KR20100099794A - Power generation system using wind and ocean current - Google Patents

Abstract

PURPOSE: A power generation system using wind force and tidal force is provided to improve generation efficiency, since a bidirectional generator, wherein a coil and a permanent magnet rotates in the opposite direction, is applied to a tidal power generator and a wind power generator. CONSTITUTION: A power generation system using wind force and tidal force comprises a tidal power generator(100), a wind power generator(200), a base(300), a coupling unit(400), and a tower post(30). The base is installed on the bottom of sea. The tower post is installed on the upper part of the base. The impeller is installed on the bottom of the tower post and is rotated by the tide. The tidal power generator is installed by the coupling unit.

Description

Power generation system using wind and ocean current

The present invention relates to a combined current and wind power generation system, and more specifically, by installing a tidal current generator and a wind power generator on one tower column, power generation by tidal current and wind power generation can be realized simultaneously to increase power generation efficiency. The present invention relates to a tidal current and wind power generation system.

As the depletion of fossil fuel becomes visible, new and renewable energy that can get energy from nature is emerging as a society.

Renewable energy includes wind generators that generate electricity from wind, algae generators that use seawater, solar generators that generate electricity from sunlight, geothermal generators that generate electricity using geothermal power, and electricity using water. There is a hydroelectric generator that produces the

However, in the related art, power generation by using any one energy source is a problem, and thus, there is a problem in that a power generation system utilizing two energy sources is not provided as a single system, thereby not improving power generation efficiency.

Accordingly, the present invention for solving the above problems is to install a tidal current generator using a tidal current and a wind generator to generate power using wind in one tower column so that it can be generated simultaneously using tidal current and wind power as one power generation system. It is aimed to provide a single wind and wind power generation system.

According to an aspect of the present invention,

The base is installed at the bottom of the sea floor where the algae flows, and a tower column protruding a certain height above the sea surface is installed above the base.

An impeller rotating by a bird at the lower end of the tower pillar is installed by using a coupling means for generating a tidal current generator by the rotational force of the impeller. It is characterized by installing a wind turbine to generate power.

According to the present invention, by installing a tidal current generator and a wind power generator on one tower pillar, it is possible to simultaneously implement the power generation by the tidal current and the wind power generation to increase the power generation efficiency as well as the coil and tidal current generator and wind generators By applying a bidirectional generator in which the permanent magnets rotate in opposite directions, it is possible to expect the effect of increasing the power generation efficiency.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, FIGS. 1 to 12.

1 is a view showing the algae, wind power generation system of the present invention,

The base 300 is made of a concrete or steel structure on the bottom of the sea floor flowing algae, and installs the tower pillar 30 protruding a certain height above the sea surface to the upper side of the base 300.

The lower end of the tower pillar 30 is provided with an impeller rotating by a bird to install a tidal current generator 100 that is generated by the rotating force of the impeller using a separate coupling means 400,

The tidal current generator 100 has a front impeller 102 and a rear impeller 103 which rotate in opposite directions with respect to the tidal current at the front and rear of the main body 101, and the front impeller inside the main body 101. By the opposite rotational force supplied from the 102 and the rear impeller 103, the coil body and the permanent magnet are generated while rotating in opposite directions to each other.

In addition, the front impeller 102 and the rear impeller 103 is preferably made of two wings, respectively.

The configuration of the front impeller 102 and the rear impeller 103 to be composed of two wings is to prevent each impeller 102 and 103 from rotating too high by the current.

On the other hand, the coupling means 400 is formed in a semi-circular shape and couples a pair of coupling holes 401 having a flange 402 for bolt coupling at both ends thereof to the lower end of the tower column (30).

At this time, the stopper protrusion 403 is formed to protrude inside the coupling sphere 401, the stopper projection 403 is fitted on the outer peripheral surface of the tower pillar 30 is fixed groove for holding the coupling means 400 does not rotate The stopper protrusion 403 is inserted into the fixing groove 404 when the coupler 401 is coupled to the tower pillar 30 using a bolt by forming a recess in the longitudinal direction.

A horizontal bar 405 having a predetermined length is formed on both sides of the coupler 401, and a vertical bar 406 is formed at the end of the horizontal bar 405, and the vertical bar 406 is formed. On the lower end of the algae generator 100 is coupled freely rotatable.

