WO2018093095A1 - Power generation apparatus using inertial rotational energy and inertial rotational energy amplification-type large capacity power generation system comprising same - Google Patents

Abstract

The present invention relates to a power generation apparatus using inertial rotational energy, and an inertial rotational energy amplification-type large capacity power generation system including the same, and the purpose of the present invention is to produce electricity with only a small amount of electricity for replenishment of external electricity and inertial rotational energy for initial start-up and to produce a large amount of electricity even with consumption of only a small cost for initial start-up through amplification of inertial rotational energy. The power generation apparatus using inertial rotational energy according to the present invention comprises: a starting unit (100) having at least one starter motor for generating a rotational force by receiving an application of electricity; at least one line of inertial rotational energy storage unit (200) for receiving the rotational force from a starting shaft of the starting unit and storing the rotational force due to inertia while rotating; and at least one row of power generation units (300) comprising a power generation shaft connected to the inertia shaft of the inertial rotational energy storage unit, and a power generator for generating electric power through a rotational force of the power generation shaft, wherein the inertial rotational energy storage unit includes: one or more inertial shafts (210) rotated by receiving the rotational force of the starting unit; one or more inertial wheels (210) rotating together with the inertial shafts, and then rotating the inertial shafts through inertia to sustain power generation at the power generation unit, wherein the starting unit receives an application of external electric power or electricity generated by the power generation unit to generate a rotational force and rotate the inertial rotational energy storage unit. The inertial rotational energy amplification-type large capacity power generation system including the power generation apparatus using the inertial rotational energy according to the present invention comprises: a power generation apparatus using inertial rotational energy; one or more amplification devices including a starting unit for generating a rotational force by receiving an application of electricity, an inertial rotational energy storage unit for storing inertial rotational energy by the starting unit, and a power generation unit for generating electricity with a capacity larger than the capacity of the power generation apparatus using the inertial rotational energy by the rotational force of the inertial rotational energy storage unit, the amplification devices connected in series with the power generation apparatus using the inertial rotational energy; and a usage-side power generation device comprising a starting unit for generating a rotational force by receiving electricity from the power generation unit of the amplification devices, and a power generation unit for outputting a larger amount of generated power than the amplification devices by the rotational force of the starting unit and supplying the same to a usage place.

Description

Power generating device using inertial rotational energy and inertial rotational energy amplification type large capacity power generation system including the same

The present invention relates to a power generation apparatus, and more particularly, to a power generation apparatus using inertial rotational energy to produce electricity with only a small amount of electricity for replenishment of external electrical and inertial rotational energy for initial start-up.

The present invention relates to an inertial rotational energy amplification type large-capacity power generation system including a power generation device using inertial rotational energy to produce a large amount of electricity at low cost through amplification of inertial rotational energy.

In general, the generator converts the rotational force of the rotation shaft into electrical energy, and generates electric energy by receiving the rotational force from a motor, etc. Recently, a generator using inertial rotational power has been proposed.

Patent document (see Patent Publication No. 10-2006-0102475) that can know the background art of the present invention is the upper support plate and the lower support plate is formed therein, respectively; A generator installed on the upper support plate of the main body; A motor installed on the lower support plate of the main body; A vertical rotation shaft rotatably installed in the main body and forming a common rotation shaft of the generator and the motor; A ball caster coupled to a lower end of the vertical rotation shaft to contact the bottom surface of the main body to support rotation of the vertical rotation shaft; A flywheel coupled to the vertical rotation shaft and integrally rotating to provide an inertial rotational force to the vertical rotation shaft; And a control panel installed at one side of the main body and controlling the operation of the motor, and the lower end of the common vertical rotation shaft connecting the generator and the motor is supported by a ball bearing or a shaft bearing in the motor, so that friction of the vertical rotation shaft is achieved. While minimizing the loss and minimizing the vibration of the vertical axis of rotation to increase the power generation efficiency of the generator, but there is a problem that requires a lot of electricity.

On the other hand, the rotational drive device is a motor type in general, there is a problem that the efficiency of electricity is low because the output is low compared to the electricity consumption due to the loss of the rotating shaft and the wear of the material.

[Preceding technical literature]

[Patent Documents]

(Patent Document 1) Published Patent Publication No. 10-2006-0102475

An object of the present invention is to provide a power generation apparatus using inertial rotational energy that generates electricity with only a small amount of electricity for replenishing external electricity and inertial rotational energy for initial start-up.

Another object of the present invention is to provide an inertial rotational energy amplification type large-capacity power generation system including a power generation device using inertial rotational energy to produce a large amount of electricity even if only a small cost for initial start-up through amplification of inertial rotational energy. The purpose is.

In accordance with an aspect of the present invention, there is provided a power generation apparatus using inertial rotational energy, comprising: a starter having one or more starting motors for generating rotational force by receiving electricity; At least one inertia rotational energy storage unit for storing rotational force by inertia while rotating while receiving rotational force from the starting shaft of the starting unit; And at least one row of power generation units including a power generation shaft connected to the inertia shaft of the inertial rotational energy storage unit and a generator for generating electricity through the rotational force of the power generation shaft, and the inertial rotational energy storage unit is rotated by receiving the rotational force of the starting unit. At least one inertial shaft to rotate, the inertial shaft and after rotating the inertial shaft through the inertia includes one or more inertia wheel to continue the power generation in the power generation unit, the starting unit is an external electricity or electricity generation of the power generation unit It is characterized in that for rotating the inertial rotational energy storage unit by generating a rotational force.

