WO2006041231A2 - Amplified electric energy producing system - Google Patents

Description

[DESCRIPTION]

[Invention Title]

AMPLIFIED ELECTRIC ENERGY PRODUCING SYSTEM

[Technical Field]

The present invention relates to a positive power electricity generation system, and more particularly to a positive power electricity generation system for generating the mechanical energy by the positive power portion operating according to the principle of the positive power portion performing relative rotation action of the negative pole rotation body and the positive pole rotation body of the circular Great Absolute with the initial input power as electrical energy that is more amplified than the initial input power, and supplying the electrical energy to the industrial fields at a low cost to install environment-friendly electric power equipment.

[Background Art]

The conventional thermal power plant obtains electrical energy by driving the steam turbine by using the energy sources such as coals or oils. The atomic power plant obtains electrical energy by driving the steam turbine by use of heat energy generated by using the uranium as energy source.

To install the electricity generation equipments of such a conventional thermal power plant or the atomic power plant, a large amount of expenses and a long- term plan are needed. As the industrial equipments increase and the standard of living improves, more home appliances are being used. Therefore, it is required to increase the electricity generation equipments in every year, but for the economical reasons, such needs could not be handled positively.

Also, it is difficult to find a proper place to build the power plant, avoiding the existing equipments. Especially, there is a problem that the local residents oppose to the building of the atomic power plant or the thermal power plant, for fear of the pollution of the air and water, and the pollution by the radiation.

The present inventor filed Korean Patent Application Nos. 1998-54443,

1999-55000, 2002-8637, 2002-82174, and 2002-82175 for the apparatus for generating electricity by use of a positive power position. Besides, the present inventor improved the electricity generation apparatus by use of the positive power applied to Korean

Patent Application Nos. 2003-64853 and 2004-24321 based on the Korean Patent

Application Nos. 2002-82174, 2002-82175 and 2002-60825 for the more efficient electricity generation method, and files a patent application for the improved system herein.

[Disclosure] [Technical Problem]

Therefore, the present invention has been made in view of the above problems.

[Technical Solution]

In accordance with an aspect of the present invention, the above and other objects can be accomplished by the provision of a positive power electricity generation system comprising an environmentally friendly electric power equipment for producing and supplying to industrial fields at a low cost the electrical energy, which was amplified than the initially input power, with the mechanical energy generated by the positive power portion operating according to the principle of a lever of seesaw Bang- Gak (direction-angle) operation with the initially input power.

As a specific means to realize the present invention, the present invention provides a positive power electricity generation system includes: a starting driving portion consisting of an operation switch for applying power supply, an electronic control device for sensing the turning-on of the operation switch, and a first and second starting motor groups, which comprises an electric motor receiving power supply and operating the driving gear by the information previously set up in the electronic control device, a decelerator, a transmission and a driving gear, in that order, and are arranged in both sides in plural numbers to engage with the circular Great Absolute relative rotation body portion; a circular Great Absolute relative rotation body portion, which is connected to the shaft supports having a predetermined space with a central shaft of a predetermined length to be rotated by plural driving gears of the starting driving portion, and is installed to interlock with the moving coordinates trinity conversion portion by the action of the electronic clutch portion of the seesaw action direction and angle lever by having attachment plates mounted on the positions dividing the facing surfaces thereof in predetermined angles; a seesaw action direction and angle lever portion, whose two rotation bodies on both sides are connected to the electronic clutch portion, operating having a declination of angle like two number of rotations, when the rotation angle of the circular Great Absolute relative rotation body is 90° three number of rotations when the rotation angle of the circular Great Absolute relative rotation body is 60° four number of rotations when the rotation angle of the circular Great Absolute relative rotation body is 45° and six number of rotations when the rotation angle of the circular Great Absolute relative rotation body is 30° an electronic clutch portion comprising a forward and reverse actuator installed on the multilayer seesaw action direction and angle lever to go forward and backward on the seesaw action direction and angle lever portion, a left and right conversion actuator for controlling the left and right locational angle of the forward and reverse actuator within a predetermined range of angle, and an electromagnetic clutch installed on the front of the forward and reverse actuator in a ball joint type to be variably attached to the attachment plate of the circular Great Absolute relative rotation body portion by the previously set up information; a moving coordinates conversion portion, which eccentrically connects the points of application having a predetermined space between themselves on both sides of the rotation central shaft of the seesaw action direction and angle lever portion with a cam inside the gear box at the lower end side of the connection rod portion, to perform an interior angle motion of 180° and an external angle motion of 180° by converting an up and down motion to a rotation motion, perform double external angle motions of relatively pushing and pulling the first and second moving coordinates cams connected to the first and second connection rods, and thereby make the moment of the forces of the moving coordinates on both sides and the force of the point of application of the seesaw action direction and angle lever portion penetrate the force of the output gear between the first and second moving coordinates cams and be unified as trinity; an amplification electricity generation device, which is connected to the output shaft installed on the moving coordinates conversion portion having an additional elastic rotation body for adding elasticity to the rotatory power generated by the action of the seesaw action direction and angle lever portion, to be rotated by the amplified rotation elasticity and generate electricity by the amplified rotatory power; and an elastic collision device portion, which is installed in parallel on both sides between the circular Great Absolute relative rotation body portion, is rotatably installed by the shaft support to make the repetitive rotatory motion made within a predetermined range of angle and is installed on one side to assistantly perform the rotation conversion of the multilayer seesaw action direction and angle lever.

