KR102201691B1 - Electric power generator - Google Patents

Abstract

The present invention relates to a generator. The problem to be solved by the present invention is to provide a high-efficiency generator capable of efficiently generating electricity. To this end, the present invention discloses a generator including: a fixed plate; a cylindrical electric plate attached to the fixed plate; an inner electromechanical induction magnet plate of a cylindrical shape attached to the fixed plate as an inner side of the electric plate; an outer electromechanical induction magnet plate in the form of a cylinder attached to the fixed plate as the outside of the electric plate; a rotating plate spaced apart from the fixed plate and rotatably installed with respect to the fixed plate; an inner electromechanical opening/closing plate in the form of a rotatable cylinder attached to the rotating plate as between the electromechanical plate and the inner electromechanical induction magnet plate; and a rotatable cylindrical outer electromechanical opening/closing plate attached to the rotating plate as between the electric plate and the outer electromechanical induction magnet plate, wherein the inner electromechanical opening/closing plate includes a magnetic field shielding and a magnetic field unshielding, and the outer electromechanical opening/closing plate includes a magnetic field shielding and a magnetic field unshielding, wherein the magnetic field shielding of the inner electromechanical opening/closing plate and the magnetic field unshielding of the outer electromechanical opening/closing plate face each other, and the magnetic field unshielding of the inner electromechanical opening/closing plate and the magnetic field shielding of the outer electromechanical opening/closing plate face each other.

Description

Electric power generator

The present invention relates to a generator, and relates to an electric generator having excellent energy conversion efficiency.

In the generator, as a magnet rotates around a coil or a coil rotates around a magnet, current flows through the coil to generate electricity. In this case, an induced magnetic field is generated in proportion to the current flowing through the coil, and a repulsive force that makes rotation difficult is generated in response thereto. These generators have an energy conversion efficiency of only about 35%.

Therefore, a technique for reducing the repulsive force that increases according to the current flowing through the coil is being studied. High-efficiency generator (Korean Patent Registration No.: 10-1141658) discloses a method of reducing the repulsive force by making the magnetic field of the field coil and the armature coil with complementary magnetic polarities opposite to each other, and a high-efficiency generator that minimizes back electromotive force and The used power generation system (Korean Patent Application No. 2011-0106945) proposes a method of reducing repulsion through a couple coil. An electric machine with a low inductance (Patent Patent Publication No. 2002-0077339) is also disclosed, in which a magnetic field induced by an electric current of an armature coil is effectively canceled to realize a low inductance.

Such a conventional generator is based on Faraday's law of electromagnetic induction, which is based on the principle of Equation 1 below, in which an electromotive force is generated by the interaction of a magnetic field and a conductor.

(Equation 1) V = B x l x v

Here, V is the induced voltage, B is the magnetic field density, l is the length of the coil, and V is the rotation speed of the rotor.

The repulsive force generated by the current flowing through the load is as Equation 2 derived by Fleming's left-hand rule.

(Equation 2) F = B x I x l

Here, F is the repulsion force, B is the magnetic field density, I is the intensity of the induced current, and l is the length of the coil.

Meanwhile, according to the new interpretation of the Faraday electromagnetic induction law, the following equations 3 and 4 can be derived.

(Equation 3) E = v x B

(Equation 4) rot E = dB/dt + b

Here, E is the induced electric field, v is the medium velocity in the magnetic field, B is the magnetic field density, and b is the potential vortex.

Equation 4 is obtained as follows by applying rot to both sides of Equation 3.

rot E = rot (v X B) = (B grad) v-(v grad) B + v div B-B in div v,

(v grad)B = dB/dt and the remaining three terms are b. This is similar to Equation 5, which shows the Lorentz law, which represents the centripetal force that causes the charged particles to bend in a spiral trajectory in a fog box.

(Equation 5) F = qE = qv x B, i.e. (E = v x B)

Where F is the force, q is the amount of charge, E is the electric field, v is the medium velocity in the magnetic field, and B is the magnetic field density.

Equations 3 and 4 show that, like a Faraday disk, an electric field can be induced even if there is no change in magnetic flux by the potential vortex b. The method of reducing the repulsive force caused by magnetic induction is to reverse the winding direction of one or more armature coils constituting the armature to cancel the induced magnetic field or to minimize the change in magnetic flux or magnetic flux applied to the armature coil. It is to arrange the S poles complementarily.

