KR102567983B1 - Rotational Power Device By External Force - Google Patents

Abstract

The present invention relates to a rotational power device in which a magnet is installed at the end of an outer rim wing of a rotating object so that rotational force is generated at the tip of the wing and the wing rapidly rotates. Such a rotary power device includes a support plate module having a connection groove formed in the center and fixed to the base plate, a support plate part including a first electrode module installed at a distance around the connection groove on the upper side of the support plate module, a pillar module formed in a cylindrical shape, and Including the second electrode plate module installed on the outer circumferential surface of the pillar module and connected to the first polarity terminal of the external DC supply device, the pillar part to which one end of the pillar module is fixed to the connecting groove, and the insertion hole formed in the center of the pillar module The hub module inserted into the hub module, the wing rod module installed on the side of the hub module, and the wing rod module installed on one side of the wing rod module, one end contacting and non-contacting the first electrode plate module according to the rotation of the wing rod module, and the other end the second electrode The switch wire module that is always in contact with the plate module, the rotating wing part including the magnet module that is fixed on the outside of the wing rod module and forms a magnetic field, and the overlapping hole is formed in the center to be inserted into the pillar module, and a part is inserted into the hub module and the wing rod It is formed in a structure in which a coil wire is wound to form a wing detachment prevention part fixed to a part of the module and an accommodation space therein, and the first input terminal line connected to the first electrode plate on one side and the second polarity of the DC supply device located outside Including the second input terminal line connected to the terminal, an even number of times more than the number of wing bar modules is installed on the outside of the support plate module, and when current flows through the first input terminal line and the second input terminal line, a magnetic field responds to the flowing current. It includes a coiling channel portion forming a.

Description

Rotational power device {Rotational Power Device By External Force}

The present invention relates to a device that rotates when electricity is applied thereto.

Currently, the development of eco-friendly technologies is actively progressing. In particular, among the development of eco-friendly technologies, technologies for reducing carbon emissions are being actively pursued. Accordingly, research is being focused on a motor that does not emit carbon even when driven in an engine that emits carbon during operation.

As technology development for such motors progresses, motors with improved performance and devices operating in conjunction with these motors are being developed.

Many motors developed to date have a problem in that driving efficiency is not high.

Republic of Korea Patent Publication No. 10-2021-0135904 (published date: 2021. 11. 16)

The present invention is intended to solve the problem of not properly using the power of a magnet.

The problem to be solved by the present invention is not limited to the problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

The rotational power device of the present invention for achieving the above object is a support plate module having a connection groove formed in the center and fixed to a base plate, and a first electrode module installed at a distance around the connection groove on the upper side of the support plate module. One end of the pillar module is fixed to the connection groove, including a support plate portion including a support plate portion, a pillar module formed in a cylindrical shape, and a second electrode plate module installed on the outer circumferential surface of the pillar module and connected to the first polar terminal of the external DC supply device. A hub module with an insertion hole formed in the center of the pillar and inserted into the pillar module, a wing rod module installed on the side of the hub module, and a wing rod module installed on one side of the wing rod module and one end of the first electrode according to the rotation of the wing rod module A switch wire module that is in contact with and non-contact with the plate module and the other end is always in contact with the second electrode plate module and a rotary blade part that is fixed to the outside of the wing rod module and includes a magnet module that forms a magnetic field, and an overlapping hole is formed in the center to form a pillar The first input terminal wire connected to the first electrode plate on one side formed in a structure in which a coil wire is wound so that a wing detachment prevention part inserted into the module and a part fixed to a part of the hub module and the wing rod module and an accommodation space therein are formed, Including the second input terminal wire connected to the second polarity terminal of the external DC supply device, the number of even times greater than the number of wing rod modules is installed on the outside of the support plate module, and the first input terminal wire and the second input terminal wire current When flows, it includes a coiling channel portion that forms a magnetic field in response to the flowing current. Here, when a magnetic field is formed in the coiling channel unit, a first polarity is formed inside the accommodation space and a second polarity opposite to the first polarity is formed outside the accommodation space, and the first polarity of the magnet module located inside the accommodation space is formed. It forms a polarity and attractive force, forms a second polarity and repulsive force of the magnet module, and rotates the rotor blades in the direction in which the attractive force is formed.

In addition, the coiling channel unit forms a magnetic field when one end of the switch wire module contacts the first electrode plate module, pulls the magnet module from one side, pushes the magnet module from the other side, and moves the wing rod module from the other side to one side. can be rotated to And when the wing rod module is separated from the first electrode plate module, when one end of the switch wire module is separated from the first electrode plate module, the magnetic field formed in the coiling channel part disappears, and the inertial force when rotated by the magnetic force line formed in the coiling channel part rotates and moves can

In addition, the rotary power device of the present invention is inserted into the pillar module, one side is in contact with the support plate portion and the other side is in contact with the first washer module and the pillar module in contact with the rotor blade portion, one side is in contact with the hub module and the other side is in contact with the blade separation prevention unit A washer unit including a second washer module may be further included.