The aforesaid present invention installs the operation switch for applying power supply, and the electronic control device for sensing the turning-on of the operation switch, and installs a motor for receiving the power supply by the previously set up information and operating the driving gear, a decelerator, a transmission and a gear, in that order, to engage with the gear in the circumference of the circular Great Absolute relative rotation body portion.

Two circular Great Absolute relative rotation body portions are mounted on both sides of the central shaft of a predetermined length, and are installed by establishing an elevation having the height corresponding to 1/3 of the radius of the rotation body not to interrupt the action of the seesaw action direction and angle lever portion. The number of rotations changes according to the setting up of the angle of the electromagnetic clutch on the predetermined positions of the circular Great

Absolute relative rotation body portion like 90°=2 number of rotations, 60°=3 number of rotations, 45°=4 number of rotations, and 30°=6 number of rotations, and the operation of the electronic clutch portion is becomes possible.

This is shown as a circular motion (energy motion) at the trinity of the moving coordinates by the amplification of the speed energy.

The rods on both sides connected to the point of application of the seesaw action direction and angle lever portion are connected to the cam of the moving coordinates at the end of the rod, and one member of the electronic clutch portion mounted on the power point of the lever is made to operate with one member of the electronic clutch on a predetermined position of the circular Great Absolute relative rotation body portion.

The electronic clutch portion on the circular Great Absolute relative rotation body portion is fixed, and the rod connected to the cam of the moving coordinates is fixed as well, and therefore the flexibility necessary for the motion should be provided by the action of the seesaw action direction and angle lever portion.

Firstly, it is the action of the electronic clutch. For example, when the circular Great Absolute relative rotation body performs rotation of 60° angle, reciprocating action necessary for the 30° respectively are needed.

To perform such an action, a separate pressure device is needed. Also, even though the capacity of the electronic clutch is in proportion to the electromagnetic force, since it is not proven with respect to the action of a great force, a separate pressure may be needed, if necessary. Secondly, it is the twist derived from the rotation angle of 15°.

Since when the electronic clutch operates in one side, the other side is in the air, the mobility of the central shaft in a predetermined angle may be sufficient. But, the rod connected to rotation of the central shaft in a predetermined angle and the point of application needs a device capable of mobility action.

The freely moving distance derived from the twist is in proportion to the distance between the power point and the point of application, and therefore, mobility device of the point of the application can be installed by computing such a distance as follows.

For example, when the rotation angle of the circular Great Absolute relative rotation body is 60° and the length of the seesaw action direction and angle lever is 15m, the results in Table 1 are obtained.

[Table 1] Constitutional elements of the mobility device

In the above table, when the distance ratio of the power point and the point of appliance is 1/5, the free moving distance of the point of appliance becomes Im x 1/5= 0.2m.

When the connection of the point of appliance is made to move like a medal, and make the diameter of the connection point of the lever and the rod be Im, if the center of the lever is moved to one side and is connected to the position in 3/4 of the diameter, the freely moving distance becomes 0.25m.

In this case, the mobility derived from the twist is absorbed, and the rod becomes capable of acting in position.

The elastic collision device is a device, which minimizes the time of pausing in the reciprocating action, integrates power by promptly reversing with a shock device like a pile driving, and is installed in the seesaw action direction and angle lever rotation body to assist the repetitive rotation. The moving coordinates conversion portion eccentrically connects the points of appliance in a predetermined space of the rotation central shaft of the seesaw action direction and angle lever portion to the lower end of the connection rod portion with a cam, and comprises a gear box, which arranges an output gear between the first and second moving coordinates cams to produce rotatory power by converting the up and down motion to rotation motion.

The first and second moving coordinates cams at the lower end of the connection rod portion are connected to both sides of the rotation central shaft of the seesaw action direction and angle lever portion in a predetermined space. The first and second moving coordinates cams performs an internal angle motion of 180° and an external angle motion of 180° and are connected to both sides of the point of appliance with the first and second connection rods. The first and second moving coordinates is constituted to make the moment of force of the moving coordinates on both sides of the double external motions of relatively pushing and pulling concentrate on the central shaft, and the force of the point of appliance in the seesaw action direction and angle lever portion be transmitted as it is.

