KR200282394Y1 - High efficiency vertical type wind-power plant - Google Patents

Abstract

The present invention relates to a high-efficiency vertical wind power generator, the purpose of which is to provide a wind cover to protect the outside of the rotor constituting the wind turbine and to wind the wind, the surface shape of the rotor is the rotational force of the wind It is formed in a structure that can reduce the reverse wind according to the structure, and one side of the rotor is opened to reduce the wind speed applied to the rotor during strong winds over a certain speed so that it can be rotated smoothly. The present invention provides a wind power generator configured to allow the flow of air between electrons, reduce the frictional force by configuring a lower bearing of the rotating shaft as a superconducting bearing, and interlock a generator with the superconducting generator. The constitution of the present invention protects the exterior of the rotor and at the same time the wind collecting wind blowing variable wind cover (1), and the inside of the variable wind collecting cover (1), the inertia weight on the outer circumferential surface not in contact with the rotating shaft (3) A pair of upper and left symmetric pairs of symmetrical pairs consisting of an open rotor 25 having a weight 21 formed thereon, coupled to a plurality of diaphragms 22 constituting an air passage with a rotating shaft, and whose surface is opened in accordance with the wind speed. (2a) and a pair of left and right symmetrical lower variable rotors 2b that are coupled to the lower part of the upper variable rotor and whose angles of the rotor blades form a right angle.

Description

High efficiency vertical type wind-power plant

The present invention relates to a high-efficiency vertical wind turbine, and more particularly to a wind turbine having a variable rotor and superconducting bearings in which concave dimples are arranged irregularly, in particular, to reduce the resistance of the rotor according to the wind speed. A concave vertical projection is formed on one side of the rotor so that one side of the rotor is opened according to the wind speed, and the lower bearing is composed of a superconducting bearing so as to reduce the friction loss of the rotor shaft that is interlocked with the rotation of the rotor. It relates to a wind power generator.

In general, the wind power generation system uses the aerodynamic properties of the kinetic energy of the air flow to rotate the blades to convert into mechanical energy and rotate the generator with this mechanical energy to obtain electricity.

The main components of the wind system include a wing (rotor), a speed increaser (gear box), a generator, a control and safety device, and additionally, a support tower for supporting these structures.

The rotor generates the kinetic energy of the wind as lift force by using the characteristics of the geometry of the wing, rotates the wing, rotates the wing, and converts it into mechanical rotation force through the rotor shaft connected to the wing. .

It has the principle of generating power by driving the generator after increasing the rotational power to the rated speed of the generator through the speed increaser.

When the rotor rotates, a counterwind is generated which reacts to the rotation of the rotor. In the related art, a structure capable of reducing the influence of the counterwind is not proposed, and thus rotation energy is lost due to the counterwind.

In addition, conventionally, when winds exceeding a certain wind speed (for example, typhoons) are not presented, a wind path that can reduce the rotational force applied to the rotor and the strength of the reverse wind is not suggested. Therefore, there was a problem that the reliability of power generation is not high.

In addition, in the past, most of the wind power is installed to generate power without a device for protecting the rotor. Thus, when the open rotor rotates only by the natural wind speed, there is a problem in power generation efficiency because the rotor's rotational force is small when the wind speed is small. However, when the rotor is installed in such an open state, there is a structural problem that the rotor can be easily damaged during power generation or non-power generation.

In addition, the rotor is generally made light using FRP material, but has a certain weight and the force of the wind is added to act as a large load on the bearing supporting the rotor shaft. Accordingly, in order to minimize friction during rotation and to avoid mechanical friction, oil or air is used. However, conventional bearings have bearing loss due to the weight of the blade or the rotational speed regardless of the type of bearing. Therefore, the loss of the rotational force of the rotor shaft with the wind speed occurs due to the bearing loss. Therefore, in order to generate a high rotational force for the same wind speed, a bearing requiring little rotational force of the bearing is required.

In addition, existing wind power generation systems use synchronous or asynchronous generators, and these generators are heavy due to iron loss using iron cores, and resistance loss occurs in copper, resulting in lower current density. As it is clear, it is heavy, bulky and reaches the limit of efficiency. Therefore, in order to increase the efficiency of the wind power generation system and to make the engine compartment small and light, a high efficiency, small and light weight generator is required.

An object of the present invention for solving the above problems is provided with a wind collecting cover that can protect the outside of the rotor constituting the wind power device and wind the wind, and the surface shape of the rotor in accordance with the rotational force of the wind It is formed in a structure that can reduce the pressure, and one side of the rotor is open to reduce the wind speed applied to the rotor during strong winds over a certain speed to enable smooth rotation, and air between the rotors assembled around the central axis It is configured to allow the flow of, and the lower bearing of the rotating shaft to configure the superconducting bearing to reduce the friction force, and to provide a wind power generator comprising a generator connected to the superconducting generator.

