KR102449464B1 - sequence power generation type generator with induced current strength selection function - Google Patents

Abstract

The present invention relates to a sequential independent power generation device having an induced current intensity selection function. The sequential independent power generation device, according to the present invention, comprises: a pair of fixed plates; a plurality of ferrite cores; a plurality of winding coils; a pair of rotating plates; a permanent magnet; and a magnet moving means. According to the present invention, even though other conditions are not changed, power generation can be achieved by selecting the induced current generation intensity by the positional movement of a magnet.

Description

Sequential power generation type generator with induced current strength selection function

In the present invention, a ferrite core on which a winding coil is wound is arranged in a circumferential shape, and a permanent magnet sequentially passes through the ends of a plurality of ferrite cores arranged in a circumferential shape so that an independent voltage is sequentially generated in each winding coil. It relates to a sequential independent power generation device, and more particularly, a plurality of outer ferrite cores in which a first winding coil is wound between a pair of fixed plates are spaced apart from each other in a predetermined first circumferential shape, and the first winding coil and A plurality of inner ferrite cores on which a second coil coil having a different number of turns is wound is spaced apart in a second circumferential shape inside the first circumferential shape, and a plurality of outer ferrite cores are rotated on the outside of the pair of fixed plates. Alternatively, a rotating plate for a rotor having permanent magnets passing through both ends of the plurality of inner ferrite cores is installed, wherein the permanent magnets are configured to be movable in an inward and outward direction from the center of the rotating plate for the rotor in an outward and outward direction. It relates to a sequential independent power generation device that can select the intensity of the organic current generated by sequentially passing the ends of the outer ferrite core with a time difference or sequentially passing the ends of the plurality of inner ferrite cores with a time difference .

In general, a generator uses the electricity generated when a conductor moves in a magnetic field to convert mechanical energy, that is, mechanical energy, generated from various energy sources such as chemical or nuclear energy in a magnetic field. It refers to a device that converts electrical energy into electrical energy according to Fleming's right-hand rule, a rule that determines the direction of magnetic field when a conductor moves and the direction of an induced electromotive force or induced current in the direction in which the conductor moves.

In recent years, although linear motion generators have been developed, most of them are composed of rotary generators. However, all generators are the same in that they generate electromotive force by electromagnetic induction.

In general, a generator consists of a field part that forms a magnetic field and an armature part that rotates in the magnetic field.

In this case, the field part is the name of the part where the magnetic field lines of the magnet form the magnetic field, and refers to the magnet attached to the housing of the generator.

In addition, the armature part means a part that emits a magnetic force line by applying a current, and is also called an armature, a rotor, or a core.

In the generator having the above configuration, a magnetic field is always formed around the wire through which current flows, and the magnetic field of the permanent magnet and the magnetic field generated in the coil of the armature rotate by the force of pushing or pulling each other. it will be done

On the other hand, looking at the process in which electricity is generated between the magnet and the coil in the conventional generator, hysteresis loss due to counter electromotive current and eddy current due to magnetic motion are generated, so that an unnecessary heavy load is applied and heat is generated.

In particular, when an excessive current is used and an unexpected short circuit (short-circuit) condition occurs, there is a problem in that various instruments and equipment are damaged due to a fire loss of a generator or a power outage due to an overload.

In addition, there is a risk of damage to the generator, so it is absolutely impossible to use 100% of the total amount of power actually produced, or use it at the risk of overloading close to the total amount of the output. Therefore, it must always use a smaller amount than the output, and the resulting loss is greater than expected, and this is the current state of power generation operation.

In addition, the force that interferes with the rotor of the generator is due to the magnetic field generated in the armature coil when a current flows through the armature coil, and this magnetic field interacts with the magnetic field of the rotor to generate a counter electromotive force that prevents the rotation of the rotor.

