KR20120019650A - The tornado self-generating system by amplifying and rotating of an air (fluid) & any transportation that is equiped with the tornado self-generating system - Google Patents
The tornado self-generating system by amplifying and rotating of an air (fluid) & any transportation that is equiped with the tornado self-generating system Download PDFInfo
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- KR20120019650A KR20120019650A KR1020100082978A KR20100082978A KR20120019650A KR 20120019650 A KR20120019650 A KR 20120019650A KR 1020100082978 A KR1020100082978 A KR 1020100082978A KR 20100082978 A KR20100082978 A KR 20100082978A KR 20120019650 A KR20120019650 A KR 20120019650A
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- amplification
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- power generation
- foil
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F03—MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
- F03D—WIND MOTORS
- F03D5/00—Other wind motors
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F03—MACHINES OR ENGINES FOR LIQUIDS; WIND, SPRING, OR WEIGHT MOTORS; PRODUCING MECHANICAL POWER OR A REACTIVE PROPULSIVE THRUST, NOT OTHERWISE PROVIDED FOR
- F03D—WIND MOTORS
- F03D80/00—Details, components or accessories not provided for in groups F03D1/00 - F03D17/00
- F03D80/70—Bearing or lubricating arrangements
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F05—INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
- F05B—INDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
- F05B2240/00—Components
- F05B2240/10—Stators
- F05B2240/12—Fluid guiding means, e.g. vanes
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F05—INDEXING SCHEMES RELATING TO ENGINES OR PUMPS IN VARIOUS SUBCLASSES OF CLASSES F01-F04
- F05B—INDEXING SCHEME RELATING TO WIND, SPRING, WEIGHT, INERTIA OR LIKE MOTORS, TO MACHINES OR ENGINES FOR LIQUIDS COVERED BY SUBCLASSES F03B, F03D AND F03G
- F05B2240/00—Components
- F05B2240/50—Bearings
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/70—Wind energy
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/70—Wind energy
- Y02E10/72—Wind turbines with rotation axis in wind direction
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/70—Wind energy
- Y02E10/728—Onshore wind turbines
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- Engineering & Computer Science (AREA)
- Life Sciences & Earth Sciences (AREA)
- Sustainable Development (AREA)
- Sustainable Energy (AREA)
- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Aviation & Aerospace Engineering (AREA)
- Wind Motors (AREA)
Abstract
Description
The present invention artificially provides air without any pollution artificially and power generation through amplification and multi-amplification of the provided air, recycling and continuously rotating the air used for power generation to produce a large amount of power in various industries and various industries. The air used in the home and continuously rotating and working on electricity is inhaled by the whirlwind effect, so the outgoing air is collected and used in various industries, or especially mounted on various means of transportation, without any fossil fuel. Bernoulli by returning various devices (wheels or propellers) necessary for the movement of the furnace and using them as electricity required by itself, continuously rotating and collecting air that is working on power generation, and discharging them through airfoils fitted to various means of transportation. Vehicles amplified by theorem and the Coanda effect Twisters that can be designed to help or to move provides a means of transportation that can move only relates to the air self-development system.
A wingless fan developed in the United Kingdom, which considered the best use of the Coanda effect as a technique related to this purpose (International Application Date August 26, 2008, Request for Examination March 17, 2010 Application No. 10-2010- 7005884) The area where the wind comes out is made circular and then placed in a large space, and the wind is sent through the blower to draw out the compressed air faster than the flow of air through the narrow space to draw the surrounding air and amplify the wind. This method has the advantage that the part where the wind comes out is located in a large space and it can be made circular so that the air can be concentrated and sent in the desired direction, and the amplification effect is about 15 times (June 20, 2010 Kang Ok-kyung, a member of Naver Guest Seoul Science School, explains According to the patent application of the fan without a fan, 271L / sec air was introduced at 15% angle into the circular nozzle of 350mm in diameter and 15mm, and the wind speed was 1m ~ 1.2 at 500 ~ 700 L / sec near the diameter due to the coanda effect. At 500 m / s, air flows, and the overall air flow rate is about 3 to 4 m / s, which is about amplified twice, and more flow amplification is needed for wind power generation.
In addition, the commercially available air amplifier using the Coanda effect consumes a lot of air through the adjustment of a nozzle of 0.08mm to one amplifier. However, 1415 L / s is discharged from the outlet by providing compressed air of up to 55 L / sec. The ship is amplified and shows a significant amplification effect of 4240 L / sec at 15cm away.
In addition, the wind power generation system using the tunnel away from the conventional outdoor wind power generation method (Application No. 10-2008-0081154 application date August 20, 2008 examination request date August 20, 2008) a number of generators in the tunnel And the propellers of each generator in the opposite direction to prepare for vortex phenomena. The large reverse propeller winds the propellers of the generators with wind in front of the generators installed. System (Application No. 10-2008-0036167 Application Date April 18, 2008 Request for Examination April 18, 2008) or Konkuk University's Alternative Program Fan Wind Power Program (Minihompy http://www.cyworld.com / hyeonid ) proved that the power can be amplified by experimenting with artificial tunnel and running 72 generators with one electric motor. Loss by propeller supplying super wind and only rotating the air of tunnel itself is insufficient to amplify by inflow of external air.
