KR20150075124A - Generating system - Google Patents

Abstract

Disclosed in the present invention is a generating system including a frame, a main shaft, a weight movement stand, a weight movement means, a first driving gear, a second driving gear, a first driven gear, a first driving force delivery shaft, a second driven gear, a second driving force delivery shaft, a magnet rotating means, a first driving force delivery gear, a second driving force delivery gear, an acceleration gear box, and a generator. The generating system according to the present invention converts pendular movement into rotation, when the weight movement stand swings left and right, and rotates the first driving force delivery shaft always in the same direction to supply the rotation force to the generator through the acceleration gear box, thereby providing an effect of generating electric energy in the generator. The magnet rotating means using a repulsive power formed between the same electrodes of a magnet is installed on a delivery shaft delivering a rotation force of the main shaft to the generator, thereby providing an effect of helping rotation of the delivery shaft.

Description

{GENERATING SYSTEM}

More particularly, the present invention relates to a power generating apparatus, and more particularly, to a power generating apparatus, more particularly, to a power generating apparatus, And a magnet rotating means for rotating the transmission shaft for transmitting the rotational force of the main shaft to the generator.

In general, a generator that obtains electric energy by using the power supplied from an engine using fossil fuel has a disadvantage in that the energy efficiency is very low. In other words, in the case of a generator employing an engine, since the generator is operated only by the engine's power, the fossil fuel must continuously be consumed in order to generate the continuous power, and not only the cost is required for generating the power, There is a problem.

On the other hand, the registered patent No. 1058874 filed and filed by the present applicant discloses an example of a power generation apparatus. The power generated by the engine is transmitted to the hydraulic motor to operate the hydraulic motor. The power of the hydraulic motor is transmitted to the shaft through the chain to rotate the shaft. The rotational force of the shaft is transmitted to the generator through the belt, It has a structure that produces energy.

However, such generators also require constant output power of the engine to operate the generator, which means that fossil fuels continue to be consumed constantly, and thus electrical energy can be obtained through fossil fuels, There is a problem that efficiency is very low.

1) Korean Patent Laid-Open No. 10-2006-0008665 (Published on Jan. 27, 2006), entitled "Small Generator Using Weight Centered Weight & 2) Korean Patent Laid-Open No. 10-2012-0026765 (Publication date: March 20, 2012), title of invention: "Swing type play device which can be driven by self- 3) Korean Patent Application No. 10-2011-0102470 (Published on Sep. 16, 2011), entitled "Energy production system through wave action" 4) Korean Registered Patent No. 10-1246920 (Registered Date: Mar. 18, 2013)

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-mentioned problems, and an object of the present invention is to provide an apparatus and a method for efficiently performing a weight movement while lifting and lowering a cold motor connected to a main shaft in one direction, A magnet rotating means is provided which uses a repulsive force formed between the same poles of the magnets on a transmission shaft that transmits the rotational force of the main shaft to the generator and is configured to be able to obtain electric energy by driving the generator by using the rotational force generated in the main shaft while rotating So as to facilitate rotation of the shaft.

The above-mentioned objects are achieved by a frame structure comprising a frame provided on an upper portion thereof and constituting a basic frame; A main shaft rotatably installed on the mounting table; A cold pedestal extending downward from the main shaft and pivotally moving in the left and right direction and rotating the main shaft while pendulum movement to repeatedly rotate counterclockwise to the normal rotation; An acceleration means for pivoting the cold pedestal; A first driving gear installed at one end of the main shaft and rotated together with the main shaft; A second driving gear provided at the other end of the main shaft and rotating together with the main shaft; A first driven gear which is engaged with the first driving gear and rotates and has a smaller diameter than the first driving gear; A first power transmission shaft installed to rotate together with the first driven gear and to rotate only when the first driven gear rotates together when the first driven gear rotates forward and the first driven gear when the first driven gear rotates reversely; A second driven gear installed to rotate in engagement with the second drive gear and having a smaller diameter than the second drive gear; A second power transmission shaft installed to rotate together with the second driven gear so as to rotate only the second driven gear when the second driven gear rotates forward and to rotate together when the second driven gear rotates reversely; A rotor rotatably mounted on the first power transmission shaft and rotatably mounted on the first power transmission shaft, the rotor being equally spaced apart from the first power transmission shaft and fixed along the circumferential direction of the housing wall surface, Wherein at least two pole permanent magnets which are magnetized so as to face the center of the housing face each other and a pole face such as the permanent magnet of the housing are opposed to each other and are magnetized so as to have repulsive force with each other, Wherein the permanent magnet of the housing is installed to assist the rotation of the first power transmission shaft to which the rotor is fixed by rotating the rotor through a repulsive force that is a force pushing the permanent magnet of the rotor A magnet rotating means; A first power transmission gear coupled to a portion of the second power transmission shaft and rotating together; And a second power transmission shaft that is coupled to a portion of the first power transmission shaft and is engaged with the first power transmission gear so that when the second power transmission shaft rotates together with the second driven gear, A second power transmission gear for forward rotation; A speed increasing gear box connected to an end of the first power transmitting shaft for increasing the rotational force of the first power transmitting shaft through a combination of a plurality of gears and outputting the rotational force; And a generator connected to an output portion of the speed increasing gear box to receive power from the speed increasing gear box to generate electric energy.