In addition, the rotary power device is inserted into the pillar module, and the first washer module is inserted into the pillar module, one surface is in contact with the support plate part and the other surface is in contact with the rotary blade part, and the first washer module is inserted into the pillar module and one surface is in contact with the hub module and the other surface is in contact with the wing separation prevention unit. 2 may include a washer unit including a washer module. At this time, the coiling channel portion may include first to third coil wires having a cross-sectional diameter of 1 mm to 1.2 mm, and a longitudinal cross section may be formed as '⊂' or '⊃'. In addition, the plurality of wing rod modules may include first to fourth wing rod modules installed at regular intervals installed on the side of the hub module. The coiling channel unit may include first to eighth coiling channel units disposed along each surface of the virtual regular octagon. In addition, the magnet module may be formed in a structure in which a first magnet and a second magnet having a width of 3 cm, a length of 10 cm, and a thickness of 2 cm are combined into one.

The present invention applies attractive and repulsive forces to the magnets installed at the outer ends of the rotating blades and rapidly rotates the wings. In addition, the overall size of the present invention may increase as the number of wings and the number of coiling channel portions increase and the length of the wing rod module increases.

1 is a perspective view of a rotational power device according to an embodiment of the present invention.
2 is an exploded perspective view of a rotary power device according to an embodiment of the present invention.
3 is a layout view of a rotational power device according to an embodiment of the present invention.
4 is a view showing a rotary blade according to an embodiment of the present invention.
5 is a view showing a magnet module according to an embodiment of the present invention.
6 is a view showing rotor blades of different sizes.
7 is a view showing different types of rotor blades.
8 is a view showing a coiling channel unit according to an embodiment of the present invention.
9 is a view showing coiling channel units having different sizes.
10 is a view showing a state in which the rotor blades are located in the receiving space of the coiling channel unit of FIG. 9 .
FIG. 11 is a view showing a current flowing in the coiling channel portion of FIG. 9 (a) viewed from above and a magnetic field formed corresponding to the flowing current.
12 shows that an attractive force is formed between one side of the coiling channel portion and the first polarity of the magnet module, and a repulsive force is formed between the other side surface of the coiling channel portion and the second polarity of the magnet module, so that the rotary blades are rotated in the direction in which the attractive force is formed. It is a diagram showing the state.
13 and 14 are views showing a state in which a magnetic field is formed in the coiling channel part and the rotor blades are rotated by inertial force, attractive force, and repulsive force.
15 to 31 are views showing the operating state of the rotary power device according to an embodiment of the present invention.

Advantages and features of the present invention and devices for achieving them may become clear with reference to embodiments described below in detail in conjunction with the accompanying drawings. This embodiment is provided to complete the disclosure of the present invention and to completely inform those skilled in the art of the scope of the invention to which the present invention belongs. Thus, the drawings shown in the present specification may be somewhat exaggerated so that a person skilled in the art can more clearly understand the present invention.

Therefore, there may be differences between the drawing shown in this specification and the rotational power device of the actual product. Therefore, the drawings and drawings shown in this specification do not define the rotational power device of the present invention. The definition of the rotary power plant of the present invention is defined solely by the claims.

Hereinafter, the present invention will be described in detail with reference to FIGS. 1 to 31 . However, after a general description of the rotational power device of the present invention with reference to Figure 1 so that the description of the present invention can be concise and clear, the configuration constituting the present invention based on the described contents and FIGS. 2 to 11 Describe the elements in detail. And, with reference to FIGS. 12 to 31, the present invention and the operation between the coiling channel part and the rotary blade part of the present invention will be described in detail.

1 is a view showing a rotational power device according to an embodiment of the present invention.

The rotational power unit 1 applies attractive and repulsive forces to magnets installed at the outer ends of rotating blades, and can quickly rotate the rotary blades 30 through inertial force formed when removing the applied attractive and repulsive forces. In particular, the rotary power device 1 rotates the rotor blades by the magnetic force formed between the rotary blade unit 30 and the coiling channel unit 50 and the inertial force when the magnetic force is disconnected, and the magnetic field is applied to the coiling channel unit 50. outputs electrical energy that forms

In particular, in the rotary power unit 1, the rotary blade unit 30 is connected to the first input terminal line 501 of the coiling channel unit 50 to the first polar terminal D of the DC supply unit, and the second electrode plate When the module 220 is connected to the second polarity terminal (E) of the DC supply device (C), it is rotated in the first direction, that is, counterclockwise. And, the second input terminal line 502 of the coiling channel unit 50 is connected to the second polarity terminal E of the DC supply device, and the second electrode module 220 is connected to the first electrode module 220 of the DC supply device C. When connected to the polar terminal (D), rotate in the second direction, that is, clockwise. That is, the rotary power device 1 rotates the rotary blade 30 clockwise or counterclockwise.