In the double internal angle motion, the moment of force arrives at the middle position of the central shaft and the first and second moving coordinates cams, and therefore, the forces of both sides are transmitted doubly. Since this force is generated successively on both sides of the seesaw action direction and angle lever portion, the superfluous force is automatically applied as the rotatory power of the additional elastic body. The additional elastic rotation body receives the power necessary for the rotation thereof from the first and second moving coordinates cams and the central shaft through the first and second connection rods connected to the point of appliance of the circular Great Absolute relative rotation body and the seesaw action direction and angle lever portion, which are basic devices, and the elasticity thereof are returned through the same course.

For reference, the terms are defined as follows. Won = displays the rotation motion below and above the + positive ray, displays sun, and shows that the solar light has relative strength and weakness and top and bottom.

Bang (direction) = displays rotation motion in four directions of the - negative ray, symbolize east, west, south and north, and shows that there are relative borders.

Gak (angle) = displays rotation motion of - negative and +positive rays angle, and shows that the positions of + and are changed mutually in a predetermined angle. Hap = displays the rotation motions of Won, Bang and Gak gather in the center, and displays the moment of mixture in the course of pushing, pulling and changing one another.

[Advantageous Effects]

The moving coordinates, which plays a centric role in the present invention, is expressed by the same terminology used in the Einstein's special theory of relativity, since it is thought that the moving coordinates of the present invention has the same nature as the moving coordinates that Einstein describes.

The internal angle motion and the external angle motion of the moving coordinates are new phenomenon of the motion of an object. In the conventional gravity, the moment of force and the rotation speed are subject to invariable proportion principle in the course that certain forces gathers in the center.

In the moving coordinates of the present system, the same moment of the force has the same speed, but since it performs double action, the force penetrates.

It is the effects of the present invention that since this force is used as the rotatory power of the additional elastic body connected to the system, the physical principle of moving coordinates trinity that integrates three forces as one is established.

The aforesaid present invention realizes an apparatus for amplifying electric energy by applying positive power according to the principle of the positive power portion that performs relative rotation action of the negative rotation body and the positive rotation of the basic circular Great Absolute, and thereby provides sufficient cheap electricity to the industrial fields by simplifying the equipment structure or maximizing the production of the energy for producing electricity, or can be applied to the power plant at a low construction cost. Accordingly, the present invention has the effects of providing electricity generating equipment for the production field or other places which need power supply at low costs by use of the equipment for producing the electric energy.

Also, after the starting motor is driven by use of the initial power supply, the present invention can use the power supply produced by the amplification electricity generation device, and can continuously provide sufficient power to other electric field components.

Also, the construction cost is reduced by reducing the construction cost and the term of works of electricity generating equipment. Especially, the present invention does not consume resources and pollutes the environment, and therefore is very useful in terms of the energy industry.

[Description of Drawings]

The above and other objects, features and other advantages of the present invention will be more clearly understood from the following detailed description taken in conjunction with the accompanying drawings, in which:

Fig. 1 is a perspective view illustrating the positive power generation system of the present invention approximately.

Fig. 2 is a drawing illustrating the circular Great Absolute relative principle to explain the positive power electricity generation system of Fig. 1. Fig. 3 is a drawing illustrating the negative and positive Great Absolute principle to explain the positive power electricity generation system of Fig. 1.

Fig. 4 is a drawing illustrating the four dimensional variation drawing to explain the positive power electricity generation system of Fig. 1. Fig. 5 is a drawing illustrating relation the Won Bang and six poles to explain the positive power electricity generation system of Fig. 1.

Fig. 6 is a drawing illustrating the positive power electricity generation system of the present invention. Fig. 7 is a drawing illustrating A-A of Fig. 2 of the positive power electricity generation system of the present invention.

Fig. 8 is a drawing illustrating the arrangement of the moving coordinates conversion portion, the additional elastic rotation body and the generator applied to the positive power electricity generation system of the present invention. Fig. 9 is a drawing illustrating B-B of Fig. 2 of the positive power electricity generation system of the present invention.

Fig. 10 is a drawing illustrating the change in the length and the speed of the moving coordinates cam of the positive power electricity generation system of the present invention. Fig. 11 is a drawing illustrating the action of the electronic clutch portion of the present invention.

Fig. 12 is a drawing illustrating the internal and external angle motions of the moving coordinates conversion portion of the present invention.