In the Faraday disk experiment, it is widely known and confirmed that an electric field or an electromotive force is induced when a conductor moves within the same magnetic field under the condition of dB/dt = 0. Therefore, E = v x B is the basis of Faraday's law, and according to rot E = dB/dt + b derived from this equation, an electric field, or current, is induced even if there is no change in magnetic flux. In some cases, E = v x B, rot E = b, in which current is induced under the condition of dB/dt = 0, is interpreted as an eddy current phenomenon.

The above-described information disclosed in the background technology of the present invention is only for improving an understanding of the background of the present invention, and thus may include information not constituting the prior art.

An object to be solved of the present invention is to provide a high-efficiency generator capable of efficiently generating electricity. As an example, the present invention is to provide a high-efficiency generator capable of efficiently generating electricity without inputting a lot of energy, with the attention of a number of electric generators that are reluctant to discharge carbon dioxide in recent years.

The high-efficiency generator according to the present invention includes a fixed plate; A cylindrical electromechanical plate attached to the fixed plate; An inner electromechanical induction magnet plate in the form of a cylinder attached to the fixed plate as an inner side of the electromechanical plate; An outer electromechanical induction magnet plate in a cylindrical shape attached to the fixed plate as an outer side of the electromotive plate; A rotating plate spaced apart from the fixed plate and rotatably installed with respect to the fixed plate; An inner electromechanical opening/closing plate in the form of a cylinder which is attached to the rotating plate and rotatable between the electromotive plate and the inner electromotive force induction magnet plate; And an outer electromechanical opening/closing plate in a cylindrical shape attached to the rotating plate and rotatable between the electromotive force plate and the outer electromechanical induction magnet plate, wherein the inner electromechanical opening/closing plate includes a magnetic field shielding part and a magnetic field non-shielding part, and the outer The electromechanical opening/closing plate includes a magnetic field shielding part and a magnetic field non-shielding part, the magnetic field shielding part of the inner electromechanical opening/closing plate and the magnetic field non-shielding part of the outer electromechanical opening/closing plate face each other, and the magnetic field non-shielding part of the inner electromotive opening/closing plate and the The magnetic field shields of the outer electrical opening and closing plate face each other.

The magnetic field shielding part and the magnetic field non-shielding part of the inner electromotive opening and closing plate are formed along a circumference, and the magnetic field shielding part and the magnetic field non-shielding part of the outer electromechanical opening and closing plate are formed along the circumference.

The electromechanical plate includes a plurality of magnetic bodies arranged along a circumference, and a field coil wound around the magnetic body, wherein the magnetic body of the electromotive plate has an S pole toward the inside and an N pole toward the outside, or The N pole is located toward the side and the S pole is located toward the outside.

The inner electromotive force induction magnet plate includes a plurality of magnetic bodies arranged along a circumference, and the magnetic body of the inner electromotive force induction magnet plate has S poles and N poles located along the circumference, or the N pole and S poles are located along the circumference, The outer electromotive induction magnet plate includes a plurality of magnetic bodies arranged along a circumference, and the magnetic body of the outer electromotive force induction magnet plate has N poles and S poles located along the circumference or S poles and N poles are located along the circumference, The S pole of the magnetic body of the inner mechanism induction magnet plate and the N pole of the magnetic body of the outer mechanism induction magnet plate face each other, and the N pole of the magnetic body of the inner mechanism induction magnet plate and the S pole of the magnetic body of the outer mechanism induction magnet plate face each other. see.

The inner electromotive opening/closing plate includes a real gear frame fitted at an end end facing the fixing plate, the inner electromotive induction magnet plate includes a real gear bearing fitted to an outer diameter surface adjacent to the fixed plate, and a real gear frame of the inner mechanical opening/closing plate It is coupled to the actual gear bearing of the inner electromagnetic induction magnet plate.

The outer mechanical opening/closing plate includes a seal gear frame fitted at an end end facing the fixing plate, the outer mechanism induction magnet plate includes a seal gear bearing fitted to an inner diameter surface adjacent to the fixing plate, and a seal gear frame of the outer mechanical opening/closing plate It is coupled to the actual gear bearing of the outer electromotive induction magnet plate.

The fixed plate includes a fixed shaft installed in the center, a fixed plate bearing fitted in a region adjacent to the fixed plate among the fixed shafts, and a rotary plate bearing fitted in an area adjacent to the rotary plate among the fixed shafts, and the rotary plate is a hollow rotary shaft installed in the center. And, a fixed plate bearing fitting frame formed in a region of the rotating shaft adjacent to the fixed plate, and a rotating plate bearing fitting frame formed in a region of the rotating shaft adjacent to the rotating plate, wherein the rotating shaft is coupled to the fixed shaft, and the fixed plate bearing is fitted. The fixed plate bearing is coupled to the frame, and the rotary plate bearing is coupled to the rotary plate bearing fitting frame.

