KR20130026350A - Hydroelectric Aberration Using Buoyancy - Google Patents

Abstract

PURPOSE: A waterwheel of hydroelectric power generation using buoyancy is provided to generate electricity by rotating a power generator by falling water, thereby preventing environmental pollution. CONSTITUTION: A waterwheel of hydroelectric power generation using buoyancy comprises a rotator cover(BT), a rotator, a floating tank blade, and a rotator cover installing stand(401). A wheel rolling stand, a water tank, a saw blade shaped stand, a blade installing stand operating unit, and a shaft bearing(H) are installed in the rotator cover. The rotator of a hook shape is installed in a rotary shaft. A water tank blade is installed in the blade installing stand, thereby being rotated by the buoyancy. The water tank blade is welded to the rotary shaft and moved by being installed in the blade installing stand. The rotator cover installing stand fixes the rotator cover in the underwater bottom at predetermined depth, thereby preventing the rotator from being float by the buoyancy.

Description

Hydropower aberration using buoyancy

The present invention is to use the buoyancy energy by the buoyancy of the water as a method for maximizing the buoyancy energy of the water to develop aberrations to create the water buoyancy energy by the rotational movement and to operate the generator to produce electricity

In general, there are hydroelectric methods using water, such as dam type, water channel change type, dam channel type, and pumping power generation. There are aberrations in which the aberration is completely submerged in water such as Francis aberration, propeller aberration, Kaplan aberration as the method of the aberration and the reaction aberration.

The present invention is a hydroelectric power generation that uses water, which is infinite life water that has come together with the creation of the earth as a permanent power generation method and method that permanently eliminates environmental pollution, which is indispensable for producing electricity, and no pollution inherent in natural laws. The flow of water is blocked by dams by methods and methods, which prevents the degradation of the natural ecology when ecologically observed, and illuminates electricity production methods and methods by permanently renewing lighting and makes electricity cheap, and also in environmental pollution and ecology fields. It is very environmentally friendly and aims to produce electricity and prevent pollution from electricity generation in the economic cycle.

It is possible to produce a large amount of electricity in time, space and location, and minimize the construction cost, and at the same time, if there is a depth and width of water, it is a method and method for making a power plant using large, medium and small buoyancy aberration. The purpose of the present invention is to permanently extinguish the environmental impact assessment and to induce the direction and method for supplying electricity by escaping the existing dam type and to produce and supply high efficiency electricity.

Looking at the effect of producing electricity by the method and method of the present invention below will not create a dam in which the environment is artificially submerged and the environment is transformed, there is no cost due to dam construction, install a reservoir to secure buoyancy energy of water Easy construction and construction in securing buoyancy energy by buoyancy. Also, there is no environmental pollution and destruction in ecological impact assessment.

In particular, the construction of low-cost construction for hydropower will bring about the effect of producing high-efficiency pure electricity.

In addition, the aberration of the present invention can be mass-standardized in the blue sea because it is easy to install the production movement, and can produce electricity in an environmentally friendly and high efficiency of the eternal blue ocean

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

In addition, the present embodiment is not limited to the rights of the present invention but is presented by way of example, various modifications may be made without departing from the technical gist of the present invention.

1 is a side view showing a hydroelectric power aberration using buoyancy according to the present invention, and an explanatory view of the power generation process, [FIG. 2] is a perspective view of a hydroelectric power aberration using buoyancy according to the present invention, and [FIG. 3] is a buoyancy according to the present invention. 4 is a perspective view showing a part of a rotating body which is an operating part of hydroelectric aberration using FIG. 4 is a front view showing the inside of the rotor cover and a partial explanatory view, and FIG. It is a detailed explanatory drawing

As shown in the figure, the buoyancy aberration includes a buoyancy control wheel which is operated by rotating the rotating shaft A while receiving buoyancy in the water of the rotating body cover BT which allows the rotating body (water) and the rotating shaft rotating shaft A to be fixedly operated. Buoyant cylinder blade (D) equipped with buoyancy switch (S) and upper wheel (buoy) mounted on the left and right plates inside the rotor cover (BT) where the rotating body (male) is installed in the water (turn). A) Clouds (C) and lower wheels (B) When the clouds (G) and the body (water) are rotated, buoyancy cylinder wings (D) are installed so that the aberrations are floated on the water by the wing mounts and buoyancy that enable the wings to move by buoyancy. It is composed of a rotating body cover mount 401 and water (turn) fixed to the sea floor 600 to prevent floating