In addition, in the conventional wind power generation, the wind turbine blade and the generator rotor integrated wind power generation system using an amplification tunnel to improve the power generation through the speed increaser with the rotational energy transmitted to the shaft using the rotational force of the propeller (Application No. 10-2001-) 0026558, filed on May 15, 2001) is a technology in which power is produced by rotating a magnet by installing a windshield to compress air passing through it, and then installing a cylindrical magnet at the end of the blade connected to the shaft. Because the wind force and the weight to support it must be transmitted to the shaft, and additional equipment is needed to support the weight.
In addition, all conventional means of transportation have used fossil energy, and recently, only means of moving to electricity are in the spotlight, but he also needs to charge and move to the electricity with a self-generating system and use the wind used for power generation again. I know there is no example to use as a means of.
The present invention is to compensate for the problems and advantages of the prior art, and to continuously rotate the artificially provided air to produce a large amount of power with little power through recycling the air used for power generation and supply to various industries or homes Purpose,
The purpose of the provision of a mobile means that can be moved by only the wind by supplying the power necessary for the movement of the means of transportation and collecting and discharging the wind rotating at high speed while being used for power generation. Leave.
In order to accomplish the above purpose, a mass flow and multi-amplification are required to create a flow-rate-rich, high-speed wind, to withstand high-speed wind, and to rotate the rotor of the generator (wing), and to use the wind used for power generation again. Wind control device and various airfoils for collecting and using wind to be used in various industries and means of transportation for design and development of equipment (amplification tunnel) for recycling and returning other generators. We want to develop and propose (Airfoil).
In order to implement the above object, since the power generation equipment necessary for power generation and the
Or, the power generation equipment that can withstand the high-speed wind and power generation is needed, so the middle is equipped with a large number of empty N-poles and S-poles, and a permanent magnet made of a cylindrical shape, or a cylindrical body incorporating a waterproof and insulated coil. Prepare an electromagnet (hereinafter referred to as an electromagnet), and attach a
Or it can withstand high speed wind and work on power generation, and the gearbox is installed to work on power generation even at low speed wind. Prepare a cylinder with square gears at both ends configured to mesh with each other in a square with the rotational power transmission device at both ends of the cylinder, and the inside of the cylinder with the square gears at both ends is prepared. In the middle is installed a gear wheel, characterized in that attaching the rotor blades (500-1) that can withstand high-speed wind and not connected across the cylinder inner diameter is installed, the rotor blade-shaped rotor Constructing a cylindrical rotor (700-1) attached to the blade (500-1), the teeth of the cylindrical rotor (700-1) The que is connected to a rotational power transmission device, and considering the characteristics of the rotating body 700-1 rotating the rotational power transmission device opposite to each other to be connected to a fixed power generation equipment to receive the rotational power to prepare for power generation And continuously connecting the respective cylindrical rotors 700-1 to each of the two rotary bodies 700-1 or more according to the speed of the wind to be provided by the plan and the angle of the provided wind. Rotor body 500-1 is installed by adjusting the rotor blades 500-1 so that the 700-1 can rotate in the same direction, and the next rotating body is installed on the inner diameter of the gear wheel at the rear of each cylindrical rotor 700-1.
Selecting an amplification tunnel (100) characterized in any one of the steps or methods of building the amplification tunnel (100) and a power generation facility, and recycling the air used for power generation through the selected amplification tunnel (100) It can continue to rotate, so that each inlet and outlet face each other at a distance with a combination of one
Combination of one
Air
Alternatively, the inlet and outlet of each amplification tunnel are constructed and installed as shown in FIG. 4 and FIG. 6, and the air
Or configured and installed at each inlet and outlet of the amplification tunnel as shown in FIG. 4 and FIG. 6 or as shown in FIG. 4 and FIG. 6 and configured to maximize the Bernoulli's theorem and the Coanda effect to introduce and amplify external air. In each of the steps and methods of constructing the
The air amplification air foil installed at the inlet of each
The
Returning the large amount of
In addition, through the whirlwind self-power generation system, the air is amplified without pollution at all, and the power used for power generation is recycled while rotating the air used for power generation. The air that is continuously rotating and working on power is sucked by the whirlwind effect to collect the outgoing air and mount it in various industries and various means of transportation.
As shown in FIGS. 9 and 10, a distribution pipe 10-1 of air entering the outer diameter of the outlet of the
The mini-amplification device as shown in FIG. 8 is connected to the adjusting
In addition, in order to provide a means of movement or to move only by air by mounting a whirlwind generation system in various means of transportation,
Control of the wind entering and exiting the inside of the body of the
The vertical air flow with the
The empty space between the
The solar cell of the solar installation is installed in the sunlight well portion of the outside of the moving means and to be provided as the power to create the wind required for the generation and movement of electricity generated by the photovoltaic facility (1000-2) Featuring stages
The present invention is to provide a variety of moving means equipped with a whirlwind self-generation system, characterized in that it is configured to be used as a power source and various devices necessary for the movement of electricity generated by the whirlwind self-generation system.
Looking at the moving method of the various moving means is equipped with the whirlwind self-power generation system as follows.
