(0001) The present disclosure relates to a flywheel power generation device, more specifically the technique of rotating a vertically installed flywheel to the perimeter of the flywheel by the propeller, and the generator from the middle shaft of the flywheel.

BACKGROUND OF THE INVENTION

(0002) The shortage of electricity has become a big problem in front of the world, and it is increasing day by day. As a result, the use of various generators to meet the power shortage has also come to the fore. As far as the current artificial power generation is concerned, there is hydro power, thermal power, wind power, solar energy, nuclear energy, gas and oil power generation, mechanical power generation etc. They consume thermal power generation, coal, gas and oil resources. They have a huge impact on investment in terms of power generation, as well as they are influenced by geographical location. However, they cannot meet the market demand. Therefore, inventing a power generation device, which is low in investment, does not pollute the environment and can provide high power, is the need of the day.

(0003) Current known flywheels are middle shaft drives, although more power is needed to rotate the flywheel, the maximum power is spent to rotate the flywheel. Therefore, maximum efficiency is not increased.

(0004) According to the former application number 202021050079 and 202021050571, the horizontal flywheel is rotated by the tire wheel from the periphery of the flywheel, in which the friction loss is high.

(0005) According to the former application numbers 202021050079 and 202021050571, the horizontal flywheel is rotated by a tire wheel from the periphery of the flywheel, which has a limit of speed, so the alternator/generator cannot be rotated at sufficient speed.

(0006) According to previous application numbers 202021050079 and 202021050571, the flywheel is installed horizontally, which is not easy to balance and rotate smoothly.

(0007) To overcome the above drawbacks, flywheel power generation equipment requires a flywheel driven by a propeller attached to the periphery of a vertically mounted flywheel, and the alternator/generator is operated by a prime mover on one side or Separate prime movers on either side.

SUMMARY OF THE INVENTION

(0008) In an embodiment, a flywheel power generation device is disclosed. The device includes a vertical flywheel configured to be installed between at least two steel structures comprising a first steel structure and a second steel structure by more than one bearing assembly on the support and of both the first steel structure and second steel structure. The device further includes a plurality of motor with propellers configured to be installed at the same distance on the perimeter of the flywheel. The device further includes a plurality of electric bus-bars configured to be installed in a circular shape on the shaft of one side of the flywheel, which is insulated by the insulator. The device further includes a friction connector configured to be installed on the first steel structure touching the bus-bar, which is insulated by the insulator. The device further includes a propeller motor connected by friction connector, bus-bar and cable. The device further includes a power supply panel configured to be installed on the first steel structure and a generator assembly installed on the second steel structure. When power is supplied to the propeller motor from friction connectors, bus-bars, cables and panels, the flywheel is rotated by the wind power of the propeller from the periphery of the flywheel, and the generator assembly rotates through the central shaft of the flywheel, which Provides optimized torque and power.

(0009) In another embodiment, the present disclosure seeks to provide a flywheel power generation device to solve the problem of power shortage. To solve the problem of power shortage, flywheel power generation equipment is used, in which three concrete or steel structures are installed in series, leaving sufficient gaps between each other. The altemator/generator assembly is installed on structure two, and the vertical flywheel drive assembly is installed in the middle by supporting structures one and two. The shaft of the other direction of the alternator or generator is extended to sufficient length to engage the front of the shaft of the drive assembly. Similarly, another drive assembly is mounted on a support of structures two and three with a vertical flywheel in the middle, and the support of the structure is supported by more than one bearing assembly, and more than one propeller equally spaced along the circumference of both flywheels. And both drive assemblies are attached to either side of the alternator/generator. Power is supplied to the propeller motor of the drive assembly by multiple rotating power units. When power is supplied by the rotating units to the propeller motors of both drive assemblies, the propellers use air force to spin the flywheel around the periphery of the flywheel, providing more torque and more power.

OBJECT OF THE INVETION

(0010) Accordingly, one of the objects of this invention is the provision of a flywheel mechanism: wherein, the flywheel is rotated vertically, so as to achieve proper balance.

(0011) Another object of the present disclosure is to use flywheel storage energy. (0012) Another object of the present disclosure is to improve production of electricity at a lower cost.

(0013) Another object of the present disclosure is to reduce or increase the diameter and weight of the flywheel.

(0014) Yet another object of the present invention is to deliver an expeditious and cost- effective flywheel power generation device.