And an electromagnet disposed between the housing permanent magnet and the rotor permanent magnet and fixed to the housing, the electromagnet capable of generating a magnetic field line in the same or opposite direction as the magnetic field line of the permanent magnet according to the direction of current to be injected, And further comprising:

The auxiliary weight is configured to have an anchor shape. The main weight is installed at the left end of the cold stand and the auxiliary weight is installed at the right end to assist the pendulum movement of the cold stand. When the main weight portion is lifted upwards through the weight lifting means, the auxiliary weight is lowered to push up the main weight so that the main weight is lifted up. When the weight is lowered, since the auxiliary weight is lighter than the main weight, the auxiliary weight portion is lifted upwardly so that the cold pedestal smoothly pivots right and left.

The above-mentioned objects are achieved by a frame structure comprising a frame provided on an upper portion thereof and constituting a basic frame; A main shaft rotatably installed on the mounting table; A cold pedestal extending downward from the main shaft and pivotally moving in the left and right direction and rotating the main shaft while pendulum movement to repeatedly rotate counterclockwise to the normal rotation; An acceleration means for pivoting the cold pedestal; A first driving gear installed at one end of the main shaft and rotated together with the main shaft; A second driving gear provided at the other end of the main shaft and rotating together with the main shaft; A first driven gear which is engaged with the first driving gear and rotates and has a smaller diameter than the first driving gear; A first power transmission shaft installed to rotate together with the first driven gear and to rotate only when the first driven gear rotates together when the first driven gear rotates forward and the first driven gear when the first driven gear rotates reversely; A second driven gear installed to rotate in engagement with the second drive gear and having a smaller diameter than the second drive gear; A second power transmission shaft installed to rotate together with the second driven gear so as to rotate only the second driven gear when the second driven gear rotates forward and to rotate together when the second driven gear rotates reversely; A first power transmission gear coupled to a portion of the second power transmission shaft and rotating together; And a second power transmission shaft that is coupled to a portion of the first power transmission shaft and is engaged with the first power transmission gear so that when the second power transmission shaft rotates together with the second driven gear, A second power transmission gear for forward rotation; A speed increasing gear box connected to an end of the first power transmitting shaft for increasing the rotational force of the first power transmitting shaft through a combination of a plurality of gears and outputting the rotational force; A generator connected to the output portion of the speed increasing gear box for generating electric energy while receiving power from the speed increasing gear box; And a rotor rotatably installed at a center of the rotary shaft of the generator, the rotor being spaced equiangularly from the circumferential direction of the housing wall surface, Wherein at least two housing permanent magnets magnetized so that one of the two magnetic pole faces is oriented toward the center of the housing and a pole face such as the permanent magnet of the housing are opposed to each other so as to have repulsive force with each other Wherein the permanent magnet of the housing is rotated through a repulsive force, which is a force pushing the rotor permanent magnet, to rotate the rotary shaft of the generator in which the rotor is fixed so that the rotating permanent magnet is magnetized and fixed to the surface of the rotor, And a magnet rotating means installed to assist the generator It is achieved by.

The electromagnet is disposed between the housing permanent magnet and the rotor permanent magnet and is fixed to the housing. The electromagnet is capable of generating a magnetic field line in the same or opposite direction as the magnetic field lines of the permanent magnet, As shown in FIG.