The present invention is characterized in that it comprises an inertial shaft for rotating the inertial shaft of the inertial rotational energy storage unit by applying electricity.

Preferably, the present invention includes a magnetic rotation unit to help the rotation of the shaft (starting shaft, inertial shaft, power generating shaft).

An inertial rotational energy amplification type large-capacity power generation system including a power generation apparatus using inertial rotational energy according to the present invention comprises: a power generation apparatus using inertial rotational energy; Electric power of a larger capacity than a power generation device using the inertial rotational energy by using the inertia rotational energy by using a starting unit for generating rotational force by applying electricity, an inertia rotational energy storage unit for storing inertia rotational energy by the starter unit, and an inertia rotational energy storage unit. At least one amplification device including a power generation unit which is generated and connected in series with the power generation device using the inertial rotational energy; And a power generation unit including a power generation unit configured to receive power from the power generation unit of the amplification device and generate a rotational force, and a power generation unit that outputs a larger amount of power than the amplification device and supplies the power to the user. do.

According to the power generation device using the inertial rotational energy and the inertial rotational energy amplification type large-capacity power generation system using the same, the rotational force by the starter is stored as the inertia rotational energy of the inertia wheel to supply electricity to the generator to produce electricity, and The inertia wheel continuously generates electricity by replenishing the rotational speed for power generation through the motor, so the power generation efficiency is very excellent in terms of cost, and also the force of the magnetic shaft (starting shaft, inertia shaft, power shaft) By helping to prevent wear of materials such as shafts and bearings, it can significantly reduce maintenance costs and reduce losses due to machine stoppages.

In addition, by amplifying the inertial rotational energy by constructing the power generation device in multiple stages, there is an effect of improving the productivity and significantly reducing the cost by producing a large amount of electricity even at a low cost.

1 is a perspective view of a power generator using inertial rotational energy according to the present invention.

Figure 2 is a perspective view of the case of the power generation device using the inertial rotational energy according to the invention separated.

3 is a plan view of a power generator using inertial rotational energy according to the present invention.

Figure 4 is a front view showing an example of the inertia wheel and brake applied to the power generation device using the inertial rotation energy according to the present invention.

5 is an exploded perspective view of a magnetic rotating part applied to the power generator using inertial rotational energy according to the present invention.

Figure 6 is a perspective view of a magnetic rotating part applied to the power generator using inertial rotational energy according to the present invention.

Figure 7 is a front view of the magnetic rotating part applied to the power generator using the inertial rotation energy according to the present invention.

8 is a perspective view of a rotor applied to the power generator using inertial rotational energy according to the present invention.

9 is a front view of the rotor applied to the power generator using the inertial rotational energy according to the present invention.

10 is a perspective view of a stator applied to a power generator using inertial rotational energy according to the present invention.

11 is a front view of a stator applied to a power generator using inertial rotational energy according to the present invention.

12 is a block diagram of an inertial rotational energy amplifying large capacity power generation system including a power generation apparatus using inertial rotational energy according to the present invention.

13 is a view showing another example of an inertial rotational energy amplifying large capacity power generation system including a power generation apparatus using inertial rotational energy according to the present invention.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

As shown in Figures 1 to 3, the generator 1000 using the inertial rotational energy according to the present invention, receiving the rotational force of the starting unit 100, the starting unit 100 to generate a rotational force by driving through electricity The inertia rotational energy storage unit 200 that rotates and stores the rotational force by inertia, and receives the rotational force from the inertia rotational energy storage unit 200 to generate electricity by the rotational force 300, the starting unit 100 And a case 400 for supporting the rotational energy storage unit 200 and the power generation unit 300.

The starting unit 100 is based on a pair of starting shafts 120 and 130 rotating by the starting motor 110 and the starting motor 110 to generate rotational force through electricity and transmitting the rotating force to the rotating energy storage unit 200. It is set as a configuration.

The starting motor 110 is a biaxial motor, and the two starting shafts 120 and 130 are symmetrically disposed so as to face each other to maintain balance and prevent damage to the bearings supporting the starting shafts 110 and 120.

The starting motor 110 is for starting the inertial rotational energy storage unit 200 and may continue to operate until the inertia rotational energy storage unit 200 is stopped or by the inertial rotational energy storage unit 200. It can be operated only up to a state capable of driving the power generation unit 300. In the latter case, if the inertia shaft 210 of the rotation energy storage unit 200 rotates at an appropriate level by detecting the rotational speed of the inertia shaft 210 of the inertia rotation energy storage unit 200 through a sensor, electricity is generated. The drive can be interrupted and stopped. That is, even if the starter motor 110 stops, the power generation unit 300 receives power through the inertial rotation energy storage unit 200 to generate power.

According to the present invention, when the rotation speed of the inertia shaft 210 of the inertial rotation energy storage unit 200 is lower than the reference rotation speed, the starting motor 110 may be controlled to be driven again.

That is, the starter motor 110 starts operation at initial start-up and operates without stopping during power generation, and operates only under conditions in which the power generation unit 300 can generate power only by the inertia rotational power of the inertial rotational energy storage unit 200. All that is possible is possible. At this time, even if the starter motor 110 continues to operate like the electron, the starter motor 110 is electrically connected to the generator of the power generation unit 300 and thus does not consume additional costs by receiving the generated electricity without input of external electricity. On and off may be repeated to adjust the rotational speed of the inertial rotational energy storage unit 200.