* Explanations of the Reference Numerals of the Main Parts of the Drawings

4: starting driving portion 6: circular Great Absolute relative rotation body 6a: reference numeral displaying the top and bottom of the positive ray 6b: reference numeral displaying the four directions of the negative ray 6c: reference numeral displaying the negative ray and angle

6d: reference numeral displaying the integration of the Won Bang and each angle

8: seesaw action direction and angle lever portion 10: moving coordinates conversion portion

12: amplification electricity generation device

14: operation switch

16: electronic control device 18: driving gear

20,22: first and second starting motor groups

24: elastic collision device portion

28: shaft support

30: collision portion 32,34: elastic collision portion

36: shaft support

38: multilayer seesaw action direction and angle lever

40: ball joint shaft

42: rotation central shaft 44 : connection rod portion

46,48: first and second connection rods

52,54: first and second moving coordinates cams

56: output gear

58: additional elastic rotation body 60: output shaft

64: generator

[Best Mode]

The preferable embodiment according to the constitution of the present invention will be explained in detail with reference to the attached drawings.

Fig. 1 is a perspective view illustrating the positive power generation system of the present invention approximately. Fig. 2 is a drawing illustrating the circular Great Absolute relative principle to explain the positive power electricity generation system of Fig. 1. Fig. 3 is a drawing illustrating the negative and positive Great Absolute principle to explain the positive power electricity generation system of Fig. 1. And, Fig. 4 is a drawing illustrating the four dimensional variation drawing to explain the positive power electricity generation system of Fig. 1. Fig. 5 is a drawing illustrating relation the Won Bang and six poles to explain the positive power electricity generation system of Fig. 1.

Fig. 6 is a drawing illustrating the positive power electricity generation system of the present invention. Fig. 7 is a drawing illustrating A-A of Fig. 2 of the positive power electricity generation system of the present invention. Fig. 8 is a drawing illustrating the arrangement of the moving coordinates conversion portion, the additional elastic rotation body and the generator applied to the positive power electricity generation system of the present invention. Fig. 9 is a drawing illustrating B-B of Fig. 2 of the positive power electricity generation system of the present invention. Fig. 10 is a drawing illustrating the change in the length and the speed of the moving coordinates cam of the positive power electricity generation system of the present invention. Fig. 11 is a drawing illustrating the action of the electronic clutch portion of the present invention. Fig. 12 is a drawing illustrating the internal and external angle motions of the moving coordinates conversion portion of the present invention.

The positive power electricity generation system (2) consists of a starting driving portion (4), a circular Great Absolute relative rotation body portion (6), a seesaw action direction and angle lever portion (8), an electronic clutch portion (40), a moving coordinates conversion portion (10), an amplification electricity generation device (12), and an elastic collision device portion (24).

The starting driving portion (4) interlocks with by rotation, and operates the circular Great Absolute relative rotation body portion (6) based on the previously set up information of the electronic control device (16) sensing the operation of the operation switch.

The starting driving portion (4) comprises an operation switch (14) for applying the power supply, an electronic control device (16) for sensing the turning-on of the operation switch (14), and a first and a second driving motor groups (20)(22) having a driving gear (18) operating by receiving the power supply by the information previously set up in the electronic control device (16) and arranged in plural numbers on both sides of the circular Great Absolute relative rotation body portion (6), which are installed to be interlocked mutually. Event though the specific illustration of the first and second starting motor groups (20)(22) is omitted, the components are connected in the order of a motor — » a decelerator → an electronic clutch → a gear, according to the conventional technique.

The driving gear (18) of the starting driving portion (4) is installed to engage with the gear (26) formed in the outer circumference of the circular Great Absolute relative rotation body (6) to generate a predetermined rotatory power.

The circular Great Absolute relative rotation body portion (6) is a rotation body, engages with the driving gear (18) of the starting driving portion (4) by use of the gear (26), and is installed to be coupled between the separated shaft supports (28), and perform rotatory motion. The circular Great Absolute relative rotation body portion (6) is installed on the shaft support (28) to perform rotation action, and the seesaw action direction and angle lever portions (8) are installed to be connected mutually, and perform repetitive rotation action within a predetermined range of angle between the circular Great Absolute relative rotation body portion (6) to generate rotatory power. Also, the circular Great Absolute relative rotation body portion (6) forms a gear (26) on the outer circumference surface, and forms attachment plates (7) respectively having a space of 120° on the sides facing each other. Figs. 2, 3, 4 and 5 that are introduced to explain the positive power electricity generation system will be explained in a more detail.

Fig. 2 is a circular Great Absolute relative drawing. While the universe rotates with the sun as the central shaft, in the present invention, the circular Great Absolute shows the shape that the forces gather at the center by rotating from the outside of the shape of the circular Great Absolute, and such phenomenon is made by relative actions.

Fig. 3 is a negative and positive Great Absolute drawing. The ends of + and borders of the circular Great Absolute are directed to the upward and downward directions relatively, which illustrates the actions thereof are connected endlessly. The mark ' ~ ' in the circular shapes of Gun, Gon, Gam and Li displayed herein means a circular motion.

