attached to the center of the lower surface via a joint 48b, and is fixed to the upper surface. The magnet 49 is attached to the center of the upper surface and includes a stationary platen 47 having a bearing 47a for rotatably connecting the rotary plate shaft 48a.

  As shown in FIG. 62, the magnetic drive device 46a according to the present invention includes a rotating disk 52 in which a rotating magnet 54 is vertically suspended and a rotating disk shaft 52a is attached to the center of the lower surface via a joint 52b. And a fixed platen 51 having a bearing 51a for rotatably connecting the rotary plate shaft 52a to the center of the upper surface.

  As shown in FIG. 63, the magnetic drive unit 46b according to the present invention includes a rotating disk 56 in which a rotating magnet 58 is suspended on the lower surface and a rotating disk shaft 56a is attached to the center of the lower surface via a joint 56b, and a disk is mounted on the upper surface. And a fixed plate 55 having a bearing 55a for rotatably connecting the rotary plate shaft 56a to the center of the upper surface.

  The magnetic drive units 46, 46a and 46b shown in FIGS. 61 to 63 show basic magnetic drive units for carrying out the magnet arrangement method according to the present invention. When implementing the arrangement method of each magnet, it will adjust according to the conditions which each Example defines.

  When implementing the magnet arrangement method of the first to fifth embodiments, the magnetic drive unit 46 of FIG. 61 is used. In the magnet arrangement methods of Examples 1 to 5, since it is a condition that one of the magnetic poles of the rotating magnet and the fixed magnet is at the same height, the length of the rotating disk shaft 48a is shortened, and the fixed magnet 49 The magnetic pole 49a on the upper side and the magnet 50b on the lower side of the rotating magnet 50 attached to the rotating disk 48 are adjusted to a close position at the same height.

  In the case of Examples 1 to 5, since the rotating magnet 50 is provided with different magnetic poles on the left and right of the plane, the magnetic poles 50a and 50b of the rotating magnet 50 have different polarities up and down. Use a combination of the ends of the different poles, or ones with left and right poles different from each other.

  When implementing the magnet arrangement method of the sixth to twenty-first embodiments, the magnetic drive device 46a of FIG. 62 is used. In the magnet arrangement methods of Examples 6 to 21, it is a condition that one magnetic pole 53a of the rotating magnet and the fixed magnet is at the same height, and the rotating magnet rotates in the fixed magnet. The rotary disk shaft 52a is adjusted so as to rotate within the fixed magnet 53. It should be noted that the magnetic pole 53b and the rotating magnet 54 do not have the same height.

  In FIG. 62, the magnetic poles 54a and 54b of the rotating magnet 54 are positioned up and down. However, in Examples 6 to 21, rotating magnets of various shapes are used. Replace with a magnet.

  When implementing the magnet arrangement method of Examples 22 to 38, the magnetic drive unit 46b of FIG. 63 is used. In the magnet arrangement methods of Examples 22 to 38, the fixed magnet is disk-shaped, the rotating magnet and the fixed magnet are in a vertical positional relationship, and the rotating magnet rotates within the circumference of the fixed magnet. Therefore, the mounting position of the rotating magnet 58 is changed to the inside, and the disk-shaped fixed magnet 57 mounted on the fixed plate 55 is adjusted to rotate within the circumference. The magnets of Examples 22 to 38 are arranged such that the rotating magnet is located below the fixed magnet, but the upper and lower positional relationship is such that the rotating magnet is located above the fixed magnet. May be.

  In FIG. 63, the magnetic poles 58a and 58b of the rotating magnet 58 are positioned up and down. However, in Examples 22 to 38, rotating magnets of various shapes are used. Replace with a magnet.

  When implementing the magnet arrangement method of Examples 39 to 48, the magnetic drive unit 46b of FIG. 63 is used. In the magnet arrangement methods of Examples 39 to 48, one of the magnetic poles of the disk-shaped fixed magnet and the rotating magnet are at the same height, and the rotating magnet rotates on the outside of the fixed magnet. The rotary disk shaft 56a is adjusted so that 58b and the magnetic pole 57a have the same height.

  In FIG. 63, the magnetic poles 58a and 58b of the rotary magnet 58 are positioned up and down. However, in Examples 39 to 48, since the rotary magnets of various shapes are used, the rotary magnet 58 rotates in accordance with each. Replace with a magnet.

  When implementing the magnet arrangement method of the embodiment 49, the magnetic drive unit 46 of FIG. 61 is used. In the magnet arrangement method of Example 49, one magnetic pole of the fixed magnet and the rotating magnet are at the same height, and the rotating magnet rotates inside the fixed magnet. Therefore, the rotating magnet 50 is attached inside. The fixed magnet 49 is attached near the outer periphery of the fixed platen 47.

  In FIG. 61, the magnetic poles 50a and 50b of the rotating magnet 50 are positioned up and down. However, in Example 49, rotating magnets having different magnetic poles on the left and right on the plane are used. Replace with a suitable rotating magnet.

  When implementing the magnet arrangement method of the embodiments 50 and 51, the magnetic drive device 46b of FIG. 63 is used. In the magnet arrangement methods of Examples 50 and 51, one of the magnetic poles of the fixed magnet and the rotating magnet are at the same height, and the rotating magnet rotates on the outside of the fixed magnet. Therefore, the rotating magnet 58 is fixed. The rotary disk shaft 56a is adjusted so as to rotate outside the magnetic pole 57a of the magnet 57.

  63, the magnetic poles 58a and 58b of the rotating magnet 58 are positioned up and down. However, in Examples 50 and 51, rotating magnets having different magnetic poles on the left and right on the plane are used. 58 is replaced with a rotating magnet suitable for it.

  When implementing the magnet arrangement method of the embodiments 52 to 54, the magnetic driving device 46 of FIG. 61 is used. In the magnet arrangement methods of Examples 52 to 54, since one of the magnetic poles of the fixed magnet and the rotating magnet are at the same height and the rotating magnet rotates outside the fixed magnet, the rotating magnet 50 is fixed. The rotary disk shaft 48a is adjusted to rotate outside the magnetic pole 49a of the magnet 49.

  In FIG. 61, the magnetic poles 50a and 50b of the rotating magnet 50 are positioned up and down. However, in Examples 52 to 54, rotating magnets having different magnetic poles on the left and right on the plane are used. 50 is replaced with a rotating magnet suitable for it.

  When implementing the magnet arrangement method of Examples 55 to 57, the magnetic drive unit 46 of FIG. 61 is used. In the magnet arrangement methods of Examples 55 to 57, one of the magnetic poles of the rotating magnet and the fixed magnet are at the same height, and the rotating magnet rotates inside the fixed magnet. The rotary disk shaft 48a is adjusted so that 50b rotates inside the fixed magnet 49.

  In FIG. 61, the magnetic poles 49a and 49b of the fixed magnet 49 are positioned up and down. However, in Examples 55 to 57, fixed magnets having different magnetic poles on the left and right on the plane are used. 49 is replaced with a rotating magnet suitable for it.

  When implementing the magnet arrangement method of the embodiment 58, the magnetic drive unit 46 of FIG. 61 is used. In the magnet arrangement method of the embodiment 58, the condition is that one of the magnetic poles of the fixed magnet and the rotating magnet are at the same height, and the rotating magnet rotates outside the fixed magnet. The rotary disk shaft 48a is adjusted so as to rotate outside the magnetic pole 49a.

  In FIG. 61, the magnetic poles 50a and 50b of the rotating magnet 50 are positioned up and down. However, in Example 58, rotating magnets having different magnetic poles on the left and right on the plane are used. Replace with a suitable rotating magnet.

  When implementing the magnet arrangement method of the embodiment 59, the magnetic drive unit 46 of FIG. 61 is used. In the magnet arrangement method of the embodiment 59, it is a condition that one magnetic pole of the rotating magnet and the fixed magnet are at the same height, and the rotating magnet rotates inside the fixed magnet. The mounting positions of the fixed magnet 49 and the rotating magnet 50 are changed so as to rotate the inside of the rotating disk shaft 48, and the rotating disk shaft 48a is adjusted.