The starting shafts 120 and 130 may be formed in various ways such as being directly formed on the starting motor 110 and being connected to the original shaft of the starting motor 110. The starting force of the starting motor 110 may be transmitted to the rotating energy storage unit 200. Include everything you convey.

Although only one starting shaft 120 of the two starting shafts 120 and 130 is shown to be connected to the rotational energy storage unit 200 so as to transmit power, both of the starting shafts 120 and 130 are connected to the rotating energy storage unit 200. The power transmission may be connected.

The starting shaft 120 and the power generation unit 300 are connected to the belt 140 as a power transmission member, for example, and the power generation unit 300 and the inertial rotational energy storage unit 200 are connected to the belt 310.

Of course, the present invention is not limited thereto, and the starting shaft 120 and the rotational energy storage unit 200 may be connected, while the rotational energy storage unit 200 and the power generation unit 300 may be connected to each other.

The belt, which is a power transmission member, is wound around a pulley formed on each shaft.

On the other hand, the starter 100 assists the rotation of the starter shafts 120 and 130 by the repulsive force, which is the pushing force of the magnet (helping the rotation mean the shaking of the starter shaft and preventing the stator and the rotor from contacting). In order to include one or more starter side magnetic rotation unit 150.

The starting unit side magnetic rotating unit 150 will be described in detail below.

The inertial rotation energy storage unit 200 is fixed to the inertial shaft 210 and the inertial shaft 210 to receive rotation force from the starting unit 100 and rotates together with the inertial shaft 210 while starting motor through inertia. It is composed of one or more inertia wheel 220 for continuously rotating the inertial shaft 210 and the brake 230 for stopping the inertia wheel 220 even when the 110 stops.

In addition, one or more auxiliary motors 240 may be configured together to compensate for rotation of the inertia wheel 220, that is, the inertia wheel 220 maintains a proper rotation speed for power generation.

The inertial shaft 210 is connected to the starter 100 through the belt 310 and is rotated by receiving a rotational force. When the auxiliary motor 240 is applied, the inertial shaft 210 is also rotated by the rotational force of the auxiliary motor 240.

Accordingly, the inertial shaft 210 may be connected to the original shaft of the auxiliary motor 240.

The inertia wheel 220 is a disk shape having a shaft hole in the center thereof, and is fitted to the circumference of the inertia shaft 210 through the shaft hole and is fixed so as not to be separated from the inertia shaft 210 through the fixing means.

The inertial wheel 220 rotates together by the rotational force of the inertial shaft 210 in the stationary state, and after the inertial shaft 210 rotates, rotates the inertial shaft 210 by the inertia, and thus, the starter 100 The power generation unit 300 is generated even if the starting motor 110 of) is stopped.

The auxiliary motor 240 is an electric motor, and according to the starting motor 110 of the starting unit 100 being both shafts, that is, two shaft motors, that is, two inertia shafts 210 are formed like the starting shafts 120 and 130. It is preferable to drive by receiving all of the electricity.

It is also possible to rotate the inertial shaft 210 of the inertial rotational energy storage unit 200 only through the starting unit 100, but if the weight of the inertial shaft 210 and the inertia wheel 220 is large, the inertia is only in the starting unit 100. Since it may take a long time and may be difficult to rotate the shaft 210 at an appropriate number of revolutions, the auxiliary motor 240 includes an initial operation with the starter 100. That is, the auxiliary motor 240 is capable of operating both at start-up and at the replenishment of the rotational speed of the inertial wheel 220, and the latter is the case when the rotational speed of the inertia shaft 210 is less than or equal to the reference value [set freely by the administrator]. It is applied to rotate the inertial shaft 210 at a predetermined speed.

The brake 230 may be in any way to forcibly stop the rotating inertial wheel 220, for example, forward and backward on the circumference of the brake 230 (forward, the direction toward the inertial wheel 220, backward) Is mounted in an opposite direction of the inertial wheel 220 and is in close contact with a circumference of the inertial wheel 220 through manual or controller control to stop the inertial wheel 220. The pad brake 230 advances back and forth by various methods such as electric, hydraulic, pneumatic, mechanical, and the like.

The inertial rotation energy storage unit 200 includes a storage unit side magnetic rotation unit 250 to help the rotation of the inertial shaft 210 by magnetic force.

The storage unit side magnetic rotating unit 250 will be described in detail below.

Although the inertial rotational energy storage unit 200 is illustrated in one column (one column) in the drawing, it may be configured in two or more columns, and the inertia rotational energy storage unit 200 may be connected in parallel with the starting unit 100. It may also be connected in series from the starter 100.

In the present invention, the starter motor 110 and the auxiliary motor 240 are to generate a rotational force by receiving electricity, electricity generated from the generator 330 of the external electricity or power generation unit 300 supplied from the power company, etc. It operates by receiving renewable energy such as wind, wind, and electricity generated by manual operation. That is, at initial start-up (with or without weak power generation electricity), external electricity (refer to electricity, renewable energy, passive power generation electricity, etc.) of the power company is applied to the starting motor 110 and the auxiliary motor 240, and generates power. When the electricity is generated by the unit 300, the external electricity is cut off and the generated electricity generated by the generator 300 is applied.

To this end, a power supply unit and a starting control unit are provided.