The power generating device according to the present invention converts the pendulum motion into a rotational motion to rotate the first power transmission shaft in the same direction at all times and supplies the rotational force to the generator through the speed increasing gear box, And the electric energy is produced from the electric power.

The power generating device according to the present invention is provided with the magnet rotating means that uses a repulsive force formed between the same poles of the magnets in the transmission shaft for transmitting the rotating force of the main shaft to the generator so as to assist rotation of the transmission shaft, It has the effect of producing electric energy.

Since the main weight and the auxiliary weight are installed at both ends of the cold stand to assist the pendulum movement of the cold stand when the cold stand moves the pendulum to the right and left, It is possible to smoothly perform pendulum motion in the cold earth, and therefore, it is possible to continuously produce electric energy continuously by providing an accurate amount of rotational energy to the generator.

1 is a front view showing a configuration of a power generation apparatus according to the present invention;
2 is a plan view for explaining a configuration of a power generating apparatus according to the present invention,
3 is a perspective view showing only the power transmitting means in the present invention,
Fig. 4 is a sectional view showing only the magnet rotating means in the present invention,
5 is a cross-sectional view showing another preferred embodiment of the magnet rotating means in the present invention,
Figs. 6 to 8 are operation diagrams of the magnet rotating means of Fig. 5,
9 and 10 are operational views of the present invention.
11 is a plan view showing another embodiment of the power generating apparatus according to the present invention,
Fig. 12 and Fig. 13 are sectional views showing only the magnet rotating means in the power generating apparatus of Fig. 11,
Figs. 14 to 16 are sectional views showing another preferred embodiment of the magnet rotating means of Fig. 12; Fig.

The present invention will now be described in detail with reference to the accompanying drawings.

1 to 3, a power generating apparatus according to the present invention includes a frame 10 constituting a basic frame, and a mounting table 10 is installed on an upper portion of the frame 10.

On the mounting table 10, a main shaft 100 is provided so as to be rotatable to the left and right, and a cold pedestal 200 extending downward is installed on the main shaft 100. The cold pedestal 200 is coupled to the main shaft 100 to pivotally move about the main shaft 100. When the cold pedestal 200 performs the pendulum movement, the main shaft 100 transmits its power And then performs forward rotation and reverse rotation repeatedly.

Here, it is preferable that the cold pedestal 200 is configured to have the shape of an anchor, but it is not necessarily limited to the shape of the cold pedestal 200, and any shape can be applied as long as the pendulum can move right and left. A main weight 210 is installed at a left end of the cold pedestal 200 and an auxiliary weight 220 is installed at a right end of the cold pedestal 200 to assist pendulum movement of the cold pedestal 200.

At this time, the main weight 210 is heavier than the auxiliary weight 220. Preferably, the auxiliary weight 220 may have a weight of about half of the weight 210. [ This is because when the main weight 210 is lifted upwardly by the weighting means, the auxiliary weight 220 is lowered to push up the main weight 210 so that the main weight 210 can be lifted up, When the main weight 210 is lowered by dropping the main body 210, the auxiliary weight 220 is lighter than the main weight 210, so that the auxiliary weight 220 is lifted upward. That is, the auxiliary weight 220 and the main weight 210 help the cold pedestal 200 to smoothly pivot left and right.

And the cold pedestal 200 is configured to pendulum movement through an acceleration exercise means. The weighting means includes a first connection ring 212 formed at the left end of the main weight 210, a second connection ring 214 formed at a lower portion of the main weight 210, A driving sprocket 310 coupled to the shaft of the driving motor 300 and rotated by receiving the power of the driving motor 300, A driven sprocket 320 rotatably mounted on the frame 10 below the main weight 210 and a first ring 332 formed at one end thereof and connected to the first connection ring 212 and a second ring And a chain 330 connecting the driving sprocket 310 and the driven sprocket 320 with a ring 334 formed therein and connected to the second connecting ring 214. Between the drive sprocket 310 and the driven sprocket 320, an auxiliary sprocket 340 is installed to hold the chain 330 sagged.