  In FIG. 61, the magnetic poles 49a and 49b of the fixed magnet 49 are positioned up and down. However, in Example 59, fixed magnets having different magnetic poles on the left and right on the plane are used. Replace with a suitable fixed magnet. 61 also uses the magnetic drive device 46 of FIG. 61 in the method of implementing the magnet arrangement method of Example 60. In the magnet arrangement method of Example 60, rotating magnets having different magnetic poles on the left and right on the plane are used. Since one of the magnetic poles of the fixed magnet is at the same height and the rotating magnet rotates inside the fixed magnet, the fixed magnet 49 and the rotating magnet are rotated so that the rotating magnet 50 rotates inside the fixed magnet 49. The mounting position of 50 is changed and the rotary disk shaft 48a is adjusted.

  FIG. 64 is a view showing a 62nd embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIG. 64, the magnet arrangement method 64 in the magnetic drive device according to the present invention includes a fixed plate 65 to which the fixed magnet 67 is attached in a state where the rotary plate shaft 66a and the fixed magnet core 67a are at the same position. The rotating magnet 68 has a rotating magnet core 68a attached with a rotating magnet core 68a in a different position from the rotating disk shaft 66a. The fixed magnet core 67a is located on the same extension of the rotating disk shaft 66a and is simultaneously provided. A part of the fixed magnet 67 is located on the boundary line between the magnetic poles 68 b and 68 c having different polarities of the rotating magnet 66.

  In the case of FIG. 64, it is shown that the magnetic pole closer to the rotating magnet 68 of the fixed magnet 67 and the magnetic pole 68c of the rotating magnet 68 are the same magnetic pole. The board 66 rotates counterclockwise. Reference numeral 65a denotes a fixed platen shaft.

  FIG. 65 is a diagram showing a 63rd embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIG. 65, the magnet arrangement method 69 in the magnetic drive device according to the present invention includes a fixed plate 70 to which a fixed magnet 72 composed of one or a plurality of magnets 72b having the same circle circumference and the same magnetic pole is attached. Rotating magnets 73 having different polarities on the left and right are composed of a rotating disk 71 attached with a non-magnetic material 73d wider than the width of the magnet 72b by a number different from the number of magnets constituting the fixed magnet 72. The plate shaft 71a, the fixed magnet core 72a, and the rotating magnet core 73a are positioned on the same or the same extension, and only one same magnetic pole of the fixed magnet 72 is positioned inside the rotating magnet 73 and at the same height as the rotating magnet 73. is doing.

  In the case of FIG. 65, it is shown that the magnetic pole of the fixed magnet 72 and the magnetic pole 73b of the rotating magnet 73 that are inside the rotating magnet 73 and at the same height as the rotating magnet 73 are the same magnetic pole, and the relationship between such magnetic poles. Then, the turntable 71 to which the rotary magnet 73 is attached rotates counterclockwise. The magnetic pole 73c represents a different polarity from the magnetic pole 73b. Reference numeral 70a denotes a fixed platen shaft.

  66 and 67 are views showing a 64th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIGS. 66 and 67, the magnet arrangement method 74, 74a in the magnetic drive device according to the present invention is made up of an annular fixed magnet 77 having the same circumference and the same magnetic pole, and a fixed magnet core 77a and a rotating disk shaft 76a. The width of the non-magnetic material 78g between the rotating magnets 78 (78d) along the outer periphery of the rotating plate 76, and the fixed plate 75 attached in the same position and a plurality of rotating magnets 78 (78d) having different polarities on the left and right sides. The rotating disk shaft 76a, the fixed magnet core 77a, and the rotating magnet core 78a are located on the same or the same extension, and one of the same magnetic poles of the fixed magnet 77 and the rotating magnet 78 are provided. Located at the same height.

  66 shows that the magnetic pole of the fixed magnet 77 and the magnetic pole 78c of the rotating magnet 78 at the same height as the rotating magnet 78 are the same magnetic pole, and the rotating magnet 78 is attached in relation to such a magnetic pole. The rotating plate 76 rotates clockwise. The magnetic pole 78b represents a different polarity from the magnetic pole 78c. Reference numeral 75a indicates a fixed platen shaft.

  In the case of FIG. 67, it is shown that the magnetic pole of the fixed magnet 77 and the magnetic pole 78e of the rotating magnet 78d at the same height as the rotating magnet 78d are the same magnetic pole. The rotating plate 76 rotates clockwise. Reference numerals 78e and 78f denote magnetic poles, each having a different polarity. In FIG. 66, the rotary magnet 78 is circular or spherical, and in FIG. 67 the rotary magnet 78d is plate-shaped. However, the shape of the rotary magnet 78 (78d) is not limited, and the left and right sides may be different polarities. That's fine.

  FIG. 68 is a view showing a 65th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIG. 68, the magnet arrangement method 79 in the magnetic drive device according to the present invention includes a stationary platen 80 in which a fixed magnet 82 having one surface made of the same magnetic pole is mounted near the outer periphery of the stationary platen 80, and left and right sides. A plurality of rotating magnets 83 having different polarities are mounted on the rotating disk 81 along the outer periphery of the rotating disk 81 in a direction in which the opposite polarities face each other, and the width of the nonmagnetic material 83d between the rotating magnets 83 is reduced. The plate shaft 81a and the rotating magnet core 83a are located on the same or the same extension, and one identical magnetic pole of the fixed magnet 82 and the rotating magnet 83 are located at the same height.

  In the case of FIG. 68, the magnetic pole of the fixed magnet 82 and the magnetic pole 83c of the rotating magnet 83 at the same height as the rotating magnet 83 are the same magnetic pole. The rotating plate 81 rotates clockwise. The magnetic pole 83b represents a different polarity from the magnetic pole 83c. Reference numeral 80a indicates a fixed plate shaft 80a.

  FIG. 69 and FIG. 70 are views showing a 66th embodiment of a magnet arrangement method in a magnetic drive and a magnet arrangement state of a magnetic drive apparatus according to the present invention.

  As shown in FIGS. 69 and 70, the magnet placement methods 84 to 84g in the magnetic drive device according to the present invention are the same in that the fixed magnet 87 having the same circumference and the same magnetic pole has the same rotating disk shaft 86a and fixed magnet core 87a. A plurality of fixed plates 85 attached in position and arcuate rotating magnets 88 (89) having different polarities on the left and right sides or magnets 90e (91e) having different polarities on the left and right sides are connected via a non-magnetic material 90d (91d). And a rotating disk 86 to which a circular magnet 90 (91) is attached, and the same magnetic pole of one of the fixed magnets 87 is at the same height as the rotary magnet 90 (91) and within the circular arc of the rotating magnet. positioned.

  69 and 70, specific examples of magnet arrangement methods 84 to 84g are shown. FIG. 69 shows a case where arc-shaped rotating magnets 88 having different polarities on the left and right are used. Further, it is shown that the magnetic pole of the fixed magnet 87 and the magnetic pole 88c of the rotary magnet 88 at the same height as the rotary magnet 88 are the same magnetic pole. Rotates clockwise. The magnetic pole 88b shows a different polarity from the magnetic pole 88c, and the reference numeral 88a shows a rotating magnet core.

  In the magnet arrangement method 84a shown in FIG. 70, a case is illustrated in which arc-shaped rotating magnets 89 having different polarities on the left and right are used. Further, it is shown that the magnetic pole of the fixed magnet 87 and the magnetic pole 89c of the rotating magnet 89 at the same height as the rotating magnet 89 are the same magnetic pole, and the fixed magnet 87 and the rotating magnet 89 have the above-described magnetic pole relationship. In this case, the turntable 86 to which the rotary magnet 89 is attached rotates clockwise.