The rotating plate includes a connection member formed at the center of the outer surface to receive power from the motor.

The present invention can provide a high-efficiency generator that does not require a lot of energy to generate electricity, has high efficiency, is economical, and has low energy consumption and low noise, thereby improving a working environment in a workplace. For example, in the related art, due to the magnetism of the iron core field coil or the magnetic field coil, a lot of energy was required to rotate them.In the present invention, instead of rotating the magnet plate, the electromotive force is generated by rotating the electromotive switch plate without magnetism at all. By allowing it to be generated, it is possible to provide a generator capable of generating electricity with high efficiency without using a large amount of energy.

1 is a diagram showing an external configuration of a generator according to the present invention.
2 is a view showing the internal configuration of the generator according to the present invention.
3 is a view showing an assembly structure and assembly method of the generator according to the present invention.
4 is a view showing the configuration and operation of an inner electromotive opening and closing plate and an outer electromechanical opening and closing plate in the generator according to the present invention.
5 is a view showing the configuration and operation of an electromotive plate, an inner electromotive force induction magnet plate, and an outer electromotive force induction magnet plate in the generator according to the present invention.
6 is a view showing a longitudinal section of the generator according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

The embodiments of the present invention are provided to more completely describe the present invention to those of ordinary skill in the art, and the following examples may be modified in various other forms, and the scope of the present invention is as follows. It is not limited to the examples. Rather, these embodiments are provided to make the present disclosure more faithful and complete, and to completely convey the spirit of the present invention to those skilled in the art.

In addition, in the following drawings, the thickness or size of each layer is exaggerated for convenience and clarity of description, and the same reference numerals refer to the same elements in the drawings. As used herein, the term “and/or” includes any and all combinations of one or more of the corresponding listed items. In addition, the meaning of "connected" in the present specification means not only the case where the member A and the member B are directly connected, but also the case where the member A and the member B are indirectly connected by interposing a member C between the member A and the member B. do.

The terms used in this specification are used to describe specific embodiments, and are not intended to limit the present invention. As used herein, the singular form may include the plural form unless the context clearly indicates another case. In addition, when used herein, "comprise, include" and/or "comprising, including" refers to the mentioned shapes, numbers, steps, actions, members, elements, and/or groups thereof. It specifies existence and does not exclude the presence or addition of one or more other shapes, numbers, actions, members, elements, and/or groups.

In this specification, terms such as inner and outer are used to describe various members, parts, regions, layers and/or parts, but these members, parts, regions, layers and/or parts should not be limited by these terms. It is self-evident. These terms are only used to distinguish one member, component, region, layer or portion from another region, layer or portion. Accordingly, the inner member, part, region, layer or part to be described below may refer to the outer member, part, region, layer or part without departing from the teachings of the present invention.

1 is a view showing the external configuration of the generator 100 according to the present invention.

1, the generator 100 according to the present invention includes an outer frame 111, a fixing plate 110 fixed to one side (for example, left) of the outer frame 111, and an outer frame ( 111) may include a rotating plate 120 rotatably coupled to the other side (eg, right).

Here, the outer frame 111 may include connecting rods 112 and 113 capable of being combined and/or disassembled into two parts, and various components to be described below on the inner and outer sides of the outer frame 111, for example, mechanisms A plate 130, an inner electromotive force induction magnetic plate 140, an outer electromotive force induction magnet plate 150, an inner electromotive force opening/closing plate 160, an outer electromechanical opening/closing plate 170, etc. may be provided (FIG. 2 to 5). For example, the connecting rods 112 and 113 may be coupled or disassembled by a bolt/nut coupling method.

In addition, the rotating plate 120 may further include a connection member 128 connected to a motor or a prime mover on the outside. The connection member 128 is, for example, a belt pulley shaft 124 coupled to the rotating plate 120, a pulley 125 connected to the belt pulley shaft 124, a bearing 126 connected to the pulley 125, and a bearing It may include a support 127 coupled to 126, and the pulley 125 may be connected to the rotation shaft of the motor or prime mover.

In addition, the electromechanical plate 130, the inner electromotive force induction magnet plate 140 and the outer electromotive force induction magnet plate 150 may be fixed to the fixed plate 110, and between the electromotive force plate 130 and the inner electromotive force induction magnet plate 140 The inner electromechanical opening/closing plate 160 and the outer electromechanical opening/closing plate 170 sandwiched between the fitted inner electromotive force plate 130 and the outer electromotive force induction magnet plate 150 may be respectively coupled to the rotating plate 120 (FIG. 2 to 5).