In order to solve these conventional problems, in Patent Registration No. 10-1324546, a rotation shaft passing hole is formed at the center point and a plurality of ferrite core fixing holes are formed at predetermined intervals along a circumference having a predetermined diameter, and are vertically parallel. a pair of fixing plates integrally coupled to each other through a fixing and spacing means to maintain the ; It has a rod shape and is installed between a pair of fixing plates in a form in which both ends are fitted in the ferrite core fixing hole, so that when the permanent magnets pass through both ends exposed to the outside of the fixing plate, the magnetic field generated from the permanent magnet forms a closed circuit. a plurality of ferrite cores; A plurality of windings installed on the outer circumferential surface of the ferrite core in the form of being wound by a predetermined number of revolutions, respectively, inducing an induced electromotive force or an induced current generated when the magnetic field of a permanent magnet passes through each ferrite core and transmitting it to the power control unit coil; Corresponding to the number of rotations of the rotational shafts respectively fixed to both ends of the rotational shafts installed in the form of penetrating the rotational shaft passing holes formed at the center points of the fixing plates in a state in which the pair of fixing plates are disposed in close proximity to the outside of the pair of fixing plates, respectively, and connected to the shaft of the rotational force generating means A pair of rotating plates for the rotor rotating together with the rotating shaft; Constructed including a; A time difference generator using bipolar balance, characterized in that, has been published.

However, in the time difference generator using the bipolar balance of Patent Registration No. 10-1324546, the ferrite cores installed on the fixed plate have winding coils wound in the same number of turns set at the time of design, and the permanent magnet is fixedly mounted on the rotating plate for the rotor. Since it has a structure that cannot be moved, the induced current intensity is equally generated in one generator. It was necessary to proceed or replace the ferrite core with the winding coil wound with a different number of turns to the fixed plate.

Registered Patent No. 10-1324546

The present invention has been devised to solve the problems of the related art as described above, and a plurality of outer ferrite cores having a first winding coil wound therein are spaced apart from each other in a predetermined first circumference shape between a pair of fixed plates, and the first winding is performed. A plurality of inner ferrite cores in which a second coil coil having a number of turns different from that of the coil is wound are spaced apart from each other in a second circumferential shape inside the first circumferential shape, and a plurality of outside ferrite cores are disposed on the outside of the pair of fixed plates as they rotate. A rotating plate for a rotor having a permanent magnet passing through both ends of a ferrite core or a plurality of inner ferrite cores is installed, wherein the permanent magnet is configured to be movable in an outward and outward direction from the center of the rotating plate for the rotor along the outer end. An organic current intensity selection function that can select the induced current intensity generated by independently passing the ends of the plurality of outer ferrite cores with a time difference or independently passing the ends of the plurality of inner ferrite cores with a time difference An object of the present invention is to provide a sequential independent power generation device having a

In addition, the present invention is configured to automatically move the position of the permanent magnet from the center to the inner and outer directions along the outer end on the rotating plate for the rotor by the driving means, so that there is no need to manually move the permanent magnet. Another object is to provide a sequential independent power generation device having an organic current strength selection function capable of automatically moving the position of a permanent magnet by control.

However, the object of the present invention is not limited thereto, and even if not explicitly mentioned, the object or effect that can be grasped from the solution or embodiment of the problem is also included therein.