The power supply unit is connected to the external motor and the generated electricity to the starter motor 110 and the auxiliary motor 240, and the starter control unit connects the starter motor 110 and the auxiliary motor 240 to an external electric or generated electric power. Is applied, but detects the amount of electricity generated by the sensor, if the generated electricity is more than the reference amount (settable by the user) to apply the generated electricity, otherwise the external electricity is applied.

The power generation unit 300 is connected to the inertial rotational energy storage unit 200 and the starting unit 100 through the belts 310 and 140 to generate electricity by rotating power of the power generation shaft 320 and the power generation shaft 320. It is composed of a generator (330).

The power generation shaft 320 is also biaxially like the starter shafts 120 and 130 and the inertial shaft 210 to balance the generator 330.

The generator 330 is used to generate electricity by the rotation of the power generation shaft 320 is used.

The generated electricity generated by the generator 330 may be stored in a power storage unit, or may be directly connected to a place of use without power storage to operate a load, or may be applied to the starter motor 110 and the auxiliary motor 240 through a power supply unit. .

The power storage unit and the start control unit are driven under the control of the central controller.

The power generation unit 300 also includes a power generation unit side magnetic rotation unit 350 to assist the rotation of the power generation shaft 320 by magnetic force.

The starting shafts 120 and 130, the inertial shaft 210, and the power generating shaft 320 are rotatably supported by the bearings in the case 400.

Hereinafter, the starter side magnetic rotation unit 150, the storage unit side magnetic rotation unit 250, and the power generation unit side magnetic rotation unit 350 will be described.

The starting part side magnetic rotating part 150, the storage part side magnetic rotating part 250, and the generating part side magnetic rotating part 350 have the same configuration except that only the installation position is different, that is, the starting side magnetic rotating part 150 is formed on the starting shafts 120 and 130. , The storage unit side magnetic rotation unit 250 is installed on the inertia shaft 210, the power generation unit side magnetic rotation unit 350 is installed on the power generation shaft 320.

As shown in FIGS. 5 to 7, the starting part side magnetic rotating part 150 is provided at the circumference of the starting side side rotor 151 through the starting side side rotor 151 and the case 400 fixed to the starting shafts 120 and 130. Rotor-side magnets which are fixedly installed at opposing surfaces of the starter side stator 152, the starter side rotor 151 and the starter side stator 152 at regular intervals along the circumferential direction, and push each other by repulsive force ( 153 and the stator side magnet 154.

The starter side rotor 151 is a disk having a shaft hole in the center thereof, and is coupled to the circumference of the starter shafts 120 and 130 through the shaft hole, and is fixed so as not to be separated from the starter shafts 120 and 130 through the fixing means. Rotate together with the start shaft (120,130).

As shown in FIGS. 5 to 9, the starter-side rotor 151 has a plurality of magnet receiving portions 151a (grooves) in which the rotor-side magnets 153 are installed at the edges at regular intervals along the circumferential direction. Is formed.

As shown in FIGS. 5 to 7, 10 and 11, the starter side stator 152 has a ring shape, and a direction opposite to the rotor side magnet 153 provided in the starter side rotor 151 is open ( It is also possible to open the opposite side) a plurality of magnet receiving portion 152a is formed at regular intervals along the circumferential direction.

The starter side stator 152 is fixedly installed at the circumference of the starter side rotor 151 through the long bolt 155 and the tightening nut 156 installed in the case 400.

The starter side stator 152 is provided with a plurality of bolt holes 152b at its periphery and four long bolts 155 are arranged along the circumferential direction of the starter side stator 152. And is installed through the nut to the case 400.

Therefore, the starter side stator 152 is fitted to the four long bolts 155 through the bolt hole and is movable along the long bolts 155, and the tightening nut in a state aligned with the circumference of the starter side rotor 151 Since it is fixed by 156, the rotor side magnet 153 and the stator side magnet 154 can be installed in the correct position for generating the maximum repulsive force.

The tightening nut 156 is fastened together on both sides of the starter side stator 152 to fix the starter side stator 152 to the long bolt 155.

The rotor side magnet 153 and the stator side magnet 154 may each have a cylindrical shape, and are inserted into the magnet receiving portions 151a and 152a.

For example, the rotor side magnet 153 is inserted into the magnet receiving portion 151a and then fixed through one or more bolts 153a that are screwed into the bolt holes of the starting side rotor 151.

Since the rotor side magnet 153 and the stator side magnet 154 are magnets having the same polarity, they generate a pushing force by the repulsive force, so that the rotor 151 and the stator 152 do not stick to each other by this force. do. That is, the rotor 151 and the stator 152 maintain the gap so that the start shafts 120 and 130 can rotate without shaking.

Heat is generated between the rotor 151 and the stator 152, and this heat can reduce power generation efficiency and cause thermal deformation, so the rotor 151 and the stator 152 are cooling holes for cooling. 151c and 152c are configured.

The rotor side cooling hole 151c is formed along the circumference of the rotor side magnet 153 inside the starting side rotor 151, and both sides are open toward the edge of the starting side rotor 151. That is, the rotor side cooling hole 151c is formed in a V shape with the rotor side magnet 153 as the center, and the air is circulated around the rotor side magnet 153 while the starting side rotor 151 is rotated. And the rotor magnet 153 is cooled.

The rotor side cooling hole 151c may be configured such that a plurality of holes penetrate the front and rear in the middle of the flow path together with both the openings.