Here, by rotating the rotating plate 120, the inner electromechanical opening/closing plate 160 may be rotated between the electromechanical plate 130 and the inner electromotive force induction magnet plate 140, and the electromechanical plate 130 and the outer electromotive force induction magnet plate ( Between 150) the outer mechanical opening and closing plate 170 may be rotated.

2 is a view showing the internal configuration of the generator 100 according to the present invention.

As shown in FIG. 2, the generator 100 according to the present invention includes a fixed plate 110, an electromotive force plate 130, an inner electromotive force induction magnet plate 140, an outer electromotive force induction magnet plate 150, a rotating plate 120, and an inner It may include an electromechanical opening/closing plate 160 and an outer electromechanical opening/closing plate 170.

Here, the fixing plate 110 may have an approximately disk shape, and may be fixed to the external body, and the rotating plate 120 has an approximately disk shape that is rotatable, which is rotatably coupled to the external body while being spaced apart from the fixing plate 110 Can be.

The electromotive plate 130 may have a substantially cylindrical shape, and one end thereof may be attached to the fixing plate 110. Here, the electromotive plate 130 may include a plurality of magnetic bodies 135, a field coil 136, and a dielectric 137 (see FIG. 5), which will be described again below.

The inner electromechanical induction magnet plate 140 may also have a substantially cylindrical shape, and one end may be attached to the fixed plate 110 as the inner side of the electromechanical plate 130. Here, the inner electromotive force induction magnet plate 140 may include a plurality of magnetic bodies 145 and dielectrics 146 (see FIG. 5), which will be described again below.

The outer electromechanical induction magnet plate 150 may also have a substantially cylindrical shape, and one end may be attached to the fixing plate 110 as the outer side of the electromotive plate 130. Here, the outer mechanism induction magnetic plate 150 may include a plurality of magnetic bodies 155 and dielectrics 156 (see FIG. 5), which will be described again below.

The inner electromechanical opening/closing plate 160 may have a substantially cylindrical shape, which is attached to the rotating plate 120 and rotated between the electromechanical plate 130 and the inner electromotive force induction magnet plate 140. Here, the inner electromechanical opening/closing plate 160 may include a magnetic shielding portion 162 and a magnetic non-shielding portion 163 (see FIG. 4), which will be described again below.

The outer electromechanical opening/closing plate 170 may have a substantially cylindrical shape, which is attached to the rotating plate 120 and rotated between the electromotive plate 130 and the outer electromotive force induction magnet plate 150. Here, the outer mechanical opening and closing plate 170 may include a magnetic shielding portion 172 and a magnetic non-shielding portion 173 (see FIG. 4), which will be described again below.

In this way, in the generator 100 according to the present invention, the inner electromotive opening/closing plate 160 rotates between the inner electromotive force induction magnet plate 140 and the electromechanical plate 130, and the outer electromotive opening/closing plate 170 is outside The electromotive force is generated in the field coil 136 by rotating between the electromotive force induction magnet plate 150 and the electromotive force plate 130, thereby generating electricity with high efficiency.

3 is a view showing an assembly structure and assembly method of the generator 100 according to the present invention.

As shown in Figure 3, the generator 100 according to the present invention may be coupled to the electromotive plate 130 to the fixed plate 110, the inner electromotive opening and closing plate 160 and the outer electromotive opening and closing plate to the rotating plate 120 170 may be coupled, a hollow rotating shaft 122 may be coupled to the center of the rotating plate 120, a solid fixed shaft 132 may be coupled to the fixed plate 110. In addition, the inner electromotive force induction magnet plate 140 as the inner side of the electromotive plate 130 may be fixed to the fixed plate 110, and the outer electromotive force induction magnet plate 150 as the outer side of the electromotive plate 130 is fixed to the fixed plate 110 Can be.

Here, the inner electromotive opening/closing plate 160 may be located between the electromotive force plate 130 and the inner electromotive force induction magnet plate 140, and the outer electromotive force opening/closing plate 170 includes the electromechanical plate 130 and the outer electromotive force induction magnet plate ( 150) can be located in between.

On the other hand, the rotating plate 120, the rotating shaft 122, the inner electromotive opening/closing plate 160 and the outer electromotive opening/closing plate 170 are a fixed plate 110, a fixed shaft 132, a electromotive plate 130, an inner electromotive induction magnetic plate ( 140) and by rotating with respect to the outer mechanism induction magnet plate 150, power generation is performed, and an assembly structure for this will be described.