The core of the rotational power device 1 of the present invention is the magnet module 340 installed on the rotor blade unit 30 and the coiling channel unit 50 formed of multiple wires. Here, the coiling channel unit 50 may be formed according to the multi-line principle in which a magnetic field is increased according to the number of equal divisions when a quantity to be used as one line is equally divided into several lines. In this specification, for convenience, it is assumed that the coiling channel unit 50 is formed by either a structure formed by dividing a portion of one wire into thirds or a structure formed by dividing a portion of one wire into quarters.

Hereinafter, in this specification, so that the description of the operation of the rotational power device 1 of the present invention can be concise and clear, the rotational power device 1 includes a first wing rod module, a second wing rod module, It is formed of the third wing rod module and the fourth wing rod module, and the coiling channel unit includes the first coiling channel unit, the second coiling channel unit, the third coiling channel unit, the fourth coiling channel unit, and the fifth coil. It is formed of a ring channel part, a sixth coiling channel part, a seventh coiling channel part, and an eighth coiling channel part, and the second electrode plate module 220 connects to the first polarity terminal (D) of the DC supply device (C). It is connected to and based on that the rotary blade 30 operates in a counterclockwise direction.

Such a rotary power device 1 includes a support plate part 10, a pillar part 20, a rotary wing part 30, a wing separation preventing part 40, and a coiling channel part 50 as components. . And it may further include a washer unit 25 installed between the components to prevent wear due to movement of the components. In addition, a direct current supply device (C) for applying current to the support plate part 10, the pillar part 20, the rotor blade part 30, and the coiling channel part 50 may be further included as a component. Here, the DC supply device C may be a battery that outputs DC current.

Hereinafter, with reference to FIGS. 2 to 10, components constituting a rotational power device according to an embodiment of the present invention will be described in detail.

Figure 2 is an exploded perspective view of a rotational power unit according to an embodiment of the present invention, Figure 3 is a layout view of the rotational power unit according to an embodiment of the present invention, Figure 4 is a rotary blade according to an embodiment of the present invention 5 is a view showing a magnet module according to an embodiment of the present invention, FIG. 6 is a view showing rotor blades of different sizes, and FIG. 7 is a diagram showing rotor blades of different types. 8 is a view showing a coiling channel unit according to an embodiment of the present invention, and FIG. 9 is a view showing a coiling channel unit having different sizes. And FIG. 10 is a view showing a state in which the rotor blades are located in the receiving space of the coiling channel unit of FIG. 9 .

The support plate part 10 is fixed to the base plate A so that the current output from the DC supply device C flows to the coiling channel part 50. As shown in FIG. 2 , such a support plate unit 10 includes a support plate module 110 and a first electrode plate module 120 . Here, the support plate module 110 may be formed in a regular octagonal or circular shape and fixed to the base plate A through the connecting member B. A circular connection groove 1100 is formed at the inner center of the support plate module, and first electrode plate modules 120 spaced apart from each other around the connection groove 1100 are installed outside the connection groove 1100. Here, the first electrode plate module 120 may be formed of a plurality of electrode plates having the same shape and size. At this time, the first electrode plate module 120 may be formed of the same number of electrode plates as the number of coiling channel units 50 . For example, the first electrode plate module 120 includes a first electrode plate 121, a second electrode plate 122, a third electrode plate 123, and a fourth electrode plate 124 as shown in FIG. , the fifth electrode plate 125, the sixth electrode plate 126, the seventh electrode plate 127, and the eighth electrode plate 128. In this case, the first electrode plate 121 to the eighth electrode plate 128 may be spaced apart at regular intervals.

The pillar part 20 is installed in the connection groove 1100 so that the current output from the DC supply device C flows to the rotor blade part 30 and the coiling channel part 50. The pillar part 20 includes a pillar module 210 and a second electrode plate module 220 . Here, the pillar module 210 becomes a pillar formed in a cylindrical shape. The second electrode plate module 220 is installed on the outer circumferential surface of the pillar module and is connected to the first polarity terminal (D) or the second polarity terminal (E) of the DC supply device (C) through a wire. The second electrode plate module 220 is formed of a copper plate and allows electricity output from the DC supply device C to be applied to the switch wire module 330 to be described later.

The first washer module 251 of the washer part 25 is inserted between the pillar part 20 and the rotary blade part 30 as shown in FIG. 2 . At this time, the first washer module 251 is inserted into the pillar module 210, one side is in contact with the support plate 10 and the other side is in contact with the rotary blade unit 30 so that it is not worn when the rotary blade unit 30 rotates. do.