The electricity generated by the whirlwind self-generating system mounted on various moving means is used as a power source required for various movement devices such as wheels or propellers required for movement, or as a power source for its own use. The air that is rotating at high speed and is working on power generation is collected by the air inlet and
In addition, it can be mounted on the plate-shaped moving means as shown in Fig. 11, or it can reduce the resistance of the fluid to the maximum, and it is mounted on the moving means designed to be suitable for fluid dynamics. And, there is no harm to the human body in the empty space between the outer tunnel (30) and the
The present invention is applied to power generation through amplification of air without any pollution, and recycled while continuously rotating the air used for power generation at high speed, and is utilized in various industries and homes with small power, and is continuously used at high speed. The air that is rotating and generating electricity is inhaled by the whirlwind effect, so it collects the outgoing air and utilizes it in various industries.In particular, the whirlpool power generation system is mounted on various means of transportation, and the wheels and propellers are electricity generated without using fossil fuel at all. It is used as self-necessary electricity, and it continues to rotate at high speed, collects air that is working on power generation, and discharges it through airfoils fitted to various means of transportation, which is amplified by Bernoulli theorem and Coanda effect. To help with the movement of the means, It is a means of transportation equipped with a whirlwind self-power generation system that does not generate any pollution, and it moves by means of transportation during the day and supplies it with power for the workplace when it arrives at work, and uses it as electricity for the house at night and charges the battery It is hoped that the pollution-free power generation that can store and use the electricity needed during the day will be used in various industries and households to contribute to handing down the pollution-free earth to descendants.
In particular, the plate-shaped moving device, which can be utilized as a submarine in land and water as well as a submarine in the air, is equipped with a whirlwind self-generation system developed by the present invention. Because it is not visible and does not use propellers, it can be usefully used for intelligence as it has no noise.
(Fig. 1) is a diagram showing the construction of one amplifying tunnel in a circular ring shape with the entrance and the exit facing each other at a slight distance.
FIG. 2 is a diagram showing the configuration of an airfoil for power generation.
Fig. 3 is a diagram showing an example of one-stage amplification of the configuration of the airfoil for power generation.
Fig. 4 is a diagram showing two-stage amplification among multiple amplifications of the configuration of the airfoil for power generation.
FIG. 5 is a diagram illustrating an example in which a power generation device is positioned by utilizing a first stage amplification of a configuration of a power generation airfoil to connect a plurality of amplification tunnels.
FIG. 6 is a diagram illustrating an example in which a power generation device is positioned by utilizing two-stage amplification of a power generation airfoil to connect a plurality of amplification tunnels.
FIG. 7 is a diagram showing the arrangement of the rotor and the stator with the blades attached and integrated in the amplification tunnel and the direction of rotation of the rotor.
Fig. 8 shows a tornado mini-amplifier for multiple amplification.
FIG. 9 is a diagram illustrating an example of collecting the incoming and outgoing winds of wind used for power generation through one amplification tunnel and collecting them into one.
FIG. 10 is a view showing an example of sealing the outside of an amplification tunnel except for collecting and collecting wind in and out of wind used for power generation through one and a plurality of amplification tunnels.
FIG. 11 is a diagram showing an example in which a whirlwind self-power generation system is mounted on a moving means of a dish-shaped vehicle and collects and moves wind used for power generation.
FIG. 12 is a view showing the configuration of a flying airfoil and a flap that can be used as a flap and the installation of left and right compressed air separation membranes for redirection.
FIG. 13 is a view showing airfoils for each of the vehicle and the vehicle.
FIG. 14 shows the rotational power transmission cogwheel and the cogwheel power transmission device of the cogwheel rotating body and show the steps of installing a fluid barrier membrane.
The present invention is to compensate for the problems and advantages of the prior art, and to continuously rotate the artificially provided air to produce a large amount of power with little power through recycling the air used for power generation and supply to various industries or homes Purpose,
It is equipped with various means of transportation to supply electric power necessary for the movement of the means of transportation, and collects and discharges the wind which is rotating at high speed while being used for power generation. In order to achieve this purpose, first, because the power generation equipment required for power generation and
Water and insulation are thoroughly constructed, and a number of power plants integrated with propellers are continuously built to rotate against each other in preparation for eddy currents, and a tunnel is built around the outside where many power plants are installed. Characterized in that the step of building an amplification tunnel (100) in which the power generation equipment is built so that a plurality of power generation facilities reverse rotation to each other, or
Or, since a power generation equipment capable of withstanding high speed wind is required, a cylindrical permanent magnet (or not marked after electromagnet) is prepared to form a cylindrical permanent magnet (or not marked after electromagnet)
The
Coils are mounted on the outside of each cylindrical
Each of the cylindrical
Or to withstand the high-speed wind and to prepare the outside of the power plant to prepare a hollow cylinder as shown in Figure 14, both ends of the outer diameter of the cylinder and the rotational
The rotor blades 500-1 attached to the cylindrical rotor 700-1 installed in the
The rotary
The
It is installed at a slight distance from the above and can be amplified by inflow of external air in order to make full use of Bernoulli's theorem and Coanda effect, and it can be rotated continuously to recycle the air used for power generation. Alternatively, the inlet and outlet of each amplifying
At the inlet of each
As shown in FIGS. 3 and 5, the air provided from the
Between the amplification
An air outlet 400-1 which may be discharged diagonally toward the inside of the
On the other hand, the outlet of each
In order to keep the speed of the air passing through the
Between the
A diagonal line from the inside of the amplifying
The air sucked quickly by the air intake port 400-1 through which a portion of the air passing through the
Or in order to increase the amplification effect of the air in the whirlwind self-generation system as shown in Figure 4 and 6 to remove the
Combined with the (201-1) compression tank for compressing and storing water or air at close or long distances of the inlet and outlet of each
Combining the compressed air moving pipe 201-2 connected to the compression tank 201-1 of the
During the self-development process of the tornado self-generation system or the non-multi-amplifier self-power generation system to generate power through the multi-amplification,
Looking at the development process of the whirlwind self-generation system composed as shown in Figures 3 and 5 above is configured as follows.