As shown in FIG. 4, the coupling part 104 is separately formed on the main body 101 of the tidal current generator 100, and the coupling part 104 and the end of the vertical bar 406 are coupled to the male and female. Combined, but the bearing 407 is installed between the coupling portion 104 and the end of the vertical bar 406 to allow the tidal current generator 100 to rotate freely with respect to the vertical bar 406, the direction of the tidal current is changed According to the tidal current generator 100 is freely rotated to straighten the posture to face the tidal current to be able to further improve the power generation efficiency.

5 is a view showing a simulation of the algae, wind power generation system of the present invention.

On the other hand, the top of the tower pillar 30 is provided with a wind turbine 200 which is exposed to the atmosphere and rotated by the wind to generate the rotational force of the blade.

The wind generator 200 condenses the front wing 2 and the rear wing 10 rotating in opposite directions with respect to the wind at the front and rear ends of the main body 1, the front wing (2) inside the main body (1) The permanent magnet 7 rotates with the rotational force transmitted through the) and the coil body 22 rotating in the opposite direction with respect to the permanent magnet 7 with the rotational force transmitted through the rear wing 10 is installed, and the main body (1) is installed to be supported by the tower column (30).

Coupling the front hub (4) to the front end of the front shaft (3) which is axially coupled to the front of the main body (1), the front blade (4) to the front hub (4) as a plurality of bolts, the front The front hub cap 5 is coupled to the front of the hub 4 so that the front shaft 3 portion can be protected from weather or external shock, and the spider 6 is placed in the middle of the front shaft 3. Fasten and install a plurality of permanent magnets 7 at appropriate intervals on the outer diameter of the spider (6).

Since the permanent magnet 7 is installed to be connected to the front shaft (3) in which the front blade (2) is axially coupled, the permanent magnet (7) is rotated in the same direction as the direction in which the front blade (2) rotates.

On the other hand, the front shaft (3) and the inner side (21) is coupled by a bearing (27a) to accommodate the rotor 20 that can rotate independently from the front shaft (3) accommodates the permanent magnet (7) in the inner diameter The coil body 22 is installed inside the main body 1 so as to face the permanent magnet 7 on the outer diameter of the rotating body 20 so that the coil body 22 is applied to the rotational force of the rear wing 10. Thereby rotating in the opposite direction to the permanent magnet (7).

A rear hub coupled to one end of the inner 21 of the rotating body 20 at an inner rear end of the main body 1 and having an end thereof exposed to the rear end of the main body 1, and coupled to an end of the rear shaft. The rear wing 10 is coupled to the 17, and the rear hub 17 is coupled to the rear hub cap 18 to protect the rear shaft.

At this time, the rear shaft and the first rear shaft 11 connected to one end of the inner side 21 of the rotating body 20 and the rear hub 17 is coupled to the end and the first rear shaft 11; Is separated into a second rear shaft 12 connected by a chain coupling 13,

The chain coupling 13 couples the first sprocket 14 to the end of the first rear shaft 11 and couples the second sprocket 15 to one side of the second rear shaft 12. The first and second sprockets 14 and 15 are connected by a double chain 16 so that the first rear shaft 11 and the second rear shaft 12 are connected. Accordingly, the rotational force of the rear wing 10 is increased. It is transmitted in the order of the rear hub 17, the second rear shaft 12, the first rear shaft 11, the rotating body 20 to rotate the coil body 22 in the opposite direction of the permanent magnet (7) will be.

The first rear shaft 11 is provided with a slip ring 24, a brush 25, and a brush holder 26 for drawing out electricity induced in the coil body 22, and are drawn out through the brush 25. The electricity is rectified by the stop not shown is transmitted to the charging station, the configuration of such a slip ring, brush and brush holder is already known in the art, so a detailed description thereof will be omitted.

Unexplained reference numerals 27a, 27b, 27c, and 27d are bearings.

On the other hand, to install the tower rotating shaft 31 connected to the main body (1) in the longitudinal direction on the inside of the tower pillar 30 in the longitudinal direction, connecting the clutch connecting shaft 33 to the lower side of the tower rotating shaft (31) At this time, by connecting the lower portion of the tower rotating shaft 31 and the upper portion of the clutch connecting shaft 33 using the coupling 32, so that the tower rotating shaft 31 and the clutch connecting shaft 33 can rotate together. and,

It is directly magnetized depending on whether the power supply to the lower portion of the clutch connecting shaft 33 is directly connected to the magnet clutch 34 for selectively supplying the rotational force of the lower working shaft 35 to the clutch connecting shaft 33, The operating shaft 35 is installed at the lower end of the magnet clutch 34.