  In the magnet arrangement method 84b shown in FIG. 70, the left and right arc-shaped rotating magnets 89 having different polarities are used, and the rotating magnet 89 is installed so that the rotating magnet core 89a is located at a position different from the rotating disk shaft 86a. Shows the case. Further, it is shown that the magnetic pole of the fixed magnet 87 and the magnetic pole 89c of the rotating magnet 89 at the same height as the rotating magnet 89 are the same magnetic pole, and the fixed magnet 87 and the rotating magnet 89 have the above-described magnetic pole relationship. In this case, the turntable 86 to which the rotary magnet 89 is attached rotates clockwise.

  In the magnet arrangement method 84c shown in FIG. 70, the left and right arc-shaped rotating magnets 89 having different polarities are used, and the rotating magnet 89 is installed so that the rotating magnet core 89a is positioned differently from the rotating disk shaft 86a. Shows the state. Further, it is shown that the magnetic pole of the fixed magnet 87 and the magnetic pole 89c of the rotating magnet 89 at the same height as the rotating magnet 89 are the same magnetic pole, and the fixed magnet 87 and the rotating magnet 89 have the above-described magnetic pole relationship. In this case, the turntable 86 to which the rotary magnet 89 is attached rotates clockwise. The magnetic pole 89b has a different polarity from the magnetic pole 89c.

  The magnet arrangement method 84d shown in FIG. 70 shows a case where a rotating magnet 90 having a circular arc shape is used by connecting a plurality of magnets 90e having different polarities on the left and right sides with a non-magnetic material 90d. Further, it is shown that the magnetic pole of the fixed magnet 87 and the magnetic pole 90c of the rotating magnet 90 at the same height as the rotating magnet 90 are the same magnetic pole, and the fixed magnet 87 and the rotating magnet 90 have the above-described magnetic pole relationship. In this case, the turntable 86 to which the rotating magnet 90 is attached rotates counterclockwise. The magnetic pole 90b has a different polarity from the magnetic pole 90c, and the reference numeral 90a indicates a rotating magnet core.

  The magnet arrangement method 84e shown in FIG. 70 shows a case where a rotating magnet 91 having a circular arc shape is used by connecting a plurality of magnets 91e having different polarities on the left and right sides with a non-magnetic material 91d. Further, it is shown that the magnetic pole of the fixed magnet 87 and the magnetic pole 91c of the rotary magnet 91 at the same height as the rotary magnet 91 are the same magnetic pole, and the fixed magnet 87 and the rotary magnet 91 have the above-described magnetic pole relationship. In this case, the turntable 86 to which the rotary magnet 91 is attached rotates counterclockwise.

  In the magnet arrangement method 84f shown in FIG. 70, a rotating magnet 91 having a circular arc shape is formed by connecting a plurality of magnets 91e having different polarities on the left and right sides with a nonmagnetic material 91d, and the rotating magnet core 91a is connected to the rotating disk shaft 86a. Indicates a state in which the rotating magnet 91 is installed at different positions. Further, it is shown that the magnetic pole of the fixed magnet 87 and the magnetic pole 91c of the rotary magnet 91 at the same height as the rotary magnet 91 are the same magnetic pole, and the fixed magnet 87 and the rotary magnet 91 have the above-described magnetic pole relationship. In this case, the turntable 86 to which the rotary magnet 91 is attached rotates counterclockwise.

  In the magnet arrangement method 84g shown in FIG. 70, a rotating magnet 91 having a circular arc shape is formed by connecting a plurality of magnets 91e having different polarities on the left and right sides with a nonmagnetic material 91d, and the rotating magnet core 91a is connected to the rotating disk shaft 86a. Indicates a state in which the rotating magnet 91 is installed at different positions. Further, it is shown that the magnetic pole of the fixed magnet 87 and the magnetic pole 91c of the rotary magnet 91 at the same height as the rotary magnet 91 are the same magnetic pole, and the fixed magnet 87 and the rotary magnet 91 have the above-described magnetic pole relationship. In this case, the turntable 86 to which the rotary magnet 91 is attached rotates counterclockwise. The magnetic pole 91b has a different polarity from the magnetic pole 91, and the reference numeral 85a in FIGS. 69 and 70 indicates a fixed platen shaft.

  71 and 72 are views showing a 67th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIGS. 71 and 72, the magnet arrangement methods 92 to 92d in the magnetic drive device according to the present invention are such that the fixed magnet 95 having the same circumference and the same magnetic pole has the same rotating disk shaft 94a and fixed magnet core 95a. The fixed plate 93 mounted in the position and the two rotary magnets 96 facing each other of the fixed magnet 95 so that the two rotary magnets 96 face each other with the opposite magnetic poles 96a and 96b facing each other. A rotating plate 94 mounted in one semicircle, and the same magnetic pole of one of the fixed magnets 95 is positioned at the same height as the rotating magnet, and the rotating plate shaft 94a and the fixed magnet core 95a are positioned on the same or the same extension. is doing.

  71 and 72, specific examples of magnet arrangement methods 92 to 92d are shown. As shown in FIG. 71, in the magnet arrangement method 92, the two rotating magnets 96 are mounted in the same semicircle of the rotating disk with the magnetic poles 96a and 96b facing each other facing each other. It shows that each side of each of the magnetic poles 96a and 96b of the two different poles constituting the rotary magnet 96 is on the rotary disk diameter line 94b. Further, it is shown that the magnetic pole of the fixed magnet 95 and the magnetic pole 96b of one rotating magnet 96 at the same height as the rotating magnet 96 are the same magnetic pole, and the fixed magnet 95 and the rotating magnet 96 have the above-described magnetic pole relationship. , The turntable 94 to which the rotating magnet 96 is attached rotates clockwise.

  As shown in FIG. 72, in the magnet arrangement method 92a, the two rotating magnets 96 are mounted in the same semicircle of the rotating disk with two fixed magnets 96 facing each other magnetic poles 96a, 96b opposite to each other. Using the rotating disk 94, it is shown that each side of the magnetic poles 96a and 96b of the two different polarities constituting the rotating magnet 96 is located inside the semicircle indicated by the rotating disk diameter line 94b. Further, it is shown that the magnetic pole of the fixed magnet 95 and the magnetic pole 96b of one rotating magnet 96 at the same height as the rotating magnet 96 are the same magnetic pole, and the fixed magnet 95 and the rotating magnet 96 have the above-described magnetic pole relationship. , The turntable 94 to which the rotating magnet 96 is attached rotates clockwise.

  As shown in FIG. 72, in the magnet arrangement method 92b, the two rotating magnets 96 are arranged on the rotating disk with the two fixed magnets 96 facing each other and the magnetic poles 96a, 96b facing each other with the left and right sides different from each other. Using a rotating disk 94 mounted in the same semicircle, each side of the magnetic poles 96a, 96b of the two different poles constituting the rotating magnet 96 is located at a position inside the semicircle indicated by the rotating disk diameter line 94b. It shows that there is. Further, it is shown that the magnetic pole of the fixed magnet 95 and the magnetic pole 96a of the rotating magnet 96 at the same height as the rotating magnet 96 are the same magnetic pole, and the fixed magnet 95 and the rotating magnet 96 have the above-described magnetic pole relationship. In this case, the rotating disk 94 to which the rotating magnet 96 is attached rotates clockwise.

  As shown in FIG. 72, in the magnet arrangement method 92c, two fixed magnets 96 are opposed to each other with their magnetic poles 96a and 96b facing each other, and the two rotating magnets 96 are integrally rotated via a nonmagnetic material 96c. Using a rotating disk 94 mounted in the same semicircle of the disk, each side of the magnetic poles 96a, 96b of the two different poles constituting the rotating magnet 96 is inside the semicircle indicated by the rotating disk diameter line 94b. It shows that it is in position. Further, it is shown that the magnetic pole of the fixed magnet 95 and the magnetic pole 96b of the rotary magnet 96 at the same height as the rotary magnet 96 are the same magnetic pole, and the fixed magnet 95 and the rotary magnet 96 have the above-described magnetic pole relationship. In this case, the rotating disk 94 to which the rotating magnet 96 is attached rotates clockwise.