(0015) To further clarify advantages and features of the present disclosure, a more particular description of the invention will be rendered by reference to specific embodiments thereof, which is illustrated in the appended drawings. It is appreciated that these drawings depict only typical embodiments of the invention and are therefore not to be considered limiting of its scope. The invention will be described and explained with additional specificity and detail with the accompanying drawings.

BRIEF DESCRIPTION OF FIGURES

(0016) These and other features, aspects, and advantages of the present disclosure will become better understood when the following detailed description is read with reference to the accompanying drawings in which like characters represent like parts throughout the drawings, wherein:

(0017) Figure 1 illustrates a perspective view of the structure of the flywheel power generation device in accordance with an embodiment of the present disclosure;

(0018) Figure 2 illustrates a side view of structure 13 of the flywheel power generating device in accordance with an embodiment of the present disclosure;

(0019) Figure 3 illustrates a side view of structure 14 of the flywheel electrical generating device in accordance with an embodiment of the present disclosure;

(0020) Figure 4 illustrates a perspective view of the rotating power unit of the flywheel power generation device in accordance with an embodiment of the present disclosure;

(0021) Figure 5 illustrates a perspective view of the additional flywheel in accordance with an embodiment of the present disclosure;

(0022) Figure 6 illustrates a perspective view of the alternator structure of the flywheel power generation device in accordance with an embodiment of the present disclosure;

(0023) Figure 7 illustrates a side view of the alternator structure of the flywheel power generation device in accordance with an embodiment of the present disclosure;

(0024) Figure 8 illustrates a perspective view of the generator structure of the flywheel power generation device in accordance with an embodiment of the present disclosure; and (0025) Figure 9 illustrates a perspective view of the rotating power unit of the flywheel power generation device in accordance with an embodiment of the present disclosure.

(0026) Further, skilled artisans will appreciate that elements in the drawings are illustrated for simplicity and may not have necessarily been drawn to scale. For example, the flow charts illustrate the method in terms of the most prominent steps involved to help to improve understanding of aspects of the present disclosure. Furthermore, in terms of the construction of the device, one or more components of the device may have been represented in the drawings by conventional symbols, and the drawings may show only those specific details that are pertinent to understanding the embodiments of the present disclosure so as not to obscure the drawings with details that will be readily apparent to those of ordinary skill in the art having benefit of the description herein.

DETAILED DESCRIPTION:

(0027) For the purpose of promoting an understanding of the principles of the invention, reference will now be made to the embodiment illustrated in the drawings and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended, such alterations and further modifications in the illustrated system, and such further applications of the principles of the invention as illustrated therein being contemplated as would normally occur to one skilled in the art to which the invention relates.

(0028) It will be understood by those skilled in the art that the foregoing general description and the following detailed description are exemplary and explanatory of the invention and are not intended to be restrictive thereof.

(0029) Reference throughout this specification to “an aspect”, “another aspect” or similar language means that a particular feature, structure, or characteristic described in connection with the embodiment is included in at least one embodiment of the present disclosure. Thus, appearances of the phrase “in an embodiment”, “in another embodiment” and similar language throughout this specification may, but do not necessarily, all refer to the same embodiment.

(0030) The terms "comprise", "comprising", or any other variations thereof, are intended to cover a non-exclusive inclusion, such that a process or method that comprises a list of steps does not include only those steps but may include other steps not expressly listed or inherent to such process or method. Similarly, one or more devices or sub-systems or elements or structures or components proceeded by "comprises...a" does not, without more constraints, preclude the existence of other devices or other sub-systems or other elements or other structures or other components or additional devices or additional sub-systems or additional elements or additional structures or additional components.

(0031) Unless, otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The system, methods, and examples provided herein are illustrative only and not intended to be limiting.

(0032) Embodiments of the present disclosure will be described below in detail with reference to the accompanying drawings.

(0033) INTERPRETATION OF NUMBERS

1- Flywheel

2- Propeller

3- Motor (Motor means any motor that runs on AC or DC power supply)

4- Support (propeller)

5- Flywheel center shaft

6- Bearing assembly

7- Coupling

8- Step up gear box

9- Coupling

10- Generator

11- Surface (structure 14)

12- Surface (structure 13)

13- Structure

14- Structure

15- AC or DC drive panel

16- Electric rotating unit

17- Friction connector

18- Cable

19- Insulator (bus-bar)

20- Insulator (friction connector)

21- Support

22- Spring

23- Cable 24- Additional flywheel.