Sequential independent power generation device having an organic current intensity selection function of the present invention for achieving the above object, a rotating shaft passing hole is formed in the center, a plurality of fixing holes for fixing a plurality of ferrite cores on the circumference are formed, , a pair of fixed plates coupled in a parallel state; a plurality of ferrite cores having a rod shape and fixedly installed between the pair of fixing plates so that both ends are fitted in the fixing holes of the ferrite core; a plurality of winding coils wound on the outer circumferential surface of the ferrite core, each induced electromotive force or an induced current generated when the magnetic field of the permanent magnet passes through each ferrite core, and delivered to the power control unit; a pair of rotating plates respectively fixed to both ends of the rotating shaft installed in a form penetrating the rotating shaft through hole in a state in which they are disposed close to each other on the outside of the pair of fixed plates to rotate together with the rotating shaft; a permanent magnet installed in the inner side of the rotating plate to have an S pole and an N pole facing each other so as to have opposite directions, and providing a magnetic field to the plurality of ferrite cores; and a magnet moving means configured on the rotating plate to move the position of the permanent magnet, wherein the fixed plate includes a plurality of outer fixing holes spaced apart from each other by a predetermined distance on a first circumference having a predetermined diameter, and the plurality of A plurality of inner fixing holes are configured to be spaced apart from each other by a predetermined interval in a second circumference shape having a smaller diameter than the first circumference shape inside of the outer fixing hole, and the outer fixing hole and the inner fixing hole are in a straight line along the outward direction from the center of the fixing plate is configured to be disposed on, the plurality of ferrite cores are composed of a plurality of outer ferrite cores fixedly installed by being fitted in the outer fixing hole, and a plurality of inner ferrite cores being fixedly installed by being fitted in the inner fixing hole, The winding coil includes a first winding coil wound around the outer ferrite core and a second winding coil wound around the inner ferrite core, wherein the first winding coil has a larger number of turns than the second winding coil. is configured so that the intensity of induced current generated when the permanent magnet passes the end of the outer ferrite core is greater than the intensity of the induced current generated when the end of the inner ferrite core passes, and the magnet moving means is the permanent magnet to move inward and outward from the center of the rotating plate in an outward direction to sequentially pass the ends of the plurality of outer ferrite cores while the permanent magnet rotates according to the rotation of the rotating plate, so that the first winding coil passes through the first winding coil. The induced current is generated or the ends of the plurality of inner ferrite cores are sequentially passed so that the second induced current is generated through the second winding coil, and the magnet moving means is formed on the rotating plate. and a guide part for guiding the movement of the permanent magnet, and a magnet fixing part for fixing the position-adjusted permanent magnet by being guided to the guide part, wherein the guide part is formed on the inner surface of the rotating plate and of the rotating plate It is formed in the form of a long hole with a predetermined length along the outward direction from the center, so that the permanent magnet is inserted and seated and the position is moved. It is configured to include a front rail groove for locking, and a rear rail groove formed on the outer surface of the rotating plate and formed along the front rail groove to be connected to the front rail groove and configured to have a width narrower than the width of the front rail groove, , The magnet fixing part is configured to extend from the permanent magnet, is configured to protrude from the rotating plate through the rear rail groove, and is configured to move along the rear rail groove by interlocking with the movement of the permanent magnet, and is threaded on the outer circumferential surface and a fixing member made of the formed coupling rod and a nut, screwed to the coupling rod, and fixing the permanent magnet to a predetermined position of the front rail groove by tightening.

According to the above, the present invention is an improvement of the time difference generator of the previously registered Patent Registration No. 10-1324546, and an outer ferrite core and an inner ferrite core are configured in different cylindrical shapes on a fixed plate, and each of the outer and inner ferrite cores The first and second winding coils are wound to have a different number of turns on the pole, and a permanent magnet is installed on the rotating plate rotating outside the fixed plate. According to the movement of the position of the magnet, the permanent magnet can selectively pass while facing the end of the outer ferrite core or the inner ferrite core, so power generation is achieved by selecting the induced current generation strength by the position movement of the magnet even without changing other conditions. can make you lose

On the other hand, in the present invention, the magnet moving means of another type can move the position of the magnet by a motor driving method, so that the magnet moves automatically without a separate manual operation, thereby improving the convenience of operation.

1 is a perspective view showing a sequential independent power generation device having an organic current intensity selection function according to a first embodiment of the present invention;
2 is an exploded perspective view showing a sequential independent power generation device having an organic current intensity selection function according to a first embodiment of the present invention;
3 is a cross-sectional view showing a sequential independent power generation device having an organic current intensity selection function according to a first embodiment of the present invention;
4 is a view showing an example of the first winding coil (a) wound on the outer ferrite core of FIG. 1 and the second winding coil (b) wound on the inner ferrite core,
5 is a view showing the arrangement of a plurality of outer ferrite cores and a plurality of inner ferrite cores installed on the fixing plate of the present invention,
6 is a view showing the position adjustment state of the permanent magnet installed so as to be position adjustable on the rotating plate for the rotor of the present invention,
7 is a view showing a state in which the installation position of the permanent magnet is changed in FIG. 3;
8 is a sectional view showing a main part of another form of the position moving means of the present invention,
9 is a perspective view showing a sequential independent power generation device having an organic current intensity selection function according to a second embodiment of the present invention;
10 is an enlarged view showing the main part of the rotating plate for the rotor shown in FIG.
11 is a view showing the positional state of the permanent magnets on both sides and the ferrite core end installed by adjusting the position on the rotating plate for the rotor of the present invention according to the second embodiment;
12 is a cross-sectional view showing a sequential independent power generation device having an organic current intensity selection function according to the second embodiment.

