KR20220076446A - Electric power generator - Google Patents

Abstract

In summary, the present invention is an electric generator. In summary, a cylindrical second stator and a second cylindrical stator composed of permanent magnets having the same polarity or different polarities, respectively, on the inner and outer surfaces of the first cylindrical stator wound with coils installed on a fixed plate. 3 After forming a stator and forming a first rotor and a second rotor each having an opening with one side open between the first stator and the second stator and between the first stator and the third stator, Induction occurring between the coils of the first stator and the magnets of the second stator and the coils of the first stator and the magnets of the third stator through the opening by rotation of the first and second rotors By generating electricity by electromotive force, it is possible to generate electricity by rotation in the first and second rotors using a small amount of electric power, improve the efficiency of power production, and reduce the high-speed rotation of the rotor. Generator capable of reducing noise generated during power generation.

Description

Electric power generator

The present invention relates to an electric generator, and in particular, a cylindrical second stator and a third cylindrical stator composed of permanent magnets of different polarities on the inner and outer surfaces of a first cylindrical stator in which a coil installed on a fixed plate is wound, and one side is open. After forming a first rotor and a second rotor including openings formed between the first stator and the second stator and between the first stator and the third stator, respectively, the first rotor and the second rotor In an electric generator generating electricity by induced electromotive force generated between the coil of the first stator and the magnet of the second stator through the opening by rotation of the first stator and the magnet of the third stator it's about

In recent years, it can be seen that the number of countries that produce electricity with solar and wind power, which generate electricity from nature, is increasing. This can be said to be a problem, Korean registered patent; 10-2221312. (2019. 12.27.) registration is posted, so the present invention uses less energy to generate electricity using less carbon dioxide by developing an electric generator It relates to an electric generator that can help the global environment by being generated.

In the present invention, the background is in the form of a disk, and the disk made of a permanent magnet, which is empty in a circular shape in the middle, is configured to have N and S polarities at both ends with the center as the center, so that the disks are opposite to each other and the opposite polarities are overlapped with each other and a coil between them The first stator core 130, which is an electric board, is formed by overlapping it in a configuration to be wound, and it is connected to the center of the fixed plate 110 to the inside, and the second stator induction magnet plate 140 is formed. On the outer side, the third stator induction magnet plate 150 is constituted to rotate on the opposite side, and the rotating plate 120 is constituted to the inner side, the first rotor 160 is installed. And to the outside, the first rotor 160 is located between the first stator core 130 and the second stator 140 installed on the fixing plate by configuring the second rotor 170 . , The second rotor 170 is positioned between the first stator core 130 and the third stator induction magnet plate 150, so that the first rotor and the second rotor are partially open In principle, the first rotor 160 rotates between the first stator core 130 and the second stator induction magnet plate 140 to generate electricity while rotating through the opening, and the second stator induction Where the permanent magnet N polarity and S polarity of the magnet plate 140 can be made, the first stator core 130 is composed of S polarity and N polarity or N polarity and S polarity, and magnetic force on the wound coil of the permanent magnet plate overlapping one another This induction can produce electricity.

While the second rotor 170 rotates, the third stator 150 has a permanent magnet S polarity and or N polarity, and the first stator has an N polarity and an S polarity of the permanent magnet plate 130 or This is a description of the background technology that can produce electricity by induced magnetic force in the coil wound between the permanent magnet plates overlapping the S polarity and the N polarity.

In the present invention, in order to generate electricity with low power, the problem is solved when it is connected to some external power to generate electricity. To configure a coil wound on a permanent magnet plate configured to be sutured, and to have N polarity and S polarity of the second stator induction magnet plate 140 in a cylindrical shape composed of permanent magnets on the inner and outer surfaces thereof, and Where the third stator induction magnet plate 150 has a configuration that can also be S polarity or N polarity, the first rotor 160 having an open opening on one side for rotation therebetween, and the constituting the second rotor 170 , between the first stator core 130 and the second stator induction magnet plate 140 , the first stator core 130 , and the third stator induction After forming between the magnet plates 150, the first rotor 160 and the second rotor 170 through the opening by the rotation, the coil in the first stator core 130, An electric generator for generating electricity by induced electromotive force generated between the magnet of the second stator induction (140), the coil of the first stator core (130), and the magnet of the third stator induction magnet plate (150) is doing

In order to solve the problem in (100) in the present invention, the body 101 made of a non-ferrous metal, which is a non-conductive metal in a cylindrical shape, can be configured as a cylindrically hollow tunnel, and both ends of the cylindrical shape are open, as shown in the example of FIG. On the left side of the main body 101, a fixing plate 110 composed of a non-conductive disk shape can be fixed by the frame on the left side of the main body, and thereby can be closed. On the right side of the main body 101, a rotating plate 120 may be installed, as in the example of FIG. 1, and thereby the right side of the main body may be closed. As in the bogie of FIG. The rotating shaft 122 of the rotating plate is connected to the fixed plate shaft 112, and the screw portion 114, which is the end of the fixed shaft 112, enters into the 123, which is the end of the rotating shaft 122, and the fixed shaft 112. A bearing (not shown) fitted in advance to the first bearing abutting portion 111 and the first bearing frame of the end 123 of the rotary shaft 122 and fixed shaft 112 by going deep inside through the outside of ), the bearing contact portion 113 at the end of the rotation plate 120 and the rotation shaft 122 meets the second bearing frame 121 in the vicinity of the connection, and can be fitted by a bearing (not shown). , As a result, the rotating shaft 122 can rotate by a bearing (not shown) that enters the first bearing frame 123 and the second bearing frame 121 .