The rotary blade unit 30 is installed on the pillar unit 20 and rotates in a first direction (counterclockwise direction) or a second direction (clockwise direction) according to the direction of the magnetic field formed in the coiling channel unit 50. This rotary blade unit 30 may be composed of a hub module 310, a wing rod module 320, a switch wire module 330, and a magnet module 340. Here, the hub module 310 has a wing rod module 320 installed on the outer surface and inserted into the pillar module 210. An insertion hole 3010 is formed at the center of the hub module 310 and inserted into the pillar module 210 . And a plurality of wing rod modules 320 are installed on the outer surface. At this time, wing rod modules 320 are installed on the side of the hub module 310 in the number of powers of 2. For example, as shown in FIG. 4, the rotor blade unit 30 includes four wing rod modules on the side of the hub module 310, that is, the first wing rod module 321, the second wing rod module 322, The third wing rod module 323 and the fourth wing rod module 324 may be installed. A switch wire module 330 is installed on one side, that is, the lower side of the wing rod module 320.

The switch line module 330 may be formed of a first switch line module 331 , a second switch line module 332 , a third switch line module 333 , and a fourth switch line module 334 . It can be installed on the lower side of the first switch line module 331 to the fourth switch line module 334 and at 1/2 of the width of the wing rod module.

3 and 4, the first switch line module 321 is installed on the lower side of the first wing rod module 321, and the second switch wire is installed on the lower side of the second wing rod module 322. Module 322 is installed. And, the third switch line module 323 is installed on the lower side of the first wing rod module 323, and the fourth switch line module 324 is installed on the lower side of the fourth wing rod module 324. The first switch wire module 331 to the fourth switch wire module 334 have one end connected to the first electrode plate module 120 according to the rotation of the first wing rod module 321 to the fourth wing rod module 324. ) is contacted or non-contacted, that is, separated, and the other end is always in contact with the second electrode plate module 220. In the meantime, the switch wire module 330 has one end in contact or non-contact with the first electrode plate module 120 while the other end is connected to the second electrode plate module 220, and the current applied from the DC supply device C is applied to the coil. A path flowing through the ring channel unit 50 is shorted or opened.

The magnet module 340 is fixed to the outside of the wing bar module 320 and forms a magnetic field. At this time, as shown in FIG. 5, the magnet module 340 is formed of a first magnet having a first polarity (S pole) on one side and a second polarity (N pole) opposite to the first polarity on the other side. can For example, the magnet module 340 is formed in a rectangular parallelepiped having a width of 6 cm, a length of 12 cm, and a height of 3 cm. In addition, the magnet module 340 may be formed in a structure in which the first magnet and the second magnet having the same size as the first magnet are connected. The magnet module 340 may be formed of a magnet having a first polarity on one side and a second polarity on the other side even when two magnets are attached by attraction.

The magnet module 340 may be accommodated in the accommodation space 500 of the coiling channel unit 50 having a second polarity (N pole) opposite to the first polarity (S pole) on the inner circumferential surface. When the magnet module 340 is located in the accommodating space 500 of the coiling channel unit 50, it can be rotated by magnetic force lines of magnetic force formed in the coiling channel unit 50.

Such a magnet module 340 may be a first magnet module 341, a second magnet module 342, a third magnet module 343 and a fourth magnet module 344 installed in each wing bar module. . At this time, as shown in FIG. 4, the first magnet module 341 is installed on one end of the first wing rod module 321 and the second magnet module 342 is installed on one end of the second wing rod module 322. installed And the third magnet module 343 is installed on one end of the third wing rod module 323 and the fourth magnet module 344 is installed on one end of the fourth wing rod module 324.

As shown in FIG. 6, the rotor blades 30, 30-1, and 30-2 having such a structure may be formed in a small size (a), a medium size (b), and a large size (c). . That is, the rotary blades 30, 30-1, and 30-2 may be formed by being deformed in various sizes. In addition, as shown in (a) of FIG. 7, the rotor blades may be formed by transforming the number of blade rod modules 320 into two rotor blades 30-3. Alternatively, as shown in (b) of FIG. 7, the number of wing rod modules 320 may be formed by being transformed into four rotor blades 30-4. Alternatively, as shown in (c) of FIG. 7, the number of wing rod modules 320 may be formed by being transformed into eight rotary blades 30-5. In addition, the number of wing rod modules 320 can be increased to 2, 4, 8, 16, 32, 64, and 128 in square form of 2.

The second washer module 252 of the washer unit 25 is inserted between the rotary blade unit 30 and the wing separation prevention unit 40 . The second washer module 252 is inserted into the pillar module 210, one side is in contact with the rotor blades 30 and the other side is in contact with the blade separation prevention unit 40 so that the rotor blades 30 are not worn when they rotate. do.

The blade detachment prevention unit 40 prevents the rotor blade portion 30 from being separated from the pillar portion 20 when the rotor blade portion 30 rotates. The wing separation prevention unit 40 has an overlapping hole 400 formed in the center and is inserted into the pillar module 210, and a part is fixed to the hub module 310 or the wing rod module 320.