The above objects, other objects, features and advantages of the present invention will be easily understood through the following preferred embodiments in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed content may be thorough and complete, and the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

In this specification, when a component is referred to as being on another component, it may be directly formed on the other component or a third component may be interposed therebetween. In addition, in the drawings, the thickness of the components is exaggerated for effective description of technical content.

Embodiments described herein will be described with reference to cross-sectional and/or plan views, which are ideal illustrative views of the present invention. In the drawings, thicknesses of films and regions are exaggerated for effective description of technical content. Accordingly, the shape of the illustrative drawing may be modified due to manufacturing technology and/or tolerance. Therefore, embodiments of the present invention are not limited to the specific form shown, but also include changes in the form generated according to the manufacturing process. For example, the etched region shown at a right angle may be rounded or have a predetermined curvature. Accordingly, the regions illustrated in the drawings have properties, and the shapes of the illustrated regions in the drawings are intended to illustrate specific shapes of regions of the device and not to limit the scope of the invention. In various embodiments of the present specification, terms such as first, second, etc. are used to describe various components, but these components should not be limited by these terms. These terms are only used to distinguish one component from another. The embodiments described and illustrated herein also include complementary embodiments thereof.

The terminology used herein is for the purpose of describing the embodiments, and is not intended to limit the present invention. In this specification, the singular also includes the plural, unless specifically stated otherwise in the phrase. As used herein, 'comprises' and/or 'comprising' does not exclude the presence or addition of one or more other elements.

In describing the specific embodiments below, various specific contents have been prepared to more specifically describe the invention and help understanding. However, a reader having enough knowledge in this field to understand the present invention may recognize that it may be used without these various specific details. In some cases, it is mentioned in advance that parts that are commonly known and not largely related to the invention are not described in order to avoid confusion for no reason in describing the present invention in describing the invention.

Hereinafter, with reference to FIGS. 1 to 8, a sequential independent power generation device 1 having an organic current intensity selection function according to a first embodiment of the present invention will be described.

Sequential independent power generation device (1) of the present invention is a pair of fixed plates 10, a plurality of ferrite cores (30a, 30b), a plurality of winding coils (40a, 40b), a pair of rotating plates for the rotor (50) , is configured to include a plurality of permanent magnets (60), the magnet moving means (70).

The fixing plate 10 is composed of a pair, and is configured to be coupled to be spaced apart from each other at a predetermined interval through the fixing and spacing means 20 in parallel with each other. Here, the fixing and spacing means 20 includes a plurality of supporters 21 formed in a circular rod shape having a predetermined diameter and length and installed between a pair of fixing plates 10; It may be composed of a plurality of bolts 22 and nuts 23 that are mutually fastened while being installed to pass through the pair of fixing plates 10 and the supporter 21 , respectively.

The fixing plate 10 has a rotation shaft passing hole 11 formed in the center and fixed holes 12a and 12b for fixing the ends of a plurality of ferrite cores at predetermined intervals along a circumference having a predetermined diameter to be formed. is composed

Specifically, the fixing plate 10 is configured with a plurality of outer fixing holes 12a spaced apart from each other in a first circumferential shape having a predetermined diameter, and the first circumferential shape inside the plurality of outer fixing holes 12a. A plurality of inner fixing holes (12b) are configured to be spaced apart from each other by a predetermined interval in the shape of a second circumference having a smaller diameter inward. In addition, each of the outer fixing hole (12a) and the inner fixing hole (12b) is configured to be arranged on a straight line along the outward direction from the center of the fixing plate (10).

The plurality of ferrite cores 30 are formed in a rod shape, and both ends are fixedly installed through the fixing holes 12a and 12b, and both ends exposed to the outside of the fixing plate 10 are permanent magnets when the permanent magnets 60 pass. Let the magnetic field generated in (60) form a closed circuit.

In the present invention, the plurality of ferrite cores 30 include a plurality of outer ferrite cores 30a fixedly installed by being fitted into the outer fixing hole 12a, and a plurality of inner ferrite cores 30b being fixedly installed by being fitted into the inner fixing hole 12b. ) is made of

A plurality of winding coils (40a, 40b) are installed in a form wound by a predetermined number of turns on the outer and inner ferrite cores (30a, 30b), respectively, and a permanent magnet (60) through each of the outer and inner ferrite cores (30a, 30b) ) is configured to induce an induced current generated when the magnetic field passes through, respectively, and transmit it to the power control unit 80 .