In order to solve the problem in (100) in the present invention, the body 101 made of a non-ferrous metal, which is a non-conductive metal in a cylindrical shape, can be configured as a cylindrically hollow tunnel, and both ends of the cylindrical shape are open, as shown in the example of FIG. On the left side of the main body 101, a fixing plate 110 composed of a non-conductive disk shape can be fixed by the frame on the left side of the main body, and thereby can be closed. On the right side of the main body 101, a rotating plate 120 may be installed as shown in the example of FIG. 1, and thereby the right side of the main body may be closed. is connected to the fixed plate shaft 112, the screw portion 114, which is the end of the fixed shaft 112, goes into the 123, which is the end of the rotating shaft 122, and goes deep inside through the outside of the fixed shaft 112. A bearing (not shown) fitted in advance to the first bearing contact portion 111 and a bearing contact portion at the end of the fixed shaft 112 fitted into the first bearing frame of the end 123 of the rotating shaft 122 and 113 may be fitted by a bearing (not shown) against a second bearing frame 121 adjacent to the rotary plate 120 and connected to the rotary shaft 122, whereby the rotary shaft 122 is The first bearing frame 123 and the second bearing frame 121 can rotate by a bearing (not shown).

In order to solve the problem in (100) in the present invention, the body 101 made of a non-ferrous metal, which is a non-conductive metal in a cylindrical shape, can be configured as a cylindrically hollow tunnel, and both ends of the cylindrical shape are open, as shown in the example of FIG. On the left side of the main body 101, a fixing plate 110 composed of a non-conductive disk shape can be fixed by the frame on the left side of the main body, and thereby can be closed. On the right side of the main body 101, a rotating plate 120 may be installed as shown in the example of FIG. 1, and thereby the right side of the main body may be closed. is connected to the fixed plate shaft 112, the screw portion 114, which is the end of the fixed shaft 112, goes into the 123, which is the end of the rotating shaft 122, and goes deep inside through the outside of the fixed shaft 112. A bearing (not shown) fitted in advance to the first bearing contact portion 111 and a bearing contact portion at the end of the fixed shaft 112 fitted into the first bearing frame of the end 123 of the rotating shaft 122 and 113 may be fitted by a bearing (not shown) against a second bearing frame 121 adjacent to the rotary plate 120 and connected to the rotary shaft 122, whereby the rotary shaft 122 is The first bearing frame 123 and the second bearing frame 121 can rotate by a bearing (not shown).

The first stator core 130 is spaced apart from each other to form a rotating plate 120 configured to oppose each other, so that the first rotor 160 can be connected to the center and the second rotor 170 is connected to the outside. Configurable, the first rotor 160 may be formed between the first stator core 130 and the second stator induction magnet plate 140 and may include an open one side, the second rotor 170 ) may be configured between the first stator core 130 and the third stator induction magnet plate 150, and one side of the first rotor 160 is open to the opening 161 and the other side of the second rotor. An electric generator that may include an opening 171 with one side of the 170 open.

As an example related to the present invention, the first stator may include: the first core configured in a cylindrical shape with both ends open; The first core is radially arranged at regular intervals along the inner circumferential surface where the permanent magnet S pole and the N pole, the N pole and the S pole are formed with the fixed plate toward the inner side, and the permanent magnet N pole formed in the second stator and Correspondingly, on the magnet plate in which the permanent magnet S pole and the N pole of the inner surface of the first core and the N pole and the S pole are overlapped, the second fixed induction permanent magnet is radiated to the N pole or S pole, and the first core The magnet plate is arranged radially at regular intervals along the outer circumferential surface, and in which the permanent magnet S pole and N pole, N pole and S pole of the first core are formed to correspond to the S pole or N of the permanent magnet formed in the third stator. The third fixed permanent magnet S pole or N may include an outer permanent magnet plate S pole or N pole in which a coil for generating electric power by induced electromotive force is disposed.

A first bearing contact portion fixed to the center of the other surface of the fixing plate as an example related to the present invention; a first bearing formed on an outer circumferential surface of the first bearing contact portion; a fixed shaft having one end connected to the other end of the first bearing contact part; and a connecting shaft having one end connected to the other end of the fixed shaft.

A through hole formed in the center of the rotating plate as an example related to the present invention; a rotating shaft formed at one end of a first bearing frame fixed to an outer region of the through hole; a second bearing frame formed at one end of the rotation shaft; a belt unit for rotating the rotating plate; a belt connecting shaft for connecting the belt unit and the rotating plate; It further includes a first support member for connecting the other surface of the belt portion to a first support, wherein the first bearing frame and the second bearing frame have a donut shape with an open center, and the rotating shaft includes the fixed shaft and The inside may be empty so that the connecting shaft can be inserted therethrough.

As an example related to the present invention, the first rotor may include: a first rotational core formed of a cylindrical non-conductive metal having both ends open; and a first opening in which a side surface of the first rotational core is partially opened, and power is generated by an induced electromotive force between the first stator and the second stator through the first opening according to the rotation of the first rotor. This can be produced.

As an example related to the present invention, the second rotor may include a second rotating core formed of a cylindrical non-conductive metal having both ends open; and a second opening in which a part of a side surface of the second rotating core is opened, and electric power is generated by an induced electromotive force between the first stator and the third stator through the second opening according to the rotation of the second rotor. This can be produced.

