KR101753689B1 - The stand-alone type magnetic generator - Google Patents

Abstract

The present invention relates to a stand-alone magnetic generator. A pair of magnet plates which are coupled to the drive shaft by forming one or more magnet grooves, a pair of magnet covers each having a magnet inside and coupled to the magnet groove, and pin grooves for fixing the drive shaft to the magnet plate, A rotor constituting a magnet hub coupled to a side surface of the magnet plate; An outer case rotatably coupled to the drive shaft through bearings so as to be arranged on both sides of the rotor to be fixed to the bottom or outer structure and forming at least one coupling groove and forming an outer groove corresponding to the magnet groove; An interval bolt coupled to the coupling groove of the outer case; A coil plate coupled to the drive shaft and arranged on both sides of the rotor in a state of being fixed to the outer case through spacing bolts and having coil grooves corresponding to the magnet grooves of the rotor to form coils in the coil grooves; A control plate coupled to the drive shaft, the control plate being fixed to an outer side of the outer case by forming a slide groove; The driving unit includes a driving plate coupled to the driving shaft and coupled to the magnet, and a driving hub coupled to the driving plate by forming a driving pin groove for fixing the driving plate to the driving shaft.

Description

The stand-alone type magnetic generator

[0001] The present invention relates to a stand-alone magnetic generator, and more particularly to a stand-alone magnetic generator which is capable of improving performance of a generator by minimizing noise and wear by preventing friction by separating a magnet and a coil generating electric power, To thereby improve the efficiency of power generation.

Generally, a generator is composed of a stator having a coil formed on the outer side of a drive shaft while a rotor is coupled to a drive shaft, as shown in Korean Patent Registration No. 10-1070385, thereby generating power by rotating the rotor.

However, even if the power generator is constructed as described above, even if the power generator can perform self-power generation, there is a problem in that generation of power is limited and power generation efficiency is poor.

It is an object of the present invention to improve the efficiency of generating electricity when a magnet is driven by forming a coil plate on both sides of a magnet and to prevent breakage while reducing wear and noise due to friction because the magnet and the coil are spaced apart, And to provide a stand-alone magnetic generator which is simple in construction and easy to manufacture and maintain.

In addition, the present invention protects the magnets and coils required for generating electric power through the magnet cover and the coil protecting portion, and can be used semi-permanently while preventing problems such as breakage of the magnets and coils due to the external environment and performance deterioration, To provide a stand-alone magnetic generator capable of providing economical effect and convenience.

Another object of the present invention is to provide a stand-alone magnetic generator capable of easily adjusting a position of a throttle plate and generating electricity smoothly with a rotor rotating easily.

According to an aspect of the present invention, A pair of magnet plates which are coupled to the drive shaft by forming one or more magnet grooves, a pair of magnet covers each having a magnet inside and coupled to the magnet groove, and pin grooves for fixing the drive shaft to the magnet plate, A rotor constituting a magnet hub coupled to a side surface of the magnet plate; An outer case rotatably coupled to the drive shaft through bearings so as to be arranged on both sides of the rotor to be fixed to the bottom or outer structure and forming at least one coupling groove and forming an outer groove corresponding to the magnet groove; An interval bolt coupled to the coupling groove of the outer case; A coil plate coupled to the drive shaft and arranged on both sides of the rotor in a state of being fixed to the outer case through spacing bolts and having coil grooves corresponding to the magnet grooves of the rotor to form coils in the coil grooves; A control plate coupled to the drive shaft, the control plate being fixed to an outer side of the outer case by forming a slide groove; And a drive unit coupled to the drive shaft and including a drive plate coupled to the magnet and a drive hub coupled to the drive plate to define a drive pin groove for fixing the drive plate to the drive shaft. to provide.

The present invention improves the efficiency of generating electricity when a magnet is driven by forming a coil plate on both sides of a magnet, and also prevents breakage by reducing wear and noise due to friction because the magnet and the coil are separated from each other. It is simple and has the advantage of convenient manufacture and maintenance.

In addition, by protecting the magnets and coils necessary for generating electric power through the magnetic cover and the coil protecting portion, it is possible to use them semi-permanently while preventing problems such as breakage of the magnets and coils due to the external environment and deterioration of performance, And it is advantageous in that it can provide convenience and convenience.