The magnet clutch 34 is selectively magnetized by the supplied current, and when the current is supplied, the magnet clutch 34 is magnetized to interconnect the lower operating shaft 35 and the upper clutch connecting shaft 33 to the operating shaft 35. The rotational force of the main body (1) is freely rotated according to the direction of the wind by allowing the clutch connection shaft 33 to rotate freely while the magnetic force is lost and the magnetic force is lost when the current is not supplied to the tower rotating shaft (31). You can do it.

Then, the worm gear 36 is coupled to the outer circumferential surface of the operating shaft 35, the worm 37 is connected to the worm gear 36, and the worm 37 is connected to the shaft of the drive motor 38. The driving shaft 35 is rotated in the forward or reverse direction by the forward and reverse driving of the driving motor 38.

On the other hand, the wind turbine 200 further comprises a control means for automatically yawing the wind generator in accordance with the wind direction and wind speed, the control means,

An encoder 51 for outputting wind direction information corresponding to a rotation angle of the wind vane 50 provided on the main body 1;

An anemometer 53 for sensing and outputting wind speed by using a rotational speed of the wind speed detection blade 52 provided at an upper portion of the main body 1;

The drive motor 38 is driven forward and backward according to the wind direction information supplied from the encoder 51 while selectively supplying current to the magnet clutch 34 according to the sensed wind speed sensed by the anemometer 53 to maintain the wind turbine main. A control unit 54 for controlling the body 1 to face the wind direction; Consists of including.

The wind vane 50 is installed on the upper part of the main body 1 to rotate according to the wind direction, and the encoder 51 is installed to be connected to the shaft of the wind vane 50 to correspond to the angle at which the wind vane 50 rotates. The wind direction information is supplied to the control unit 54 in the form of a pulse.

In addition, the wind speed detection blade 52 is installed to rotate in accordance with the wind speed on the upper portion of the main body (1), and the wind speed meter (53) on the main body (1) to be connected to the axis of the wind speed detection blade (52) And the wind speed sensor 53 outputs the wind speed information corresponding to the rotational speed of the wind speed detection blade 52 to the control unit 54.

Here, if the operation of the control unit 54 will be described in more detail,

The control unit 54 controls the main body 1 to rotate freely according to the wind direction by cutting off the current supplied to the magnet clutch 34 when the sensing wind speed is less than or equal to the preset first reference wind speed 12m.

The control unit 54 supplies a current to the magnet clutch 34 when the sensing wind speed is between the first reference wind speed 12m and the second reference wind speed 18m, which are set in advance, to operate the shaft 35 and the clutch tower. After the rotary shaft 31 is connected, the driving motor 38 is forward and backward driven according to the wind direction information of the encoder 51 so that the main body 1 of the wind power generator is forcibly rotated along the wind direction. ) To face the wind head-on,

The control unit 54 supplies a current to the magnet clutch 34 when the sensed wind speed is equal to or greater than the predetermined second reference wind speed 18m so that the operating shaft 35 and the clutch tower rotating shaft 31 are connected. By driving the motor 38 forward and backward, the main body 1 of the wind power generator is orthogonal to the wind direction as shown in FIG. 7 so that the front and rear wings 2 and 10 do not drive in a strong wind. This is to prevent the phenomenon that the front and rear wings 2 and 10 are damaged by the wind speed.

The first reference wind speed and the second reference wind speed, which are the operating standards of the control unit 54, are data obtained by a long experiment, and at the wind speeds lower than the first reference wind speed, the front and rear vanes 2 of the present invention. Main body (1) can freely rotate freely along the direction of the wind while (10) is hitting the wind in the front, and in the wind higher than the first reference fan and lower than the second reference wind speed (2) ( 10) rotates at a relatively high speed, so that the main body 1 rotates too quickly and may cause damage to the internal frictional components. Therefore, the main body 1 gradually rotates using the rotational force of the driving motor 38. In the wind faster than the second reference wind speed, the front and rear blades (2) and (10) may be damaged by rotating at a too fast speed so that the main body (1) is controlled to be perpendicular to the wind direction as shown in FIG. 8. To do The.

Reference numeral 39 denotes a stopper installed inside the tower pillar 30 to block the tower rotation shaft 31 from continuously rotating in one direction, and reference numerals 40a, 40b, 40c, and 40d denote bearings supporting the shaft.

1 is a current, wind power generation system of the present invention.

Figure 2 is a perspective view showing a coupling means applied to the present invention.

Figure 3 is a front view showing a coupled state of the tidal current generator applied to the present invention.