Therefore, when the drive motor 300 rotates in the normal direction, the chain 330 rotates in one direction to lift the main weight 210 and the cold base 200 rotates to the left, When the chain 330 rotates in the opposite direction, the main weight 210 descends and the cold platform 200 rotates to the right. At this time, when the main motor 210 is lifted up while the driving motor 300 rotates in a forward direction, the auxiliary weight 220 is lowered to relieve the driving motor 300 from lifting the main weight 210, When the driving motor 300 rotates in the reverse direction to lower the main weight 210, the main motor 210 has a force to be lowered by the weight of the main weight 210, so that no load is applied to the driving motor 300. That is, the driving motor 300 is assisted by the auxiliary weight 220 when lifting the main weight 210. When the main weight 210 is lowered, the main weight 210 is slowly lowered Because it is only a role to hold, it will not be burdened.

When the cold pedestal 200 is rotated to the left or right via the weighting means, the main shaft 100 receives the power and rotates when it alternates left and right. The rotational force of the main shaft 100 is transmitted to the power transmitting means To the generator (600) to produce electrical energy in the generator (600).

That is, the power transmission means converts the left and right rotational force of the main shaft 100 into a rotational force in one direction and transmits it to the speed increasing gear box 500. In the speed increasing gear box 500, the rotational force is increased and transmitted to the generator 600, (600).

The power transmission unit includes a first driving gear 400 and a second driving gear 410 that are installed at one end and the other end of the main shaft 100 and rotate together with the main shaft 100. A first driven gear 420 having a diameter smaller than that of the first driving gear 400 is installed in the first driving gear 400 so as to be meshed with the first driven gear 400, And a second driven gear 430 having a diameter smaller than that of the driving gear 410 is provided so as to be meshed and configured to rotate together.

A first power transmission shaft 440 is coupled to the first driven gear 420 so as to rotate together and a second power transmission shaft 450 is coupled to the second driven gear 430 so as to rotate together . The first driven gear 420 and the first power transmitting shaft 440 are coupled through the unidirectional bearing B so that when the first driven gear 420 rotates forward, The first driven gear 420 rotates with respect to the first power transmission shaft 440 and rotates only the first driven gear 420 when the first driven gear 420 rotates together.

Here, a magnet rotating means 460 using a repulsive force formed between the same poles of the magnets is provided on a transmission shaft for transmitting the rotational force of the spindle 100 to the generator, so as to assist rotation of the transmission shaft. 4, the magnet rotating means 460 includes a cylindrical housing 461 and a housing 461, the center of which is fixed to the first power transmission shaft 440 And a rotor 462 rotatably installed on the housing 461 and spaced equally from each other and fixed along a circumferential direction of a wall surface of the housing 461. One pole face of the two pole faces faces the center of the housing 461 At least two housing permanent magnets 461a magnetized so as to face each other and a pole face such as the housing permanent magnet 461a facing each other and being magnetized so as to have repulsive force with each other and fixed to the surface of the rotor 462 Or more rotor permanent magnets 462a. That is, the rotor permanent magnet 461a and the housing permanent magnet 462a are arranged such that the poles having the same polarity are opposed to each other and the repulsive force, which is a force pushing them, acts. Accordingly, the housing permanent magnet 461a pushes and rotates the rotor 462 through a repulsive force which is a force pushing the rotor permanent magnet 462a to rotate the first power transmission shaft 440 And is configured to assist rotation.

Further, as shown in FIG. 5, the housing permanent magnet 461a and the rotor permanent magnet 462a are fixed to the housing 461, and the housing permanent magnet 461a And an electromagnet 463 capable of generating magnetic lines of force in the same or opposite direction as the magnetic lines of force of the first and second plates 461a and 461a. That is, the housing permanent magnet 461a and the rotor permanent magnet 462a are disposed so as to exert repulsive force with each other, and the electromagnet 463 is disposed between the housing permanent magnet 461a and the rotor permanent magnet 462a.

6, when current is supplied to the electromagnet 463 disposed between the housing permanent magnet 461a and the rotor permanent magnet 462a, the permanent magnet 461a and the rotor 462a, A canceling space O is formed between the permanent magnets 462a so that the repulsive force R is not felt between the permanent magnet 461a and the rotor permanent magnet 462a. When the center of the housing permanent magnet 461a and the rotor permanent magnet 462a are slightly shifted from each other by the rotation of the rotor 462, a repulsive force in the right and left of the canceling space O acts strongly, .