  As shown in FIG. 72, in the magnet arrangement method 92d, two fixed magnets 96 are opposed to each other with their magnetic poles 96a and 96b facing each other, and the two rotating magnets 96 are integrally rotated via a nonmagnetic material 96c. A rotating disk 94 mounted in the same semicircle of the disk is used, and each side of the two different polarities 96a and 96b constituting the rotating magnet 96 is located on the rotating disk diameter line 94b. Is shown. Further, it is shown that the magnetic pole of the fixed magnet 95 and the magnetic pole 96b of the rotary magnet 96 at the same height as the rotary magnet 96 are the same magnetic pole, and the fixed magnet 95 and the rotary magnet 96 have the above-described magnetic pole relationship. In this case, the rotating disk 94 to which the rotating magnet 96 is attached rotates clockwise. 71 and 72 indicate a fixed platen shaft.

  73 and 74 are views showing a 68th embodiment of the magnet arrangement method in the magnetic drive and the magnet arrangement state of the magnetic drive apparatus according to the present invention.

  As shown in FIGS. 73 and 74, the magnet arrangement methods 97 to 97c in the magnetic drive device according to the present invention include an annular fixed magnet 100 having the same circumference and the same magnetic pole, and a rotary disk shaft 99a and a fixed magnet core 100a. Non-magnetic material 101e (102d) between the fixed plate 98 attached in the same position and one magnet 101d having different polarities on the left and right sides or an arcuate or adjacent magnet 101d (102e) facing each other. ) Is provided with a rotating plate 99 to which a rotating magnet 101 (102) composed of a plurality of magnets 101d (102e) is arranged so as to be wider than the width of the magnet 101d (102e), and the rotating magnet 101 (102) is The same magnetic pole of one of the fixed magnets 100 located at the inner side of the fixed magnet 100 is at the same height as the rotary magnet 101 (102), and the rotary disk shaft 99a and the fixed magnet core. 00a is positioned on the same or on the same extension.

  73 and 74, specific examples of magnet arrangement methods 97 to 97b are shown. As shown in FIG. 73, the magnet arrangement method 97 shows a rotating magnet 101 in which a plurality of magnets 101d having different polarities on the left and right are arranged in an arc shape with their opposite polarities facing each other. Further, it is shown that the magnetic pole of the fixed magnet 100 and the magnetic pole 101b of the rotating magnet 101 at the same height as the rotating magnet 101 are the same magnetic pole, and the fixed magnet 100 and the rotating magnet 101 have the above-described magnetic pole relationship. In this case, the rotating disk 99 to which the rotating magnet 101 is attached rotates counterclockwise.

  As shown in FIG. 74, in the magnet arrangement method 97a, the widths of the non-magnetic bodies 101e (102d) between the magnets 101d having different polarities on the left and right sides and adjacent magnets 101d with the opposite polarities facing each other are magnetized. The rotating magnet 101 is provided so as to be wider than the width of 101d. Further, it is shown that the magnetic pole of the fixed magnet 100 and the magnetic pole 101b of the rotating magnet 101 at the same height as the rotating magnet 101 are the same magnetic pole, and the fixed magnet 100 and the rotating magnet 101 have the above-described magnetic pole relationship. In this case, the rotating disk 99 to which the rotating magnet 101 is attached rotates counterclockwise.

  As shown in FIG. 74, in the magnet arrangement method 97b, the rotating magnet 101 in which the left and right magnets 101d having different polarities are arranged is shown. Further, it is shown that the magnetic pole of the fixed magnet 100 and the magnetic pole 101b of the rotating magnet 101 at the same height as the rotating magnet 101 are the same magnetic pole, and the fixed magnet 100 and the rotating magnet 101 have the above-described magnetic pole relationship. In this case, the rotating disk 99 to which the rotating magnet 101 is attached rotates counterclockwise. The magnetic pole 101a has a different polarity from the magnetic pole 101b, and the reference numeral 101c indicates a rotating magnet core.

  As shown in FIG. 74, in the magnet arrangement method 97c, the rotation is such that the width of the non-magnetic body 102d between the adjacent magnets 102e is larger than the width of the magnet 102e. A magnet 102 is shown. Further, it is shown that the magnetic pole of the fixed magnet 100 and the magnetic pole 102b of the rotating magnet 102 at the same height as the rotating magnet 102 are the same magnetic pole, and the fixed magnet 100 and the rotating magnet 102 have the above-described magnetic pole relationship. In this case, the rotating disk 99 to which the rotating magnet 102 is attached rotates counterclockwise. The magnetic pole 102a has a different polarity from the magnetic pole 102b, and the reference numeral 102c indicates a rotating magnet core. 73 and 74 indicate a fixed platen shaft.