First, the inner mechanical opening/closing plate 160 having one side attached to the rotating plate 120 may include a real gear frame 161 fitted at an end facing the fixed plate 110. In addition, the inner electromechanical induction magnet plate 140 having one side attached to the fixed plate 110 may include a real gear bearing 142 fitted to the outer diameter surface 141 adjacent to the fixed plate 110.

Here, the actual gear frame 161 coupled to the inner electromotive opening and closing plate 160 is coupled to the actual gear bearing 142 coupled to the inner electromotive induction magnet plate 140, so that the inner electromotive opening and closing plate 160 induces the inner electromotive force It can rotate with respect to the magnet plate 140. In addition, since the bearing pin 143 is coupled to the outer diameter surface 141 of the inner electromotive force induction magnet plate 140, separation of the actual gear bearing 142 may be prevented.

Next, the outer mechanical opening/closing plate 170 may include a seal gear frame 171 fitted at an end facing the fixed plate 110. In addition, the outer electromechanical induction magnet plate 150 may include a real gear bearing 152 fitted to the inner diameter surface 151 adjacent to the fixed plate 110.

Here, the actual gear frame 171 coupled to the outer electromotive opening and closing plate 170 is coupled to the actual gear bearing 152 coupled to the outer electromotive induction magnet plate 150, so that the outer electromotive opening and closing plate 170 induces the outer electromotive force It can be rotated with respect to the magnet plate 150. In addition, since the bearing pin 153 is coupled to the inner diameter surface 151 of the outer electromotive force induction magnet plate 150, separation of the actual gear bearing 152 may be prevented.

Meanwhile, the fixing plate 110 includes a fixed shaft 132 installed in the center and extended elongated, a fixed plate bearing 134 fitted in a region 131 adjacent to the fixed plate 110 among the fixed shafts 132, and a fixed shaft 132 ), may include a rotating plate bearing 135 fitted in an area 133 adjacent to the rotating plate 120.

In addition, the rotating plate 120 is a rotating shaft 122 that is long installed in the center and is hollow, a fixed plate bearing fitting frame 121 formed in an area adjacent to the fixed plate 110 among the rotating shafts 122, and a rotating plate among the rotating shafts 122 It may include a rotating plate bearing fitting frame 123 formed in an area adjacent to 120.

Here, the rotating shaft 122 is coupled to the fixed shaft 132, the fixed plate bearing 134 is coupled to the fixed plate bearing fitting frame 121, and the rotating plate bearing 135 may be coupled to the rotating plate bearing fitting frame 123. have. In addition, the bolts are coupled to the region 133 of the fixed shaft 132 extending through the rotating plate bearing fitting frame 123, so that the above-described components are not separated from each other and the structure can be integrally maintained.

Meanwhile, the rotating plate 120 may further include a connection member 128 connected to a motor or a prime mover in the outer center. The connection member 128 is, for example, a connection plate 124a that blocks the bearing fitting frame 123 of the rotating plate 120, a belt pulley shaft 124 coupled to the connection plate 124a, and a belt pulley shaft 124 A pulley 125 connected to the pulley 125, a bearing 126 connected to the pulley 125, and a support 127 connected to the bearing 126 may be included, and the pulley 125 may be connected to a rotation shaft of a motor or prime mover. .

4 is a view showing the configuration and operation of the inner electromotive opening and closing plate 160 and the outer electromotive opening and closing plate 170 in the generator 100 according to the present invention. Here, the inner electromotive opening/closing plate 160 is interposed between the electromotive force plate 130 and the inner electromotive force induction magnet plate 140, and the outer electromotive force opening/closing plate 170 is the electromechanical plate 130 and the outer electromotive force induction magnet plate 150 It can be interposed between.

As shown in FIG. 4, the inner electromotive opening/closing plate 160 and the outer electromechanical opening/closing plate 170 of the generator 100 according to the present invention have similar configurations and functions, only different diameters. For example, the inner electromotive open/close plate 160 and the outer electromotive open/close plate 170 may include magnetic shielding portions 162 and 172 and magnetic non-shielding portions 163 and 173, respectively. Here, the magnetic shielding portions 162 and 172 are formed of a material having a high relative magnetic permeability (a ratio between the magnetic permeability and air (vacuum) permeability) such as a material that is difficult to pass through the magnetic field, for example, iron, nickel, and cobalt. In addition, the magnetic non-shielding portions 163 and 173 may be formed of a material having a low magnetic permeability, such as air, copper, aluminum, or plastic.