As an example related to the present invention, the first rotor is located outside the second stator, the first stator is located outside the first rotor, and the second rotor is located outside the first stator , outside of the second rotor, the third stator is located, is formed outside the third stator, one end is closed by the fixing plate, the other end is closed by the rotating plate housing body; a second support configured to support the housing body by being connected to the other surface of the rotating plate formed at the other end of the housing body; a belt portion formed on one side of the first support to rotate the rotating plate; and a first support configured to support the housing body by being connected to one surface of the fixing plate formed at one end of the housing body.

In the present invention, as an electric generator, a cylindrical mechanical plate of the first stator 130 is configured on a stationary plate 110, and a cylindrical mechanical induction magnet plate of the second stator 140 is configured toward the inside thereof, and the first stator ( 130) has a cylindrical shape on the third stator 150 and is spaced apart in the longitudinal direction of one end of the fixed plate 110 to oppose each other on the opposite side. , The first rotor 160 is installed in a cylindrical shape toward the fixing plate, but is located between the first stator 130 and the second stator 140, and the second rotor 170 is the first stator 130. It is located between the task 3 stator (150).

The N polarity of the wound coil and the second stator 140 between the first stator 130 and the second stator 140 overlapping each other with different polarities through a part of an open opening on one side of the cylindrical shape of the first rotor 160 Alternatively, an induction current is generated in the coil between the magnets generating attractive and repulsive forces between the S-polar induction magnet plate and the overlapping magnets of the first stator 130, and electricity is generated in the cylindrical shape of the second rotor 170. Induction between the S-polarity or N-polarity magnets of the coil and the third stator 150 between the magnets generating attractive and repulsive force between the overlapping magnets of the first stator 130 through an opening partly opened on one side. Electricity can be generated by generating an electric current, so it has the advantage of being able to produce electricity with low-capacity energy.

1 is a side view of an electric generator according to an embodiment of the present invention.
2 is a cross-sectional view constituting a relationship between a stator plate shaft and a rotor shaft according to an embodiment of the present invention.
3 is a cross-sectional view showing the configuration of the first stator according to the embodiment of the present invention.
4 is a view showing the configuration of a first stator and a second stator according to an embodiment of the present invention.
5 is a diagram showing the configured relationship of the first rotor and the second rotor according to the embodiment of the present invention.
6 is a view cited in a further embodiment of the present invention.

It should be noted that the technical terms used in the present invention are only used to describe specific embodiments, and are not intended to limit the present invention. In addition, the technical terms used in the present invention should be interpreted as meanings generally understood by those of ordinary skill in the art to which the present invention belongs, unless otherwise defined in particular in the present invention, and excessively inclusive It should not be construed as the meaning of "in" or in an excessively reduced meaning. In addition, when a technical term used in the present invention is used, it should be understood by being replaced with a technical term that can be correctly understood by those skilled in the art. In addition, general terms used in the present invention should be interpreted as defined in advance or according to the context before and after, and should not be interpreted in an excessively reduced meaning.

Also, the singular expression used in the present invention includes the plural expression unless the context clearly dictates otherwise. In the present invention, terms such as “consisting of” or “comprising” should not be construed as necessarily including all of the various components or various steps described in the invention, and some of the components or some steps may not be included. It should be construed that it may further include additional components or steps.

In addition, terms including ordinal numbers such as 1st, 2nd, etc. used in the present invention may be used to describe the components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

Hereinafter, a preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings, but the same or similar components are assigned the same reference numerals regardless of reference numerals, and redundant description thereof will be omitted.

In addition, in the description of the present invention, if it is determined that a detailed description of a related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted. In addition, it should be noted that the accompanying drawings are only for easy understanding of the spirit of the present invention, and should not be construed as limiting the spirit of the present invention by the accompanying drawings.

1 and 5 are diagrams showing the configuration of an electric generator 101 according to an embodiment of the present invention.

1 to 5 , the electric generator 101 is a fixed plate 110 serving as a housing body 100 . Spindle (120). First stator 130 . second stator 140 , third stator 150 . The first rotor 160 is composed of a second rotor 170 . Not all of the components of the electric generator 101 shown in Figs. 1 to 5 are essential, and the electric generator 101 may be implemented by more components than those shown in Figs. , the electrical generator 101 may be implemented with fewer components.

The housing body 100 is made of a cylindrical non-conductive metal.

In addition, the housing body 100 is provided with a volumetric space having a hollow structure so that other components 130 , 140 , 150 , 160 , 170 , can be formed therein.

In addition, the housing body 100 is formed in an open structure at the upper end (or the other end / other surface / left surface) and the lower end (or one / one surface / right surface), and the side is formed in a closed structure.

That is, as shown in FIG. 1 , one end (or right/lower end) and the other end of the housing body 100 in a state in which the housing body 100 is arranged in the horizontal direction (or longitudinal/longitudinal direction). (or the seating surface/upper side) is in an open state, and the fixing plate 110 is fixed to one end of the housing body 100 , and the rotating plate 120 is fixed to the other end of the housing body 100 .

At this time, one end and/or the other end of the housing body 100 includes a first stator 130 fixed to the other surface of the fixing plate 110 in a volume space within the housing body 100 , and one surface of the rotating plate 120 . The first rotor 160 and the second rotor 170 fixed to the After the third stator 150 formed outside is formed, a finished structure in which left and right sides are closed by the fixing plate 110 and the rotating plate 120 may be formed.