The plurality of winding coils 40a and 40b includes a plurality of first winding coils 40a wound around a plurality of outer ferrite cores 30a and a plurality of second winding coils wound on a plurality of inner ferrite cores 30b ( 40b), each of the first winding coils 40a is configured to have a larger number of turns compared to each of the second winding coils 40b, so that the permanent magnet 60 is disposed at the end of the outer ferrite core 30a. The intensity of the induced current generated when passing through is configured to be greater than the intensity of the induced current generated when passing through the end of the inner ferrite core 30b.

That is, since the induced current intensity induced in the coil is proportional to the number of turns (number of turns) the coil is wound around the core, the first winding coil 40a having a larger number of turns than the second winding coil 40b has a higher number of windings. A large induced current can be induced compared to the second winding coil 40b having a smaller .

A pair of rotating plates 50 for a rotor is a pair of rotating shafts 51 which are installed in a state to pass through the rotating shaft passing holes 11 formed at the center points of the fixed plates 10 in a state in which they are respectively disposed adjacent to the outside of the pair of fixed plates 10 . ) is fixed to both ends of the rotational force generating means 90 is configured to rotate together with the rotational shaft 51 in response to the number of rotations of the rotational shaft 51 connected to the shaft.

The permanent magnet 60 is installed in a form facing the S pole and the N pole so that the S pole and the N pole have opposite directions on the inside of the rotating plate 50 for the rotor, and rotates together with the rotating plate 50 for the rotor, and a plurality of outer ferrite cores 30a ) or to provide a magnetic field to the plurality of inner ferrite cores 30b.

The magnet moving means 70 moves the permanent magnet 60 installed on the rotating plate 50 for the rotor inward and outward from the center of the rotating plate 50 for the rotor to the outside in the direction of the outer end, so that the permanent magnet 60 is the rotating plate for the rotor The ends of the plurality of outer ferrite cores 30a are sequentially passed while rotating according to the rotation of 50 so that an induced current is generated through the first winding coil 40a, or of the plurality of inner ferrite cores 30b. It is a configuration for generating an induced current through the second winding coil 40b by passing the ends sequentially.

The magnet moving means 70 is formed on the rotating plate 50 for the rotor and includes a guide portion 71 for guiding the positional movement of the permanent magnet 60, and a permanent magnet 60 guided by the guide portion 71 to adjust the position. ) is configured to include a magnet fixing part 75 for fixing.

The guide part 71 is formed on the inner surface of the rotating plate 50 for the rotor, and is formed in the form of a long hole with a predetermined length from the center of the rotating plate 50 for the rotor to the outside, so that the permanent magnet 60 is inserted and seated. A front rail groove 72 to allow movement, is formed on the outer surface of the rotating plate 50 for a rotor and is formed along the front rail groove 72 so as to be connected to the front rail groove 72, the front rail groove 72 It is configured to include a rear rail groove 73 configured to have a narrower width than the width of the .

Magnet fixing part 75 is configured to extend from the permanent magnet 60, is configured to protrude from the rotating plate 50 for the rotor through the rear rail groove 73, in conjunction with the movement of the permanent magnet (60) It is configured to move along the rear rail groove 73 and is made of a coupling rod 76 having a thread on the outer circumferential surface, and a nut, and is screwed to the coupling rod 76 and fastens the permanent magnet 60 to the front rail groove. (72) may be configured to include a fixing member (77) for fixing to a predetermined position.

In this embodiment, the user manually changes the position of the permanent magnet 60 to fix the position at the outer end of the front rail groove 72 as shown in FIG. 6 (a), or as shown in FIG. The position can be fixed to the inner end of the front rail groove (72).

The user rotates the fixing member 77 in the fastening direction of the coupling rod 76 to release the fastening, and moves the permanent magnet 60 to the outer end or the inner end of the front rail groove 72 . Then, by fastening the fixing member 77 to the coupling rod 76 again and tightening it, the position of the permanent magnet 60 in the front rail groove 72 can be maintained.