In the coiling channel unit 50, an accommodation space 500 is formed inside by winding the first to third coil wires having a cross-sectional diameter of 1 mm to 1.2 mm more than 55 times, and the cross section is 'U' or 'c'. It can be formed into a 'shaped structure. For example, as shown in FIG. 8, the coiling channel unit 50 has a structure in which a first wall surface bent by 15 cm to one side of the forehead surface and a second wall surface bent by 15 cm to the other side of the forehead surface are formed when the interval is 6 cm. can be formed as As shown in (a) of FIG. 9, the coiling channel unit 50 is formed in a size in which the length of the forehead surface is 20 cm and the length of the first and second wall surfaces is 15 cm, or in (b) of FIG. As shown in, the length of the forehead surface may be 30 cm, and the length of the first wall surface and the second wall surface may be formed in a size of 15 cm. And, as shown in (c) of FIG. 9, the length of the forehead surface may be 40 cm, and the length of the first wall surface and the second wall surface may be formed in a size of 15 cm. In this way, the coiling channel portion 50 of various sizes may be used according to the adjustment of the intensity of the magnetic force line formed with the magnet module 340 . For example, when it is necessary to form a relatively large magnetic force with the magnet module 340, the coiling channel portion having the same structure as in FIG. 9 (c) is used, and when a relatively small magnetic force is to be formed, FIG. ) The coiling channel unit having the same structure may be used.

When the current F is applied from the DC supply device C, the coiling channel unit 50 forms a magnetic field in a direction perpendicular to the moving direction of the current. In addition, lines of magnetic force are generated along the direction in which the magnetic field is formed. At this time, when a magnetic field is formed in the coiling channel portion 50, the second polarity is applied to the inside of the coiling channel portion 50 and the first polarity is applied to the outside, so that the magnetic field is in the direction in which the current (F) moves and may be formed in a direction perpendicular to. In addition, the lines of magnetic force may be formed in a direction from the outside to the inside. Alternatively, when a magnetic field is formed in the coiling channel portion 50, the first polarity is on the inside of the coiling channel portion 50 and the second polarity is on the outside, so that the magnetic field is It can be formed in a vertical direction.

On the other hand, the coiling channel unit 50 does not form a magnetic field unless current is applied from the DC supply device C.

The coiling channel unit 50 includes a first input terminal line 501 connected to the first electrode plate 120 and a second input terminal line 502 connected to the second polar terminal E of the DC supply device C. It can be formed as a structure containing. The coiling channel unit 50 forms a first polarity and attraction of the magnet module 340 located inside the accommodation space 500 and forms a second polarity and repulsive force of the magnet module 340, and the rotary blade unit 30 ) is rotated in the direction in which the attractive force is formed. Here, the coiling channel unit 50 may be formed in an even number greater than the number of wing rod modules 320. For example, when the number of wing rod modules 320 is 4, the number of coiling channel units 50 may be 8. That is, the coiling channel unit 50 may be formed of the first coiling channel unit 51 to the eighth coiling channel unit 58 .

The coiling channel unit 50 and the magnet module 340 quickly form attractive and repulsive forces.

Hereinafter, with reference to FIGS. 10 to 31, the operation of the rotational power device of the present invention will be described in detail.

10 is a view showing a state in which the rotor blades are located in the receiving space of the coiling channel portion of FIG. 9, and FIG. 11 is a current flowing through the coiling channel portion viewed from above in FIG. 12 is a diagram showing a magnetic field formed in response to a flowing current, and FIG. 12 is an attraction between one side of the coiling channel portion and the first polarity of the magnet module, and a repulsive force between the other side of the coiling channel portion and the second polarity of the magnet module. This is a view showing a state in which the rotor blades are rotated toward the formed attraction. 13 and 14 are diagrams showing a state in which a magnetic field is formed in the coiling channel part and the rotor blades are rotated by inertial force, attractive force, and repulsive force, and FIGS. 15 to 31 are rotation according to an embodiment of the present invention. It is a diagram showing the operating state of the power unit.

As shown in FIG. 10, in the rotor blade unit 30, one end of the magnet module 340 in the receiving space 500 of the coiling channel unit 50 is the end of the first wall surface or the second wall surface of the coiling channel unit 50. It can be positioned so as to keep a distance of about 3 cm from. At this time, the separation distance may be a free space to prevent being caught on the first wall surface and the second wall surface of the coiling channel unit 50 when the rotary blade unit 30 rotates. In addition, the rotary wing unit 30 may be located at the central point of the forehead surface height and rotated.

As shown in FIG. 11, when a current F flows through the coiling channel portion 50, a magnetic field is formed in a direction perpendicular to the direction in which the current flows according to Fleming's left-hand rule. For example, when a current flows in the coiling channel portion 50 in a clockwise direction, a magnetic field may be formed in a direction perpendicular to the flowing current, and when a current flows in the coiling channel portion 50 in a counterclockwise direction, a magnetic field may be formed perpendicular to the flowing current. A magnetic field can be formed in one direction. Lines of magnetic force are formed corresponding to the direction of the magnetic field thus formed.