In addition, the other end and one end of the housing body 100 are fixed through the first supporter 10 and the second supporter 20 , respectively.

That is, the first support 10 is connected to the other surface of the rotating plate rotating plate 120 formed at the other end of the housing body 100 to support the housing body 100 .

In addition, on one side of the first support 10, a belt part 30 for rotating the rotating plate 120 formed on the other end of the housing body 100 is operated by rotation by an external motor, and the belt part ( 30), the rotating plate 120 rotates clockwise or counterclockwise according to the rotation.

The second support 20 is connected to one surface of the fixing plate 110 formed at one end of the housing body 100 to support the housing body 100 .

The fixing plate 110 is made of a disk-shaped non-conductive metal.

In addition, the fixing plate 110 is fixed to an open area of one surface of the housing body 100 . At this time, the outer diameter of the fixing plate 110 is configured to be equal to or smaller than the inner diameter of one surface of the housing body 100, and the fixing plate 110 is fitted to one surface of the housing body 100 to form a closed structure. have.

As shown in FIG. 2 , one end of the fixing shaft 112 is connected to the center of the other surface of the fixing plate 110 and a first bearing contact part 111 is formed in front of the connected fixing plate 110, and the first A first bearing (not shown) may be configured on the outer peripheral surface of the bearing contact portion 111 (or outside). At this time, as shown in FIG. 2 , one surface of the first bearing contact portion 111 is the fixed shaft (112)), a bearing is connected to the outer surface of the first bearing contact part 111 (not shown), and this is again at the central edge of the rotating plate 120, the rotating shaft 122 is When the second bearing contact part 113, which is the end of the fixed shaft 112, enters the inner hole of the second bearing frame 121, which is the connecting part, a bearing (not shown) is fitted to the outside of the rotating plate and The rotating shaft can be rotated.

In addition, as shown in FIG. 2 , a fixed shaft 112 is formed at the other end of the first bearing contact part 111 in the longitudinal direction.

In addition, the connecting shaft 113 is formed at the other end of the fixed shaft 112 in the longitudinal direction.

At this time, a portion of the other side of the connecting shaft 113 is configured in a spiral shape so that a bolt (not shown) can be coupled thereto.

The first bearing contact portion 111, the fixed shaft 112, and the second bearing contact portion 113 are cut through a milling machine (not shown) with a single cylindrical shaft, and the first bearing contact portion 111 ), the fixed shaft 112 and the second bearing contact portion 113 may be configured to have a smaller outer diameter (or radius) in that order.

Also, as shown in FIG. 2 . A plate hole 124 is formed in the center of the rotating plate 120 , and a second bearing frame 121 fixed to the outer region of the through hole 124 is formed, and at one end of the second bearing frame 121 . A rotation shaft 122 is formed in the longitudinal direction, and a first bearing frame 123 is formed at one end of the rotation shaft 122 in the longitudinal direction. In this case, the second bearing frame 121 and the first bearing frame 123 may have a donut shape with an open center. In addition, the rotating shaft 122 is configured in an empty state so that the fixed shaft 112 and the second bearing contact part 113 can be inserted therethrough.

The rotating plate 120 is made of a disk-shaped non-conductive metal.

In addition, the rotating plate 120 is fixed to the open area of the other surface of the housing body (100). At this time, the outer diameter of the rotating plate 120 is configured to be equal to or smaller than the inner diameter of the other surface of the housing body 100, and the rotating plate 120 is fitted to the other surface of the housing body 100 to form a closed structure. have.

Also, as shown in FIG. 5 . A plate-tong hole 124 is formed in the center of the rotating plate 120 , a first bare frame 121 fixed to an outer region of the through-hole 124 is formed, and one end of the first bearing frame 121 is formed. A rotating shaft 122 is formed in the longitudinal direction, and a second bearing frame 123 is formed at one end of the rotating shaft 122 in the longitudinal direction. In this case, the first bearing frame 121 and the second bearing frame 123 may have a donut shape with an open center. In addition, the rotating shaft 122 is configured in an empty state so that the fixed shaft 112 and the connecting shaft 113 can be inserted therethrough.

In addition, in the fixed plate 110 and the rotating plate 120, the first stator 130, the second stator 140, the third stator 150, the first rotor 160 and After the second rotor 170 is formed, respectively, in order to completely configure the electric generator 101 by the housing body 100, the fixed shaft 112 and the second The bearing contact part 113 is inserted through, the first bearing frame 123 is located on the outer surface of the first bearing (not shown), and the second bearing frame 121 is the second bearing contact part 113 . It is located on the outer surface of the second bearing (not shown) configured on the outer circumferential surface (or outside).

In addition, one end of the second bearing contact portion 113 of the fixed shaft 112 passes through the through hole 124 , toward the rear of the rotating plate 120 , and the screw portion 114 at the end of the fixed shaft 112 passes inward. It comes in and is closed with a washer covering the bearing of (not shown) and can be fixed with a screw, and after that, the connecting member 31 of the second connecting shaft 32 is attached (not shown). It is fixed with a screw, the belt part 30 is formed, and as the belt part 30 is connected to the rotating plate 120 , the rotating plate 120 rotates clockwise or according to the rotation of the belt part 30 . Rotating counterclockwise, according to the rotation of the first rotating plate 160 and the second rotor 170, the first stator 130, the second stator 140 and / or the third stator ( 150) can produce power by induced electromotive force between them.