It is the figure which showed the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 2nd Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 3rd Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 4th Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed 5th Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 6th Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 7th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 8th Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed 9th Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 10th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed 11th Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 12th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed 13th Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 14th Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed 15th Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 16th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 17th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed 18th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 19th Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 20th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 21st Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 22nd Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 23rd Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed 24th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 25th Example of the arrangement | positioning state of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 26th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 27th Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 28th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 29th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 30th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 31st Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 32nd Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 33rd Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed 34th Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 35th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 36th Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 37th Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 38th Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 39th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed 40th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 41st Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 42nd Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 43rd Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 44th Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 45th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 46th Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 47th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 48th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 49th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 50th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 51st Example of the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 52nd Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 53rd Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 54th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 55th Example of the arrangement | positioning state of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 56th Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 57th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 58th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 59th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 60th Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the magnetic drive device of a magnetic drive device. It is the figure which showed the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the magnetic drive device of a magnetic drive device. It is the figure which showed the arrangement | positioning method of the magnet in the magnetic drive which is this invention, and the magnetic drive device of a magnetic drive device. It is the figure which showed the 62nd Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 63rd Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 64th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 64th Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 65th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 66th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 66th Example of the magnet arrangement | positioning method in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 67th Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 67th Example of the arrangement | positioning state of the magnet of the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 68th Example of the arrangement | positioning state of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device. It is the figure which showed the 68th Example of the arrangement | positioning state of the magnet in the magnetic drive which is this invention, and the arrangement | positioning state of the magnet of a magnetic drive device.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Magnet arrangement method 1a-1d Magnet arrangement method 2 Fixed platen 3 Rotary platen 3a Rotary platen shaft 4 Fixed magnet 4a Fixed magnet core 4b-4e Fixed magnet 5 Rotary magnet 5a Rotary magnet core 5b Magnetic pole 5c Magnetic pole 6 Magnet arrangement method 6a-6o Magnet arrangement method 7 Fixed plate 8 Rotary plate 8a Rotary plate shaft 9 Fixed magnet 10 Rotating magnet 10a Magnetic pole 10b Magnetic pole 10c Non-magnetic material 10d Rotating magnet core 10e Inclined surface 11 Magnet arrangement method 11a-11p Magnet arrangement method DESCRIPTION OF SYMBOLS 12 Fixed platen 13 Rotary platen 13a Rotary platen shaft 14 Fixed magnet 15 Rotating magnet 15a Magnetic pole 15b Magnetic pole 15c Nonmagnetic material 15d Rotating magnet core 15e Inclined surface 16 Magnet arrangement method 16a-16i Magnet arrangement method 17 Fixed platen 18 Rotary plate 18a Rotating disc shaft 19 Fixed magnet 20 Rotating magnet 20a Magnetic pole 20b Magnetic pole 20c Non-magnetic material 20d Non-magnetic material 20e Flat magnet 21 Magnet arrangement method 21a Magnet arrangement method 21b Magnet arrangement method 22 Fixed plate 23 Rotary plate 23a Rotary plate shaft 24 Fixed magnet 25 Rotary magnet 25a Magnetic pole 25b Magnetic pole 25e Flat magnet 26 Magnet Arrangement Method 26a Magnet Arrangement Method 26b Magnet Arrangement Method 27 Fixed Plate 28 Rotation Plate 28a Rotation Disc Shaft 29 Fixed Magnet 29a Fixed Magnet 29b Rotation Magnet Core 29c Rotation Magnet Core 29d Rotation Magnet 29e Rotation Magnet Core 29f Rotation Magnet 29g Rotation Magnet 29h Rotating magnet core 29i Rotating magnet core 30 Rotating magnet 30a Magnetic pole 30b Magnetic pole 31 Magnet arrangement method 32 Fixed disk 33 Rotating disk 33a Rotating disk shaft 34 Fixed magnet 34a Magnetic pole 34b Magnetic pole 35 Rotating magnet 35a Rotating magnet 35b Rotating magnet core 35c Rotating magnet core 35c Magnet core 35d times Rotating magnet 35e Rotating magnet core 35f Rotating magnet 35g Rotating magnet 35h Rotating magnet core 35i Rotating magnet core 36 Magnet arrangement method 37 Fixed platen 38 Rotating platen 38a Rotating platen shaft 39 Fixed magnet 39a Fixed magnetic core 40 Rotating magnet 40a Magnetic pole 40b Magnetic pole 41 Magnet arrangement method 42 Fixed plate 43 Rotary plate 43a Rotary plate shaft 44 Fixed magnet 44a Magnetic pole 44b Magnetic pole 45 Rotary magnet 45a Rotary magnet core 46 Magnetic drive unit 46a Magnetic drive unit 46b Magnetic drive unit 47 Fixed platen 47a Bearing 48 Rotary plate 48a Rotation Panel shaft 48b Joint 49 Fixed magnet 49a Magnetic pole 49b Magnetic pole 50 Rotating magnet 50a Magnetic pole 50b Magnetic pole 51 Fixed plate 51a Bearing 52 Rotating disc 52a Rotating disc shaft 52b Joint 53 Fixed magnet 53a Magnetic pole 53b Magnetic pole 54 Rotating magnet 54a Magnetic pole 54b 55 fixed plate 55a bearing 56 rotating plate 56a rotating plate shaft 56b joint 57 fixed magnet 57a magnetic pole 57b magnetic pole 58 rotating magnet 58a magnetic pole 58b magnetic pole 59 magnet arrangement method 60 fixed plate 61 rotating plate 61a rotating plate shaft 62 fixed magnet 63 rotating magnet 63 63a magnetic pole 63b magnetic pole 63c non-magnetic material 64 magnet arrangement method 65 fixed plate 65a fixed plate shaft 66 rotary plate 66a rotary plate shaft 67 fixed magnet 67a fixed magnet core 68 rotary magnet 68a rotary magnet core 68b magnetic pole 68c magnetic pole 69 magnet arrangement method 70 fixed plate 70a fixed plate shaft 71 rotary plate 71a rotary plate shaft 72 fixed magnet 72a fixed magnet core 72b magnet 73 rotary magnet 73a rotary magnet core 73b magnetic pole 73c magnetic pole 73d non-magnetic material 74 magnet arrangement method 74a magnet arrangement method 75 fixed Panel 75a Fixed plate axis 6 Rotating disk 76a Rotating disk shaft 77 Fixed magnet 77a Fixed magnet core 78 Rotating magnet 78a Rotating magnet core 78b Magnetic pole 78c Magnetic pole 78d Rotating magnet 78e Magnetic pole 78f Magnetic pole 78g Non-magnetic material 79 Magnet arrangement method 80 Fixed disk 80a Fixed disk shaft 81 Rotation Panel 81a Rotating disk shaft 82 Fixed magnet 83 Rotating magnet 83a Rotating magnet core 83b Magnetic pole 83c Magnetic pole 83d Non-magnetic material 84-84g Magnet arrangement method 85 Fixed disk 85a Fixed disk shaft 86 Rotating disk 86a Rotating disk shaft 87 Fixed magnet 87a Fixed magnet Core 88 Rotating magnet 88a Rotating magnet core 88b Magnetic pole 88c Magnetic pole 89 Rotating magnet 89a Rotating magnet core 89b Magnetic pole 89c Magnetic pole 90 Rotating magnet 90a Rotating magnet core 90b Magnetic pole 90c Magnetic pole 90d Nonmagnetic material 90e Magnet 91 Rotating magnet 91a Rotating magnet core 91b Magnetic pole 91b Magnetism Pole 91d Non-magnetic material 91e Magnet 92-92d Magnet arrangement method 93 Fixed plate 93a Fixed plate shaft 94 Rotary plate 94a Rotary plate shaft 94b Rotary plate diameter line 95 Fixed magnet 95a Fixed magnet core 96 Rotary magnet 96a Magnetic pole 96b Magnetic pole 96c Non-magnetic Body 97 to 97d Magnet arrangement method 98 Fixed plate 98a Fixed plate shaft 99 Rotary plate 99a Rotary plate shaft 100 Fixed magnet 100a Fixed magnet core 101 Rotating magnet 101a Magnetic pole 101b Magnetic pole 101c Rotating magnet core 101d Magnet 101e Non-magnetic body 102 Rotating magnet 102a Magnetic pole 102b magnetic pole 102c rotating magnet core 102d non-magnetic material 102e magnet

Claims (70)