3 and 5, the air sucked through the suction air moving path 300-5 installed at the outlet of each
The
The air incident in the diagonal direction toward the inside of the
The air turned into a straight line passing through the rotor blades 500-A1 then rotates the rotor blades 500-A2 of the rotor 700-A2 and rotates the rotor 700-A2. The electromotive force is generated in the stator 800-A2 to produce electric power, and the direction of air is changed to the diagonal direction, which is the opposite direction of the initial inclination.
The rotor 700-A2, which passes through the rotor blades 500-A2 of the rotor 700-A2, is changed to an oblique direction, which is the opposite direction in which the air is first incident in the diagonal direction, and is installed next. Since the rotor blades 500-B2 of B2) rotate in opposite directions, the rotor blades 700-B1 are slightly spaced apart in consideration of the magnetic field effects that rotate in the opposite directions to the 700-A1 and 700-A2. Electromotive force is generated in the stator 800-B1 by rotating the 700-B1 upward while passing through the rotor blades 500-B1 of the rotor 700-B1 in which the stator 800-B1 is installed. To generate power, and the wind changes back to a straight line.
The air turned into a straight line passing through the rotor blades 500-B1 then rotates the rotor blades 500-B2 of the rotor 700-B2 and rotates the rotor 700-B2. The electromotive force is generated in the stator 800-B2 to produce electric power, and the direction of air is changed to the diagonal direction in the same direction as the initial diagonal direction.
As described above, the
Passed through the
The rest is sucked into the inlet of the
In addition, looking at the development process of the whirlwind self-generation system for power generation through the multi-amplification configured as shown in Figures 4 and 6 are as follows.
4 and 6, the
The air drawn in through the
Is directed toward the inside of the
The air quickly discharged through the amplified air outlet 201-4 is formed by the
Or in the tornado self-generation system, characterized in that the step of continuously installing a plurality of generator facilities 1000 to rotate in opposite directions to correspond to the vortex phenomenon in the amplification tunnel (100),
3 and 5, the
According to each step, amplified by inflowing air at the inlet of each
Alternatively, the permanent rotor or
The
Rotating power is rotated by the power transmission gear (1000-1) is installed to be spaced apart from the
In addition, through the whirlwind self-power generation system, the air is amplified without pollution at all, and the power used for power generation is recycled while rotating the air used for power generation. The air that is continuously rotating and working on power is sucked by the whirlwind effect to collect the outgoing air and mount it in various industries and various means of transportation.
As shown in FIGS. 9 and 10, a method of installing a distribution pipe 10-1 of air entering the outer diameter of the outlet of the
The mini-amplification device as shown in FIG. 8 is connected to the adjusting
In addition, in order to provide a means of movement or to move only by air by mounting a whirlwind generation system in various means of transportation,
Control of the wind entering and exiting the inside of the body of the
The empty space between the
Traveling airfoils (400A-1, 400A-2) suitable for various means of mounting the
Discharge of each of the
As shown in FIG. 12, the air flow paths 405-1, 405-2, 405-3, and 405-4 of the flying
The front and rear
When the
As shown in FIG. 13, the
The
The combined air foil (400D) is separated from each other up, down, left and right, the inlet is directed to the outside of the moving means and configured to control the intake and discharge by the incoming and outgoing wind control device.
The solar cell is installed at the outside of the moving means so that the solar cell is installed so as to be provided as electric power generated by the photovoltaic facility 1000-2 to generate the wind required for power generation and movement.
It is constructed to be used as a variety of devices necessary for the movement of electricity generated by the whirlwind self-generation system and its own power source.
The flying
The method of moving the various means of transportation equipped with the whirlwind self-powering system is basically to drive the devices (devices necessary for various movements, such as propellers of automobile wheels or moving means) necessary for the movement of electric power generated by the self-power generation. It provides a means of moving the generated electricity to industry by moving in contact with the ground or water surface.
Referring to Figures 11 and 12 with reference to the moving method of the various means of transportation equipped with the whirlwind self-power system proposed by the present invention will be described.
In order for the various moving means equipped with the tornado self-powering system to go straight (40) and (405-1) of the discharge air moving path in front of the flying air foil (400A) by the control device of the incoming and outgoing wind When air is sent to 405-2, the up and down inner blades 403-1 and 403-2 are moved backward by the forward reverse hydraulic device 507, and the upper and lower discharge ports 401-1 are opened and Up and down outlets 401-2 in the air are closed through the up and down outlets 401-1 in the front. The lower air exiting the lower outlet 401-1 flows in a straight line, and the upper air exiting the upper outlet 401-1 flows in a curved line to generate lift, and can be moved forward by the air sent backward. For braking and reversing, if the air is supplied to the exhaust air moving paths 405-3 and 405-4 by adjusting the control device of the incoming and outgoing winds (40), the exhaust outlets (401-2) In order to switch the direction up and down during the process, if only one of the air is supplied to (405-3) and (405-4), the upper and lower compressed air separation barriers and the (404-2) will rotate. Since it is supported by the up and down
In addition, when the flying
In addition, the vertical moving air foil (400B) used for vertical rise and fall is sucked up and discharged down to suck up the air above, and the amplified air can lift various moving means. It suggests a means of transportation equipped with whirlwind self-power, which can be lowered but discharged upwards and sucked down depending on the situation.