And Gun and Gam are +, and Gon and Li are -.

Fig. 4 is a four dimensional variation drawing, and illustrates that the + poles and the poles of the circular Great Absolute drawing perform circular motions, going through four stages, respectively.

Even though Jin and Gan are +₅ and Tae and Son are -, but Gun, Gon, Gam and Li are + (positive poles) and Jin, Gan, Tae and Son are (negative pole) in terms of the relative concept. Fig. 5 is a Won Bang and Six poles drawing. Six poles illustrate that an energy like the solar energy can be obtained when motion in the four directions and up and down motion of the universe are performed.

Among the reference numerals that are not explained, 6a is the reference numeral displaying the top and bottom of the positive ray line, 6b is the reference numeral displaying the four directions of the negative ray line and means rotating with,

6c is a reference numeral displaying the negative and positive ray angle, and 6d is a reference numeral displaying the collection of Won Bang and each pole. And, the display of the Jin, Gan, Tae and Son displays the rotation of the planet and the three lines outside thereof display the rotation of the solar system.

The attachment plates (7) are formed to cross each other, avoiding facing each other when attached to the circular Great Absolute relative rotation body portion (6), and, are formed to have a space of 60° between themselves, as a result.

The attachment plates (7) are attached to the circular Great Absolute relative rotation body portion (6), and thus are formed to rotate, drawing a circle according to the rotation of the circular Great Absolute relative rotation body portion (6).

The circular Great Absolute rotation body portion (6) is formed to make the thickness of the width in the central portion large, and make the thickness of the width in the edge small, to improve durability.

The seesaw action direction and angle lever portion (6) as a rotation body comprises shaft support (36), a multilayer seesaw action direction and angle lever (38) installed to rotate by the shaft support (36) having an elastic collision device portion (24) for performing rotation conversion accessorily, an electronic clutch portion (40) installed at both ends of the horizontal line of the multilayer seesaw action direction and angle lever (38) to perform location alternation of the forward and backward motion and the position of the edge with a predetermined range of angle by the previously set up information, and connection rod portions (44) connected to the moving coordinates conversion portion (10), having a predetermined space between each other on both sides of the rotation central shaft (42) of the multilayer seesaw action direction and angle lever (38).

The elastic collision device portion (24) is installed in a position to make possible the maximum operation thereof in a proper shape, the number and shape of the elastic collision device portion (24) are changed depending on the design pattern, and here the elastic collision device portion (24) is constituted of an elastic collision portion

(32)(34). And the elastic collision device portion (24) is manufactured by adopting the collision portion (30) formed on the side of the multilayer seesaw action direction and angle lever (38) of the seesaw action direction and angle lever portion (8), and an explosion device like the pile driving, for example, as a damper for promptly buffering the conversion to the rotation direction by periodically colliding with the collision portion (30) based on the previously set up information.

The electronic clutch portion (40) comprises a forward and reverse actuator (41) installed to go forward and backward on the multilayer seesaw action direction and angle lever (38), a right and left conversion actuator (43) for controlling the left and right location angle of the forward and reverse actuator (41) within a predetermined range of angle, and an electromagnet clutch (45) installed on the front of the forward and reverse actuator to be variably attached to the attachment plate (7) of the circular Great Absolute relative rotation body portion (6) by the previously set up information.

The electromagnet clutch (45) is installed on the forward and reverse actuator (41) in a ball joint type to be closely attached to the attachment plate (7).

The forward and reverse actuator (41) goes forward and backward by being controlled by the pressure supplied from the pressure device (47). The left and right conversion actuator (43) operates according to the electric signal by the previously set up information and correct the angle of the forward and reverse actuator (41). The left and right conversion actuator (43) moves left and right within a predetermined range of angle, make the transmission of the rotatory power by the electromagnetic clutch (45) and the attachment plate (7) easy, and make the operation of the seesaw action direction and angle portion (8) accurate.

The moving coordinates conversion portion (10) installs a connection rod portion (44) connected to the seesaw action direction and angle lever portion (8) installed on the shaft support (36) with a first and a second connection rod (46)(48), and an output gear (56) engaging between a first and a second moving coordinates cams (52)(54), which are eccentrically connected with a cam (50) to the lower part of the first and second connection rods (46)(48) of the connection rod portion (44) and are fixed by a shaft, to rotate in one direction.