  A fixed plate with a semicircular fixed magnet with the same circumference and the same magnetic pole so that the fixed magnet core is positioned slightly different from the rotary plate axis at the center of the fixed plate, and a rotary plate outside the fixed magnet The fixed platen can be rotated by a rotating plate fitted with rotating magnets that are substantially C-shaped with the shaft and the rotating magnet core slightly cut off by about a quarter so that the shaft and the rotating magnet core are slightly different from the center. A method of arranging magnets in a magnetic drive device comprising a rotating disk attached in a configuration.   2. The method for arranging magnets in a magnetic drive device according to claim 1, further comprising a stationary plate having a substantially elliptical shape and a stationary magnet having the same circumference and the same magnetic poles attached to a central portion of the stationary platen.   2. The method for arranging magnets in a magnetic drive device according to claim 1, further comprising: a fixed plate having a trapezoidal shape and a fixed magnet having the same circumference and the same magnetic pole attached to a central portion of the fixed plate.   2. The method for arranging magnets in a magnetic drive device according to claim 1, further comprising: a fixed plate having a fixed magnet having a square shape and the same periphery and having the same magnetic pole attached to a central portion of the fixed plate.   It consists of a fixed plate in which a plurality of circular fixed magnets having the same shape and size are joined to each other at the central portion of the fixed plate and the same magnetic poles are joined to each other in a configuration comprising the same magnetic poles. A method for arranging magnets in the magnetic drive device according to claim 1.   A fixed plate with a cylindrical fixed magnet with a hollow inside and the same circumference consisting of the same magnetic pole, and a magnet with magnetic poles with different polarities on the inside of the fixed magnet facing each other in a fan shape A magnet disposing method in a magnetic drive device, comprising: a rotating disk on which a plurality of connected rotating magnets are attached such that the rotating magnet core is positioned between the rotating disk shaft and the rotating magnet.   A rotating magnet in which a plurality of magnets composed of magnetic poles with opposite polarities facing each other and facing each other with a non-magnetic material in a fan shape is attached so that the rotating disk shaft is positioned between the rotating magnet core and the rotating magnet. The method for arranging magnets in a magnetic drive device according to claim 6, comprising a rotating disk.   Attach a rotating magnet with magnets consisting of magnetic poles with different polarities on both sides to the opposite ends of a non-magnetic material facing each other so that the rotating magnet core is positioned between the rotating disk shaft and rotating magnet. 7. The method for arranging magnets in a magnetic drive device according to claim 6, wherein the magnets are arranged on a rotating disk.   A rotating magnet in which magnets consisting of magnetic poles with different polarities on the front and back are connected to both ends of a nonmagnetic material curved with the opposite polarities facing each other is attached so that the rotating disk shaft is positioned between the rotating magnet core and the rotating magnet. The method for arranging magnets in a magnetic drive device according to claim 6, comprising a rotating disk.   Rotating magnets connected to both ends of a non-magnetic material curved with opposite poles facing each other so that the front and back are magnetic poles with opposite poles facing each other so that the rotating magnet and rotating magnet core are separated by a rotating shaft The method for arranging magnets in a magnetic drive device according to claim 6, comprising: an attached rotating disk.   A rotating disk with rectangular parallelepiped rotating magnets with the same surrounding four sides consisting of the same magnetic pole so that one side of the rotating magnet overlaps the diameter of the rotating disk and one corner of the rotating magnet is on the outer periphery of the rotating disk The method for arranging magnets in the magnetic drive device according to claim 6, comprising:   A rectangular rotating magnet with magnetic poles of different polarities on both sides of the rotating magnet, the boundary line of the magnetic poles of different polarities of the rotating magnet overlaps the diameter of the rotating disk, and the corners on both sides of the rotating magnet with different polarities are The method for arranging magnets in a magnetic drive device according to claim 6, comprising a rotating disk attached so as to be on the outer periphery.   A rotating magnet in which a plurality of flat magnets with magnetic poles with different polarities on the front and back sides are connected to each other. The central part of the rotating magnet overlaps the diameter of the rotating disc, 7. The method of arranging magnets in a magnetic drive device according to claim 6, wherein the rotating disk is mounted such that the corners on both sides are on the outer periphery of the rotating disk.   A rotating magnet having a horizontally long rectangular parallelepiped with magnetic poles of different polarities at both ends overlaps the diameter of the rotating disk with the boundary between the magnetic poles of different polarities of the rotating magnet, and the rotating magnet is on one semicircular shape of the rotating disk. 7. The method of arranging magnets in the magnetic drive device according to claim 6, wherein the rotating disk is mounted so as to be in the position of.   A rotating magnet with the same magnetic pole surrounding and the left side as an inclined surface overlaps the right side of the rotating magnet close to the diameter of the rotating disk, and the two corners of the inclined surface of the rotating magnet are positioned close to the outer peripheral surface of the rotating disk The method for arranging magnets in the magnetic drive device according to claim 6, wherein the rotating disk is mounted in such a manner.   A rotating disk mounted around a rotating magnet having the same magnetic pole and an inclined surface on the left side so that the right side of the rotating magnet overlaps the diameter of the rotating disk and the acute angle of the rotating magnet is located on the outer peripheral surface of the rotating disk The method for arranging magnets in the magnetic drive device according to claim 6, comprising:   A substantially arc-shaped rotating magnet having magnetic poles of different polarities on both sides is overlapped with the center of the rotating magnet on the diameter of the rotating disk, and the rotating magnet is oriented in the direction of the rotating disk axis. 7. The method of arranging magnets in a magnetic drive device according to claim 6, wherein the rotating magnet core when the rotating magnet is circular comprises a rotating disk with the rotating magnet attached at a position between the rotating shafts.   A substantially arc-shaped rotating magnet having magnetic poles of different polarities on both sides is overlapped with the center of the rotating magnet on the diameter of the rotating disk, and the rotating magnet is oriented in the direction of the rotating disk axis. 7. The method for arranging magnets in a magnetic drive device according to claim 6, comprising: a rotary magnet core in the case where the rotary magnet is circular; and a rotary disk attached at a position where the rotary shaft is between the rotary magnets.   A substantially U-shaped rotating magnet having magnetic poles of opposite polarities at both ends, with the central portion of the rotating magnet overlapping near the axis of the rotating disk, and both ends of the rotating magnet facing the inner circumference of the fixed magnet The method for arranging magnets in a magnetic drive device according to claim 6, comprising a mounted rotating disk.   An even number of circular magnets composed of magnetic poles of the same shape and the same size, but with opposite poles on the front and back, and rotating magnets with the same number of rotating magnets arranged in an arc shape so that the magnetic poles with different polarities on the left and right sides are different from each other The method for arranging magnets in the magnetic drive device according to claim 6, further comprising a rotating disk attached near the outer peripheral surface of the magnetic driving device.   A substantially semicircular rotating magnet having the same circumference and the same magnetic pole is parallel to a meridian in which a line connecting both ends of the rotating magnet is vertically lowered from the rotating disk axis, and is vertically lowered downward from the rotating disk axis. 7. The method of arranging magnets in a magnetic drive device according to claim 6, wherein the rotating disk is mounted in a state where the meridian is on the left side of the rotating magnet.   A flat plate with a fixed magnet attached with a fixed magnet consisting of the same magnetic pole on one side, and a plurality of plate magnets made of magnetic poles with different polarity on the upper or lower side of the fixed magnet. A rotating disk having a rotating magnet core mounted so that a rotating magnet core is located between the rotating disk shaft and the rotating magnet. Placement method.   A rotating disk shaft is positioned between a rotating magnet core and a rotating magnet. A rotating magnet is formed by connecting a plurality of plate-like magnets made of magnetic poles with different polarities, facing each other with the same polarity facing each other in a fan shape through a non-magnetic material. 23. The method for arranging magnets in a magnetic drive device according to claim 22, characterized in that the rotating disk is mounted in such a manner.   The rotating magnet core is located between the rotating disk shaft and the rotating magnet. The rotating magnet core consists of a plate-shaped magnet consisting of magnetic poles with different polarities facing each other and attached to both ends of a fan-shaped non-magnetic material. The method for arranging magnets in the magnetic drive device according to claim 22, comprising a rotating disk attached to the magnetic disk drive.   A rotating disk comprising a rotating magnet core and a rotating disk with a rotating disk shaft positioned between the rotating magnet core and a rotating magnet comprising magnetic poles attached to both ends of a fan-shaped non-magnetic material. The method for arranging magnets in the magnetic drive device according to claim 22.   The rotating magnet is located between the rotating magnet core and the rotating disk shaft, with the rotating magnet consisting of a plate-shaped magnet consisting of magnetic poles with different polarities facing each other and facing each other on both ends of a fan-shaped non-magnetic material. 23. The method for arranging magnets in a magnetic drive device according to claim 22, characterized in that the rotating disk is mounted in such a manner.   