3 is;

As shown in FIG. 3 , the first stator 130 includes a first stator 130 configured in a cylindrical shape, and the first stator 130 is connected to one surface of the fixing plate 110 and has an inner peripheral surface of the first stator 130 . 2 The inner permanent magnet plate wound on the first stator 130, which generates electric power by induced electromotive force corresponding to the N polarity of the permanent magnet plate formed in the stator 140, is directed toward the second stator into the S pole and the N pole. The four (holes) of the electric board magnet plate 131 through the four (holes) of the electric circuit board connection column 115 of the electric circuit board magnet 131 overlapping the S pole with the N pole and the N with the S pole of the divided magnet plate. ) through the hole, the short bar projections on the back of the electrical board are aligned with (not shown) to the electrical board fixing pin hole 133 through the hole and overlapped with the flaps, and finally covered with the electrical board cover 132 with bolts (not shown). ) can be fixed with bolts, and are radially arranged at regular intervals along the inner circumferential surface of the magnet plate of the cylindrical first stator 130 in which the coil is formed.

The first stator 130 has a first stator 130 configured in a cylindrical shape, and the outer peripheral surface of the first stator 130 corresponds to the N pole or the S polarity of the permanent magnet formed in the third stator 150 . The outer permanent magnet on which the first stator 130, which produces electric power by induced electromotive force, is wound, opposes toward the third stator and is divided into an N pole and an S pole, and the N pole is the S pole and the N pole It can be arranged radially at regular intervals along the outer circumferential surface of the magnet plate of the cylindrical first stator 130 in which a coil is formed by installing a magnet plate overlappingly with an S.

4 is;

The configuration in FIG. 4 is a description of the second stator 140 and the third stator 150, and is connected to the fixing plate 110 shown in FIG. 2, wherein the second stator 140 is the first stator ( 130) as being configured inside the first rotor 160 connected to the inside, it can be installed smaller than the inner diameter of the first rotor 160,

The third stator is configured on the outside of the first stator 130 and configured on the outside of the second rotor 170 connected to the outside of the first stator 130 and the second rotor 170 ) can be configured larger than, the second stator 140 can be configured with an N polarity, and the third stator 150 can be configured with an S polarity.

5 is;

The configuration in FIG. 5 is composed of a first rotor 160 and a second rotor 170 and is connected to the rotation plate 120 as shown in the example shown in FIG. 2 , and the description is as follows.

The first rotor 160 is configured to rotate between the first stator 130 and the second stator 140 connected to the fixed plate 110 including an opening having an open side.

The second rotor 170 is connected to the rotating plate 120 to rotate between the first stator 130 and the third stator 150 and includes an opening with one side open. It can also be configured to

If the configuration is described again below, the S pole and the N pole of the inner permanent magnet electromotive plate including the coil formed in the first stator 130 are overlapped with the N pole and the S pole, and/or the outer permanent magnet is the electric plate with the N In the place where the polarity and the S polarity are made, after overlapping the S polarity and the N polarity, it is configured to induce an induced electromotive force to be generated from the N pole of the permanent magnet formed in the third stator 150, and the first opening ( 161) and the second opening 171 may be formed in the same direction as shown in FIG. 5, or may be formed in different directions (for example, 90 degrees perpendicular to each other and 180 degrees opposite to each other according to the designer's design). It can also be formed as a can, etc.).

In addition, as shown in FIG. 2 , the other surface of the rotating plate 120 is fixed by the first connection member 121 , and the belt part 30 is formed on the other surface of the first connection member 31 . and a first support member 121 for connection with the first support 10 is formed on the other surface of the belt part 30 .

In addition, as shown in FIG. 5 , the first rotor 160 and the second rotor 170 are respectively formed on one surface of the rotation plate 120 . In this case, the outer diameter of the first rotor 160 is formed smaller than the inner diameter of the second rotor 170 .

That is, the first rotor 160 is formed based on the central portion of one surface of the rotation plate 120 , and the second rotor 170 is formed at a distance from the outer peripheral surface of the first rotor 160 . do. In this way, the fixed plate 110 is configured to face the rotating plate 120 . The first stator 130 has a cylindrical shape, and both ends are open.

In addition, as shown in FIG. 2 , a fixed shaft 112 is formed at the other end of the first bearing contact part 111 in the longitudinal direction.

In addition, the connecting shaft 113 is formed at the other end of the fixed shaft 112 in the longitudinal direction.

At this time, a portion of the other side of the connecting shaft 113 is configured in a spiral shape so that a bolt (not shown) can be coupled thereto.

Here, the first bearing contact portion 111 , the fixed shaft 112 and the connecting shaft 113 are cut through a milling machine (not shown) for one cylindrical shaft, and the first bearing contact portion 111 . , the fixed shaft 112 and the connecting shaft 113 may be configured to have a wider outer diameter (or radius) in the order.

Also, as shown in FIG. 4 . A first stator 130 is formed on one side of the other surface of the fixing plate 110 . At this time, one side of the other surface of the fixing plate 110 and the first stator 130 are fixed to the connecting post 114 of the other surface of the fixing plate 110 by four.

The rotating plate 120 is made of a disk-shaped non-conductive metal.