As shown in FIG. 12 in the accommodating space 500 of the coiling channel unit 50 that forms such a magnetic field, when the rotary blade unit 30 is located, one side of the coiling channel unit 50 is a coil. An attractive force is formed between the inner side of one side of the ring channel portion 50 (the inner side of the left side) and the first polarity (S pole) of the magnet module, and the other side of the coiling channel portion 50 is coiled. A repulsive force is formed between the inner side of the other side surface of the channel unit 50 (the inner side of the right side) and the second polarity (N pole) of the magnet module. In this way, the rotary blade unit 30 naturally rotates in the direction in which the attractive force is formed while pulling in the direction in which the attractive force is formed and pushing in the direction in which the repulsive force is formed. More specifically, the rotational power unit 1 is connected to the DC supply unit (C) and operated through the DC current output from the DC supply unit (C). As an example, as shown in (a) of FIG. 13, in the rotary power device 1, the second electrode plate module 220 of the pillar portion 20 connects to the first polarity of the DC supply device C through a wire. It is connected to the terminal (D) and the coiling channel unit 50 is connected to the second polarity terminal (E) of the DC supply device (C) through the second input terminal line 502 to generate current from the DC supply device (C). It is applied so that an electric field can be formed. As shown in (b) of FIG. 13, the current output from the DC supply device (C) is transmitted from the first polarity terminal (D) to the switch of the second electrode plate module 220 of the column part and the rotary blade part 30. It flows through the path of the first input terminal line (D) and the second input terminal line (E) of the wire module 330, the first electrode plate 120, and the coiling channel unit 50. At this time, the current (F) flows to the second input terminal line (E) through the first input terminal line (D) and forms a magnetic field in the coiling channel portion (50). At this time, the N polarity may be formed on the inside of one side and the inside of the other side of the coiling channel unit 50, and the S polarity may be formed on the outside of one side and the outside of the other side. Alternatively, the S polarity may be formed on the inside of one side and the inside of the other side of the coiling channel unit 50, and the N polarity may be formed on the outside of one side and the outside of the other side.

When the magnetic module 340 of the rotor blade unit 30 is accommodated in the coiling channel unit 50 having such a polarity, the magnetic force line G of the coiling channel unit 50 is the magnetic module 340. The magnet module 340 is pulled while forming an attractive force with one side, and the magnet module 340 is pushed while forming a repulsive force with the other end of the magnet module 340 . In the meantime, as shown in (c) of FIG. 13, the rotary blade 30 rotates counterclockwise. At this time, the rotary blade unit 30 is rotated by the magnetic force line (G) of the magnetic field formed in the coiling channel unit 50, and the switch wire module 330 of the rotary blade unit 30 rotates the first electrode plate module 120 ) and non-contact, that is, it can be separated. At this time, as the movement path of the current output from the DC supply device (C) is cut off, the magnetic field and lines of magnetic force disappear from the coiling channel unit 50 as shown in (c) of FIG. 13 . However, even if the magnetic field disappears from the coiling channel unit 50, the rotating blade unit 30 continues to rotate while maintaining its rotation state due to inertial force, as shown in FIG. 14(a). At the same time, the rotary blade unit 30 moves from one electrode plate to another electrode plate. For example, the rotor blade unit 30 moves from the seventh electrode plate 127 to the eighth electrode plate 128 by inertial force. Again, when the switch wire module 330 contacts the eighth electrode plate 128, as shown in (b) of FIG. A magnetic field is formed in the coiling channel portion 58, and through the repulsive force and attractive force between the eighth coiling channel portion 50 and the magnet module 340 formed by the magnetic force lines of the magnetic field, will rotate clockwise.

When current is output from the DC supply device (C), the rotary blade unit 30 rotates by receiving attractive and repulsive forces from the coiling channel unit 50, and when current is not output from the DC supply device (C), it rotates itself. It rotates by the inertial force of and continuously rotates. That is, the rotary blade unit 30 repeatedly receives attractive and repulsive forces and rotates through inertial forces that are repeatedly generated.