In addition, the heat dissipation fin 151d for dissipating heat of the starter-side rotor 151 is also included.

The heat dissipation fin 151d is installed on at least one surface of the front and rear surfaces of the starter side rotor 151 to dissipate heat of the starter side rotor 151, and is in surface contact with the starter side rotor 151 through bolting or the like. It is composed of a fixed portion to be fixed and a heat dissipation portion is bent at a predetermined angle from the fixed portion.

The starter side stator 152 also includes a cooling hole 152c and a heat dissipation fin 152d.

The stator side cooling hole 152c is formed around the stator side magnet 154 as the start-side stator 152 has a ring shape and communicates with the inside and the outside in a direction crossing the circumference.

The storage unit side magnetic rotating unit 250 and the power generation unit side magnetic rotating unit 350 also have the same configuration as the starting unit side magnetic rotating unit 150, that is, the storage side rotor 251, the storage side stator 252, and the rotor side magnet 253. , Stator side magnet 254, power generation side rotor 351, power generation side stator 32, rotor side magnet 353, stator side magnet 354, cooling holes and heat radiation fins, Since it can implement by 150, detailed description is abbreviate | omitted.

The case 400 may be configured in various ways for installation of the starting unit 100, the inertial rotational energy storage unit 200, and the power generation unit 300. For example, the case body 410 having a box shape in which an upper portion thereof is opened. And a cover 420 for opening and closing the upper opening of the case body 410. Cover 420 may be a variety of opening and closing methods, such as sliding, rotating, removable.

In addition, the wheel 430 is provided to be carried with a small force.

In addition, the case 400 is composed of a plurality of diaphragms. The diaphragm is applied for installation of the starting shafts 120 and 130, the inertia shaft 210, the power generating shaft 320, and the long bolt.

The present invention may be provided with an operation panel, an operation indicator for the control of the starter 100, the inertial rotational energy storage unit 200 and the power generation unit 300.

The operation of the power generator using the inertial rotational energy according to the present invention is as follows.

1.Start up.

When the start switch is selected, electricity is applied to the start motor 110 of the start unit 100 to drive the start shafts 120 and 130. At this time, the auxiliary motor 240 may be in a stationary state or may be driven by applying electricity to rotate the inertial shaft 210.

While the starting shafts 120 and 130 are rotating, the starting side rotor 151 of the starting side magnetic rotating unit 150 rotates, and at this time, the starting side is driven by the pushing force of the rotor side magnet 153 and the stator side magnet 154. The shafts 120 and 130 rotate more quickly (the rotation of the starting shafts 120 and 130 is not shaken and does not come into contact with each other, so that the rotation becomes faster).

2. Save energy (rotational energy).

The rotational force of the starter 100 is transmitted to the power generation unit 300 and the inertial rotational energy storage unit 200 through the belts 140 and 310.

The inertial shaft 210 of the inertial rotation energy storage unit 200 is rotated by the rotational force of the starting unit 100 (also with the rotational force of the auxiliary motor 240 when the auxiliary motor 240 is applied).

As the inertia shaft 210 rotates, the inertia wheel 220 rotates. The inertia wheel 220 stores the inertia rotational force and the inertia shaft 210 is rotated by the inertia rotational force of the inertia wheel 220.

The inertial shaft 210 is smoothly rotated by the pushing force between the rotor side magnet 253 and the stator side magnet 254 of the storage side magnetic force rotating unit 250.

For example, when the starter motor 110 is controlled to be off, when the inertia shaft 210 rotates at a predetermined rotational speed (as much as possible by the power generation unit 300), the starter motor 110 is turned off (secondary motor). When the 240 is applied, the auxiliary motor 240 may also be turned off, and when the starting motor 110 is turned off, the starting shafts 120 and 130 are only in a free state, while the inertial shaft of the inertial rotational energy storage unit 200 is applied. 210 continues the rotation by the inertia rotational power stored in the inertia wheel 240.

On the other hand, when the rotational speed of the inertia shaft 210 falls below the reference rotational speed, at least one of the starter motor 110 and the auxiliary motor 240 is supplied with electricity to restart and adjust the inertia shaft 210 to the reference rotational speed.

3. Development.

The rotational force of the inertial shaft 210 of the inertial rotation energy storage unit 200 is transmitted to the power generation shaft 320.

The generator 330 is driven by the rotational force of the power generation shaft 320, the generator 330 converts the rotational energy into electrical energy to produce electricity. The generated electricity generated by the generator 330 is directly supplied to power storage or a load in the power storage unit.

On the other hand, when stopping the power generation device of the present invention for maintenance or the like, when the brake 230 is operated, the brake 230 stops the rotation of the inertial wheel 220.

The present invention is composed of only the starting unit 100 and the rotational energy storage unit 200 can be used as a rotational drive device using inertial rotational energy. That is, the inertial shaft 210 of the rotation energy storage unit 200 is connected to a load (industrial machinery, engine, construction equipment, etc.) operated by receiving rotational force.

Hereinafter, an inertial rotational energy amplification type large capacity power generation system including a power generation apparatus using inertial rotational energy according to the present invention.

In the present invention, amplification means to increase the storage amount of inertial rotational energy than the previous stage to produce a larger amount of electricity than the previous stage.