In addition, the rotating plate 120 is fixed to the open area of the other surface of the housing body (100). At this time, the outer diameter of the rotating plate 120 is configured to be equal to or smaller than the inner diameter of the other surface of the housing body 100, and the rotating plate 120 is fitted to the other surface of the housing body 100 to form a closed structure. have.

Also, as shown in FIG. 2 . A plate-tong hole 124 is formed in the center of the rotating plate 120 , a first bare frame 121 fixed to an outer region of the through-hole 124 is formed, and one end of the first bearing frame 121 is formed. A rotating shaft 122 is formed in the longitudinal direction, and a second bearing frame 123 is formed at one end of the rotating shaft 122 in the longitudinal direction. In this case, the first bearing frame 121 and the second bearing frame 123 may have a donut shape with an open center. In addition, the rotating shaft 122 is configured in an empty state so that the fixed shaft 112 and the connecting shaft 113 can be inserted therethrough.

In addition, the first stator 130 , the second stator 140 , the third stator 150 , the first rotor 160 and the second After the rotor 170 is formed, in order to completely configure the electric generator 101 by the housing body 100, the fixed shaft 112 and the connecting shaft 113 into the inner space of the rotating shaft 122 This is inserted through, the second bearing frame 123 is located on the outer surface of the first bearing (not shown), and the first bearing frame 121 is configured on the outer circumferential surface (or outside) of the connecting shaft 113 . It may be located on the outer surface of the second bearing (not shown).

In addition, one end of the connecting shaft 113 passes through the 124 of the through hole (example A), protrudes to the outside of the rotating plate 120 , and is fixed by a belt pulley connecting member 125 .

In addition, as shown in FIG. 5 , the other surface of the rotating plate 120 is fixed by a belt-free connection member 121 , and the belt shaft 32 is formed on the other surface of the belt-free connection member 31 . The belt free 30 is formed on one end of the belt shaft, and the second support 20 is formed on the other surface of the belt part 30 .

As described above, as the belt unit 30 is connected to the rotating plate 120 , the rotating plate 120 rotates clockwise or counterclockwise according to the rotation of the belt unit 30 , and the first rotating plate According to the rotation of 160 and the second rotor 170, power can be produced by induced electromotive force between the first stator 130 and the second stator 140 and/or the third stator 150. have.

In addition, as shown in FIG. 5 , the first rotor 160 and the second rotor 170 are respectively formed on one surface of the rotation plate 120 . In this case, the outer diameter of the first rotor 160 is formed smaller than the inner diameter of the second rotor 170 .

That is, the first rotor 160 is formed based on the central portion of one surface of the rotation plate 120 , and the second rotor 170 is formed at a distance from the outer peripheral surface of the first rotor 160 . do. In this way, the fixed plate 110 and the rotating plate 120 are configured to face each other. The first stator 130 has a cylindrical shape, and both ends are open.

In addition, the first stator 130 is fixed to one side of the other surface of the fixing plate 110 by the second connecting member 132 .

In addition, as shown in FIG. 3 , the first stator 130 has a first core 130 configured in a cylindrical shape, and a permanent formed in the second stator 140 is formed on the inner circumferential surface of the first core 130 . The magnet corresponds to the N pole toward the fixed plate, and the inner permanent magnet in which the first stator core 130, which produces electric power by induced electromotive force, is wound, is directed toward the fixed plate. A magnet plate that overlaps with an S pole is installed at the pole, and a coil is formed therebetween, and is radially arranged at regular intervals along the inner circumferential surface of the magnet plate of the cylindrical first core 130 .

The first stator 130 has a first core 130 configured in a cylindrical shape, and the outer peripheral surface of the first core 130 corresponds to the N pole of the permanent magnet formed in the third stator 150, which corresponds to an induced electromotive force. The first stator core 130 that produces electric power by Magnet plates are installed to overlap the poles with S, and a coil is formed therebetween radially at regular intervals along the outer peripheral surface of the magnet plate of the cylindrical first core 130 .

In addition, as shown in FIG. 4 , the outer diameter of the second stator 140 is such that the second stator 140 is located inside the inner circumferential surface of the first rotor 160 . ) to be smaller than the inner diameter, the second stator 140 may be disposed to be spaced apart from the inner circumferential surface of the first rotor 160 by a preset interval.

The third stator 150 has a cylindrical shape, and has an open shape at both ends.

In addition, as shown in FIG. 3 , the third stator 150 is on the inner peripheral surface of the cylindrical outer body, and the permanent magnet is the S pole on the outer peripheral surface of the wound coil 130 of the first stator 130 . A magnet plate on both sides with an N pole and an N pole with an S pole or an N pole with an S pole so that the magnetic forces are opposed to each other by attractive force are installed overlappingly, and the third stator 130 ) on the inner circumferential surface of the cylindrical outer body, radially as the N pole of the permanent magnet.

In addition, as shown in FIG. 3 , the inner diameter of the third stator 150 is the second rotor 170 so that the third stator 150 is located on the outer peripheral surface of the second rotor 170 . Formed to be larger than the outer diameter of the second rotor 170, the third stator 150 may be spaced apart by a preset interval on the outer circumferential surface.

The first rotor (or first mechanism opening/closing plate) 160 is made of a cylindrical non-conductive metal.

In addition, as shown in FIG. 2 , one end (or one side/right side) and the other end (or the other side/left side) of the first rotor 160 are in an open state, The other end is fixed to one surface of the rotating plate 120 .