(0034) Referring to Figure 1, a perspective view of the structure of the flywheel power generation device is illustrated in accordance with an embodiment of the present disclosure. The device 100 includes a vertical flywheel 1 configured to be installed between at least two steel structures comprising a first steel structure 13 and a second steel structure 14 by more than one bearing assembly 6 on the support 11 and 12 of both the first steel structure 13 and second steel structure 14.

(0035) In an embodiment, a plurality of motor with propellers 2 is configured to be installed at the same distance on the perimeter of the flywheel 1.

(0036) In an embodiment, more than one support is mounted at equal intervals from the periphery of the flywheel 1, and the motor 3 with propeller 2 is mounted on the support 4.

(0037) In an embodiment, a plurality of electric bus-bars is configured to be installed in a circular shape on the shaft 5 of one side of the flywheel 1, which is insulated by the insulator. (0038) In an embodiment, a friction connector is configured to be installed on the first steel structure 13 touching the bus-bar, which is insulated by the insulator.

(0039) In an embodiment, a propeller motor 3 is connected by friction connector, bus-bar, cable and AC or DC drive.

(0040) In an embodiment, wherein each propeller motor 3 is provided with a no-load relay and overload, and automatically disconnected the entire power supply if any motor 3 is tripped for any reason.

(0041) In an embodiment, a power supply panel is configured to be installed on the first steel structure 13 and a generator assembly 10 is installed on the second steel structure 14, when the power is supplied to the propeller motor 3 through the cable, friction connector and busbar, the propeller 2 rotates the flywheel 1 through the periphery of the flywheel by the force of the wind, and the generator assembly 10 rotates through the central shaft 5 of the flywheel 1, thereby optimized torque and power are obtained.

(0042) In another embodiment, the flywheel 1 is mounted perpendicular to the first support

12 of the first steel structure 13 and the second support 11 of the second steel structure 14. Spherical-shaped electric bus-bars are installed on the shaft 5 of the flywheel 1 with the help of insulators, and the friction connector is installed on the surface of the first steel structure

13 with the help of insulators, which are connected by touching the bus-bars.

(0043) In another embodiment, wherein the generator assembly 10 is mounted on the surface of the second steel structure 14, and the input shaft of the step-up gear box 8 is connected to the shaft 5 of the flywheel 1 by the coupling 7, and the output shaft of the step-up gear box 8 is connected to the shaft 5 of the generator 10 by the coupling 9, in which the speed of the propeller 2 is controlled by the AC or DC drive panel which provides the optimized speed to the generator.

(0044) In another embodiment, spherical bus-bars are installed on the body of the shaft 5, insulated by insulators, and the friction connector is installed on the surface 12 of the first steel structure 13 by insulating them. Which touch the bus-bar and are pressed by the spring.

(0045) In another embodiment, the storage energy is increased by installing additional one or more flywheels in between the flywheel 1 and altemator/generator 10, which produce more power by adding a higher capacity alternator.

(0046) In another embodiment, such that power is supplied to the propeller motor 3 by cables, friction connectors, bus-bars from the AC or DC drive 15, and the propeller 2 rotates the flywheel 1 by wind force from the periphery of the flywheel and the generator assembly is rotated by the centre shaft 5 of the flywheel 1, providing optimized torque as well as the benefit of flywheel storage energy.

(0047) The device include flywheel 1, propeller 2, propeller motor 3, propeller support 4, flywheel shaft 5, bearing assembly 6, coupling 7, step up gear box 8, coupling 9, generator 10, structure surface 11, structure surface 12, Includes Structure 13 and Structure 14, AC or DC drive panel 15, bus-bar assembly 16 and friction connector assembly 17.

(0048) According to Figure 1, structures 13 and 14 of sufficient capacity are installed vertically on the ground keeping sufficient distance in front of each other. The said structure is of steel or concrete, which may be given additional side supports to strengthen it. The middle shaft 5 of the single piece flywheel 1 is mounted with support surfaces 12 and 11 of the structure 13 and 14. Multiple bearing assembly 6 is used for mounting the flywheel 1. By installing more than one support 4 on the periphery of the flywheel 1, the propeller 2 with motor 3 is installed with the supports 4. The electric panel 15 is installed on the structure 13 of the flywheel 1. The circular-shaped electric bus-bar 16 installed on the shaft 5 with help of insulator 19, and the friction connector 17 is installed on the surface 12 of the structure 13 with the help of the insulator 20, which abuts the bus-bar 16 Connected by touch. The cable 23 coming out of the AC or DC drive panel 15 is connected to the friction connector 17, the bus-bar touching the friction connector 16 and the propeller motor 3 is connected to the cable 23 and cable 18.