When the permanent magnets 60 are rotated in association with the rotation of the rotating plate 50 for the rotor in a state where the position is fixed at the outer end of the front rail groove 72, each permanent magnet 60 is a first winding coil As the ends of the outer ferrite cores 30a on which 40a is wound sequentially pass, the magnetic field generated from the permanent magnet 60 forms a closed circuit, and an induced current is induced in the first winding coil 40a, and the induced current is may be transmitted to the power control unit 80 .

On the other hand, when the permanent magnet 60 is rotated in conjunction with the rotation of the rotating plate 50 for the rotor in a state where the position is fixed at the inner end of the front rail groove 72, each permanent magnet 60 is a second As the winding coil 40b sequentially passes through the ends of the wound inner ferrite cores 30b, the magnetic field generated from the permanent magnet 60 forms a closed circuit, and an induced current is induced in the second winding coil 40b, and induced The current may be transmitted to the power control unit 80 .

As described above, the present invention provides a plurality of outer ferrite cores 30a on which a first winding coil 40a having a predetermined number of turns is wound, and a second winding coil having a different number of turns from that of the first winding coil 40a. A plurality of inner ferrite cores 30b on which 40b is wound are arranged in two columns having different diameters between a pair of fixed plates 10, respectively, and the permanent magnet 60 is a magnet moving means 70. By being configured so that it is possible to move and fix the position in and out from the center of the rotating plate 50 for the rotor in the outward direction, the permanent magnet 60 is optionally, as shown in FIG. 3, the ends of the outer ferrite cores 30a It is configured to pass through or pass through the ends of the inner ferrite cores 30b as shown in FIG. 7 to generate different induced current strengths.

As described above, the magnet moving means 70 of the present invention is formed on the rotating plate 50 for the rotor and has a guide portion 71 for guiding the movement of the permanent magnet 60, and the guide portion 71. It is configured to include a magnet fixing part 75 for fixing the guided and positioned permanent magnet 60 , and the user manually changes the position of the permanent magnet 60 and is positioned at the outer end of the front rail groove 72 . Although it has been described as being configured to be fixed or fixed to the inner end of the front rail groove 72, referring to FIG. 8, the magnet moving means 70' of the present invention is a permanent magnet automatically by a motor driving method. It can be configured to move the position (60).

The magnet moving means 70 ′ of the present invention shown in FIG. 8 is formed on the rotating plate 50 for a rotor and includes a guide part 71 , which guides the position movement of the permanent magnet 60 , and the permanent magnet 60 by a motor. It is configured to include a magnet movement driving unit 80 for moving the position in a driving manner.

The magnet movement driving unit 80 includes a driving motor 82 fixedly installed at the outer end of the rotating plate 50 for the rotor, a rotating support unit 83 installed at the inner end of the rear rail groove 73, and a rear rail groove ( 73), one end is configured to be rotated by the rotation support unit 83, and the other end is configured to be coupled with the drive shaft of the drive motor 82, configured to rotate according to the driving of the drive motor 82, and is formed on the outer circumferential surface. The screw rod 84 having a threaded thread is fixed to the rear surface of the permanent magnet 60 and is installed to be inserted into the rear rail groove 73, and the screw rod 84 is penetrated through the screw rod 84 and the ball-screw It is configured to be connected in this way and is configured to include a moving member 86 for moving the permanent magnet 60 along the front rail groove 72 while moving along the screw rod 84 according to the rotation of the screw rod 84 . do.

With the above configuration, according to the driving control of the driving motor 82, the permanent magnet 60 is automatically positioned at the outer end or the inner end of the front rail groove 72 without the need to manually select the induced current strength. development can proceed.

On the other hand, a power control unit that is connected to both ends of the winding coils 40a and 40b wound around each ferrite core 30a and 30b on the fixed plate 10 on one side of the present invention, and to which each winding coil 40a, 40b is connected. A terminal plate 90 capable of connecting the input terminal of 80 may be provided.

At this time, the terminal plate 90 of the present invention is electrically connected to both ends of the first winding coil 40a wound around the outer ferrite core 30a, and a first terminal part ( 91) and a second terminal portion 92 that is electrically connected to both ends of the second winding coil 40b wound around the inner ferrite core 30b and can connect the input terminal of the power control unit 80 do. Accordingly, the first induced current induced from the first winding coil 40a wound around each outer ferrite core 30a may be transmitted and input to the power control unit 80 through the first terminal unit 91, and each The second induced current induced from the second winding coil 40b wound around the inner ferrite core 30b may be transmitted and input to the power control unit 80 through the second terminal unit 92, and the power control unit 80 may be configured to separately store and manage the first organic current transmitted through the first terminal unit 91 and the second organic current transmitted through the second terminal unit 92 , respectively.