In particular, in the means of transportation equipped with the whirlwind self-power generation system, if you want to move on the ground without the need for flying or diving, electricity is generated by installing the power generation equipment to the maximum. If you want to fly, design a structure suitable for hydrodynamics, construct lightly with minimum power generation facilities, and use one or more facilities that amplify air. If the water is forcibly filled in the place filled with light gas such as helium, the gas is compressed and the waterproof and well-insulated blower acts as a pump, and the air compressor has a high density of water. Water on the floor and on the floor is discharged to compress and discharge the water. To be able to develop in water and self-twisters are all-weather means of transportation that can be moved to the proposed development with the all-weather transportation system.
(10) ------- Incoming wind integrated pipe
(10-1) ----- Incoming Wind Distribution Pipe
(20) ------- Outgoing wind integrated pipe
(20-1) ----- Outgoing Wind Collection Pipe
(30) ------- External Tunnel
(40) ------- In and Out wind conditioner
50 ------- Vehicle
(51) ------- Outer body
52 ------- Directional Guide
90 ------- Rotating
(90-1) ----- Rotational power transmission device Fixed bearings and fixed devices
(90-2) ----- Rotating
(91) ------- Rotational power transmission gear
(100) ------ Amplified Tunnel
(100-1) ---- Amplified tunnel air and water barrier
(200) ------ Blower (commercially available)
(201) ------ Air Compressor (commercially available)
(201-1) ---- Compressed Air Transfer Pipe
(201-2) ---- Amplified air exhaust pipe
(300) ------ Power Intake Air Foil (Outlet)
(301) ------ Air Intake
(301-1) ---- Front air intake
(301-2) ---- Rear air intake
(301-3) ---- Left air intake
(301-4) ---- Right air intake
(302) ------ Suction Air Tutorial
(303) ------ inner wing of air suction wing
304 ------ Outer wing of air suction wing
(305) ------ Suction Air Transfer Furnace
(400) ------ Power Generation Airfoil Airfoil
(400A)--Airfoil
(400A-1) --- Upper wing flying airfoil
(400A-2) --- Lower wing flying airfoil
(400B) ----- Travel Air Foil
(400C) ----- Vertical Moving Air Foil
(400C-1) --- Front wing of vertical movement airfoil
(400C-2) --- Rear wing of vertical moving airfoil
(400C-3) --- Left wing of vertical moving airfoil
(400C-4) --- Right wing of vertical moving airfoil
(400D) ----- Combined Air Foil
(400D-1) --- Front Combination Air Foil
(400D-2) --- Combined Air Foil
(400D-3) --- Left combined air foil
(400D-4) --- Right Combination Air Foil
(401) ------ Air outlet
(401-1) ---- Forward Air Vent
(401-2) ---- Rear reverse and braking air outlet
(402) ------ Exhaust Air Tutorial
(403) ------ Inside wings of air exhaust booster
(403-1) ---- Wing Inside Upper Air Exhaust Amplifying Wing
(403-2) ---- Underside wing of air exhaust booster
(404) ------ Outer Wing of Air Exhaust Booster
(404-1) ---- Front wing of air exhaust booster wing
(404-2) ---- Rear flap of air exhaust booster blade (with flaps)
(405) ------ Compressed Air Transfer Furnace
(405-1) ---- Compressed Air Transport
(405-2) ---- Compressed air path for forward lower propulsion
(405-3) ---- Compressed air path for rear braking and reverse
(405-3) ---- Compressed air path for rear braking and reverse
(406) ------ Left and right separation membrane
(406-1) ---- Left and right direction air separation barrier
(406-2) ---- Front and rear exhaust air separation barrier
(406-3) ---- The upper and lower exhaust air separation barrier for up and down direction
(407) ------ Front and rear outer blades for front and rear reversing
(408) ------ Connecting device for rear flap changeover
(409) ------ Winglet
(500) ------ Wings attached to or integral with the rotor
(500-1) ---- Wings attached to or integral with the rotor
(500-A1) --- Wing attached or integrated to the first rotor of the amplifying tunnel
(500-A2) --- Wing attached or integrated to the second rotor of the amplifying tunnel
(500-B1) --- Wings attached or integral to the third rotor of the amplifying tunnel
(500-B2) --- Wing attached or integrated to the fourth rotor of the amplifying tunnel
(600) ------ whole direction of rotary air
(600-1) ---- direction of incident air
(700) ------ Rotor with wing attached or integrated
(700-1) ---- Cog wheels with blades attached to or integral with the cylinder
(700-A1) --- the first rotor of a winged or integrated amplified tunnel
(700-A2) --- second rotor of amplified tunnel with wing attached or integrated
(700-B1) --- third rotor of amplified tunnel with wing attached or integrated
(700-B2) --- fourth rotor of amplified tunnel with attached wing or integral
(800) ------ Stator of amplifying tunnel
(800-A1) --- First stator in amplifying tunnel
(800-A2) --- Second stator of amplified tunnel
(800-B1) --- third stator of amplified tunnel
(800-B2) --- 4th stator of amplified tunnel
(900) ------ Mini Amplifier
(900-1) ---- Compressed air connection unit of mini amplifier
(900-2) ---- Intermediate pipe of mini amplifier
(900-3) ---- Compressed air movement path of mini amplifier
(900-4) ---- The inner pipe of the mini amplifier
(900-5) ---- Compressed air outlet of mini amplifier
(900-6) ---- Amplified air discharge transfer pipe connection of mini amplifier
(900-7) ---- Outer pipe of mini amplifier
(900-8) ---- Flow control device of mini amplifier