And the position of the throttle plate can be easily adjusted so that the rotor can easily rotate and generate electricity smoothly.

1 and 2 are a perspective view and a front view showing a stand-alone magnetic generator according to the present invention.
3 is an exploded perspective view showing a rotor of a stand-alone magnetic generator according to the present invention.
4 is an exploded perspective view showing an outer case of a stand-alone magnetic generator according to the present invention.
5 is an exploded perspective view showing a coil plate of a stand-alone magnetic generator according to the present invention.
6 is a perspective view showing a throttle of a stand-alone magnetic generator according to the present invention.
7 is an exploded perspective view showing a driving unit of a stand-alone magnetic generator according to the present invention.
8 is an exploded perspective view showing a stand-alone magnetic generator according to the present invention.

In order to achieve the above object, the present invention is as follows.

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

The independent magnetic generator 100 of the present invention includes a drive shaft 10, a rotor 20, an outer case 30, an interval bolt 40, a coil plate 50, a throttle plate (not shown) 60, and a driving unit 70.

First, the drive shaft 10 is formed to rotate in place by an external force, and is formed as a shaft generally used at present, and a detailed description thereof will be omitted.

3 and 8, the rotor 20 is coupled to the drive shaft 10 and rotates together with the drive shaft 10.

In detail, the magnet plate 21 coupled to the drive shaft 10 and including two or more magnet grooves 21a is formed.

Here, it is preferable that the magnet groove 21a further includes an attachment groove 21aa larger than the diameter of the magnet groove 21a.

This is for allowing the magnet cover 22 to be described later to be easily engaged with the magnet groove 21a.

A magnet cover 22 is formed on the magnet plate 21 to receive the magnet m in the magnet groove 21a.

Here, the magnet cover 22 is formed to cover two magnets m from both sides.

In other words, it is formed in the same shape as a general lid (not shown in the figure) to protect the magnet m.

The magnet cover 22 may be provided with a mounting frame 22a so that the magnet cover 22 can be easily mounted on the mounting groove 21aa formed in the magnet groove 21a.

That is, the magnet cover 22 is coupled to the magnet plate 21 and rotates together with the magnet plate 21.

The magnet hub 23 is formed such that the magnet plate 21 is rotated like the drive shaft 10 by fixing the magnet plate 21 to the drive shaft 10 by being coupled to the side surface of the magnet plate 21 and the drive shaft 10 have.

The magnet hub 23 is formed with a pin groove 23a to which the pin p is coupled to fix the magnet hub 23 to the drive shaft 10.

That is, the magnet hub 23 is formed to be coupled to the drive shaft 10 through the pin p while being coupled to the magnet plate 21 through a coupling member (not shown) such as a bolt.

In addition, the magnet plates 21 are formed as a pair, and two magnet hubs 23 coupled to the magnet plate 21 are formed in pairs.

4 and 8, the outer case 30 is coupled to the inner side of the drive shaft 10 and is formed to be fixed to a floor or an outer structure.

In addition, a bearing 31 is formed so that the driving shaft 10 can be coupled to the center portion of the rotor 20 smoothly, and the engaging groove 32 is formed at each of the corner portions. The magnet groove 21a of the rotor 20, The outer grooves 33 corresponding to the outer circumferential surface are formed.

The outer case 30 is arranged on both sides of the rotor 20 and is formed symmetrically with respect to each other.

In addition, the outer case 30 may further include at least one fixing groove 34 to which a coupling member such as a bolt is coupled.

This is for adjusting the position of the throttle plate 60 together with the fixing of the throttle plate 60 to be described later.

The outer groove 33 formed in the outer case 30 is formed such that a coupling member used when the coil c is coupled to the coil plate 50 to be described later is positioned.

The gap bolt 40 is coupled to the coupling groove 32 formed in the outer case 30 and is formed to connect and fix the pair of outer cases 30 to each other.

5 and 8, the drive plate 10 is inserted into the coil plate 50. The coil plate 50 is coupled to the gap bolt 40 coupled to the outer case 30, 30, respectively.