1 is a perspective view showing an embodiment of the present invention before the operation of the wind turbine,

Figure 2 is a perspective view showing an embodiment at the time of operating the wind power device of the present invention,

Figure 3 is a front view showing the interior of the wind power device,

Figure 4 is a perspective view of a rotor constituting the wind power device of the present invention,

5 is a plan view showing a partially open state of the rotor of the present invention wind device.

<Explanation of symbols for main parts of the drawings>

(1): variable wind cover (2a): upper variable rotor

(2b): Lower variable rotor (3): Rotating shaft

(4): superconductor bearing (5): upper bearing

(11): Wind turbine wings (21): Inertial weight

(22): diaphragm 23: dimple

24: horizontal frame 25: open rotor

(26): elastic spring (51): horizontal frame

52: hinged vertical frame (251): hinge

The construction of the present invention to achieve the object as described above and to solve the conventional drawbacks is a vertical wind turbine consisting of a vertical rotor, rotary shaft speed increase gear (gearbox), generator, control and safety devices, etc. In the apparatus,

A variable wind collecting cover that protects the outside of the vertical rotor and winds at the same time,

Open rotor installed inside the variable windshield cover, the inertial weight is formed on the outer peripheral surface not in contact with the rotating shaft, coupled to the rotating shaft is formed of a plurality of diaphragms (Diaphragm) forming an air passage and part of the open rotor according to the wind speed With a pair of upper and lower symmetrical rotors,

The lower variable rotor is coupled to the lower side of the upper variable rotor, and the angle of the rotor blade is characterized in that consisting of a pair of lower symmetrical lower rotor.

The variable wind collecting cover is characterized in that it is composed of four wind blowing wings that are opened and closed with a predetermined angle by one side is coupled to the hinged vertical frame vertically coupled with a quadrilateral horizontal frame supporting the upper bearing of the rotating shaft.

Each of the variable rotors are irregularly arranged randomly (random) on one surface of the central portion, the central portion is separated in the vertical direction, one side is fixed to the diaphragm and the horizontal frame, the other side is coupled to the inertial weight It is characterized in that the open rotor is installed to be opened in the opposite direction of rotation by the hinge and the elastic spring (operated when the wind speed is 30m / sec or more).

The lower part of the rotating shaft is composed of a permanent magnet, and the rotating shaft is inserted into the superconductor bearing, and the rotating force of the rotating shaft is configured to be transmitted to the superconducting generator.

Hereinafter, the configuration and the operation of the embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view showing an embodiment of the present invention before the operation of the wind turbine, Figure 2 is a perspective view showing an embodiment of the operation of the present invention wind turbine, Figure 3 is a front view showing the interior of the present invention wind turbine, Figure 4 A perspective view showing a rotor constituting the wind turbine of the present invention is shown. The configuration is a vertical wind turbine comprising a vertical rotor, a rotating shaft speed increase gear (gearbox), a generator, a control and a safety device, and the like.

In the non-power generation, at the same time to protect the outside of the vertical rotor and the wind collecting variable wind cover 1 is configured on the outside.

The variable wind collecting cover 1 is coupled to one side by a hinged vertical frame 52 which is vertically coupled with a quadrilateral horizontal frame 51 supporting the upper bearing 5 of the rotating shaft 3 to form a predetermined angle. It is composed of four wind vane 11 that is opened and closed with.

The opening of the wind collecting wing is opened by installing a normal opening device (not shown) using an actuator or the like.

Inside the variable wind collecting cover 1, a pair of vertically lateral symmetrical rotors 2a, which are rotated according to the wind speed, are installed, and inertia is formed on an outer circumferential surface not in contact with the rotating shaft 3 which transmits the rotational force to the power generator. The weight 21 is formed, and once the rotation is started, even if the wind speed is reduced by the inertial force due to the weight, it is possible to continuously rotate for a certain period of time.

And it is combined with a plurality of diaphragms (Diaphragm, 22) forming an air passage with the rotating shaft, as well as supporting the connection between the rotating shaft and the rotor, as well as extra wind to the other rotor symmetrical without losing the wind hit on one side Supply to accelerate the rotor.

And the variable rotor (2a, 2b) is formed to reduce the resistance to the reverse wind to a part surface, and constitutes a structure that is opened in accordance with the wind speed more than a certain speed, looking at the configuration in detail the concave dimple ( 23 is formed in an irregular (random) arrangement, the central portion is separated in the vertical direction, one side is fixed to the diaphragm 22 and the horizontal frame 24, the other side is a hinge coupled to the inertial weight 21 ( 251) and an open rotor 25 which is opened in the opposite direction of the rotation direction by the elastic spring (operated when the wind speed is 30 m / sec or more, 26) is configured to allow power generation by continuous rotation of the rotor. .