Hereinafter, with reference to FIGS. 9 to 12, a sequential independent power generation device having an organic current intensity selection function according to a second embodiment of the present invention will be described.

In the following description, the same reference is given to the same configuration as in the first embodiment, and the description thereof is omitted, and only the configuration having a difference will be described.

In the second embodiment, each of the longitudinal ends of the front rail grooves 72a and 72b formed on the inner surfaces of each of the pair of rotor-type rotating plates 50a and 50b have outer left and right magnet moving grooves 72aa extending in both directions. , 72ba) and the inner left and right magnet moving grooves 72ab and 72bb are formed.

In a state in which the permanent magnet 60 is moved to the outer or inner ends of the front rail grooves 72a and 72b, the outer left and right magnet movement grooves 72aa and 72ba formed at the ends of the front rail grooves 72a and 72b or the inside It is configured to be movable left and right along the left and right magnet moving grooves 72ab and 72bb.

The present invention is formed so as to be connected to the outer left and right magnet movement grooves 72aa and 72ba on the outer surface of the rotating plates 50a and 50b, and the permanent magnets 60a and 60b are positioned to be moved along the outer left and right magnet movement grooves 72aa and 72ba. At this time, the outer rod moving grooves 73aa and 73ba for moving the coupling rod 76 also are configured.

In addition, the outer surface of the rotating plate (50a, 50b) is formed to be connected to the inner left and right magnet movement grooves 72ab and 72bb, when the permanent magnets 60a and 60b are moved along the inner left and right magnet movement grooves 72ab and 72bb. , the coupling rod 76 is also configured to move the inner rod moving grooves (73ab, 73bb) for moving together.

At this time, the outer left and right magnet moving grooves 72aa and 72ba are configured in an arc shape having the same curvature as that of the plurality of outer ferrite cores 30a arranged in the first circumferential shape, and the inner left and right magnet moving grooves 72ab and 72bb are , is configured in an arc shape having the same curvature as the plurality of inner ferrite cores 30b arranged in a second circumferential shape to move the permanent magnets 60a and 60b along the outer left and right magnet moving grooves 72aa and 72ba. However, according to the rotation of the rotating plates 50a and 50b, the permanent magnets 60a and 60b are configured to pass sequentially through the ends of the outer ferrite core 30a, and also permanently along the inner left and right magnet movement grooves 72ab and 72bb. Even when the magnets 60a and 60b are moved, the permanent magnets 60a and 60b sequentially pass through the ends of the inner ferrite core 30b according to the rotation of the rotating plates 50a and 50b.

In the present invention according to the second embodiment, in a state in which the permanent magnets 60a and 60b are moved to the outer or inner ends of the front rail grooves 72a and 72b, the outer left and right magnet moving grooves 72aa and 72ba formed at each end. ) or by moving left and right along the inner left and right magnet moving grooves 72ab and 72bb, so that the position can be adjusted.

When the permanent magnets 60a and 60b on both sides pass through both ends of the ferrite core 30a and 30b, the central axis of the ferrite core, the center of the permanent magnet 60a on one side, and the center of the permanent magnet 60b on the other side It is configured such that the center of at least one side of the permanent magnet 60a and the center of the other side of the permanent magnet 60b are shifted from the central axis of the ferrite cores 30a and 30b without a position in which they all coincide. .

With this configuration, as the rotor plates 50a and 50b on both sides rotate, one permanent magnet 60a first passes one end of the ferrite core and then, the permanent magnet 60b on the other side rotates the other side of the ferrite core. As the end passes, the attraction between the permanent magnets 60a and 60b and the ferrite cores 30a and 30b is dispersed according to the rotation of the rotating plates 50a and 50b on both sides to make the rotation easier, thereby improving the power generation efficiency. can do it

In the above, the present invention has been shown and described in connection with preferred embodiments for illustrating the principles of the present invention, but the present invention is not limited to the construction and operation as shown and described as such. Rather, it will be apparent to those skilled in the art that many changes and modifications can be made to the present invention without departing from the spirit and scope of the appended claims. Accordingly, all such suitable alterations and modifications and equivalents are to be considered as falling within the scope of the present invention.