As shown in FIG. 12, the inertial rotational energy amplification type large-capacity power generation system including the power generation apparatus using the inertial rotational energy according to the present invention is a power generation device using the inertial rotational energy (hereinafter referred to as a 'power generation starting device') (1000) ), Generating rotational power by receiving the electricity generated by the power generation starting device 1000 and generating electricity by the rotational power, but outputting generating energy larger than the power generation (electrical) energy of the power generation starting device 1000 (in the case of two or more gradually) One or more amplification devices (three of them are shown and described as an example, 2000-1,2000-2,2000-3) that generate a large power output, and are supplied with electricity generated from the tertiary amplification device 2000-3. It is composed of the use-side power generation device 3000 for generating electricity and supplying it to the user by using the generation and the rotational force greater than the tertiary amplification device 2000-3, the power generation starting device 1000 is authorized to pay the electricity Not working In addition, since the amplification apparatuses 2000-1, 2000-2, 2000-3 and the use-side power generation apparatus 3000 generate electric power by using the electric energy generated by the preceding power generation apparatus, a separate large cost is required. Big development is possible without the need for a small cost.

Since the power generation starting apparatus 1000 has been described above, a detailed description thereof will be omitted, and the electricity generated by the power generation unit 300 is applied to the first starting unit 2100-1 of the first amplifying apparatus 2000-1.

The first to third amplification apparatus (2000-1,2000-2,2000-3) is the first to third starter (2100-1,2100-2,2100-3), the first to third rotation energy storage The unit 2200-1, 2200-2, 2200-3 and the primary to third power generation units 2300-1, 2300-2, and 2300-3, each of which is configured with the power generation starting device 1000. Since it is the same, a detailed description is omitted.

In the first to third amplification apparatus (2000-1, 20002, 2000-3), the first starter 2100-1 is electrically connected to the power generation unit 300 of the power generation starter 1000 through a line, the first The power generation unit 2300-1 of the amplifying device 2000-1 is electrically connected to the second starter 2100-2 through a line, and the power generation unit 2300-2 of the secondary amplifying device 2000-2 is Electrical connection through the line with the third starter 2100-3, the third power generation unit 2300-3 of the third amplification device 2000-3 and the starter 3100 of the power generator 3000 It consists of a chain of connections that are electrically connected through a line.

Here, the first to third amplification devices (2000-1, 2000-2, 2000-3) from the power generation starting device 1000 to generate a large electricity by receiving a large amount of electricity gradually, that is, a large power generation starting motor and a generator The larger the capacity, the more inertial wheels are used.

The flow of generated electricity flows into the power generation starting device 1000-the primary amplifying device 2000-1-the secondary amplifying device 2000-2-the tertiary amplifying device 2000-3-the use-side power generating device 3000. The lines connecting them are connected or cut off by a switch, for example, the state in which the primary amplification device 2000-1 is capable of self-power generation (sets the rotational speed of the primary starter and satisfies the set rotational speed). When the primary starter 2100-1 starts up, the power generator starter 1000 and the primary amplifier 2000-1 are blocked to stop the power generator starter 1000, and the primary amplifier 2000-1. Only operate 1).

Relationship between the primary amplifier 2000-1 and the secondary amplifier 2000-2, Relationship between the secondary amplifier 2000-2 and the tertiary amplifier 2000-3, Third amplifier 2000 -3) and the use-side power generation device 3000 are also the same. Therefore, only the use-side power generation device 3000 is finally operated to supply electricity to the use destination, and the rest is stopped.

Of course, the power generation starting device 1000 and the first to third amplifying devices 2000-1, 2000-2, and 2000-3 may generate electricity through the power generation unit and supply the electricity to the user in a state where they are electrically disconnected from each other. It is possible.

On the other hand, each of the power generation unit (300, 2300-1, 2300-2, 2300-3) can be applied to the starting portion of the trailing start that is connected in series, it is also possible to apply the generated electricity to its own starter Thus, the power generation units 300, 2300-1, 2300-2, and 2300-3 are electrically connected to their starting units 100, 2100-1, 2100-2, and 2100-3 through lines, and of course Configured to be connected or disconnected via a switch.

The use-side power generator 3000 generates a rotational force by receiving power from the tertiary power generation unit 2300-3 of the tertiary amplifying device 2000-3, and generates a rotational force. The rotational energy storage unit 3200 rotates the 3200 and rotates the power generator 3300 on the use side to generate electricity.

Electricity generated by the use-side power generation unit 3300 may be configured to be supplied to the user and additionally applied to its starting unit 3100.

The present invention starts the power generation start device 1000, the first to third amplification device (2100-1, 2100-2, 2100-3) and the start-up unit so that the continuous power generation action of the use-side power generation device 3000 is made smoothly Rotation speed sensor for detecting rotation speed of (100, 2100-1, 2100-2, 2100-3, 3100) and electricity generated by power generation unit (300, 2300-1, 2300-2, 2300-3, 3300) A measuring instrument is provided and includes a controller which controls the switch on and off based on the detected value of each rotation speed sensor and the amount of power measured by the measuring instrument.