In addition, as shown in FIG. 5 , the first rotor 160 includes a first rotating core 160 made of a cylindrical non-conductive metal with both ends open, and a part of a cylinder of the first rotating core 160 . (or a part of one side/side) is configured as an open first opening 161 . In this case, the first opening 161 may be configured in plurality by being spaced apart by a preset interval. In addition, when the first opening 161 is configured in plurality, one end (or the other end) of the first rotating core 161 may be connected (or fixed) through a connecting member (not shown) or the like. Here, the first opening 161 is an inner permanent magnet including a coil formed in the first stator 130 positioned on both sides of the first rotor 160, respectively, from the fixed plate to the S pole and the N pole. Using N pole as N pole and S pole as N pole, the magnet plates overlap each other by attractive force, and/or the outer permanent magnet is from the fixed plate. It is a purpose for inducing an induced electromotive force to be generated between the N-pole from the permanent magnet fixing plate formed on the second stator 140 to be overlapped.

The second rotor (or the second electromechanical opening/closing plate) 170 is made of a cylindrical non-conductive metal.

In addition, as shown in FIG. 5 , one end and the other end of the second rotor 170 are in an open state, and the other end of the second rotor 170 is fixed to one surface of the rotating plate 120 . . 5, the second rotor 170 has a second rotational core 170 made of a non-conductive cylindrical metal with both ends open, and a part of a cylinder of the second rotational core 170 (or One side/part of the side) is configured as an open second opening 171 . In this case, the second opening 171 may be configured in plurality by being spaced apart by a preset interval. In addition, when the second opening 171 is configured in plurality, one end (or the other end) of the second rotating core 170 may be connected (or fixed) through a connecting member (not shown) or the like. Here, the second opening 171 is an S pole and an N pole from an inner permanent magnet fixing plate including a coil formed on the first stator 130 positioned on both sides of the second rotor 170, respectively. It is a purpose for inducing an induced electromotive force to be generated between the N pole of the permanent magnet formed in the third stator 150 from the fixed plate, and/or the outer permanent magnet is installed to overlap with the S pole. In this case, the first opening 161 and the second opening 171 may be formed in the same direction as shown in FIG. 5 , or in different directions (for example, 90 degrees perpendicular to each other according to a designer's design). It may be formed by forming such that they are formed to be 180 degrees opposite to each other.

In addition, the second rotor 170 is formed at a distance from the outer circumferential surface of the first rotor 160 , and between the first rotor 160 and the second rotor 170 , the first A stator 130 is formed, the first rotor 160 is formed at a distance from the inner circumferential surface of the first stator, and the second stator 140 is formed inside the inner circumferential surface of the first rotor 160 . is formed, and the third stator 150 is formed outside the outer circumferential surface at a distance from the outer circumferential surface of the second rotor 170 .

As shown in FIG. 5 or FIG. 4 , the first rotor 160 is spaced apart from the outer peripheral surface of the second stator 140 and is located outside the second stator 140 .

In addition, the first stator 130 is spaced apart from the outer circumferential surface of the first rotor 160 and is located outside the first rotor 160 .

In addition, the second rotor 170 is spaced apart from the outer circumferential surface of the first stator 130 and is located outside the first stator 130 ,

In addition, the third stator 150 is spaced apart from the outer peripheral surface of the second rotor 170 and is located outside the second rotor 170 .

In this way, the second stator 140, the first rotor 160, the first stator 130, the second rotor 170, and the third stator 150 are sequentially performed based on the center. As the first rotor 160 and the second rotor 170 rotate by the arrangement, the first rotor 160 and the second rotor 170 are respectively formed An induced electromotive force between the first stator 130 and the second stator 140 and the first stator 130 and the third stator 150 through the first opening 161 and the second opening 171 It can produce current (or electricity) according to

In the practice of the present invention, as described above, the cylindrical second stator and the third stator are configured with permanent magnets of two different polarities, respectively, on the inner and outer surfaces of the cylindrical first stator on which the coil installed on the fixing plate is wound, , After forming a first rotor and a second rotor including an opening with one side open between the first stator and the second stator and between the first stator and the third stator, respectively, the first rotor Electricity is generated by the induced electromotive force generated between the coil of the first stator and the magnet of the second stator and the coil of the first stator and the magnet of the third stator through the opening by the rotation of the second rotor. By using a small amount of power, electricity can be generated by rotating the first rotor and the second rotor, improving the efficiency of power production, and reducing the high-speed rotation of the rotor to reduce noise generated during power generation can reduce

further explanation; In the invention that is also an exception to realize the present invention as described above, in the modified invention, a coil wound can be formed by overlapping the iron core plate of the first fixing plate 130, or by using a permanent magnet disk and changing the inner diameter and outer diameter to different widths. Magnet plates having different polarities by having the same width in polarity are sequentially overlapped so that the polarity is different, and a coil can be wound between the overlapping plates, and the second fixed plate 140 and the first 3 fixing plate 150, like the magnet plate of the first fixing plate 130, the second fixing plate and the third fixing plate to the N polarity and S polarity, left / right of both ends of the cylindrical shape of a cylindrical shape, the second stator (140) The third stator 150 toward the inside can wind the coil toward the outside, so that it can induce electricity and also produce electricity.