Fig. 11 is a drawing illustrating the internal and external angle motions of the moving coordinates conversion portion of the present invention. The lower ends of the first and second connection rods (46,48) connected to both sides of the rotation central shaft of the seesaw action direction and angle lever portion (8) in a predetermined space are connected to the first and second moving coordinates cams (52,54), and perform an internal angle motion of 180° and an external angle motion of 180°. Also, the first and second moving coordinates cams connected to the first and second connection rods on both sides of the point of application are constituted to let the moment of force of moving coordinates cams on both sides of double external motions pulling and pushing relatively gather in the central shaft and thereby let the force of the point of application of the seesaw action direction and angle lever portion (8) be transmitted as it is. In the double internal angle motion, the moment of force arrives at the middle position of the central shaft and the first and second moving coordinates cams (52,54), and therefore, the forces of both sides are transmitted doubly. Since this force is generated successively on both sides of the seesaw action direction and angle lever portion (8), the superfluous force is automatically applied as the rotatory power of the additional elastic body (58). The additional elastic rotation body (58) receives the power obtained by the circular Great Absolute relative rotation body portion (6), which are basic devices, as the power necessary for the rotation thereof, from the first and second moving coordinates cams (52)(54) and the central shaft through the first and second connection rods (46)(48) connected to the point of appliance of the seesaw action direction and angle lever portion (8), and the elasticity thereof are returned through the same course. In the output gear (56), an output shaft (60) is constituted to connect the output gears (56) and transmit the rotatory power to the additional elastic rotation body (58), and thereby convert the up and down motion to the rotation motion.

The seesaw action direction and angle lever portions (8), moving coordinates conversion portions (10), additional elastic rotation bodies (58), amplification electricity generation devices (12) and electronic clutch portions (40) can be installed in plural numbers according to the design, and are not limited in number.

The output gear (56) and the first and second moving coordinates cams (52)(54) of the moving coordinates conversion portion (10) are mounted and fixed inside the gear box (62) and are connected to the connection rod portion (44) with a cam (50).

In the connection rod portion (44), the first and second connection rods (46)(48) are installed to have a predetermined space on both sides of the seesaw action direction and angle lever (8), in order not to interrupt the motion of the seesaw action direction and angle lever (8).

The additional elastic rotation body (58) is installed on one side of the moving coordinates conversion portion (10), having a predetermined space therefrom, with an output shaft (60) forming the shaft of the output gear (56) to be transmitted the rotatory power of the seesaw action direction and angle lever (8). The additional elastic rotation body (58) is constituted to output rotatory power that is more increased in speed than the input rotatory power by the conventional gear collection.

When the amplification electricity generation device portion (12) is installed in the moving coordinates conversion portion (10), it is connected to the output shaft (60) in the order of a generator (64) connected through the transmission (64-1), an accelerator (R), a transmission (T), an electronic clutch (C) and an additional elastic rotation body (58), and also comprises the generator (64) driven by the accelerated rotatory power. The power supply generated by the generator (64) is supplied to industries through the general power transmission equipment (66). Also, it is installed to make the electricity generated here be supplied as the power supply of the first and second starting motor groups (20) (22) of the starting driving portion (4) and other electricity generating electric field components (68).

The electronic control device (16) controls the first and second starting motor groups (20)(22), the forward and reverse actuator (41), the left and right conversion actuator (43), the elastic collision device portion (24), the pressure device (47)(49) and the power transmission equipment (66) by the previously set up information. The operation of the positive power electricity generation system (2) constituted as shown above will be explained. When a user turns on the operation switch (14) to use the initial power supply by the battery or other power supply devices, the electronic control device (16) recognizes this and supplies power to the first and second starting motor groups (20)(22) of the starting driving portion (4) by the previously set up information.

Accordingly, the driving gears (18) of the first and second starting motor groups (20)(22) perform rotation motion within a range by the previously set up information.

When the driving gear (18) rotates forwardly by the operation of the first and second starting motor groups (20)(22), the circular Great Absolute relative rotation body portion (6) in position rotates in the clockwise direction. At this time, the electronic clutches (45) on both sides of the seesaw action direction and angle lever portion (8) are operated alternately by the action of the forward and reverse actuator

(41) and the right and left conversion actuator (43) based on the previously set up signal of the electronic control device (16).

Here, the multilayer seesaw action direction and angle lever (38) of the seesaw action direction and angle lever portion (8) makes the reciprocating motion according to the conversion of the rotatory power, by hitting the collision portion (30) formed on the side thereof with the first and second elastic collision portions (32)(34) of the elastic collision device portion (24).

Accordingly, when the electronic control device (16) recognizes that the circular Great Absolute relative rotation body portion (6) and the seesaw action direction and angle lever portion (8) rotate by the previously set up information, the electronic control device (16) advances the first electronic collision portion (32) to hit the collision portion (30) protruded on the outer circumference of the multilayer seesaw action and angle lever (38), and thereby makes the conversion of the rotation direction and the reciprocating action easy. Therefore, the circular Great Absolute relative rotation body portion(6) continuously rotates, and when the attachment plate (7) arrives within the range of 60° with respect to the electromagnetic clutch (45) of the multilayer seesaw action direction and angle lever (38), the electronic control device (16) advances the forward and reverse actuator (41), and make the electromagnetic clutch (45) be attached to the attachment plate (7) in the position a, and thereby be transmitted the rotatory power, by the previously set up information.