(900-9) ---- Flow control fixture of mini amplifier
(1000) ----- Power plant integrated with amplification tunnel
(1000-1) --- Power plant installed away from amplifying tunnel
(1000-2) --- Solar power generation equipment equipped with solar cells
(1000-3) --- Power generation equipment with piezoelectric elements and generated by vibration
Claims (18)
Outside the plurality of cylindrical permanent magnet rotor 700 in which the rotor blades 500 are integrated, the stator 800 is thoroughly waterproof and insulated so that the permanent magnet rotor rotates to generate electric current so that it can come into power generation. Install the power generation facilities,
Rotors of each power plant to connect the power plants continuously, so that the rotors of two or more power plants can rotate in the same direction depending on the wind speed to be provided by the plan and the angle of the wind to be provided. Adjust and install the rotor blades attached to the
The fluid is composed of an outer diameter slightly smaller than the inner diameter of the cylindrical permanent magnet rotor 700 of the next installed power plant is not affected by the magnetic field between each other except the last of the continuously positioned cylindrical permanent magnet rotor 700. The barrier film 100-1 is installed in the vicinity of the next cylindrical permanent magnet rotor 700 or slightly overlapped to form a tunnel shape so that two or more two or more in the same direction depending on the wind to be provided by the plan. Constructing an amplification tunnel 100 constructed to integrate a plurality of rotating power generation facilities; And
Through the amplification tunnel 100, the air used for power generation can be continuously rotated and recycled, and each amplified tunnel 100 or a combination of a plurality of amplified tunnels 100 can be amplified by inflow of surrounding air. The inlet and the outlet can face each other at a distance, and the first and end facing each other is characterized by the step of installing in a variety of forms, such as a circular ring form or """shaped or spiral,
Combination of one amplification tunnel 100 or a plurality of amplification tunnels 100 allows each inlet and outlet to face each other at a slightly distance, the first and the end of the circular ring form or the """shape Alternatively, each inlet and outlet of each amplification tunnel 100 formed in various forms such as a spiral is configured and installed as shown in FIG. 4 and FIG. 6 and configured to maximize the Bernoulli's theorem and the Coanda effect to introduce and amplify external air. Air intake air foil (300) and exhaust air amplification air foil (400) for power generation,
In the vicinity or at a distance of the air suction air foil 300 and the exhaust air amplification air foil 400 for power generation, waterproof and insulation were thoroughly and correspond to the total capacity of the power generation facilities provided in the respective amplification tunnels 100. The prepared air compression device 201 is prepared, and the air suction part of the compression device includes the air suction path 305 of the air suction air foil 300 and the air discharge path 405 of the exhaust air amplification air foil 400. Connect and install
A mini amplifier 900 configured as shown in FIG. 8 is prepared at the air inlet 301 of the intake air foil 300 for power generation, and the mini amplifier 900 and the air compressor 201 are compressed air moving pipes ( 201-1), the amplified air outlet 201-4 through the amplified air movement pipe 201-3 to the mini-amplifier 900, the air outlet 401 of the exhaust air amplified air foil (400) Installing in the discharge air in a desired direction; And
Amplified air movement pipe 201-3 through the compressed air discharge port 900-5 of the mini-amplification device 900 installed in the intake air foil 300 for power generation of the air provided by the air compression window 201 By aspirating the air inside the amplification tunnel 100 to achieve first amplification, and the first amplified air of the power exhaust air amplification air foil 400 installed at each inlet of the amplification tunnel 100. The air is discharged through the amplified air outlet 201-4 installed in the air outlet 401, and the air at the inlet of the amplified tunnel 100 is introduced into the amplified tunnel 100 by a double effect of being sucked from the amplified tunnel 100 and discharged from the inlet. To achieve multiple amplification,
The multi-amplified air rotates the rotor of a large number of power plants installed in each of the amplification tunnels, and then rotates and recycles the tunnel continuously so that a large amount of electricity can be produced with a small force. Whirlwind self-generation system characterized in that the step of providing power to the compressor to self-power generation.
In the construction of the power plant, the rotor is composed of a cylindrical electromagnet rotor, and when the rotor of the power plant is the cylindrical electromagnet rotor, since electricity is not applied to the electromagnet, the rotor does not float in the middle of the stator 800. Cyclone self-generating system is installed on both ends of the cylindrical electromagnet rotor is installed power generation equipment with a cylindrical electromagnet rotor characterized in that the step of installing by adding a device for fixing with a bearing.