(0049) According to Figure 1, the generator assembly is installed on the surface of Structure 14, the input shaft of Step-Up Gear Box 8 is connected to the shaft of the flywheel 1 by coupling 7, and the output shaft of step-up gear box 8 is connected to the shaft of generator 10 by coupling 9.

(0050) According to Figure 1 the speed of the propeller will be controlled by AC or DC drive panel 15 and the generator will be delivered to adequate speed, wherein each propeller motor 3 is provided with a no-load relay and overload, and automatically disconnected the entire power supply if the motor 3 is tripped for any reason.

(0051) Figure 2 shows a side view of a flywheel generator structure 13 according to one embodiment of the present disclosure. Structure 13 is made of steel or concrete of sufficient height, width, length and capacity. On the surface of which a side shaft of a flywheel 1 with a multiple bearing assembly 6 is installed and an AC or DC drive power panel 15 is installed. Several circular-shaped bus-bars 16 are installed on the shaft 5 body of the flywheel 1, and the friction connector 17 is installed on the support 21 by touching the bus-bars, and the panel 15 and the friction connector 17 are connected by cables 23.

(0052) Figure 3 illustrates a side view of structure 14 of the flywheel electrical generating device in accordance with an embodiment of the present disclosure. Structure 14 is made of steel or concrete of sufficient height, width, length and capacity, which is made in two steps. Flywheel is installed at one step and generator assembly is installed at the other step. The second side shaft of flywheel 1 is installed on the surface 11 with more than one bearing assembly 6, and the generator assembly is connected to the shaft 5 of flywheel 1.

(0053) Figure 4 illustrates a perspective view of the bus-bar and friction connector of the flywheel electrical generating device in accordance with an embodiment of the present disclosure. A view of the bus-bar and friction connector of the flywheel electrical generating device, installing bus-bar 16 on top of circular shaped insulators 19 on the body of shaft 5 between flywheel 1, and installing support 21 on surface 12 of structure 13, The friction connector 17 has been installed by insulating it by insulating 21 on support 21. And the friction connector is pressed by Spring 22 and touching bus-bar 16. More than one Bus-bar Assembly and friction Connector Assembly is installed.

(0054) Figure 5 illustrates a perspective view of the additional flywheel in accordance with an embodiment of the present disclosure. Installing an additional one or more flywheel 24 will increase storage energy, which produce more power by adding more capacity alternators. (0055) According to this device, when power is supplied to the propeller motor 3 by the AC or DC drive 15 via cable 23, friction connector 17, bus-bar 16 and cable 18, the propeller 2 rotates the flywheel with the force of the wind from the circumference of the flywheel, thus, more torque and power is achieved by the flywheel 1 is rotated by the propeller 2 from the periphery of the flywheel 1, and the altemator/generator assembly is rotated by the center shaft 5 of the flywheel.

(0056) Currently, the technical solution adopted by this device to solve the problem of power shortage is: in which, the vertical flywheel 1 is installed between two steel structures by more than one bearing assembly 6 on the support of both structures, and more than one motor 3 with propeller 2 is installed at the same distance on the perimeter of the flywheel 1. More than one electric bus-bar 16 is installed in a circular shape on the shaft 5 of one side of the flywheel 1, which is insulated by the insulator. The friction connector 17 is installed on structure 13 touching the bus-bar 16, which is insulated by the insulator. The propeller motor 3 is connected by friction connector 17, bus-bar 16 and cable. Power supply panel 15 is installed on Structure 13 and generator assembly installed on Structure 14. When power is supplied to the propeller motor 3 by friction connector, bus-bar and cable from the power supply panel, the flywheel 1 rotates from the wind force of the propeller 2, rotates through the perimeter of the flywheel 1, and the generator assembly 10 rotates through the middle shaft 5 of the flywheel 1, thereby obtaining higher torque and getting more power.

(0057) The length, width, thickness and capacity of all parts and equipment engaged in this invention will be reduced or increased according to the composition.

(0058) The propeller motor of this device will be AC or DC.

(0059) Instead of the open propeller engaged in this device, the flywheel can be rotated by installing a close propeller.