More specifically, as shown in FIG. 15, in the rotary power unit 1, the first magnet module 341 of the rotary blade unit 30 is accommodated at the midpoint of the first coiling channel unit 51, and the first coil unit 341 is accommodated. The second magnet module 342 of the rotary blade unit 30 is accommodated at the midpoint of the third coiling channel unit 53, and the second magnet module 342 of the rotor blade unit 30 is accommodated at the midpoint of the fifth coiling channel unit 55. Current is applied from the DC supply device (C) in a state where the third magnet module 343 is accommodated and the fourth magnet module 344 of the rotor blade unit 30 is accommodated at the midpoint of the seventh coiling channel unit 57. then it can work. As shown in FIG. 15, the first switch line module 331 of the rotary power device 1 is in contact with the first electrode plate 121, and the second switch line module 332 is in contact with the third electrode plate 123. ), the third switch line module 333 may contact the fifth electrode plate 125, and the fourth switch line module 334 may contact the seventh electrode plate 127. At this time, a magnetic field is formed in the first coiling channel unit 51, the third coiling channel unit 53, the fifth coiling channel unit 55, and the seventh coiling channel unit 57. At this time, the lines of magnetic force G of the first coiling channel portion 51 form attractive and repulsive forces with the first magnet module 341, and the second coiling channel portion 52 forms the first wing rod module 321. rotate in the direction it is located. In addition, the magnetic field lines of the third coiling channel unit 53 form attractive and repulsive forces on the second magnet module 342 and move the second wing rod module 322 in the direction where the fourth coiling channel unit 54 is located. let it In addition, the line of magnetic force of the fifth coiling channel unit 55 forms attractive and repulsive forces with the third magnet module 343 and moves the third wing rod module 323 in the direction where the sixth coiling channel unit 56 is located. let it In addition, the line of magnetic force of the seventh coiling channel unit 57 forms attractive and repulsive forces with the fourth magnet module 344, and the fourth wing rod module 324 moves in the direction where the eighth coiling channel unit 58 is located. Let it be. That is, the rotational power device 1 rotates the first wing rod module 321 to the fourth wing rod module 324.

In addition, as shown in FIG. 16, when the first wing rod module 321 to the fourth wing rod module 324 rotate, the first switch line module 331 to the fourth switch line module 324 Separated from the first electrode plate 121, the third electrode plate 123, the fifth electrode plate 125, and the seventh electrode plate 127, the first coiling channel portion 51 and the third coiling channel portion ( 53), the magnetic fields formed in the fifth coiling channel unit 55 and the seventh coiling channel unit 57 disappear. At this time, the first wing rod module 321 to the fourth wing rod module 324 include the first coiling channel unit 51, the third coiling channel unit 53, the fifth coiling channel unit 55, and Even if the magnetic field disappears in the seventh coiling channel unit 57, as shown in FIG. 16, the first wing rod module 51 to the fourth wing rod module 54 are rotated by the centrifugal force and the second electrode plate The first switch line module 331 is in contact with (112), the second switch line module 332 is in contact with the fourth electrode plate 124, and the third switch line module 333 is in contact with the sixth electrode plate 126. As a result of this contact, the fourth switch wire module 334 may come into contact with the eighth electrode plate 128 . In addition, when a magnetic field is formed in the second coiling channel unit 52, the fourth coiling channel unit 54, the sixth coiling channel unit 56, and the eighth coiling channel unit 58, it is shown in FIG. As described above, the second coiling channel portion 52 forms attractive and repulsive forces with the first magnet module 341 accommodated therein, and the third coiling channel portion 53 forms the first wing rod module 321. The fourth coiling channel unit 54 forms an attraction and a repulsive force with the second magnet module 342 accommodated therein, and the second wing rod module 322 is the fifth coiling channel unit ( 55) is moved in the direction where it is located. In addition, the sixth coiling channel unit 56 forms attractive and repulsive forces with the third magnet module 343 accommodated therein, and moves the third wing rod module 323 in the direction where the seventh coiling channel unit 57 is located. make it move In addition, the eighth coiling channel unit 58 forms attractive and repulsive forces with the fourth magnet module 344 accommodated therein, and moves the second wing rod module 322 in the direction where the fifth coiling channel unit 55 is located. make it move And again, as shown in FIG. 18, the magnetic field in the second coiling channel unit 52, the fourth coiling channel unit 54, the sixth coiling channel unit 56, and the eighth coiling channel unit 58 When disappears, the first wing rod module 321 to the fourth wing rod module 324 are maintained in a rotating state by centrifugal force, and as shown in FIG. ), the second switch line module 332 contacts the fifth electrode plate 125, the third switch line module 333 contacts the seventh electrode plate 127, and the fourth switch line module 334 The silver may come into contact with the first electrode plate 121 .

In this way, in the rotary power device 1, when one end of the plurality of switch wire modules 330 is in contact with the first electrode plate module 120, some of the coiling channel portion 50 The magnetic force line of the magnetic field formed in pulls one side of the magnet module 340 and pushes the other side of the magnet module 340 to rotate the wing rod module 320 counterclockwise. On the other hand, in the rotary power device 1, when one end of the switch wire module 330 is separated from the first electrode plate module 120, the wing rod module 320 rotates with manpower and repulsion, that is, moves by inertia. do. In addition, the wing rod module 320 rotating by inertial force allows one end of the switch wire module 330 to come into contact with the first electrode plate module 120 and rotates by the magnetic force lines of the magnetic field formed in the coiling channel part 50. Let it be.

In other words, as shown in FIGS. 15 to 31, the rotary power device 1 is formed when the attractive force and repulsive force formed between the rotary blade unit 30 and the coiling channel unit 50 and the applied attractive and repulsive force disappear. Rotate the rotary blades 30 through the inertial force. Such a rotary power device 1 can quickly rotate the rotary wing unit 30.