The coil plate 50 is formed with a coil groove 51 corresponding to the magnet groove 21a formed in the rotor 20 and coupled with the coil c.

The coil plate 50 is arranged to be symmetrical with respect to one another while two pairs of the coil plates 50 are arranged on both sides of the rotor 20 like the outer case 30.

And a coil protecting portion 53 including a fixing portion 52 coupled to the inside of the coil c so as to protect the coil c coupled to the coil groove 51 may be further formed.

Here, the coil protecting part 53 is formed of two pairs so as to be coupled to both sides of one coil c.

In addition, the fixed portion 52 formed in the coil protecting portion 53 is formed with a spaced apart groove 52a.

When the coil c is coupled to the fixed portion 52 of the coil protecting portion 53, the spacing groove 52a is opened or narrowed according to the size of the coil c, So that the coils (c) of various sizes can be firmly fixed to the coil protecting portion (53).

In addition, the coil plate 50 coupled to the outer case 30 is formed with a groove h corresponding to the coupling groove 32 formed in the outer case 30.

In addition, the coil c formed on the coil plate 50 is connected to an external power supply device (not shown) so that electricity generated by the rotor 20 and the coil plate 50 can be used. It is one thing.

The coils c are arranged on both sides of the rotor 20, and the coils c facing each other may be connected to each other.

6 and 8, the adjusting plate 60 is formed such that the driving shaft 10 is fitted inwardly and fixed to the outer case 30 through the coupling member to the outside of the outer case 30.

The adjustment plate 60 is formed with an elongated slot groove 61 for adjusting the position of the adjustment plate 60 when the switch plate 60 is engaged with the outer case 30. The slide groove 61 is formed in the outer case 30 And the engaging member is formed to be engaged with the engaging member.

In addition, the control board 60 is formed with a switch s which can receive a signal from the outside and emit a signal.

For example, the switch s is configured to transmit an electric signal to the outside while receiving an electric signal from an external power source.

In addition, a battery (not shown) capable of applying power to the switch s is connected to the switch s to charge the power source.

7 and 8, the drive unit 70 is coupled to the drive shaft 10 inwardly and is configured to be rotated simultaneously with the rotation of the drive shaft 10.

The driving plate 71 is coupled to the driving plate 71 through a coupling member and the driving plate 71 is fixed to the driving shaft 10 A driving hub 72 is formed.

The drive hub 72 is formed with a drive pin groove 72a to which the pin p is coupled so that the drive hub 72 can be easily coupled to the drive shaft 10.

In addition, the drive plate 71 is provided with a groove hk to which the magnet m is coupled.

In addition, the driving unit 70 is formed so that the switch s and the magnet m coupled to the throttle plate 60 can exchange signals with each other, and the driving unit 70 is driven by a signal generated from the switch s. Is rotated.

The rotor 20 and the driving unit 70 are coupled to the driving shaft 10 to rotate the rotor 20 and the driving unit 70 like the driving shaft 10 and the outer case 30 and the coil plate The outer case 30 and the coil plate 50 are formed in a fixed state without being rotated unlike the drive shaft 10.

When the coupling between the driving shaft 10, the rotor 20, the outer case 30, the spacing bolts 40, the coil plate 50, the throttle plate 60, the driving unit 70, And a groove (not shown) to which the coupling member is coupled is formed. Therefore, a detailed description thereof will be omitted.

In addition, the drive shaft 10 is connected to the rotor 20, the outer case 30, the gap bolts 40, the coil plate 50, the throttle plate 60, and the drive unit 70 in which the drive shaft 10 is located. (Not shown in the figure) is formed, and thus a detailed description thereof will be omitted.

The magnet plate 21, the outer case 30, and the coil plate 50 formed on the rotor 20 are arranged in a symmetrical form in which two pairs of magnet plates are opposed to each other.

Hereinafter, the operation according to the preferred embodiment of the present invention will be described.

First, as shown in Fig. 8, the magnet m is coupled to the inside of the pair of magnet covers 22. As shown in Fig.

The mounting surface 22a of the magnet cover 22 is arranged in the mounting groove 21aa included in the magnet groove 21a while connecting the magnet cover 22 to the magnet groove 21a formed in the magnet plate 21 So that the magnet cover (22) is coupled to the magnet plate (21).