(0060) EXAMPLES FOR ASSESSMENT

1. Alternator rpm = 100

Flywheel rpm = 100

Accordingly, the motor speed will be gradually increased by wireless remote or wire remote from AC or DC drive until the alternator acquires sufficient speed.

2. Generator RPM = 1500

Step Up Gear Box Ratio = 1 : 100

If the ratio of the step-up gear box is 1 : 100, then the gear box will have to be rotated 15 times from the incoming direction for 1500 rpm.

If the gear box has to be rotated 15 times in the incoming side, the flywheel has to be rotated 15 times.

Accordingly, the motor speed will be gradually increased by wireless remote or wire remote from AC or DC drive until the generator acquires sufficient speed. IN ANOTHER EMBODIMENT, DEVICE FURTHER COMPRISES:

(0061) In one embodiment, at least three structures consisting a first structure, a second structure and a third structure installed in series leaving substantial differences between each other.

(0062) In one embodiment, an alternator/generator 12 is mounted on a second assembly structure, and a drive assembly 8 is mounted centrally by support the first and second assembly structures, and another drive assembly 8 is mounted centrally by support the second and third structures. In which both drive assemblies 8 are attached to the shaft of the alternator/generator 12. Wherein the other direction of the alternator or generator is long enough to be forward connected to the shaft 6 of the drive assembly, wherein the flywheel of the drive assembly is supported by more than one bearing 5.

(0063) In one embodiment, a plurality of motor 10 with propellers 9 are mounted at the same distance on the perimeter of the flywheel 8, wherein on the shaft 6 on one side of the flywheel, more than one power bus-bar 17 is installed in a circular shape, which remains insulated by the insulator and friction connectors 18 are installed on structure by touching with bus-bars, which are insulated by insulators, wherein the propeller motor 10 is connected to the friction connector, bus-bar and cable.

(0064) In one embodiment, a second vertical flywheel drive assembly 8 is mounted in the middle, supporting from the second and third assembly structures, and is coupled to the shaft

6 of the alternator/generator 12, and power is supplied to propeller motor 10 through the panel 4, bus-bar 17, friction connector 18 and cable 21. So the air force of the propeller 9 causes the flywheel 8 to rotate from the periphery of the flywheel 8, and the alternator/generator assembly 12 is rotated by the two drive assemblies 8 on either side, resulting in optimized torque and power.

(0065) In another embodiment, when power is supplied to propeller motor 10 by rotating unit

7 from an AC or DC drive, propeller 9 rotates flywheel 8 by the force of wind from the perimeter of flywheel 8, wherein both flywheel 8 runs simultaneously at the same speed, causing the alternator/generator 12 to rotate from both sides such that the rotating Alternator/generator 12 from both sides takes the most advantage of flywheel 8's storage energy.

(0066) In another embodiment, the shaft 6 is mounted in the middle of a vertically mounted assembled flywheel 8 or a monolithic flywheel 8, and the end of said shaft is fixed in a bearing 5 mounted on the surface between the first and second structure. Two or more motor propellers 9 are installed on the periphery of the flywheel 8 and a rotating power unit 7 is installed on the shaft 6 of the flywheel mounted on the surface of the first and third structure. (0067) In another embodiment, the shaft 6 is mounted between a vertically mounted assembled flywheel or a monolithic flywheel 8, and said shaft 6 The end of the bearing 5 is installed on the surface between the first and second structures and there is another flywheel 8 installed vertically on the surface between the second and third structures, in which two or more motor propellers 9 are installed on the periphery of the flywheel (8) and a rotating power supply unit 7 is installed on the shaft 6 of the flywheel 8 and on the surface of the first and third structures.

(0068) In another embodiment, the second end of the flywheel's shaft 6 is connected by coupling to the input shaft of Step Up Gear Box 16 installed on surface of the second structure, and the output shaft of Step Up Gear Box 16 is connected to the first shaft of generator 12 via one side locking bearing/freewheel 11, wherein the shaft 6 on the other side of generator is extended to a sufficient length so that shaft is connected to shaft of another drive assembly via one side locking bearing/freewheel 11 such that the generator 12 is rotated from both sides by connecting two drive assemblies to both shafts of generator.

(0069) In another embodiment, the bus-bar 17 and the propeller motor 10 are connected by cables 20, and a number of insulated friction connectors 18 are installed on the surface of the structure, which are touches to the bus-bar 17, in which the AC or DC drive and the friction connector 18 are connected by the cable 21, such that the flywheel 8 is rotated by the air force of the propeller 9, the bus-bar rotates with the shaft 6 by touching 17the friction connector 18, and supplies power to the propeller motor 10.