7, when the rotor 462 rotates clockwise slightly by the rotation of the first power transmission shaft 440, when the rotor 462 is rotated about the clockwise direction by the rotation of the first power transmission shaft 440, Disconnect the current. Then, the rotor permanent magnet 462a starts to receive strong repulsive force R from the housing permanent magnet 461a, and is further rotated clockwise by the pushing force. 8, the rotor 462 rotates more and the rotor permanent magnet 462a enters the lower portion of the housing permanent magnet 461a. At this time, the electromagnet 463 So that the housing permanent magnet 461a prevents the entrance of the rotor permanent magnet 462a from being hindered by the housing permanent magnet 461a. By thus selectively making the canceling space O between the permanent magnet 461a and the rotor permanent magnet 462a through the electromagnet 463, the rotor 462 continues to be rotated by inertia and repulsive force You will be assisted in turning.

When the second driven gear 430 is engaged with the second power transmission shaft 450 and is coupled through the one-way bearing B so that the second power transmission shaft 450 is rotated when the second driven gear 430 is rotated forward, The second driven gear 430 rotates only while the second driven gear 430 rotates and the first driven shaft 440 rotates together when the second driven gear 430 rotates reversely . Therefore, when the main shaft 100 rotates, the first driving gear 400 and the second driving gear 410 rotate together. When the main shaft 100 rotates in the reverse direction, the first driving gear 400 rotates in the reverse direction The first driven gear 420 and the first power transmission shaft 440 are rotated in the normal direction and when the main shaft 100 is rotated in the normal direction, the second driven gear 410 rotates in the forward direction and the second driven gear 430 And the second power transmitting shaft 450 rotate in the reverse direction. At this time, when the main shaft 100 is rotated in the opposite direction, the power of the second driven gear 430 is not transmitted to the second power transmission shaft 450 due to the characteristic of the unidirectional bearing B, The power of the first driven gear 420 is not transmitted to the first power transmission shaft 440 so that only the second power transmission shaft 450 rotates in the opposite direction. Here, the uni-directional bearing B is purchased and used as a commercially available product, and a detailed description thereof will be omitted because it is a known technology. In addition, although the present invention is configured to transmit or block the power through the one-way bearing (B), the present invention may be applied in a different manner instead of the one-way bearing (B) A first power transmission gear 470 is coupled to a portion of the second power transmission shaft 450 so as to rotate together. A second power transmission gear 480 is connected to a portion of the first power transmission shaft 440, When the second power transmission shaft 450 rotates together with the second driven gear 430 in the reverse direction, the first power transmission shaft 440 is engaged with the first power transmission shaft 440, ). Accordingly, the first power transmission shaft 440 always provides the rotation energy while the main shaft 100 is in the forward rotation, regardless of the forward rotation and the reverse rotation.

Next, the rotational force of the first power transmission shaft 440 is increased in the speed increasing gear box 500 to be transmitted to the generator. This speed increasing gear box 500 is configured to transmit the first power transmission through the combination of the plurality of gears The rotational force of the shaft 440 is increased and output, and a detailed description thereof will be omitted because it is a known technique.

Next, a drive pulley 700 is installed on the output shaft 510 output from the speed increasing gear box 500, a driven pulley 710 is installed on the shaft of the generator 600, and a drive pulley 700 and a driven pulley 710 Is connected through a belt 720 so that the power of the output shaft 510 is transmitted to the generator 600.

In the meantime, the present invention further includes a motion control means for limiting the movement radius when the cold pedestal 200 pivots to the left and right. That is, the cold pedestal 200 always performs the right and left pendulum movements at the same height through the motion control means.

The motion control means includes a first stopper 222 extending downward from the auxiliary weight 220, a second stopper 216 extending downward from the main weight 210, And the first stopper 222 of the auxiliary weight 220 is disposed at a position where the first stopper 222 touches the main weight 210 when the main weight 210 moves to the left, A first touch sensor 800 that senses the touch and transmits a signal that the drive motor 300 operates in the opposite direction, and a second touch sensor 800 that is installed in a lower portion of the frame 10 and in which the main weight 210 moves to the right The auxiliary weight 220 is installed at a position where the second stopper 216 of the main weight 210 touches at a point of time when the auxiliary weight 220 reaches the highest point. When the second stopper 216 touches the auxiliary weight 220, And a second touch sensor 810 for transmitting a signal to operate in the opposite direction. Of course, it is configured to transmit signals of the first touch sensor 800 and the second touch sensor 810 to the driving motor 300 to control the operation of the driving motor 300 through a separate controller.