Further, the magnetic shielding portions 162 and 172 and the magnetic non-shielding portions 163 and 173 may be formed in pairs along the circumference. As an example, a pair of magnetic shielding portions 162, (A,B) in the inner electromotive opening and closing plate 160 are facing and spaced apart to be formed along a circumference, and a pair of magnetic non-shielding portions 163 face each other. It can be spaced apart and formed along the circumference. In addition, a pair of magnetic shielding portions 172 (A, B) are faced and spaced apart from the outer electrical opening and closing plate 170 and formed along the circumference, and a pair of magnetic non-shielding portions 173 faced and spaced apart therebetween. It can be formed along the circumference.

In addition, the magnetic shielding portion 162 of the inner mechanical opening and closing plate 160 and the magnetic non-shielding portion 173 of the outer mechanical opening and closing plate 170 may be arranged to face each other, and the magnetic ratio of the inner mechanical opening and closing plate 160 The closed part 163 and the magnetic shielding part 172 of the outer mechanical opening/closing plate 170 may be arranged to face each other.

In this way, the magnetic shielding portion 162 and the magnetic non-shielding portion 163 of the inner mechanical opening and closing plate 160, and the magnetic shielding portion 172 and the magnetic non-shielding portion 163 of the outer electrical opening and closing plate 170 are rotated. Due to the motion, the magnetic flux density between the electromotive plate 130 and the inner electromotive force induction magnet plate 140 changes, and the magnetic flux density between the electromotive force plate 130 and the outer electromotive force induction magnet plate 150 changes, eventually, the field coil 136 ) Flows in to generate electricity.

Here, as the inner electromotive opening/closing plate 160 rotates, the magnetic flux density for the N and S poles of the inner electromotive induction magnet plate 140 and the S pole (or N pole) of the electromotive plate 130 changes, and the outer side With the rotation of the electromechanical opening/closing plate 170, the magnetic flux density with respect to the S and N poles of the outer electromechanical induction magnet plate 150 and the N pole (or S pole) of the electromechanical plate 130 is changed, so that the field coil 136 ) Flows. This is described again below.

5 is a view showing the configuration and operation of the electromotive plate 130, the inner electromotive force induction magnet plate 140, and the outer electromotive force induction magnet plate 150 among the generator 100 according to the present invention.

As shown in FIG. 5, among the generator 100 according to the present invention, the electromotive plate 130, the inner electromotive force induction magnet plate 140, and the outer electromotive force induction magnet plate 150 may all be formed in a cylindrical shape. An inner electromotive force induction magnetic plate 140 may be positioned on the inner side of the center 130 and an outer electromotive force induction magnet plate 150 may be positioned on the outer side.

The electromotive plate 130 may include a plurality of magnetic bodies 135 arranged along a circumference, a field coil 136 wound around the magnetic body 135, and a dielectric 137 connecting the plurality of magnetic bodies 135. have. Here, two magnetic bodies 135 are shown in FIG. 5, a field coil 136 is wound around the magnetic body of one side (A), and a field coil is not wound around the magnetic body 135 of the other side (B). Shown in the state. In addition, the magnetic body 135 of the electromotive plate 130 may have an S-pole toward the inside and an N-pole toward the outside, or conversely, an N-pole toward the inside and an S-pole toward the outside.

The inner electromechanical induction magnet plate 140 may include a plurality of magnetic bodies 145 arranged along a circumference, and a dielectric 146 connecting the plurality of magnetic bodies 145. Here, in the magnetic body 145 of the inner electromotive force induction magnet plate 140, the N-pole and the S-pole may be positioned from the reference point along the circumference, or the S-pole and the N-pole may be positioned from the reference point along the circumference. For example, a 1 may have an N pole, a 1 with an S pole, a 1 with an N pole, a 2 with an S, a 2 with an N, and a 2 with an S.

In addition, the outer electromotive force induction magnet plate 150 may include a plurality of magnetic bodies 155 arranged along a circumference, and a dielectric 156 connecting the plurality of magnetic bodies 155. Here, in the magnetic body 155 of the outer electromotive force induction magnet plate 150, the S pole and the N pole may be positioned from the reference point along the circumference, or the N pole and the S pole may be positioned along the circumference. For example, an S pole may be located in A 1, an N pole in B 1, an S pole in C 1, an N pole in A 2, an S pole in B 2, and an N pole in C 2.