(0070) In another embodiment, the low rpm alternator/generator 10 is driven unidirectionally or bidirectionally by a prime mover 1 without a gear box, and the high rpm alternator/generator 10 is driven unidirectionally or bidirectionally by a prime mover 1 with a gear box. In another embodiment, by coupling a side locking bearing/freewheel between the alternator/generator 12 and the prime mover 8, the alternator/generator 12 is required to rotate by coupling the prime mover 8 on either side.

(0071) In another embodiment, wherein the alternator/generator 12 is driven in one direction by a monolithic flywheel or assembled flywheel prime mover 8, or is driven in two directions by two flywheel prime movers 8.

(0072) In another embodiment, the alternator/generator 12 is coupled to the drive assembly 8 on both sides by one side locking bearings/freewheels 11, so that no damage can be caused if one of the drive assemblies accidentally rotates in reverse. (0073) INTERPRETATION OF NUMBERS

1- Structure

2- Structure

3- Structure

4- Electrical panel

5- Bearing assembly with bearing

6- Shaft

7- Rotating electricity unit

8- Flywheel

9- Propeller

10- Motor (Motor means any motor that runs on AC or DC power supply)

11- One side locking bearing/freewheel

12- Altemator/Generator

13- Surface (structure)

14- Extension support

15- Coupling

16- Step up gear box

17- Bus-bar

18- Friction connector

19- Insulator

20- Incoming supply cables

21- Outgoing supply cables

(0074) Figure 6 illustrates a perspective view of the alternator structure of the flywheel power generation device in accordance with an embodiment of the present disclosure.

(0075) Including structure 1, structure 2, structure 3, electrical panel 4, bearing assembly 5, shaft 6, rotating electricity unit 7, flywheel 8, propeller 9, motor 10, one side locking bearing/freewheel 11, alternator 12 and surface 13.

(0076) According to Figure 6, steel or concrete structures of sufficient length, width, height and capacity are installed in series 1, 2, 3 and with sufficient distance between each other. A shaft 6 is placed in the middle of a vertically installed assembled flywheel 8 or a monolithic flywheel 8, the end of the said shaft 6 is fixed in bearing 5 installed on surface 13 between structures 1 and 2. Two or more motor propellers have been installed on the perimeter of flywheel 8. And a rotating power unit 7 is installed on shaft 6 of flywheel 8 and on surface 13 of structure 1. Power is supplied to the incoming of rotating power unit 7 by AC or DC drive and power is supplied to the propeller motor from the outgoing of rotating power unit 7. The second end of shaft 6 of flywheel 8 is connected to the first shaft of Alternator 12 installed on surface 13 of Structure 2 through one side locking bearing/freewheel 11. Further and shaft 6 of a vertical flywheel assembly is fixed in bearing assembly 5 installed on surface 13 of structures 2. And shaft 6 of flywheel 8 is connected to shaft 6 in the other direction of alternator 12 via one side locking bearing/freewheel 11. Rotating power unit 7 is installed on the surface of Structure 3 and shaft 6 of Flywheel 8. Power is supplied to the incoming of rotating power unit 7 by AC or DC drive and power is supplied to the propeller motor from the outgoing of rotating power unit 7. Both flywheel 8's propeller motor 10 is powered by the same AC or DC drive to rotate all motor propellers at the same speed. The second direction shaft of alternator 12 is extended to a sufficient length so that shaft 6 can be connected to shaft 6 of flywheel 8 via one side locking bearing/freewheel 11. Thus generator 12 is rotated from both sides by connecting two drive assemblies to both shafts of generator 12.

(0077) According to Figure 6, when power is supplied to the propeller motor (10) by an AC or DC drive unit, the propeller (9) rotates the flywheel by air force along the periphery of the flywheel (8), both flywheels (8) run simultaneously at the same speed, causing the alternator/ generator (12) is rotate from both directions, so the altemator/generator (12) takes advantage of the stored energy of both flywheels (8).

(0078) Figure 7 illustrates a side view of the alternator structure of the flywheel power generation device in accordance with an embodiment of the present disclosure. With two flywheel propeller assemblies vertically installed between steel structures 1, 2, 3. The propeller with motor 10 has been installed by installing 2 or more extension support 14 from the perimeter of the said flywheel 8.