Now, the operating relationship of the power generation apparatus according to the present invention constructed as above will be described.

4, when the cold pedestal 200 moves to the left, the first driving gear 400 and the second driving gear 410 rotate together with the main shaft 100, 1 driven gear 420 and the second driven gear 430 rotate in reverse while engaged with each other. The first driven gear 420 and the first power transmission shaft 440 are idly rotated without power transmission and the second driven gear 430 and the second power transmission shaft 450 are transmitted with power, . In this state, the power of the second power transmission shaft 450 is transmitted to the first power transmission shaft 440 through the first power transmission gear 470 and the second power transmission gear 480, 440 are rotated forward and the rotational force of the first power transmission shaft 440 operates the generator 600 through the speed increasing gear box 500 to obtain electric energy.

5, when the cold pedestal 200 moves to the right, the first driving gear 400 and the second driving gear 410 are rotated in the reverse direction together with the main shaft 100, The first driven gear 420 and the second driven gear 430 are engaged and rotated forward. Then, the first driven gear 420 and the first power transmission shaft 440 are transmitted with power, and the second driven gear 430 and the second power transmission shaft 450 are idly rotated, . Accordingly, the rotational force of the first power transmitting shaft 440 operates the generator 600 through the speed increasing gear box 500 to obtain electric energy.

The magnet rotating means 460 provided on the first power transmission shaft 440 rotates the rotor 462 through the repulsive force R which is the force that the permanent magnet 461a pushes the rotor permanent magnet 462a And is rotated to assist rotation of the rotor. Therefore, when the rotor 462 starts to rotate once due to the power of the force supplied through the second power transmission shaft 450 and the pushing force of the magnet, the rotor rotates naturally continuously.

As described above, even if the cold pedestal 200 moves pivotally to the left and right, the first power transmission shaft 440 always rotates in the normal direction, thereby providing a continuous rotational force to the speed-increasing gearbox 500, Generator 600 is always supplied with the same rotational force to produce electric energy.

11 and 12 show another embodiment of the power generating apparatus according to the present invention.

The power generating apparatus according to the present embodiment differs from the power generating apparatus of the first embodiment only in the position where the magnet rotating means is installed.

According to the present embodiment, a frame 10 constituting a basic framework is provided, and a main shaft 100 installed to be rotatable on the mounting base 10, (200) installed to pendulum movement and rotating the main shaft while pendulum movement to repeatedly rotate counterclockwise and counterclockwise to the main shaft, weight-moving means for pivoting the cold pedestal, A second driving gear 410 installed at the other end of the main shaft and rotated together with the main shaft; a second driving gear 410 installed to rotate in engagement with the first driving gear, A first driven gear 420 having a diameter smaller than that of the first driving gear; a second driven gear 420 that is coupled to the first driven gear and rotates together, rotation A second driven gear 430 having a smaller diameter than that of the second driven gear, and a second driven gear 430 having a smaller diameter than the second driven gear, A second driven gear installed to rotate together with the second driven gear so as to rotate only the second driven gear when the second driven gear rotates forward and to rotate together with the second driven gear when the second driven gear rotates reversely, A first power transmission gear 470 coupled to a portion of the second power transmission shaft and rotating together with the first power transmission shaft, and a second power transmission gear 470 coupled to a portion of the first power transmission shaft, A second power transmission gear 480 that receives the power when the second power transmission shaft rotates counterclockwise together with the second driven gear to forwardly rotate the first power transmission shaft, and a second power transmission gear 480 connected to the end of the first power transmission shaft And through a combination of multiple gears, A speed increasing gear box 500 for increasing the rotational force of the transmission shaft and outputting the rotational force; and a generator 600 connected to the output portion of the speed increasing gear box for receiving the power of the speed increasing gear box to generate electric energy .