In the construction of power generation facilities and amplifying tunnels, it can withstand high speed wind and work on power generation, and a speed increaser is installed to work on power generation at low speed wind, and power is transmitted from a rotating body by receiving rotation power through a rotating power transmission device. To work on
Preparing a hollow cylinder as shown in Figure 14 and at both ends of the cylinder to prepare a cylinder with square gears on both ends configured to engage the square with the rotational power transmission device,
Inside the cylinder with the square gears installed at both ends, the gear wheel can endure the high speed wind in the middle and attach the rotor blade 500-1 of the plane shape which is not connected across the cylinder inner diameter. Is installed and builds a cylindrical rotor 700-1 is attached to the rotor blades 500-1 of the plane shape,
Two cylindrical bodies 700-1 or more cylindrical bodies 700-1 are continuously connected to each of the cylindrical rotors 700-1, depending on the speed of the wind to be provided by the plan and the angle of the provided wind. -1) is installed by adjusting the rotor blade 500-1 to rotate in the same direction,
The inner diameter of the gear wheel at the rear of each of the cylindrical rotors 700-1 includes a fluid barrier membrane 100-1 composed of an outer diameter slightly smaller than the inner diameter of the cog wheels of the next rotating member 700-1. Construct the amplification tunnel 100 in which power generation facilities are separated by constructing a tunnel shape by installing except the cylindrical rotating body 700-1 which is installed at the rear so as to overlap or slightly overlap the rotating body 700-1.
To connect the rotary power transmission device to the cog wheels of the plurality of cylindrical rotating body 700-1 constituting the amplification tunnel, considering the characteristics of the rotating body 700-1 for rotating the rotary power transmission device opposite to each other A tornado self-power generation system characterized in that the step of separating the power generation equipment and the amplification tunnel is prepared so as to receive the rotational power to work on power generation.
In the construction of power generation facilities and amplification tunnels, a plurality of power generation facilities with waterproof and insulation are constructed continuously so that they can rotate in opposite directions in preparation for vortex phenomena, and surround the outside where many power generation facilities are constructed. The tornado self-generating system, characterized in that for constructing an amplification tunnel (100) in which the power plant is built so that a plurality of power plants are reversely rotated by building a tunnel in a cylinder.
In the step of amplifying the air, it is configured and installed at each inlet and outlet of each amplification tunnel as shown in Figs. 3 and 5 so as to make the most of Bernoulli's theorem and the Coanda effect to inflow and amplify the outside air. The air suction and discharge guide is installed to build an air intake air foil 400 and an air discharge air amplification air foil 300 for power generation in which the air outlet 401 and the inlet 301 are configured in a planned and intended direction.
In the vicinity or at a distance of the air suction air foil 300 and the exhaust air amplification air foil 400 for power generation, waterproof and insulation were thoroughly and correspond to the total capacity of the power generation facilities provided in the respective amplification tunnels 100. Prepare a plurality of blowers 200 prepared, the air inlet of the blower 200 is connected to the intake air movement path 305 of the air intake air foil 300, the blower of the blower 200 amplified exhaust air Characterized in that the step of connecting the discharge air movement path 405 of the air foil (400),
The air provided from the blower 200 is provided with an air trap 402 in the exhaust air amplification air foil 400 for power generation, and the amplified tunnel 100 in a straight line or diagonal line through the air outlet 401 in a planned and intended direction. Exhaust air in the inward direction, and inside the amplification tunnel 100, the air at the inlet of the amplification tunnel 100 is sucked at the same speed at the air inlet 301 of the air intake air foil 300 for power generation. Whirlwind self-powering system, characterized in that the step of amplifying by inflow and rotating in the planned and intended direction
The suction air foil 300 and the air amplification air foil of the power generation airfoil have an overall shape in a straight shape and the outlet and the inlet are directed toward the inside of the tunnel, and an air guide is installed to control the flow of air in a desired direction. Intake foil and exhaust air amplification air foil for power generation, characterized in that configured to
In the step of installing the air discharge air foil and the suction air foil to achieve amplification of the air, the air discharge amplification air foil is installed at the inlet of the amplification tunnel and the intake air foil is not installed at the outlet air intake and Whirlwind self-generation system, characterized in that the mini-amplifier is installed outside the amplification tunnel
In order to utilize the air continuously rotating the amplification tunnel in various industries and moving means, the distribution pipe 10-1 of air entering the outer diameter of the outlet of the amplification tunnel 100 as shown in FIGS. 9 and 10. Install or connect the air coming in and out of the air as a pipe surrounding the amplification tunnel (100) into one, the air inlet pipe (10) to the incoming and outgoing wind control device (40), the amplification tunnel (100) Install the pipe (20-1) to collect the outgoing air to the outer diameter of the inlet of the wind) or the air coming in and out of the air integrated pipe (10) to collect the air coming in and out into the pipe surrounding the amplification tunnel (100) It is connected to the control device 40 of the wind turbines installed and spaced apart from the control device 40 and the blower 200 or air compressor 201 or amplification tunnel of the incoming and outgoing wind It is constructed by moving to an easy-to-operate place, sealed with an external tunnel 30, and a plurality of piezoelectric elements are serially disposed at the lower end of the external tunnel 30 so as to absorb the vibration energy caused by the operation of the power generation facility and work on power generation. Or installing the power generation equipment connected in parallel and constructing the electric power to be provided as a power source of the blower or the air compressor.
The incoming and outgoing wind control device 40 includes a mini-amplification device as shown in Figure 8, or the airfoil of Figures 2, 3, 4, 5, 6, and 13 suitable for various industries or transportation means. Tornado self-generating system characterized by the steps of properly connecting or mounting the foil
It is a method that can provide electricity generated in various industries, vehicles and homes, and wind used for power generation at the same time because it is usefully used without the need for separate energy to make wind required for the movement of various industries or vehicles.