(0079) Figure 8 illustrates a perspective view of the generator structure of the flywheel power generation device in accordance with an embodiment of the present disclosure. Including structure 1, structure 2, structure 3, electrical panel 4, bearing assembly 5, shaft 6, rotating electricity unit 7, flywheel 8, propeller 9, motor 10, one side locking bearing/freewheel 11, alternator 12, surface 13, coupling and step-up gear box 16.

(0080) According to Figure 8, steel or concrete structures of sufficient length, width, height and capacity are installed in series 1, 2, 3, and with sufficient distance between each other. A shaft 6 is placed in the middle of a vertically installed assembled wheel 8 or a monolithic wheel 8, the end of the said shaft 6 is fixed in bearing 5 installed on surface 13 between structures 1 and 2. Two or more motor propellers 9 have been installed on the perimeter of flywheel 8. And a rotating power unit 7 is installed on shaft 6 of flywheel 8 and on surface 13 of structure 1. Power is supplied to the incoming of rotating power unit 7 by AC or DC drive and power is supplied to the propeller motor from the outgoing of rotating power unit 7. The second end of the flywheel 8's shaft 6 is connected by coupling 15 to the input shaft of Step- Up Gear Box 16 installed on surface 13 of Structure 2 and the output shaft of Step-Up Gear Box 16 is connected to the first shaft of generator 12 via one side locking bearing/freewheel 11. Further and on the perimeter of a vertically installed flywheel 8 have 2 or more motor propeller 9 installed. And a rotating power unit 7 is installed on shaft 6 of flywheel 8 and on surface 13 of structure 3. Power is supplied to the incoming of rotating power unit 7 by AC or DC drive and power is supplied to the propeller motor from the outgoing of rotating power unit 7. The second end of the flywheel 8's shaft 6 is connected by coupling 15 to the input shaft of step-up gear box 16 installed on surface 13 of structure 2 and the output shaft of step- up gear box 16 is connected to the second shaft of generator 12 via one side locking bearing/freewheel 11. The shaft on the other side of the alternator/generator 12 is extended to a sufficient length and the shaft 6 is connected to the shaft 6 of another step-up gear box 16 through a bearing/freewheel 11 on one side. The second shaft of the step-up gear box 16 is coupled to the shaft of the flywheel 8 and is mounted on the surface of the structure 3 through the flywheel shaft. The power rotating unit is installed on the shaft 6 of the flywheel 8 and on the surface of the structure 3. Means another prime mover assembly is attached to the second shaft of the alternator/generator. And by rotating both the assemblies together at the same speed, more torque and power is achieved.

(0081) According to Figure 8, when power is supplied to propeller motor 10 by rotating unit 7 from an AC or DC drive, propeller 9 rotates flywheel 8 by wind force from the perimeter of flywheel 8. Both flywheel 8 are run simultaneously at the same speed, causing generator 12 to rotate from both sides through step up gear box 16. Rotating generator 12 from both sides takes the most advantage of flywheel 8's storage energy.

(0082) Figure 9 According to an embodiment of current disclosure, the flywheel power generation shows the perspective of the rotating power unit of the device. In which many busbars 17 have been installed in a circular shape on the body of Shaft 6, and insulating by insulator 19. Bus-bar 17 is connected to propeller motor 10 by cable 21. And many frictions connector 18 have been installed on the surface of structure 1 and 3. Friction connectors are connected by touching with bus-bar 17. When the flywheel rotates, bus-bar also rotate with flywheel. When power is supplied to propeller motor 10 through cable 20, fiction connector 14, bus-bar 14 and cable 21 by AC or DC drive, so the propeller 9 rotate the flywheel 8 by air force from the periphery of the flywheel 8, and bus-bar 17 also rotate with shaft 6 of flywheel 8 by touching with friction connector 18.

(0083) EXAMPLES FOR ASSESSMENT

1. Alternator RPM = 100

Accordingly, the speed of the both prime mover propeller motor will be gradually increased by AC or DC drive from wireless remote or wire remote until the generator achieves a speed of 100 rpm.

2. RPM Generator = 1500

Step Up Gear Box Ratio = 20: 1

Flywheel RPM = 75

Accordingly, the speed of the both prime mover propeller motor will be gradually increased by AC or DC drive from wireless remote or wire remote until the flywheel achieves a speed of 75 rpm.

One side drive alternator/generator

Flywheel diameter = 10 meter

Flywheel weight = 10 ton

Then

Both side drive alternator/generator

Flywheel diameter = 10 meter

Flywheel weight = 5 tone.