In the present embodiment, a magnet rotating means 460 using a repulsive force formed between the same poles of the magnets is provided on the rotating shaft of the generator to assist rotation of the rotating shaft. 12, the magnet rotating means 490 includes a housing 491 provided in a cylindrical shape and coupled to the rear side of the generator 600, and a housing 491 housed in the housing 491, And a rotor 462 fixed to the rotating shaft 610 of the housing 491 and rotatably mounted on the rotating shaft 610. The rotating shaft 461 is fixed to the housing 491 along the circumferential direction of the wall surface of the housing 491, At least two or more housing permanent magnets 491a magnetized so as to face the center of the housing 491 and magnetizing faces such as the housing permanent magnet 491a face each other and are magnetized so as to have repulsive force with each other, And at least two rotor permanent magnets 492a fixed to the surface of the rotor 492. That is, the rotor permanent magnets 491a and the housing permanent magnets 492a are arranged so that the poles having the same polarity are opposed to each other and the repulsive force, which is a force pushing them, acts. Therefore, the rotation of the rotary shaft 610 of the generator, to which the rotor 462 is fixed, is rotated by pushing the rotor 462 through the repulsive force of the housing permanent magnet 491a pushing the rotor permanent magnet 492a .

13, the housing permanent magnet 491a and the rotor permanent magnet 492a are fixed to the housing 491, and the housing permanent magnet 491a and the permanent magnet body 492 are fixed to the housing 491, And an electromagnet 493 capable of generating magnetic lines of force in the same or opposite direction as the magnetic lines of force of the first and second plates 491a and 491a. That is, the electromagnet 493 is disposed between the housing permanent magnet 491a and the rotor permanent magnet 492a in a state where the permanent magnet 491a and the rotor permanent magnet 492a are arranged so as to exert repulsive force with each other.

14, when current is supplied to the electromagnet 493 disposed between the housing permanent magnet 491a and the rotor permanent magnet 492a, the permanent magnet 491a and the rotor A canceling space O is formed between the permanent magnets 492a so that the repulsive force R is not felt between the permanent magnet 491a and the rotor permanent magnet 492a. When the center of the housing permanent magnet 491a and the rotor permanent magnet 492a are slightly shifted from each other by the rotation of the rotor 492, a repulsive force in the right and left of the canceling space O acts strongly, .

15, when the rotor 492 rotates slightly in the clockwise direction due to the rotation of the rotating shaft 610, the current which has been supplied to the electromagnet 493 through the switch S is interrupted back and forth. 16, the rotor permanent magnet 492a starts to receive strong repulsive force R from the housing permanent magnet 491a, and further rotates clockwise by the pushing force. The rotor 492 rotates more and the rotor permanent magnet 492a enters the lower portion of the housing permanent magnet 491a and at this time the electromagnet 493 is turned on via the switch S So that the entry of the rotor permanent magnet 492a is not interrupted by the housing permanent magnet 491a. Thus, by selectively making the canceling space O between the permanent magnet 491a and the rotor permanent magnet 492a through the electromagnet 493, the rotor 492 continues to be driven by inertia and repulsive force You will be assisted in turning.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. Anyone who can afford it will know.

100: Spindle 200: Cold wind
210: main weight 220: auxiliary weight
300: drive motor 400: first drive gear
410: second driving gear 420: first driven gear
430: second driven gear 440: first power transmission shaft
450: second power transmission shaft 460: magnet rotating means
470: first power transmission gear 480: second power transmission gear
500: Incremental gearbox 600: Generator

Claims (5)