In this way, the N pole of the inner mechanism induction magnet plate 140 faces the S pole of the outer mechanism induction magnet plate 150, and the S pole of the inner mechanism induction magnet plate 140 is the N pole of the outer mechanism induction magnet plate 150 You can face it. Accordingly, a change in magnetic flux density occurs between the magnetic body 135 of the electromotive plate 130, the inner electromotive force induction magnet plate 140 and the outer electromotive force induction magnet plate 150, thereby improving power generation efficiency.

In this way, the inner electromotive force induction magnet plate 140 is located inside the electromotive force plate 130 and the inner electromotive force opening/closing plate 160, and the outer electromotive force induction magnetic plate 150 is the electromotive force plate 130 and the outer electromotive force opening and closing It may be located outside the plate 170.

The inner electromechanical induction magnet plate 140 may include, for example, a cylindrical dielectric 146 such as paper or resin, and a plurality of magnetic bodies 145 attached to the outside of the dielectric 146 through an adhesive. The outer electromechanical induction magnet plate 150 may also include, for example, a cylindrical dielectric 156 such as paper or resin, and a plurality of magnetic bodies 155 attached to the outside of the dielectric 156 through an adhesive.

6 is a view showing a longitudinal section of the generator 100 according to the present invention.

As shown in Fig. 7, most of the components of the present invention can be accommodated inside the main body. That is, a cylindrical electromotive plate 130 is attached to the fixed plate 110, and an inner electromotive force induction magnet plate 140 in a cylindrical shape is attached to the fixed plate 110 as an inner side of the electromotive plate 130, and also the electromotive plate ( As the outer side of 130), a cylindrical outer mechanism induction magnet plate 150 is attached to the fixing plate 110. In addition, an inner electromechanical opening/closing plate 160 in a cylindrical shape that is attached to the rotating plate 120 and rotatable is provided between the electromechanical plate 130 and the inner electromotive force induction magnet plate 140, and the electromotive plate 130 and the outer electromotive force are guided. An outer electromechanical opening/closing plate 170 of a cylindrical shape that is attached to the rotating plate 120 and rotatable between the magnet plates 150 is provided.

In this way, the inner electromotive opening/closing plate 160 rotates between the electromotive force plate 130 and the inner electromotive force induction magnet plate 140, so that electric current flows through the field coil 136 of the electromotive plate 130 to generate electricity. That is, the magnetic flux density between the magnetic body 135 of the electromechanical plate 130 and the magnetic body 145 of the inner electromotive force induction magnet plate 140 changes with time, so that a current is applied to the field coil 136 of the electromechanical plate 130 Flows.

In addition, the outer electromechanical opening/closing plate 170 rotates between the electromechanical plate 130 and the outer electromotive force induction magnet plate 150, so that a current flows through the field coil 136 of the electromotive plate 130 to generate electricity. That is, the magnetic flux density between the magnetic body 135 of the electromechanical plate 130 and the magnetic body 155 of the outer electromotive force induction magnet plate 150 changes with time, so that a current is applied to the field coil 136 of the electromechanical plate 130 Flows.

What has been described above is only one embodiment for implementing @ according to the present invention, and the present invention is not limited to the above-described embodiment, and departs from the gist of the present invention as claimed in the following claims. Without it, anyone of ordinary skill in the field to which the present invention pertains will have the technical spirit of the present invention to the extent that various modifications can be implemented.

100; Generator 110; Fixed plate
120; Rotating plate 121; Fixed plate bearing seat
122; Axis of rotation 123; Rotary plate bearing seat
124; Belt pulley shaft 125; Pulley
126; Bearing 127; support fixture
128; Connecting member 130; Electromechanical
131; Bearing coupling 132; Fixed shaft
133; Bearing coupling 134; Fixed plate bearing
135; Rotary plate bearing 135; Magnetism
136; Field coil 137; dielectric
140; Inner mechanism induction magnetic plate 141; Outer surface
142; Actual gear bearing 143; Bearing pin
145; Magnetic body 146; dielectric
150; An outer mechanism induction magnetic plate 151; Inner mirror surface
152; Actual gear bearing 153; Bearing pin
155; Magnetic body 156; dielectric
160; Inner mechanical opening and closing plate 161; Actual gear frame
162; Magnetic shield 163; Magnetic unshielded part
170; Outer mechanism opening and closing plate 171; Actual gear frame
172; Magnetic shield 173; Magnetic unshielded part

Claims (8)