From a rotating disk with a rectangular parallelepiped rotating magnet with a different polarity relationship up and down, with the left side of the rotating magnet overlapping the meridian of the rotating disk and one corner of the rotating magnet positioned on the outer periphery of the rotating disk The method for arranging magnets in the magnetic drive device according to claim 22, wherein:   A rectangular rotating magnet with magnetic poles of different polarities on both sides of the rotating magnet, the boundary of the magnetic pole at the center of the rotating magnet overlaps the meridian of the rotating disk, and the corners on both sides of the magnetic poles of different polarities outside the rotating magnet are 23. The method for arranging magnets in a magnetic drive device according to claim 22, comprising a rotating disk mounted so as to be positioned on an outer periphery of the rotating disk.   Rotating magnets that connect a plurality of flat magnets with magnetic poles with different polarities on the front and back sides, the boundary line of the magnetic pole at the center of the rotating magnet overlaps the meridian of the rotating disk, and the two corners of the rotating magnet are 23. The method of arranging magnets in the magnetic drive device according to claim 22, comprising a rotating disk mounted so as to be positioned on the outer periphery.   Mount a horizontally long rotating magnet with magnetic poles of different polarities on both sides so that the center of the rotating magnet overlaps the meridian of the rotating disk and the rotating magnet is located in one semicircle of the rotating disk The method for arranging magnets in the magnetic drive device according to claim 22, wherein the magnets are arranged on a rotating disk.   Rotating magnets with different polarities on the top and bottom and with the left side inclined surface overlap the right side of the rotating magnet close to the diameter of the rotating disk, and the two corners of the inclined surface of the rotating magnet are close to the outer peripheral surface of the rotating disk The method for arranging magnets in a magnetic drive device according to claim 22, comprising a rotating disk mounted so as to be positioned.   Rotating magnets with different polarities at the top and bottom and with the left side as an inclined surface overlap the right side of the rotating magnet close to the diameter of the rotating disk, and the acute angle forming the inclined surface of the rotating magnet is located on the outer peripheral surface of the rotating disk 23. The method of arranging magnets in the magnetic drive device according to claim 22, characterized in that the rotating disk is mounted in such a manner.   A rotating magnet with a substantially arc shape with magnetic poles of different polarities on both sides of the plane was mounted with the center of the rotating magnet overlapping the diameter of the rotating disk and the inner side of the rotating magnet facing the direction of the rotating disk core. The method for arranging magnets in a magnetic drive device according to claim 22, comprising a rotating disk, wherein the rotating magnet core is located between the rotating magnet and the rotating disk shaft.   A generally arc-shaped rotating magnet with magnetic poles of different polarities on both sides of the plane was mounted with the center of the rotating magnet overlapping the diameter of the rotating disk and the inside of the rotating magnet facing the direction of the rotating disk axis. The method for arranging magnets in a magnetic drive device according to claim 22, comprising a rotating disk, wherein the rotating disk shaft is located between the rotating magnet and the rotating magnet core.   A substantially U-shaped rotating magnet having magnetic poles of different polarities at both ends was mounted with the central portion of the rotating magnet overlapping close to the axis of the rotating disk and both ends of the rotating magnet facing the circumference of the fixed magnet. The method for arranging magnets in the magnetic drive device according to claim 22, comprising a rotating disk.   An even number of circular magnets with magnetic poles of the same shape and the same size but with different polarities on the front and back sides are arranged on the left and right, and the same number of rotating magnets arranged in an arc shape on the left and right sides near the outer peripheral surface of the rotating disk The method for arranging magnets in the magnetic drive device according to claim 22, comprising a rotating disk attached to the magnetic disk drive.   A line connecting the two ends of a rotating magnet with the same magnetic pole around the same semicircular shape with different polarities in the upper and lower sides is parallel to the meridian that is vertically lowered downward from the rotating disk axis, and rotates. 23. The method of arranging magnets in a magnetic drive device according to claim 22, comprising a rotating disk attached with a meridian vertically lowered from the disk axis on the left side of the rotating magnet.   A rotating magnet in the shape of a rectangular parallelepiped with magnetic poles of different polarities at both ends on a plane so that the center of the rotating magnet overlaps the meridian of the rotating disk, and both sides of magnetic poles of different polarities outside the rotating magnet 23. The method of arranging magnets in the magnetic drive device according to claim 22, wherein the rotating disk is mounted so that the corners thereof are positioned on the outer periphery of the rotating disk.   A fixed disk with a flat disk and a fixed magnet with the same circumference and the same magnetic pole, and a rectangular parallelepiped rotating magnet with a magnetic pole of different polarity, the boundary line of the magnetic poles of different polarity overlaps the meridian of the rotating disk, A magnet placement method in a magnetic drive device, further comprising: a rotating disk attached so that the corners on both sides of the magnetic poles of different polarities outside the rotating magnet are positioned on the outer periphery of the rotating disk.   The center of a rotating magnet that connects two or more flat magnets with magnetic poles with different polarities facing each other with the opposite polarities facing each other overlaps the meridian of the stationary platen, and further, both sides of magnetic poles with different polarities outside the rotating magnet 40. The method of arranging magnets in the magnetic drive device according to claim 39, comprising: a rotating plate attached so that the corner of the rotating plate is positioned on the outer periphery of the fixed platen.   A flat plate magnet consisting of magnetic poles with different polarities on both sides is mounted on both ends of a fan-shaped non-magnetic material with the opposite poles facing each other. From the rotating disc mounted so that the core of the rotating magnet is at the same position as the fixed plate axis 40. A method of arranging magnets in a magnetic drive device according to claim 39.   A rectangular parallelepiped rotating magnet consisting of magnetic poles with different polarities is positioned so that the right side of the rotating magnet overlaps the meridian of the rotating disk, and one magnetic pole surface of the rotating magnet faces the circumferential surface of the fixed magnet 40. A method of arranging magnets in a magnetic drive device according to claim 39, comprising one or more rotating disks disposed and attached at positions facing the inclined shape.   A rectangular parallelepiped magnet consisting of magnetic poles with different polarities on the front and back faces each other with different polarities facing each other through a non-magnetic material at equal intervals to form a fan-shaped rotating magnet, and the core of the rotating magnet is the fixed platen shaft 40. The method of arranging magnets in the magnetic drive device according to claim 39, comprising: a rotating disk attached so as to be in the same position as the magnetic disk.   An arc-shaped rotating magnet equipped with magnetic poles with different polarities on both sides, and a rotating disk mounted so that the boundary line of the magnetic poles with different polarities is on the meridian of the rotating disk and the inner side of the rotating magnet faces the rotating disk axis 40. A method of arranging magnets in a magnetic drive device according to claim 39.   Place the different poles facing each other at equal intervals so that the boundary line of the different poles of the flat magnet consisting of magnetic poles with different polarities on the rotating disk is located on the meridian of the rotating disk. 40. The magnetic drive device according to claim 39, comprising: a rotating disk provided with a rotating magnet having a circular configuration in which the different poles are connected to each other with a nonmagnetic material so that the different poles are not in direct contact with each other. Arrangement method of magnets.   Place the different poles facing each other at equal intervals so that the boundary line of the different poles of the flat magnet consisting of magnetic poles with different polarities on the rotating disk is located on the meridian of the rotating disk. In order to prevent the different poles from being in direct contact with each other, a non-magnetic material is provided between them to form a circular shape, and at least one portion of the circular shape is provided with a non-magnetic material at a wider interval. 40. The method of arranging magnets in the magnetic drive device according to claim 39, comprising: an attached rotating disk.   The inside of a rotating magnet that is arranged in a circular shape with equal intervals facing each other so that the boundary line of the magnetic poles of the different polarity of the flat magnet composed of magnetic poles of different polarity on the front and back faces the meridian of the rotating disk Is a structure in which each flat magnet is in contact with different poles, and the outside of the rotating magnet is formed in a circular shape by connecting each other with a non-magnetic material, and at least one of the circular shapes is more widely spaced. 40. The method of arranging magnets in a magnetic drive device according to claim 39, comprising a rotating disk on which rotating magnets connected in series with a nonmagnetic material are attached.   Several flat magnets composed of magnetic poles with different polarities on the front and back are arranged on a rotating disk at a position where the different polarities face each other with a considerable gap between them, and they are non-magnetic between the flat magnets. 40. The method for arranging magnets in a magnetic drive device according to claim 39, comprising a rotating disk to which rotating magnets connected in a body are attached.   The boundary between the fixed pole with a fixed magnet with the same magnetic pole near the outer peripheral surface and the flat magnetic pole with the opposite poles inside and outside the fixed magnetic pole Magnetic drive comprising a rotating disk having rotating magnets arranged in a circular shape at equal intervals by overlapping a plurality of magnets having different polarities at the ends at a position having an angle of about 90 ° Method for arranging magnets in the apparatus.   