The flight air foil (400A) is composed of a plane wing shape of the overall shape as shown in Figure 12 the flat bottom and the convex curve above,
The hollow inside is equipped with a lower barrier and a front and rear barrier, and the lower barrier is equipped with a hydraulic device that can move back and forth, and the rear barrier is installed at the rear of the lower barrier, which is connected with the rear wing. Is configured to act as flaps, and the airfoil (400A) is characterized by the step of building the air outlet front and rear opposite to each other
The driving air foil 400B is formed in a straight shape as a whole as shown in FIG. 13, and the driving air foil 400B is characterized in that the front and rear air outlets are constructed so as to face the outside of the amplifying tunnel opposite to each other.
Vertical moving air foil (400C) can be installed in the overall shape as shown in Figure 13, the shape of the date or the bottom of the small, vertical, characterized in that the air outlets above and below are built to face the outside of the amplification tunnel opposite each other Mobile Air Foil (400C)
Combined air foil (400D) is the upper and lower parts of the overall appearance as shown in Figure 13 without the amplification tunnel, and the air outlet (400D) characterized in that the steps to be constructed so that the upper and lower air outlets to face the outside of the amplification tunnel opposite to each other ).
External tunnel 30 constructed by moving the power generation equipment installed apart from the control device 40 and the blower 200 or the air compression device 201 or the amplification tunnel of the incoming and outgoing wind to an easy operation. To configure the outer body 51 in various shapes suitable for various moving means or installed in the interior (mainly lower ends of the various moving means) of various shapes of the already configured,
Control of the wind entering and exiting the inside of the body of the various shapes 51 or the interior of the vehicle 50 of the various means of transportation or already built a vehicle 50 of the boarding and loading space Install the device 40,
The vertical air flow with the flight air foil 400A and the traveling air foil 400B configured as shown in FIGS. 12 and 13 suitable for various moving means to which the air adjusting device 40 and the passage through which the air can move are connected. Foil 400C and the combined air foil (400D) characterized in that the step of building to suit the characteristics at the appropriate position of the outside of the various means of transportation means,
The empty space between the outer tunnel 30 and the outer body 51 of various shapes of the various moving means and the vehicle body 50 of the various shapes of the various moving means is sealed as necessary, and harmed to the human body, such as helium. Characterized by a stage with or without gas lighter than air,
The solar cell of the solar installation is installed in the sunlight well portion of the outside of the moving means and to be provided as the power to create the wind required for the generation and movement of electricity generated by the photovoltaic facility (1000-2) Featuring stages
Steps to build the various devices necessary for the movement of the electricity generated by the whirlwind self-generation system and the power required
Insulating and generating the power plant and the blower or air compressor thoroughly and waterproof and insulation of the entire body and the outer body to prepare for power generation and amplification in the water, as well as the ground and air Various means of transportation equipped with whirlwind self-generation system configured to move among them
The solar power generator and the electricity generated only by the electric power generation equipment by the vibration provided by the electricity stored in the battery to provide power to the blower or the air compressor to make the wind and the amplification tunnel (100) Vehicle equipped with whirlwind self-generation system characterized in that the step is excluded
Means for transporting a whirlwind self-power generation system equipped with the flying air foil 400A, the traveling air foil 400B, and the vertically moving air foil 400C and the combined air foil 400D.
Moving means equipped with a whirlwind self-power generation system equipped with the traveling air foil (400B), vertical moving air foil (400B), combined air foil (400D)
Movement means equipped with a whirlwind self-generation system equipped with a vertical moving air foil (400C) and a combined air foil (400D).
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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KR1020100082978A KR20120019650A (en) | 2010-08-26 | 2010-08-26 | The tornado self-generating system by amplifying and rotating of an air (fluid) & any transportation that is equiped with the tornado self-generating system |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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KR1020100082978A KR20120019650A (en) | 2010-08-26 | 2010-08-26 | The tornado self-generating system by amplifying and rotating of an air (fluid) & any transportation that is equiped with the tornado self-generating system |
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KR20120019650A true KR20120019650A (en) | 2012-03-07 |
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KR1020100082978A KR20120019650A (en) | 2010-08-26 | 2010-08-26 | The tornado self-generating system by amplifying and rotating of an air (fluid) & any transportation that is equiped with the tornado self-generating system |
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
KR20150118414A (en) * | 2014-04-14 | 2015-10-22 | 윤주학 | An aerogenerator |
WO2017034359A1 (en) * | 2015-08-27 | 2017-03-02 | 광주과학기술원 | Unmanned flying object capable of flying without propeller |
WO2019074148A1 (en) * | 2017-10-11 | 2019-04-18 | 마당월드 주식회사 | Energy generation device using difference in density of fluid |
-
2010
- 2010-08-26 KR KR1020100082978A patent/KR20120019650A/en not_active Application Discontinuation
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
KR20150118414A (en) * | 2014-04-14 | 2015-10-22 | 윤주학 | An aerogenerator |
WO2017034359A1 (en) * | 2015-08-27 | 2017-03-02 | 광주과학기술원 | Unmanned flying object capable of flying without propeller |
WO2019074148A1 (en) * | 2017-10-11 | 2019-04-18 | 마당월드 주식회사 | Energy generation device using difference in density of fluid |
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