Fixed plate;
A cylindrical electromechanical plate attached to the fixed plate;
An inner electromechanical induction magnet plate in the form of a cylinder attached to the fixed plate as an inner side of the electromechanical plate;
An outer electromechanical induction magnet plate in a cylindrical shape attached to the fixed plate as an outer side of the electromotive plate;
A rotating plate spaced apart from the fixed plate and rotatably installed with respect to the fixed plate;
An inner electromechanical opening/closing plate in a cylindrical shape, which is attached to the rotating plate and rotatable between the electromotive plate and the inner electromotive force induction magnet plate; And
It includes an outer electromechanical opening/closing plate in a cylindrical shape that is attached to the rotating plate and rotatable between the electromotive plate and the outer electromotive force induction magnet plate,
The inner electromotive opening and closing plate includes a magnetic field shielding part and a magnetic field non-shielding part, the outer electromechanical opening and closing plate includes a magnetic field shielding part and a magnetic field non-shielding part, and the magnetic field shielding part of the inner electromechanical opening and closing plate and the outer electromechanical opening and closing plate The magnetic field non-shielding part faces each other, the magnetic field non-shielding part of the inner electromotive opening and closing plate and the magnetic field shielding part of the outer electromechanical opening and closing plate face each other,
The magnetic field shielding part and the magnetic field non-shielding part of the inner electromotive opening and closing plate are formed along a circumference, the magnetic field shielding part and the magnetic field non-shielding part of the outer electromechanical opening and closing plate are formed along the circumference, and the magnetic field shielding part is made of iron, nickel or cobalt. Is formed, the magnetic field non-shielding portion is formed of copper, aluminum or plastic,
The electromechanical plate includes a plurality of electromechanical plate magnetic bodies arranged along a circumference, a field coil wound around the plurality of electromechanical plate magnetic bodies, and a electromechanical plate dielectric connecting the plurality of electromechanical plate magnetic bodies, wherein the electromechanical plate magnetic body is The S pole is located toward the inside and the N pole is located toward the outside or the N pole is located toward the inside and the S pole is located toward the outside,
The inner electromotive force induction magnet plate includes a plurality of inner electromotive force induction magnetic plate magnetic bodies arranged along a circumference, and an inner electromotive force induction magnet plate dielectric connecting the plurality of inner electromotive force induction magnet plate magnetic bodies, wherein the inner electromotive force induction magnet plate magnetic body is along the circumference. The S pole and the N pole are located or the N pole and the S pole are located along a circumference, and the outer electromotive force induction magnetic plate comprises a plurality of outer electromotive induction magnet plate magnetic bodies arranged along the circumference, and the plurality of outer electromotive force induction magnet plate magnetic bodies. Including a dielectric material of the outer electromechanical induction magnet plate to be connected, wherein the outer electromechanical induction magnet plate magnetic body has an N-pole and an S-pole positioned along a circumference or an S-pole and an N-pole positioned along the circumference. A generator in which a pole and an N pole of the magnetic body of the outer electromotive force induction magnetic plate face each other, and an N pole of the magnetic body of the inner electromotive force induction magnet plate and the S pole of the magnetic body of the outer electromotive force induction magnet plate face each other. delete delete delete The method of claim 1,
The inner electromechanical opening/closing plate includes a thread gear frame fitted at an end facing the fixed plate,
The inner electromechanical induction magnet plate includes a real gear bearing fitted to an outer diameter surface adjacent to the fixed plate,
A generator in which the actual gear frame of the inner electromotive open/close plate is coupled to the actual gear bearing of the inner electromotive induction magnet plate. The method of claim 1,
The outer mechanical opening and closing plate includes a thread gear frame fitted at an end facing the fixed plate,
The outer mechanism induction magnet plate includes a real gear bearing fitted to an inner diameter surface adjacent to the fixed plate,
The actual gear frame of the outer electromotive opening/closing plate is coupled to the actual gear bearing of the outer electromotive induction magnet plate. The method of claim 1,
The fixed plate includes a fixed shaft installed in the center, a fixed plate bearing fitted in a region of the fixed shaft adjacent to the fixed plate, and a rotating plate bearing fitted in a region of the fixed shaft adjacent to the rotating plate,
The rotating plate includes a hollow rotating shaft installed in the center, a fixed plate bearing fitting frame formed in a region of the rotating shaft adjacent to the fixed plate, and a rotating plate bearing fitting frame formed in a region of the rotating shaft adjacent to the rotating plate,
The rotating shaft is coupled to the fixed shaft, the fixed plate bearing is coupled to the fixed plate bearing fitting frame, and the rotating plate bearing is coupled to the rotating plate bearing fitting frame. The method of claim 1,
The rotating plate includes a connection member formed to receive power from the motor in the center of the outer surface, generator.

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