Moreover, the rotary power unit 1 may increase in overall size as the number of wing rod modules of the rotor blade unit and the number of coiling channel units increase and the length of the wing rod module increases.

Although the embodiments of the present invention have been described with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can be implemented in other specific forms without changing the technical spirit or essential features of the present invention. you will be able to understand Therefore, it should be understood that the embodiments described above are illustrative in all respects and not restrictive.

1: Rotation power unit
10: support plate
110: support plate module 1100: connection groove
120: first electrode plate module
121: first electrode plate 122: second electrode plate
123: third electrode plate 124: fourth electrode plate
125: fifth electrode plate 126: sixth electrode plate
127: 7th electrode plate 128: 8th electrode plate
20: column part
210: pillar module 220: second electrode plate module
25: washer part
251: first washer module 252: second washer module
30,30-1,30-2: Rotating blades
310: hub module 3010: insertion hole
320: wing bar module
321: first wing rod module 322: second wing rod module
323: third wing rod module 324: fourth wing rod module
330: switch line module
331: first switch line module 332: second switch line module
333: third switch line module 324: fourth switch line module
340: magnet module
341: first magnet module 342: second magnet module
343: third magnet module 344: fourth magnet module
3401: first magnet 3402: second magnet
40: wing separation prevention unit 400: overlapping hole
50: coiling channel unit
51: first coiling channel unit 52: second coiling channel unit
53: third coiling channel unit 54: fourth coiling channel unit
55: fifth coiling channel unit 56: sixth coiling channel unit
57: 7th coiling channel unit 58: 8th coiling channel unit
500: accommodation space
501: first input terminal line 502: second input terminal line
A: base plate B: connecting member
C: DC supply device D: 1st polarity terminal
E: Second polarity terminal F: Current
G: lines of magnetic force

Claims (5)

Includes a support plate module 110 having a connection groove 1100 formed in the center and fixed to the base plate A, and a first electrode module 120 installed at a distance around the connection groove 1100 on the upper side of the support plate module. a support plate portion 10;
A connection groove 1100 including a pillar module 210 formed in a cylindrical shape and a second electrode plate module 220 installed on the outer circumferential surface of the pillar module and connected to the first polar terminal D of the external DC supply device C. ) The pillar part 20 to which one end of the pillar module 210 is fixed;
The hub module 310 having an insertion hole 3010 formed in the center and inserted into the pillar module 210, the wing rod module 320 installed on the side of the hub module 310, and one side of the wing rod module 320 A switch wire module 330 installed in the wing bar module 320, one end of which contacts and does not contact the first electrode plate module 120 and the other end always contacts the second electrode plate module 220, and the wing Rotating blades 30 including a magnet module 340 fixed to the outside of the rod module 320 and forming a magnetic field;
An overlapping hole 400 is formed in the center and inserted into the pillar module 210, and a part of the wing separation prevention unit 40 fixed to some of the hub module 310 and the wing rod module 320; and
The first input terminal line 501 formed in a structure in which a coil wire is wound so that an accommodation space 500 is formed therein and connected to the first electrode plate 120 at one side, and the second input terminal line 501 of the DC supply device C located outside Including the second input terminal line 502 connected to the polar terminal E, the number of even times greater than the number of wing rod modules 320 is installed on the outside of the support plate module 110, and the first input terminal line 501 and a coiling channel portion 50 that forms a magnetic field in response to the flowing current when current flows through the second input terminal line 502. The method of claim 1, wherein the coiling channel unit 50,
When a magnetic field is formed, a first polarity is formed inside the accommodation space and a second polarity opposite to the first polarity is formed outside the accommodation space,
The first polarity and attraction of the magnet module 340 located inside the accommodation space 500 are formed, and the second polarity and repulsive force of the magnet module 340 are formed, and the rotary blades 30 are moved in the direction in which the attraction is formed. To rotate, the rotational power unit (1). The method of claim 1, wherein the coiling channel unit 50,
When one end of the switch wire module 330 is in contact with the first electrode plate module 120, a magnetic field is formed, pulling the magnet module 340 from one side, and pushing the magnet module 340 from the other side to the wing rod module. A rotational power device (1) that rotates (320) from the other side to one side. The method of claim 3, wherein the wing rod module 320,
When one end of the switch wire module 330 is separated from the first electrode plate module 120,
As the magnetic field formed in the coiling channel unit 50 disappears,
A rotational power device (1) that rotates and moves by inertia when rotated by lines of magnetic force formed in the coiling channel portion (50). According to claim 1,
A first washer module 251 inserted into the pillar module 210 and having one surface in contact with the support plate part 10 and the other surface in contact with the rotary blade part 30;
A rotary power device including a washer unit 25 inserted into the pillar module 210 and including a second washer module 252 having one side in contact with the hub module 310 and the other side in contact with the wing departure prevention unit 40 (One).