The magnet plate 21 and the magnet hub 23 are fixed to each other by using a coupling member while closely contacting the magnet hub 23 to the pair of magnet plates 21 individually.

Then the pin 20 is fixed to the driving shaft 10 by coupling the pin p to the pin groove 23a formed in the magnet hub 23 while coupling the driving shaft 10 to the inside of the rotor 20.

The coils c are coupled to the coil grooves 51 formed in the coil plate 50. The coils c formed on the coil protector 53 while the coil protector 53 is positioned on both sides of the coil c, The coil 52 is inserted into the inside of the coil c so that the coil coils c are coupled to the coil coils 53 on both sides.

In addition, while the coil protecting portion 53 is coupled to the coil groove 51, the coil protecting portion 53 is firmly fixed to the coil plate 50 by using the engaging member.

A pair of coil plates 50 are formed as described above.

One coil plate 50 is coupled to one side of the outer case 30. The gap bolt 40 is inserted into the coupling groove 32 formed in the outer case 30, To be coupled to the coil plate (50).

In addition, the outer case 30 and the coil plate 50 may be completely fixedly coupled using a coupling member according to the purpose or convenience of the user.

One outer case 30 and one coil plate 50 are coupled to the drive shaft 10 while being coupled to the drive shaft 10 so as to be positioned at one side and the other side of the rotor 20, respectively.

When the pair of outer casings 30 and the coil plate 50 are coupled to the drive shaft 10, the pair of outer casings 30 and the coil plate 50 are coupled to each other through the gap bolts 40, So that the outer case 30 and the coil plate 50 are fixed to each other.

A bearing 31 is formed in the outer case 30 so that the drive shaft 10 can be smoothly rotated in a state where the drive shaft 10 is fitted in the outer case 30 and the outer case 30 and the coil plate 50 It is possible to maintain the fixed state.

The outer case 30 may be coupled to the outer structure 30 or the outer case 30 may be coupled to the outer case 30 through the pedestal 80 by coupling the outer case 30 with the pedestal 80, It will be possible.

Then, the control plate 60 and the driving unit 70 are coupled to the driving shaft 10.

The fixing groove 34 formed in the outer case 30 while inserting the engaging member into the slide groove 61 of the regulating plate 60 while positioning the regulating plate 60 in the outer direction of the outer case 30, So that the adjustment plate 60 is engaged with the outer case 30.

A magnet m is coupled to a groove hk of a drive plate 71 formed on the drive unit 70 and a drive hub 72 is coupled to the drive plate 71 using a coupling member. The drive unit 70 is firmly fixed to the drive shaft 10 while the pin p is engaged with the drive pin groove 72a formed in the drive shaft 72. [

Here, when the driving unit 70 is coupled to the driving shaft 10, the switch s coupled to the throttle plate 60 and the magnet m formed in the driving unit 70 are coupled to each other while adjusting their positions to correspond to each other .

The rotor 20, the outer case 30, the spacing bolts 40, the coil plate 50, the throttle plate 60, and the driving unit 70 are coupled to the drive shaft 10, and the independent magnetic generator 100, .

In detail, the switch s coupled to the throttle plate 60 corresponds to the magnet of the driving unit 70 while rotating the throttle plate 60.

Here, the position of the adjusting plate 60 can be adjusted while rotating the adjusting plate 60 through the slide groove 61 formed in the adjusting plate 60.

The reason for adjusting the position of the driving unit 70 by rotating the throttle plate 60 as described above is that the driving unit 70 must be positioned such that the signal transmitted from the switch s and the magnetic field of the magnet m coupled to the driving unit 70, , The position of the throttle plate 60 is adjusted.

Then, when a signal is transmitted from the outside to the switch s coupled to the throttle plate 60, the signal corresponds to the magnet m of the driver 70 and the driver 70 rotates.

Then, the driving shaft 10 to which the driving unit 70 is coupled rotates at the same time.

The rotor 20 coupled to the drive shaft 10 rotates simultaneously with the rotation of the drive shaft 10 and electricity is generated while an electrical reaction with the coil c formed on the coil plate 50 occurs, Electricity can be delivered to the outside through the coil (c), and the electricity can be charged or used separately.