Another (Example)

6 : When citing and explaining, the first rotor 160 and the (electrical open/close plate) of the second rotor 170 are formed by putting a magnetic plate in the center of a non-conductive metal ( When inserting the magnet plate, make the second stator magnet plate and the first stator 130 have the same polarity along the magnet plate (that is, the inner second fixed plate magnet is N When the polarity becomes the N polarity of the first rotating plate 160 (the magnet plate in the opening and closing plates is also the same polarity of the inner magnet, and the polarity of the magnet plate of the first fixing plate 130 to the outside becomes S polarity, the second The magnet plate of the first rotating plate 160 is also of the same polarity to the outside, the S polarity. When the second rotating plate 170 also has the S polarity of the inner first fixed plate 130, the second rotating plate magnet is also of the same polarity. It is installed to have an S polarity as a repulsive force, and when the magnet plate of the third stator 150 has an N polarity, it is also set to have an N polarity, which is the same polarity.

In addition, considering the blocking effect of magnetic force and a lot of load for rotation, the thickness and strength of the inner magnet plate can be selected and used.

In addition, if it is not a magnetic plate, an exception can be made in the case of an iron core plate, and when both the inside and the outside have the same polarity, the thin magnetic plates must have the same polarity as long as the efficiency is not reduced because the (electrical open/closed plate) is too thick. It can also be installed and used by sticking it together.

Those of ordinary skill in the art to which the present invention pertains will be able to modify and modify the above-described contents without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

101: electric generator 100: housing body
10: first support 20: second support
110: fixed plate 120: rotating plate
130: first stator core 140: second stator guide plate
150: third stator guide plate 132: electrical board connection part
131: a magnet of the electrical board 133: an electrical board fixing pinhole 160: a first rotor 170: a second rotor
30: belt part 31: belt connection member
50: rotary plate protector 40: motor stand
41: motor 111: bearing contact
112: fixed shaft 113: connecting shaft
121: first bearing frame 122: rotation shaft
123: second bearing frame 124: through hole
125: Gozhou material 114: first stator connecting column

Claims (5)

The inside of the body made of a cylindrical non-conductive metal is composed of an empty tunnel so that both ends are open to the body 101; to the left is a fixing plate 110; and a rotating plate 120 that rotates to the right of the body 101 having both ends open;
The main body 101 tunnel is closed by the fixed plate 110 on the left side and closed by the rotating plate 120 on the right side of the main body,
A first stator 130, a second stator 140, and a third stator 150 in which coils are wound along the inner and outer periphery of the first stator, which are formed on one side of the other surface of the fixing plate 110. Positioning , The rotating plate 120 is spaced apart from the fixed plate 110 and is made of a disk-shaped non-conductive metal to face; The first rotor 160 and the second rotor 170 formed on one surface of the rotating plate 120 are cylindrical and may include an opening partly opened on one surface of the electric generator. The method of claim 1,
A first bearing contact portion 111 fixed to the center of the other surface of the fixing plate 110:
A first bearing (not shown) formed on the outer periphery of the first bearing contact portion may be connected:
A fixed shaft 112 connected to the first bearing contact portion: And
a second bearing contact portion 113 having one end formed at the other end of the fixed shaft 112; A threaded portion 114 formed at the end is formed, and the rotating shaft 122 is coupled to the rotating plate 120 to be coupled to the outside of the fixed shaft 112 .
A second bearing 121 frame formed near the other surface of the rotating plate 120 is formed, a rotating shaft 122 is formed on one shaft, and a first bearing 123 frame is formed at one end of the rotating plate 120 . The method of claim 1,
The first stator, The first stator 130 configured in a cylindrical shape with both ends open:
The first stator 130 is radially disposed along the inner circumferential surface at regular intervals. A first stator 130 having a coil wound between a permanent magnet having an N polarity formed in the second stator 140 and a permanent magnet having an inner S polarity and N polarity alternately overlapped for generating electric power by induced electromotive force toward the outside : And, a permanent magnet having an N polarity formed in the third stator 150, which is radially arranged at regular intervals along the outer circumferential surface of the first stator 130, and an induced electromotive force toward the inside to produce electric power A first stator 130 comprising a permanent magnet having an N pole and an N pole alternately superimposed on the N pole and the S pole on the permanent magnet plate having the outer N polarity and S polarity on which the coil is wound, and connecting them It is connected through the connection hole of the electrical board 131 by composing four of the electrical board connection posts 115 for An electric generator that can be fixed with a sidewalk by finally covering it with a cover (132) and finishing (not shown). 4. The method of claim 3,
A through hole formed in the center of the rotating plate:
A first bearing frame fixed to an outer region of the through hole:
A rotating shaft formed at one end of the first bearing frame:
A second bearing frame formed at one end of the rotation shaft:
A belt unit for rotating the rotating plate:
a belt connecting shaft for connecting the belt unit and the rotating plate;
A connecting plate for connecting the belt unit and the rotating plate:
The first bearing frame and the second bearing frame,
It is a donut shape with an open center,
Electric generator, characterized in that the rotating shaft is empty inside so that the fixed shaft can be inserted through to be connected. The method of claim 1,
The first rotor may include: a first rotational core formed of a cylindrical non-conductive metal having both ends open; and a first opening in which a part of a side surface of the first rotational core is opened, and power is transmitted by an induced electromotive force between the first stator and the second stator through the first opening according to the rotation of the first rotor. A second rotating core made of a cylindrical non-conductive metal with both ends open to the second rotor: and
A portion of the side surface of the second rotational core includes a second opening,
Electric power generator, characterized in that the electric power is produced by the induced electromotive force between the first stator and the third stator through the second opening according to the rotation of the second rotor.

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