The reason why the dimples are randomly arranged is to maintain the straightness as the dimple shape is formed in the golf ball. That is, to induce diffuse reflection so that a constant echo does not work by the wind.

Therefore, if the arrangement of the dimples is arranged regularly, there is no reason for dimple formation.

In addition, a pair of left and right symmetrical lower variable rotors 2b coupled to a lower portion of the upper variable rotor and having a right angle to the rotor blades are configured at the bottom to constitute two stages in two vertical stages. The rotor was configured to receive a large amount of air.

In addition, the lower part of the rotating shaft 3 is composed of a permanent magnet, the rotating shaft 3 is inserted into the superconductor bearing 4, and the rotating force of the rotating shaft is transmitted to the superconducting generator (not shown) to maximize efficiency. It was configured to.

Figure 5 shows a plan view showing a partially open state of the wind turbine rotor of the present invention, the concave dimples 23 formed in the center portion is shown on both ends with a central separation surface, the open circuit The electron 25 is installed on the inertial weight 21 coupled by the hinge, one side is fixed to the weight, one side is fixed to the open rotor 25 one side of the elastic spring 26 is a fixed speed or more It shows the appearance of being elastically deformed and opened according to the wind direction. The elastic spring is restored to the original position of the rotor when the wind speed is less than 30m per second.

1, 2, and 3, the illustration of the elastic spring installed in the inertial weight is omitted.

Referring to the operation of the present invention configured as described above are as follows.

First, connecting the power generator (pump, compressor, vibrating device, circular saw, ash mill, ash refinery) and the shaft for using the wind power device of the present invention, the variable wind collecting cover (1) so that the rotor rotates when a certain speed or more Open the wind to wind up.

The upper and lower rotors are rotated by the collected wind so that power is transmitted to the rotating shaft. At this time, the reverse wind due to the rotation of the rotor is reduced by the dimple, and the rotational speed is increased to the wind vane, inertial weight and diaphragm.

When the wind blows over a certain speed, the open rotor is opened in the opposite direction of rotation by the hinge and the elastic spring to rotate continuously.

The amount of rotation received from the rotating shaft passes through the superconductor bearing and reaches the superconducting generator with almost no loss, thus generating high efficiency.

The present invention is not limited to the above-described specific preferred embodiments, and any person having ordinary skill in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention claimed in the claims. Of course, such changes will fall within the scope of the claims.

As described above, the present invention has a pair of symmetrical rotors with a diaphragm around the vertical axis of rotation, so that air is symmetrically paired through the space formed by the diaphragm and the axis of rotation from one rotor to the other rotor. It accelerates the wind and smooths the flow of air, and irregularly arranged concave dimples on the surface reduce air resistance to minimize the resistance to backwind. This structure is designed to reduce the resistance to wind, and the bearing supporting the lower part of the rotating shaft is composed of a superconducting bearing to reduce frictional loss due to rotation and transfer it to the superconducting generator for power generation. It is devised that the industrial applicability is expected.

Claims (4)

In the vertical wind turbine comprising a vertical rotor, a rotary shaft speed increase gear (gearbox), a generator, a control and a safety device, A variable wind collecting cover (1) for protecting the outside of the vertical rotor and wind blowing at the same time, It is installed inside the variable wind collecting cover 1, the inertial weight 21 is formed on the outer circumferential surface that is not in contact with the rotating shaft 3, coupled with a plurality of diaphragms (Diaphragm, 22) forming an air passage with the rotating shaft A pair of left and right symmetrical upper variable rotors 2a composed of open rotors 25, the one side of which is open in accordance with the wind speed, High efficiency vertical wind turbine generator characterized in that it is coupled to the lower portion of the upper variable rotor and consists of a pair of left and right symmetrical lower variable rotor (2b) to form a right angle of the rotor blades. The method of claim 1, The variable wind collecting cover 1 has one side coupled to a hinged vertical frame 52 which is vertically coupled with a quadrangular horizontal frame 51 supporting the upper bearing 5 of the rotating shaft 3. High efficiency vertical wind turbine generator, characterized in that consisting of four wind blowing wings (11) that are opened and closed. The method of claim 1, Each of the variable rotors (2a, 2b) is formed irregularly (random) arranged in a concave dimple 23 on one surface of the central portion, the central portion is separated in the vertical direction, one side is the diaphragm 22 and the horizontal frame An open rotor fixed to (24), the other side of which is opened in the opposite direction of rotation by a hinge 251 and an elastic spring (operated when the wind speed is 30 m / sec or more, 26) coupled to the inertial weight 21 High efficiency vertical wind power generator, characterized in that 25 is installed. The method of claim 1, The lower part of the rotating shaft 3 is composed of permanent magnets, the rotating shaft 3 is inserted into the superconductor bearing 4, and the rotating force of the rotating shaft is configured to be transmitted to the superconducting generator. Device.