Figure 4 is a partial cross-sectional view showing a coupling state of the current generator and the coupling means applied to the present invention.

5 is a view simulating the algae, wind power generation system of the present invention.

Figure 6 is a sectional view showing a wind power generator applied to the present invention.

7 to 9 are enlarged views showing the internal configuration of the wind power generator applied to the present invention.

Figure 10 is a block diagram showing a wind turbine control means applied to the present invention.

11 is a flowchart showing a control process of the present invention.

12 is a view showing an operating state of the wind turbine of the present invention.

Explanation of symbols for main parts of the drawings

1: main body, 2: front wings,

3: front axle, 7: permanent magnet,

10: rear wing, 11,12: rear axle,

13: chain coupling, 22: coil body,

30: tower pillar, 31: tower rotating shaft,

32: coupling, 33: clutch connecting shaft,

34: magnet clutch, 35: working shaft,

36: worm gear, 37: worm,

38: drive motor, 50: wind vane,

51: encoder, 52: wind detection wing,

53: anemometer, 54: control unit,

100: algae generator, 101: main body,

102: front impeller, 103: rear impeller,

200: wind turbine, 300: base,

400: coupling means, 401: coupling means,

402: flange, 403: stopper projection,

404: fixed groove, 405: horizontal bar,

406: vertical bar, 407: bearing,

Claims (5)

The base 300 is installed at the bottom of the sea floor where the algae flows, and the tower pillar 30 protruding a certain height above the sea surface is installed above the base 300, A tidal current generator 100, which is provided with an impeller rotating by a tidal current at the lower end of the tower pillar 30, is installed by using the coupling means 400, and an upper part of the tower pillar 30 is winded. Combined with the wind power generating system, characterized in that the wind power generator 200 is installed to generate a rotational force of the blade with the blade to rotate by. The method of claim 1, wherein the coupling means 400 A pair of coupling holes 401 having a flange 402 for bolt coupling at both ends thereof formed in a semi-circular shape and coupled to the lower end of the tower pillar 30, and have a predetermined length on both sides of the coupling hole 401. A horizontal bar 405 is formed, and a vertical bar 406 is formed at a lower end of the horizontal bar 405, and the tidal current generator 100 is freely rotated at a lower end of the vertical bar 406. Algae, wind power generation system characterized in that the combined configuration. The stopper protrusion 403 is formed to protrude from the inside of the coupler 401, and the stopper protrusion 403 is fitted on the outer circumferential surface of the tower pillar 30 so that the coupling means 400 does not rotate. Tidal, wind power generation system, characterized in that the concave formed in the longitudinal direction of the holding groove 404 to hold. According to claim 1, The tidal current generator 100 is provided with a front impeller 102 and a rear impeller 103 to rotate in opposite directions with respect to the tidal flow in front and rear of the main body 101, the main body 101 In the interior of the coil body and the permanent magnet that is generated while rotating in opposite directions by the opposite rotational force supplied from the front impeller 102 and the rear impeller 103 is installed, the coupling means on the upper portion of the main body 101 Combined portion 104 is further formed to be coupled to free rotation by the bearing 407 at the end of the vertical bar (406) of 400, tidal power, combined wind power generation system. According to claim 1, The wind turbine 200 is the front wing (2) and rear wing (10) which rotates in opposite directions with respect to the wind at the front and rear ends of the main body (1) installed on the top of the tower pillar (30). The shaft is coupled to, the inside of the main body (1) for the permanent magnet (7) and the permanent magnet (7) rotates by the rotational force transmitted through the front wing (2) with respect to the permanent magnet (7) Coil body 22 is installed to rotate in the opposite direction, Coupling the front hub (4) to the front end of the front shaft (3) which is axially coupled to the front of the main body (1), the front blade (2) to the front hub (4), the front shaft (3) Fastening the spider 6 in the middle portion, and fixed to the outer diameter of the spider 6 a plurality of permanent magnets 7 are installed at appropriate intervals, The rotating body 20, in which the front shaft 3 and the inner side 21 are coupled by the bearing 27a, is installed to accommodate the permanent magnet 7 in the inner diameter, and is permanently disposed outside the rotating body 20. The coil body 22 is installed to face the magnet 7, and the end of the coil body 22 is connected to one end of the inner body 21 of the rotating body 20 at the rear end of the main body 1, and the end thereof is connected to the rear end of the main body 1. Install the rear shaft exposed, combined with the rear wing (10) to the rear hub (17) coupled to the end of the rear shaft, algae, wind power generation system characterized in that combined.

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