Under the condition that the electromagnetic clutch (45) and the attachment plate (7) are attached to each other, the circular Great Absolute relative rotation body portion (6) rotates, and when the attachment plate (7) arrives in the position b, the forward and reverse actuator (41) retreats by the signal of the previously set up information, and at the same time, the left and right conversion actuator (43) operates to make the angle of the forward and reverse actuator (41) maintain a straight line with the attachment plate in the position b.

Here, since the electromagnetic clutch (45) is installed in the forward and reverse actuator (41) in a ball joint type the position alteration thereof is made easily, and the electromagnetic clutch (45) maintains the state of being closely attached to the attachment plate (7). Accordingly, when the attachment plate (7) goes out of the position c, after the circular motion rotation body portion (6) rotates and the attachment plate (7) moves to the position c under the condition that the electromagnetic clutch (45) and the attachment plate (7) are attached to each other, the forward and reverse actuator (41) and the left and right conversion actuator (43) are restored to the initial state by the previously set up information.

In the foregoing, the operation of the electronic clutch portion (40) in the side of the A portion. The A and C portions, which perform the same action, perform the same descending action, and the B and D portions do the ascending action. The detailed operation thereof are the same as the action of the electronic clutch portion (40) of the A portion, which is explained in the foregoing.

Therefore, the C and D portions of the multilayer seesaw action direction and angle lever (38) of the seesaw action direction and angle lever portion (8) perform reciprocating motion contrary to the reciprocating motion of the A and B portions. Here, the number of the seesaw action direction and angle lever portion (8) can be increased or decreased according to the installation usage thereof, and therefore can be adjusted according to the electricity generating amount.

And, the first and second connection rods (46)(48) are connected to the multilayer seesaw action direction and angle lever (38) of the seesaw action direction and angle lever portion (8), and are connected to and rotate the cam (50) inside the gear box (62) by repeating ascending and descending motion, and thereby the rotation of the first and the second moving coordinates cams (52)(54) are performed, and the output gear (56) arranged between the first and the second moving coordinates cams (52)(54) rotates the output shaft (60). As shown above, the first and second moving coordinates cams (52,54) are connected to the lower end of the connection rod portion (44) connected to both sides of the rotation central shaft of the seesaw action direction and angle lever portion (8) having a predetermined space, and perform an internal angle motion of 180° and an external angle motion of 180°. In first and second moving coordinates cams (52)(54) connected to both sides of the point of appliance with the first and second connection rods (46)(48), the moment of force of the moving coordinates on both sides of the double external motions of relatively pushing and pulling concentrate on the central shaft, and the force of the point of appliance in the seesaw action direction and angle lever portion (8) is transmitted as it is (please refer to Fig. 11).

In the double internal angle motion, the moment of force arrives at the middle position of the central shaft and the first and second moving coordinates cams, and therefore, the forces of both sides are transmitted doubly. Since these forces are generated successively on both sides of the seesaw action direction and angle lever portion (8), the superfluous force generated here is automatically applied as the rotatory power of the additional elastic body (58).

The additional elastic rotation body (58) receives the power obtained by the circular Great Absolute relative rotation body(6) as the power necessary for the rotation thereof from the first and second moving coordinates cams (52)(54) and the central shaft through the first and second connection rods (46)(48) connected the point of appliance of the seesaw action direction and angle lever portion (8), which are basic devices, and the elasticity thereof are returned through the same course.

Therefore, when the circular Great Absolute relative rotation body portion (6) rotates by the speed energy, the electromagnetic clutch (45) of the electronic clutch portion (40) of the seesaw action direction and angle lever portion (8) is connected to the attachment plate (7) at a predetermined angle and thereby the rotatory power is transmitted. Accordingly, the length and the speed of the first and second moving coordinates cams (52)(54) connected to the first and second connection rods (46)(48) connected to the point of application of the multilayer seesaw action direction and angle lever (38) of the seesaw action direction and angle lever portion (8) are changed, and the first and the second moving coordinates cams (52)(54) are driven by the amplified amount of the speed energy. The rotatory power by the rotation of the output shaft (60) is increased in speed by passing through the additional elastic rotation body (58) of the amplification electricity generation device (12), and the output rotary power is applied to the generator (64), and amplifies the electricity generating amount. The additional elastic rotation body (58) is to compensate for the part, where the operating force makes a blank in the turnaround point, when the seesaw action direction and angle lever (8) rotates up and down, and does an ancillary function.