A frame provided on the upper part and constituting a basic frame;
A main shaft rotatably installed on the mounting table;
A cold pedestal extending downward from the main shaft and pivotally moving in the left and right direction and rotating the main shaft while pendulum movement to repeatedly rotate counterclockwise to the normal rotation;
An acceleration means for pivoting the cold pedestal;
A first driving gear installed at one end of the main shaft and rotated together with the main shaft;
A second driving gear provided at the other end of the main shaft and rotating together with the main shaft;
A first driven gear which is engaged with the first driving gear and rotates and has a smaller diameter than the first driving gear;
A first power transmission shaft installed to rotate together with the first driven gear and to rotate only when the first driven gear rotates together when the first driven gear rotates forward and the first driven gear when the first driven gear rotates reversely;
A second driven gear installed to rotate in engagement with the second drive gear and having a smaller diameter than the second drive gear;
A second power transmission shaft installed to rotate together with the second driven gear so as to rotate only the second driven gear when the second driven gear rotates forward and to rotate together when the second driven gear rotates reversely;
A rotor rotatably mounted on the first power transmission shaft and rotatably mounted on the first power transmission shaft, the rotor being equally spaced apart from the first power transmission shaft and fixed along the circumferential direction of the housing wall surface, Wherein at least two pole permanent magnets which are magnetized so as to face the center of the housing face each other and a pole face such as the permanent magnet of the housing are opposed to each other and are magnetized so as to have repulsive force with each other, Wherein the permanent magnet of the housing is installed to assist the rotation of the first power transmission shaft to which the rotor is fixed by rotating the rotor through a repulsive force which is a force pushing the permanent magnet of the rotor A magnet rotating means;
A first power transmission gear coupled to a portion of the second power transmission shaft and rotating together;
And a second power transmission shaft that is coupled to a portion of the first power transmission shaft and is engaged with the first power transmission gear so that when the second power transmission shaft rotates together with the second driven gear, A second power transmission gear for forward rotation;
A speed increasing gear box connected to an end of the first power transmitting shaft for increasing the rotational force of the first power transmitting shaft through a combination of a plurality of gears and outputting the rotational force; And
And a generator connected to an output portion of the speed increasing gear box to receive electric power from the speed increasing gear box to generate electric energy.
The method according to claim 1,
An electromagnet disposed between the housing permanent magnet and the rotor permanent magnet and fixed to the housing and capable of generating a magnetic field line in the same or opposite direction as the magnetic field line of the permanent magnet according to the direction of current to be injected, Wherein the power generating device comprises:
The method according to claim 1,
Wherein the cold pedestal is configured to have an anchor shape and the main body is disposed at the left end of the cold pedestal and the auxiliary pedestal is provided at the right end to assist the pendulum movement of the cold pedestal,
The main weight is heavier than the auxiliary weight, and when the main weight portion is lifted upwards through the weight movement means, the auxiliary weight is lowered to push the main weight to be lifted up well, When the main weight is lowered by releasing the main weight portion, the auxiliary weight is lifted upwardly because the auxiliary weight is lighter than the main weight, so that the cold pedestal smoothly pivots right and left .
A frame provided on the upper part and constituting a basic frame;
A main shaft rotatably installed on the mounting table;
A cold pedestal extending downward from the main shaft and pivotally moving in the left and right direction and rotating the main shaft while pendulum movement to repeatedly rotate counterclockwise to the normal rotation;
An acceleration means for pivoting the cold pedestal;
A first driving gear installed at one end of the main shaft and rotated together with the main shaft;
A second driving gear provided at the other end of the main shaft and rotating together with the main shaft;
A first driven gear which is engaged with the first driving gear and rotates and has a smaller diameter than the first driving gear;
A first power transmission shaft installed to rotate together with the first driven gear and to rotate only when the first driven gear rotates together when the first driven gear rotates forward and the first driven gear when the first driven gear rotates reversely;
A second driven gear installed to rotate in engagement with the second drive gear and having a smaller diameter than the second drive gear;
A second power transmission shaft installed to rotate together with the second driven gear so as to rotate only the second driven gear when the second driven gear rotates forward and to rotate together when the second driven gear rotates reversely;
A first power transmission gear coupled to a portion of the second power transmission shaft and rotating together;
And a second power transmission shaft that is coupled to a portion of the first power transmission shaft and is engaged with the first power transmission gear so that when the second power transmission shaft rotates together with the second driven gear, A second power transmission gear for forward rotation;
A speed increasing gear box connected to an end of the first power transmitting shaft for increasing the rotational force of the first power transmitting shaft through a combination of a plurality of gears and outputting the rotational force;
A generator connected to the output portion of the speed increasing gear box for generating electric energy while receiving power from the speed increasing gear box; And
A rotor rotatably installed at a center of the rotary shaft of the generator, the rotor being equally spaced apart from each other and extending in the circumferential direction of the wall surface of the housing; Wherein at least two permanent magnet pieces of the housing are magnetized so as to face the central portion of the housing and one pole face of the two pole faces are opposed to each other such that the pole faces of the housing permanent magnet face each other, Wherein the permanent magnet of the housing rotates the rotor through a repulsive force which is a force pushing the rotor permanent magnet to rotate the rotary shaft of the generator fixed to the rotor, And a magnet rotating means installed to assist the generator.
5. The method of claim 4,
An electromagnet disposed between the housing permanent magnet and the rotor permanent magnet and fixed to the housing and capable of generating a magnetic field line in the same or opposite direction as the magnetic field line of the permanent magnet according to the direction of current to be injected, Wherein the power generating device comprises:

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