Or

(0084) By rotating the alternator/generator in both directions, the weight of the flywheel is reduced and speed is increased and more torque is achieved.

(0085) Flywheel power generation device solves the problem of power loss: in which three structures of concrete or steel are connected in series leaving sufficient gap between each other. The alternator/generator assembly 12 is mounted on structure 2, and the vertical flywheel drive assembly is mounted in the middle of structures 1, 2 and 2, 3 with surface supports. And shaft 6 of both drive assemblies is connected to both shaft 6 of the alternator/generator. Wherein a vertical flywheel drive assembly is centrally mounted with support structures 1 and 2, the shaft of which is supported by more than one bearing assembly, and more than one propeller 9 is paralleled along the periphery of the flywheel. The rotating power unit is mounted on the flywheel shaft and the structure surface. Power is supplied to the propeller motor by the said rotating power unit. Similarly, another drive assembly is mounted in the middle taking support structures 2 and 3, and is connected to the other direction shaft of the alternator/generator. When power is supplied to the propeller motor by the power unit 7, the air force of the propeller 9 causes the flywheel to rotate, and the alternator/generator assembly is also rotate, resulting in more torque and more power.

ADVANTAGES OF INVENTION

(0086) Accordingly, the main advantage of this invention is that high torque and maximum efficiency are achieved by rotating the alternator/generator from both sides.

(0087) Another advantage of the invention is the provision of a flywheel system in which different benefits are obtained using an assembled flywheel or a monolithic flywheel.

(0088) Another advantage of this invention is the provision of a flywheel mechanism: in which high torque is obtained from low force by rotating the flywheel from the end of the flywheel, as well as flywheel storage energy.

(0089) Another advantage of this invention is the provision of a flywheel system: in which more electricity is produced at a lower cost.

(0090) Another advantage of this invention is the provision of a flywheel mechanism: instead of one large flywheel, more than one flywheel is installed, thereby reducing the effort and risks involved in handling the larger flywheel.

(0091) Another advantage of this invention is the provision of a flywheel mechanism: transportation is easier using the assembled flywheel.

(0092) Another advantage of this invention is the provision of a flywheel system: which reduces the weight of the flywheel and increases the diameter and adds more torque and storage energy by adding to both sides.

PURPOSE OF INVENTION

(0093) Accordingly, the main objective of this invention is to achieve high torque and maximum efficiency by rotating the alternator/generator from both sides.

(0094) Another objective of this invention is the provision of a flywheel system: by rotating the alternator/generator from both sides, by reducing the weight of the flywheel, more torque and storage energy can be achieved by increasing the diameter.

(0095) Another objective of this invention is the provision of a flywheel mechanism: in which high torque is obtained from low force by rotating the flywheel from the end of the flywheel, and at the same time flywheel storage energy is also used. (0096) Another objective of this invention is the provision of a flywheel system: in which more electricity can be produced at a lower cost.

(0097) Another purpose of this invention is the provision of a flywheel mechanism: in which the diameter and weight of the flywheel can be reduced or increased.

(0098) Another objective of this invention is the provision of a flywheel mechanism: which does not require heavy structure.

(0099) Another purpose of the invention is the provision of a wheel system in which one or more assembled wheels or monolithic wheels are used in drive assembly.

(0100) Another objective of this invention is the provision of a flywheel system: in which more electricity can be produced at a lower cost.

(0101) The drawings and the forgoing description give examples of embodiments. Those skilled in the art will appreciate that one or more of the described elements may well be combined into a single functional element. Alternatively, certain elements may be split into multiple functional elements. Elements from one embodiment may be added to another embodiment. For example, orders of processes described herein may be changed and are not limited to the manner described herein. Moreover, the actions of any flow diagram need not be implemented in the order shown; nor do all of the acts necessarily need to be performed. Also, those acts that are not dependent on other acts may be performed in parallel with the other acts. The scope of embodiments is by no means limited by these specific examples. Numerous variations, whether explicitly given in the specification or not, such as differences in structure, dimension, and use of material, are possible. The scope of embodiments is at least as broad as given by the following claims.

(0102) Benefits, other advantages, and solutions to problems have been described above with regard to specific embodiments. However, the benefits, advantages, solutions to problems, and any component(s) that may cause any benefit, advantage, or solution to occur or become more pronounced are not to be construed as a critical, required, or essential feature or component of any or all the claims.