The boundary line between the fixed pole with the same magnetic pole on the outer surface and the flat magnetic pole on the outer side of the fixed plate and the flat magnet on the outer side of the fixed pole A plurality of magnets at a position having an angle of about 90 ° are overlapped with each other, and a rotating disk in which circular magnets are arranged in a circular shape at equal intervals is overlapped. 49. A method of arranging magnets in the magnetic drive device according to 49.   The boundary line between the fixed plate with a disk-shaped fixed magnet with the same circumference and the same magnetic pole, and the flat magnetic poles with the opposite poles on the outside and the outside of the fixed plate is the meridian of the rotating disk And a rotating disk in which a plurality of magnets are stacked in a circular shape at equal intervals by overlapping a plurality of different poles at each end at a position having an angle of about 90 ° with respect to each other. 50. A method of arranging magnets in the magnetic drive device according to claim 49.   A fixed plate with two substantially fixed crescent-shaped fixed magnets facing each other and mounted in a substantially elliptical shape with the same circumference consisting of the same magnetic poles, and a rectangular parallelepiped-shaped rotating magnet with magnetic poles of different polarities outside this An arrangement of magnets in a magnetic drive, characterized by comprising a rotating disk mounted near the outer periphery at a position where a boundary line of different polarity overlaps the meridian of the rotating disk.   A fixed plate with a fixed magnet so that the center of the line connecting both ends of a substantially crescent-shaped fixed magnet with the same circumference and the same magnetic pole overlaps the center of the fixed plate, and a magnetic pole of a different polarity outside this 53. The arrangement of magnets in magnetic drive according to claim 52, comprising: a rotating disk with a rectangular parallelepiped rotating magnet attached near the outer periphery at a position where the boundary of the different poles overlaps the meridian of the rotating disk.   A rectangular parallelepiped with two fixed magnets with a substantially crescent shape joined together with the vertices of the curved portions joined together and attached in a substantially X shape with the same circumference consisting of the same magnetic pole, and a magnetic pole of a different polarity outside this 53. The arrangement of magnets in a magnetic drive according to claim 52, comprising: a rotating disk in which a circular rotating magnet is attached near the outer periphery at a position where a boundary line of different polarity overlaps the meridian of the rotating disk.   A fixed plate with a rectangular parallelepiped fixed magnet with magnetic poles of different poles attached near the outer periphery at a position where the boundary of the different poles overlaps the meridian of the rotary plate, and two approximately crescent-shaped rotary magnets inside the fixed plate A magnet placement method in a magnetic drive comprising: a rotating disk that is joined face-to-face and attached in a substantially elliptical shape with the same circumference comprising the same magnetic poles.   A rotating disk equipped with a rotating magnet so that the center of the line connecting both ends of a substantially crescent-shaped rotating magnet having the same circumference and the same magnetic pole overlaps near the center of the rotating disk, and a magnetic pole of a different polarity outside this 56. The magnet of the magnetic drive according to claim 55, further comprising: a fixed plate having a rectangular parallelepiped shape and a fixed plate mounted near the outer periphery at a position where a boundary line of different polarity overlaps the meridian of the rotating plate. Placement method.   Two rotating magnets having a substantially crescent shape are joined together with the vertices of the curved portions joined together, and a rotating disk mounted in a substantially X shape having the same circumference and the same magnetic pole, and a rectangular parallelepiped fixed magnet having different poles 56. The method of arranging magnets in magnetic drive according to claim 55, comprising a fixed plate attached near the outer periphery at a position where the boundary line of the different polarity overlaps the meridian of the rotating plate.   A stationary plate with a substantially donut-shaped stationary magnet with the same circumference consisting of the same magnetic poles with rounded edges on the outside and a substantially circular hole inside, and a magnetic pole of a different polarity on the outside A magnet arrangement method in magnetic drive, comprising: a rotating disk having a rectangular parallelepiped rotating magnet provided near the outer periphery at a position where a boundary line of different polarity overlaps the meridian of the rotating disk.   A fixed plate with a rectangular parallelepiped fixed magnet with magnetic poles with different polarities attached near the outer periphery at a position where the boundary line of the different polarities overlaps the meridian of the rotating plate, and the four sides inside this are rounded outward. A magnet placement method in magnetic drive, comprising: a rotating disk provided with a substantially donut-shaped rotating magnet having a substantially circular hole inside and having the same circumference and the same magnetic pole.   The boundary line between the fixed plate with a fixed magnet with a fixed magnet made of the same magnetic pole on one side and a flat plate with magnetic poles with different polarities inside and outside is located on the meridian of the rotating plate The magnets in the magnetic drive device are characterized by comprising a rotating disk which is arranged in a circular shape by arranging different poles facing each other at equal intervals and connecting each other with a non-magnetic material in a circular shape. Placement method.   A rotating disk is provided with a rotating magnet suspended from the lower surface and a rotating disk shaft attached to the center of the lower surface via a joint, and a fixed magnet is mounted on the upper surface and a bearing for rotatably connecting the rotating disk shaft to the upper surface center. A magnetic drive device comprising a fixed plate.   A rotating disk in which a rotating magnet is vertically suspended and a rotating disk shaft is attached to the center of the lower surface via a joint, and a bearing for rotatably connecting the rotating disk shaft to the center of the upper surface with an annular fixed magnet on the upper surface. 62. The magnetic drive device according to claim 61, wherein the magnetic drive device comprises:   A rotating disk having a rotating magnet vertically installed on the lower surface and a rotating disk shaft attached to the center of the lower surface via a joint, and a disk-shaped fixed magnet on the upper surface, for rotatably connecting the rotating disk shaft to the upper surface center. 62. The magnetic drive device according to claim 61, comprising a fixed plate provided with a bearing.   From a fixed plate with a fixed magnet attached with the rotary plate shaft and fixed magnet core in the same position, and a rotary plate with a rotary magnet with a different polarity on the left and right attached to the rotary magnet core in a different position from the rotary plate shaft Wherein the fixed magnet core is positioned on the same extension of the rotating disk shaft, and at the same time, a part of the fixed magnet is positioned on the boundary line between the magnetic poles of different polarities of the rotating magnet. .   The number of magnets is different from the number of magnets constituting the fixed magnet, and a fixed plate with one or more fixed magnets composed of the same magnetic poles around the same circle and rotating magnets with different polarities on the left and right. The rotating disk shaft, the fixed magnet core, and the rotating magnet core are located on the same or the same extension, and only one same magnetic pole of the fixed magnet is provided. A method for arranging magnets in a magnetic drive device, wherein the magnets are positioned inside the rotating magnet and at the same height as the rotating magnet.   A fixed plate with an annular fixed magnet with the same circumference and the same magnetic pole attached with the fixed magnet core and the rotary plate shaft in the same position, and a plurality of rotary magnets with different polarities on the left and right sides along the outer circumference of the rotary plate The rotating disk shaft, the fixed magnet core, and the rotating magnet core are positioned on the same or the same extension, and one of the fixed magnets has the same magnetic pole. A method of arranging magnets in a magnetic drive device, wherein the rotating magnets are positioned at the same height.   Rotating along the outer periphery of the rotating plate in the direction of facing the opposite poles of a plurality of rotating magnets with different polarities facing each other with a fixed plate with a fixed magnet consisting of the same magnetic pole on one side near the outer periphery of the fixed plate The rotating disk shaft and the rotating magnet core are positioned on the same or the same extension, and the same magnetic pole on one of the fixed magnets and the rotating magnet have the same height. A method for arranging magnets, wherein   Non-magnetic a fixed plate with fixed magnets with the same circumference and the same magnetic pole attached with the rotary plate shaft and fixed magnet core in the same position, and arc-shaped rotating magnets with different polarities on the left and right or magnets with different polarities on the left and right It consists of a rotating disk with a plurality of rotating magnets connected to each other through a body, and one of the fixed magnets is located at the same height as the rotating magnet and within the arc of the rotating magnet. A method for arranging magnets in a magnetic drive device.   The fixed magnet, which has the same circumference and the same magnetic pole, is mounted with the rotating disk shaft and the fixed magnet core in the same position, and the two rotating magnets are connected to the poles of different polarities, close to both sides of the fixed magnet. The two rotating magnets face each other and are mounted in the same semicircle of the rotating disk, and one fixed magnetic pole of the fixed magnet is located at the same height as the rotating magnet. A method of arranging magnets in a magnetic drive device, characterized in that the cores are positioned on the same or the same extension.   An annular fixed magnet with the same circumference consisting of the same magnetic pole and a fixed plate mounted with the rotary plate shaft and fixed magnet core in the same position, and one magnet with different polarities on the left and right or different arcs facing each other Alternatively, it comprises a rotating disk equipped with a rotating magnet composed of a plurality of magnets arranged so that the non-magnetic material width between adjacent magnets is wider than the width of the magnet, and the rotating magnet is positioned inside the fixed magnet and fixed. A magnet arranging method, wherein one same magnetic pole of a magnet is at the same height as a rotating magnet, and a rotating disk shaft and a fixed magnet core are positioned on the same or the same extension.

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