In this way, the coil plate 50 is positioned on both sides of the rotor 20, and electric power is generated at both sides of the rotor 20 when the rotor 20 rotates, thereby increasing the electricity generation efficiency.

Also, since the independent magnetic generator 100 has a simple structure, it is easy to manufacture, use, and maintain, thereby reducing manufacturing costs and maintenance costs, thereby providing excellent economic effects.

The friction between the rotor 20 and the coil plate 50 does not occur because the rotor 20 for generating electricity and the coil plate 50 are spaced apart from each other. , Dust and the like can be completely blocked in advance, so that the independent magnetic generator 100 can be used semi-permanently without failure or breakage, thereby providing convenience to the users.

The magnet m formed on the rotor 20 and the coil c formed on the coil plate 50 are surrounded by the magnet cover 22 and the coil protecting portion 53, (c) is protected from the external environment, problems such as breakage and deterioration of the performance of the magnet (m) and the coil (c) can be prevented in advance.

The magnets m and the coil c are easily connected to the rotor 20 and the coil through the coil grooves 51 of the coil plate 50 and the magnet groove 21a formed in the magnet plate 21 of the rotor 20. [ So that it can be fixed and fixed to the plate 50.

The position of the switch s coupled to the throttle plate 60 can be easily controlled through the slide groove 61 formed in the throttle plate 60 and the position of the magnet m and the switch s is easily generated and the rotor 20 is easily driven so that electricity can be easily generated by the smooth rotation of the rotor 20. [

Although the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, It is obvious to those who have knowledge of.

10:
20: Rotor
21: Magnet plate 21a: Magnetic groove
22: magnet cover 23: magnetic hub
23a: Pin groove
30: outer case
31: Bearing 32: Coupling groove
33: outer groove
40: Spacing bolt
50: coil plate
51: Coil groove
60: Throttle
61: Slide groove
70:
71: drive plate 72: drive hub
72a: drive pin groove
80: Stand
100: Stand-alone magnetic generator

Claims (5)

A drive shaft 10;
A pair of magnet plates 21 coupled to the drive shaft 10 by forming one or more magnet grooves 21a and a pair of magnet plates 21 having a magnet m inside thereof and coupled to the magnet groove 21a, A rotor 20 constituting a magnet hub 23 coupled to a side surface of the magnet plate 21 by forming pin grooves 23a for fixing the drive shaft 10 to the magnet plate 21;
Are rotatably coupled to the drive shaft (10) through bearings (31) so as to be arranged on both sides of the rotor (20), and are fixed to a floor or an outer structure and form one or more engagement grooves (32) An outer case 30 forming an outer groove 33 corresponding to the outer case 30;
An interval bolt (40) coupled to an engagement groove (32) of the outer case (30);
The rotor 20 is disposed on both sides of the rotor 20 in a state of being fixed to the outer case 30 through the gap bolts 40 and connected to the drive shaft 10, A coil plate (50) for forming a coil groove (51) and coupling the coil (c) to the coil groove (51);
A throttle plate 60 coupled to the drive shaft 10 and fixed to the outer side of the outer case 30 by forming a slide groove 61;
A drive plate 71 coupled to the drive shaft 10 and coupled to the magnet and a drive pin groove 72a for fixing the drive plate 71 to the drive shaft 10 are formed on the drive plate 71, And a driving unit (70) having a driving hub (72) coupled thereto,
The magnet cover 21a of the magnet plate 21 formed on the rotor 20 further includes a mounting groove 21aa and a mounting frame 22a mounted on the mounting groove 21aa is formed in the magnet cover 22. [ A stand-alone magnetic generator characterized further comprising a built-in magnetic generator.
delete The stand-alone magnetic generator according to claim 1, wherein the outer case (30) is further formed with at least one fixing groove (34).
The stand-alone magnetic generator according to claim 1, wherein the outer case (30) further comprises a pedestal (80) for fixing the outer case (30) to the floor.
The coil according to claim 1, wherein the coil plate (50) is further provided with a coil protecting portion (53) having a fixing portion (52) coupled to the inside of the coil (c) And,
Wherein the fixing portion (52) further includes an incised gap groove (52a) formed therein.

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