On the other hand, while the seesaw action direction and angle lever portion

(8) repeats seesaw action reciprocatingly rotating within a predetermined range of angle as shown above, the rotatory power, which is increased in speed, passing through the additional elastic rotation body (58) operating through the output shaft (60) by the rotation of the output gear (56) of the gear box (62), generates electricity by operating the generator (64) of the amplification electricity generation device (12), and provides sufficient amount of electricity to the first and second starting motor groups (20)(22) and other electric field components (68).

The motor groups can be installed additionally on the left and right sides besides the first and second starting motor groups (20)(22) constituting the starting driving portion (4), as long as it is allowed, and are not limited in number.

And it is natural that one or more pairs of seesaw action direction and angle lever portions (8) can be installed between the circular Great Absolute relative rotation body (6) according to the characteristics of the design.

The circular Great Absolute relative rotation bodies (6) rotate in the same direction and in the same number of rotations, and reciprocating the seesaw action direction and angle lever portions (8) alternately and thereby amplifies the energy to convert the moving coordinates conversion portion (10) to perform a rotation motion. The size of the circular Great Absolute relative rotation body portion (6) and the seesaw action direction and angle lever portion (8) can be variously changed according to the design pattern, and is not limited to the technical idea disclosed herein. The components applied to the circular Great Absolute relative rotation body portion (6) and the seesaw action direction and angle lever portion (8) can be manufactured with a material that promotes the distortion or reduces the weight, and can be variously changed in the quality of material or shape, and are not limited to the drawings illustrated herein.

Although the preferred embodiment of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claim.

Claims

[CLAIMS]

[Claim 1]

A positive power electricity generation system, comprising: a starting driving portion comprising an operation switch for applying power supply, an electronic control device for sensing the turning on of the operation switch, an positive power portion for performing four direction and top and bottom motion by the relative rotation of the negative pole rotation body and the positive pole rotation body of the circular Great Absolute, and a first and a second motor groups arranged in plural numbers on both sides to engage with a circular Great Absolute relative rotation body in the order of an electric motor for operating a driving gear by receiving the power supply based on the previously set up information, a decelerator, a transmission and a driving gear; a circular Great Absolute relative rotation body portion, which relatively connects circular Great Absolute rotation bodies on both sides of a central shaft of a predetermined length to shaft supports in a predetermined space to be rotated by plural driving gears of the starting driving portion, and mounts attachment plates on the positions dividing the surfaces facing each other by a predetermined angle to interlock with the moving coordinates conversion portion by the operation of the electronic clutch portion of the seesaw action direction and angle lever; a seesaw action direction and angle lever portion, whose two rotation bodies on both sides are connected to the electronic clutch portion operating having a declination of angle like two number of rotations, when the rotation angle of the circular Great Absolute relative rotation body is 90° three number of rotations when the rotation angle of the circular Great Absolute relative rotation body is 60° four number of rotations when the rotation angle of the circular Great Absolute relative rotation body is 45° and six number of rotations when the rotation angle of the circular Great Absolute relative rotation body is 30°; an electronic clutch portion comprising a forward and reverse actuator installed on the multilayer seesaw action direction and angle lever to go forward and backward on the seesaw action direction and angle lever portion, a left and right conversion actuator for controlling the left and right locational angle of the forward and reverse actuator within a predetermined range of angle, and an electromagnetic clutch installed on the front of the forward and reverse actuator in a ball joint type to be variably attached to the attachment plate of the circular Great Absolute relative rotation body portion by the previously set up information; a moving coordinates conversion portion, which eccentrically connects the points of application having a predetermined space between themselves on both sides of the rotation central shaft of the seesaw action direction and angle lever portion with a cam inside the gear box at the lower end side of the connection rod portion, to perform an interior angle motion of 180° and an external angle motion of 180° by converting an up and down motion to a rotation motion, perform double internal and external angle motions of relatively pushing and pulling the first and second moving coordinates cams connected to the first and second connection rods, and thereby make the moment of the forces of the moving coordinates on both sides and the force of the point of application of the seesaw action direction and angle lever portion be integrated as trinity with the output gear between the first and second moving coordinates cams; an amplification electricity generation device, which is connected to the output shaft installed on the moving coordinates conversion portion having an additional elastic rotation body for adding elasticity to the rotatory power generated by the action of the seesaw action direction and angle lever portion, to be rotated by the amplified rotation elasticity and generate electricity by the amplified rotatory power; and an elastic collision device portion, which is installed in parallel on both sides between the circular Great Absolute relative rotation body portion, is rotatably installed by the shaft support to make the repetitive rotatory motion made within a predetermined range of angle and is installed on one side to assistantly perform the rotation conversion of the multilayer seesaw action direction and angle lever.