The operation of the inertial rotational energy amplification type large-capacity power generation system including a power generation device using inertial rotational energy according to the present invention is as follows. Table 1 below shows an example in which the electric power and the inertia wheels generated by the power generation unit and the power input to the starter of each power generation unit are described in numerical values. The weight of the inertia wheel is heavy and is only an example to show that the capacity of the electricity applied to the starter and the power generated by the power generation unit increases with the next step, but is not limited thereto.

division	Power generation start device	Primary power increase type generator	Secondary output increase type generator	3rd power increase type generator	Power generator
Starting input	93w	0.3kw	2kw	6kw	100kw
Power generation	1.2kw	6kw	20kw	100kw	1,000kw
Inertia wheel weight	5 kg, 2 pieces	20 kg, 2 pieces	60 kg, 2 pieces	300 kg, 2 pieces	1,500 kg, 2

1. Start up the power generation system.

As described above, in the power generation starting apparatus 1000, the starting unit 100 generates a rotational force and the power generation unit 300 generates power through the rotational force.

2. Amplification (inertia rotation energy amplification, power generation increase).

Electricity generated by the power generation unit 300 of the power generation starting device 1000 is supplied to the first starting unit 2100-1 of the primary amplifying apparatus 2000-1 so that the primary starting unit 2100-1 can rotate the rotational force. The rotational force generated by the primary starting unit 2100-1 is transmitted to the primary inertial rotational energy storage unit 2200-1 and then the primary power generation unit through the primary inertia rotational energy storage unit 2200-1. Passed to 2300-1, the primary power generation unit 2300-1 develops.

The electricity generated by the primary power generation unit 2300-1 is supplied to the secondary starting unit 2100-2 of the secondary amplifying apparatus 2000-2 so that the secondary starting unit 2100-2 generates a rotational force, The rotational force generated in the secondary starter 2100-2 is transmitted to the secondary inertial rotational energy storage unit 2200-2 and then the secondary power generation unit 2230-2 through the secondary inertia rotational energy storage unit 2200-2. 2) the secondary power generation unit 2300-2 is developed.

The electricity generated by the secondary power generation unit 2300-2 is supplied to the tertiary starting unit 2100-3 of the tertiary amplifying apparatus 2000-3 so that the tertiary starting unit 2100-3 generates rotational force, The rotational force generated in the third starter 2100-3 is transmitted to the third inertial rotational energy storage unit 2200-3, and the third is generated by the inertia rotational power stored in the third inertial rotational energy storage unit 2200-3. The power generation unit 2300-3 produces electricity.

3. Where to use.

The electricity generated by the tertiary amplification apparatus 2000-3 is supplied to the starter 3100 of the power generator 3000, and the starter 3100 generates rotational force. The rotational force of the starting unit 3100 is stored in the inertial rotational energy storage unit 3200 and supplied to the power generation unit 3300, and the power generation unit 3300 produces electricity and supplies it to the user.

On the other hand, in the present invention, it is also possible to use two or more use-side power generators 3000-1,3000-2.

When only one use-side power generator 3000 is used, there is a problem such that damage to a component occurs quickly due to deterioration, that is, when two or more use-side power generators 3000-1 and 3000-2 are used, There are advantages such as burnout prevention.

The first and second use-side power generators 3000-1 and 3000-2 include first and second starters 3100-1 and 3100-2 and first and second rotational energy storage units 3200-1 and 3200-2. ) And the first and second power generation units 3300-1 and 3300-2, and the specific functions thereof are the same as described above.

The connection of the first and second use-side power generation apparatuses 3000-1 and 3000-2 is configured to perform the following operations.

The first use-side power generator 3000-1 receives electricity from the tertiary amplification device 2000-3, rotates and generates electricity, and supplies electricity to the user. [At this time, the second use-side power generator 3000-2 stops. ]do.

When a predetermined time (freely changed according to a user's setting) has elapsed, the first power generation unit 3300-1 of the first use-side power generation device 3000-1 may generate a second value of the second use-side power generation device 3000-2. It is connected to the starter 3100-2 while being disconnected from the place of use.

In the second use side power generator 3000-2, the second starter 3100-1 generates a rotational force through electricity supplied from the first use side power generator 3000-1, and the second power generator 3000-2 generates a rotational force through the rotational force. The rotational energy storage unit 3200-2 continuously transmits the rotational force to the second power generation unit 3300-2 while storing the rotational energy to generate electricity from the second power generation unit 3300-2 and supply it to the user. When the second use-side power generator 3000-2 satisfies a condition capable of generating power by itself, the first use-side power generator 3000-1 is in a stopped state.

The second use-side power generator 3000-2 operates for a predetermined time to supply electricity to the user. When this time elapses, the second power generator 3300-2 of the second use-side power generator 3000-2 is operated. It is connected to the first starter 3100-1 of the first use-side power generator 3000-1, and is disconnected from the place of use.

The condition that the first power generation device 3000-1 cuts off while supplying electricity to the place of use is stably supplied electricity to the place of use by the second power generation unit 3300-2 of the second use side power generation device 3000-2. The second power generation unit 3300-1 of the first use-side power generation device 3000-1 may be supplied, and the condition that the second use-side power generation device 3000-2 cuts off while supplying electricity to the user is used. It is a condition that can supply electricity stably to the place of use.

In addition, the present invention may be composed of only the power generation start device 1000 and the use-side power generation device 3000, the electricity generated by the power generation start device 1000 is supplied to the starting portion of the use-side power generation device 3000 for use The object of the present invention is achieved by generating more electricity in the side power generation device 3000 than in the power generation unit of the power generation starting device 1000.

As those skilled in the art would realize, the described embodiments may be modified in various ways, all without departing from the spirit or scope of the present invention. It is to be understood, however, that the present invention is not limited to the specific forms referred to in the description, but rather includes all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. Should be.