10… fixed plate
11… shaft through hole
12a… outer anchor hole
12b… inner anchor hole
20… Fixing and spacing means
30a… outer ferrite core
30b… inner ferrite core
40a… 1st winding coil
40b... 2nd winding coil
50… Rotor plate
51… rotation shaft
60… permanent magnet
70… terminal board
80… power control unit
90… means of generating rotational force
70… Magnet moving means
71… guide
72… front rail groove
73… rear rail groove
75… magnetic fixing part
76… combined rod
77… fixing member
80… Magnet moving drive unit
82… drive motor

Claims (1)

a pair of fixing plates having a rotation shaft passing hole formed in the center, a plurality of fixing holes for fixing a plurality of ferrite cores on a circumference, and coupled in a parallel state;
a plurality of ferrite cores having a rod shape and fixedly installed between the pair of fixing plates so that both ends are fitted in the fixing holes of the ferrite core;
a plurality of winding coils wound on the outer circumferential surface of the ferrite core, each induced electromotive force or an induced current generated when the magnetic field of the permanent magnet passes through each ferrite core, and delivered to the power control unit;
a pair of rotating plates respectively fixed to both ends of the rotating shaft installed in a form penetrating the rotating shaft through hole in a state in which they are disposed close to each other on the outside of the pair of fixed plates to rotate together with the rotating shaft;
a permanent magnet installed in the inner side of the rotating plate to have an S pole and an N pole facing each other so as to have opposite directions, and providing a magnetic field to the plurality of ferrite cores;
and a magnet moving means configured on the rotating plate to move the position of the permanent magnet.
A plurality of outer fixing holes are configured in the fixing plate to be spaced apart from each other by a predetermined distance in a first circumferential shape having a predetermined diameter, and are spaced apart from each other by a predetermined interval in a second circumferential shape having a smaller diameter than the first circumferential shape inside the plurality of outer fixing holes. A plurality of inner fixing holes are constituted,
The outer fixing hole and the inner fixing hole are configured to be arranged on a straight line along the outward direction from the center of the fixing plate,
The plurality of ferrite cores include a plurality of outer ferrite cores fitted and fixedly installed in the outer fixing hole, and a plurality of inner ferrite cores fitted and fixedly installed in the inner fixing hole,
The plurality of winding coils includes a first winding coil wound around the outer ferrite core and a second winding coil wound around the inner ferrite core, wherein the first winding coil has more windings than the second winding coil. It is configured to have a bow, and the intensity of induced current generated when the permanent magnet passes through the end of the outer ferrite core is greater than the intensity of the induced current generated when the end of the inner ferrite core passes,
The magnet moving means moves the permanent magnet inward and outward along the outward direction from the center of the rotating plate, so that the permanent magnet rotates according to the rotation of the rotating plate, and passes the ends of the plurality of outer ferrite cores sequentially. The first induced current is generated through the first winding coil or the ends of the plurality of inner ferrite cores are sequentially passed to generate the second induced current through the second winding coil,
The magnet moving means is formed on the rotating plate and is configured to include a guide part for guiding the positional movement of the permanent magnet, and a magnet fixing part for fixing the position-adjusted permanent magnet by being guided to the guide part,
The guide part is formed on the inner surface of the rotating plate and is formed in the form of a long hole with a predetermined length from the center of the rotating plate in the outward direction so that the permanent magnet is inserted and seated in a front rail groove so that the position is moved, and the outer surface of the rotating plate It is formed in and is formed along the front rail groove to be connected to the front rail groove and is configured to include a rear rail groove configured to have a width narrower than the width of the front rail groove,
The magnet fixing part is configured to extend from the permanent magnet and protrude from the rotating plate through the rear rail groove, and is configured to move along the rear rail groove in conjunction with the movement of the permanent magnet, and has a thread on the outer circumferential surface An organic current strength selection function, characterized in that it comprises a coupling rod formed and a nut, screwed to the coupling rod, and fixing the permanent magnet to a predetermined position of the front rail groove by tightening. Sequential independent power generation unit with.

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