[Description of the code]

100: starting part, 110: starting motor

120,130: starting shaft, 140,310: belt

200: rotational energy storage unit, 210: inertial shaft

220: inertial wheel, 230: brake

240: auxiliary motor, 300: power generation unit

320: power generation shaft, 330: generator

1000: power generator (power generator) using inertial rotational energy

2000-1, 2000-2, 2000-3: Amplifier

3000: generator on the use side,

The present invention generates electricity by using only a small amount of electricity at the beginning, and also generates large electricity stably through amplification of inertia, which is easily applied to various products using electricity, and is particularly effectively used in mountain areas where electricity supply is difficult. It is possible.

Claims (13)

1. A starter part 100 having one or more starter motors for generating rotational force by receiving electricity;

   At least one row of inertial rotational energy storage unit 200 which stores rotational force by inertia while rotating while receiving rotational force from the starting shaft of the starting unit;

   And a power generation unit 300 including one or more rows including a power generation shaft connected to the inertia shaft of the inertial rotation energy storage unit and a generator for producing electricity through the rotational force of the power generation shaft,

   The inertial rotational energy storage unit has one or more inertial shafts 210 that rotate and receive rotational force of the starting unit, and rotates the inertial shafts through inertia after rotating with the inertial shafts so that power generation is continued in the power generation unit. And an inertia wheel (220), wherein the starting unit generates a rotational force by applying external electricity or electricity generated by the power generation unit to rotate the inertial rotational energy storage unit.
2. The power generation apparatus using inertial rotational energy of claim 1, further comprising one or more auxiliary motors (240) for rotating the inertial shaft in response to external or generated electricity.
3. According to claim 1 or claim 2, It is installed on one or more of the start shaft and inertial shaft and the power generation shaft and comprises one or more magnetic rotating unit to help the rotation of the start shaft, inertial shaft and power generation shaft through the mutually pushing magnetic force Power generating device using inertial rotational energy.
4. 4. The magnetic force rotating part of claim 3, wherein each of the magnetic rotating parts includes at least one rotor fixed to the starting shaft, the inertia shaft, and the power generating shaft, a stator fixedly installed at a circumference of the rotor, and opposite surfaces of the rotor and the stators. Each of which is installed at predetermined intervals along the circumferential direction, the power generation device using the inertial rotational energy, characterized in that it comprises a rotor-side magnet and a stator-side magnet generating a pushing force.
5. The power generation apparatus using inertial rotational energy according to claim 4, comprising at least one of a rotor side cooling means and a stator side cooling means for cooling the heat generated between the rotor and the stator.
6. 6. The rotor-side cooling means and the stator-side cooling means include cooling holes through which air circulates to cool the heat, and the cooling holes of the rotor-side cooling means include a starter side rotor and a storage side rotor. Power generators using inertial rotational energy, characterized in that each side is formed along the circumference of the rotor-side magnets while both sides are open toward the ends of the starter side rotor and the storage side rotor to circulate air. .
7. The power generation apparatus using inertial rotational energy of claim 5, wherein the stator has a ring shape and is fixed by a nut while being movable to a long bolt installed along the stator.
8. The power generation apparatus using inertial rotational energy according to claim 1 or 2, further comprising a brake for stopping rotation of the inertia wheel.
9. A power generator using inertial rotational energy according to claim 1;

   The inertia rotational energy is converted into a starting unit for generating rotational force by receiving electricity from the power generation device using the inertial rotational energy, an inertia rotational energy storage unit for storing inertia rotational energy by the starter unit, and a rotational force of the inertia rotational energy storage unit. At least one amplifying device including a power generating unit for generating electricity having a larger capacity than the used power generating device, and connected in series with the power generating device using the inertial rotational energy;

   And a power generation unit including a power generation unit configured to receive power from the power generation unit of the amplification device and generate a rotational force, and a power generation unit that outputs a larger amount of power than the amplification device and supplies the power to the user. Inertial rotation energy amplification type large capacity power generation system including a power generation device using inertial rotation energy.
10. A power generator using inertial rotational energy according to claim 1;

    The inertia rotational energy is used as a starting unit for generating rotational force by receiving electricity from a power generation device using inertial rotational energy, an inertia rotational energy storage unit for storing inertia rotational energy by the starter unit, and a rotational force of the inertia rotational energy storage unit. An inertial rotational energy amplification-type large-capacity power generation system comprising a power generation apparatus using inertial rotational energy, characterized in that the power generation unit includes a power generation unit for generating electricity and supplying electricity to a user.
11. The method according to claim 9 or 10, wherein the use-side power generation device is connected to apply the electricity generated by two or more, respectively, to the starter of the other use-side power generation device, one of which generates electricity to apply to the user while the other Inertial rotational energy amplification type large-capacity power generation system comprising a power generation device using inertial rotational energy, characterized in that the stop.
12. The power generation apparatus according to claim 9, wherein at least one of the inertial rotational energy generation device, the amplification device, and the use-side power generation device is connected to apply electricity generated from each power generation unit to its starting unit. Inertial rotary energy amplification type large capacity power generation system including a device.
13. The method according to claim 9, wherein the amplifying device and the use-side power generation device is configured to operate only the use-side power generation device by electrically blocking each starter and the preceding power generation unit when each power generation unit generates electricity of a design generation amount. Inertial rotation energy amplification type large capacity power generation system including a power generation device using inertial rotation energy.

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