In the above, the rotating body (male), which is an operating part of the buoyancy aberration, rotates the buoyant cylinder blade (D) hollowed out between the left and right semicircular plates DT of the rotating body cover on which the bearing H is installed, as shown in (44). A) The buoyancy vane mounting bracket and the mounting table (a), which are fixed to the welding 37 as shown in (30), are installed so as to bend in the direction in which the buoyant vane (ra) floats. As shown in (30), the welding shaft (37) is fixedly installed on the rotary shaft (A), and the blade mounting bracket (A) and the mounting bracket (A) are wide open in the shape of a trumpet as shown in (30). Is installed on

In the above buoyant cylinder wing, the upper and lower wheel rotary shaft 701, which penetrates the left and right side surfaces J on the wing mounting center portion 81 as shown in (21), is fitted as shown in (C2), so that The buoyancy wing is installed to move up and down like 57

In the above, the wheel (bar) as shown in (47) is fitted to the end of the wheel rotation shaft 701 protruding as shown in (C2) is installed

As shown in (30) above, the wing mounting bracket and the wing mounting bracket (a) are spaced apart in a trumpet type to allow the buoyancy tube wing and the wing to move as shown in (57).

And in the water (turn) buoyancy tube wing (ra) is strongly connected to the wing mount (a) and the wing mount (a) at the speed of the action (305) floating in the water due to buoyancy and the wing mount ( (A) The wing holder (B) is installed on the wing holder (A) and the wing holder (A) to strengthen the structure of the wing holder (A) so that the buoyant cylinder wing (D) can be smoothly operated. Welding 37 wing mount

And (452) on the rotary shaft bearing (H) installed with (222) on the E-bearing mount (101) in the center of the radius (108) of the side semi-circular plate (bar), which is the elliptical structure of the rotor cover (sa). As shown, the rotation shaft (A) is fitted so that the rotation shaft is protruding and the power transmission chain blind 10 is installed at the end 580.

The rotor (water) of the aberration, in which the buoyancy cylinder blade (D) is installed on the rotating shaft (A), is fitted to the bearing (H) so that the rotor (water) rotates in water (turn) as buoyancy (305). Rotating body cover (4) and the rotatable cover is buried in the sea floor bottom 600 with the mounting fixture 22 as shown in (JJ) and firmly installed on the bottom of the sea floor 600, the end of the rotating cover installation (401) ( As JJ), bolt or welding is fixed and installed so that the wings are locked in the water.

In the rotor cover BT, the buoyancy cylinder blade D is set as 305, and the rotor is a saw blade installed in the cylindrical inner surface of the rotor cover BT as 200 when the rotor is rotated. The saw blade AC of the buoyancy vane switch S, which is mounted on the upper surface OJ of the large buoyant barrel blade as 550, is installed at a narrow interval, such as 200, inside the rotor cover 4. The (key) of the switch S is hooked to the saw blade AC of the saw blade 200 so that the (key) is contacted so as to be engaged and operated as 555.

As described above, the rotor cover BT has a cylindrical half cut like the 108 and is open like the 104, and half of the rotatable body (male) is positioned inside the cover BT as shown in (221). It is the pivot cover to install fork

The cover BT has a lower end (Fig.) Fixedly installed at the end of the rotor cover mounting stand 401 as shown in (JJ) so that the rotor (male) with the buoyant cylinder blade (La) installed is immersed in the water turn. do

When the rotating body (water) installed in the rotating body cover (BT) is rotated as shown in (305) by the buoyancy energy rising light object in the water (turn) as follows.

1 to 5

The buoyancy cylinder blade (D) installed on the blade mounting bracket (A) installed on the rotary shaft (A) is rotated in the water (turn) to rotate the blade mounting bracket (A) and rotate the rotary shaft (305) FIG. 1. Detailed description with reference to

In the buoyancy aberration composed of the rotating body (male), the rotating body cover (BT), and the cover mounting table 401, the buoyancy cylinder blade (D) is driven at the top dead center (7) by the rotating body cover (BT) mounting table (401). The buoyancy aberration top (OJ) protrudes slightly above the surface of the water and buoyancy aberration is installed in the water

And the rotor (A) is installed between the wing mounting brackets (A) installed on the left and right rotary shaft (D) is a wing filled with empty air, the wing is configured to receive a lot of buoyant energy in the water and the rotary shaft (A) It is preferable that it is installed in the blade mounting base fixedly welded to the

According to the present invention, the saw blade stage PF having the saw blade AC installed on the inner side O4 of the rotating body cover BT is formed to be elliptical on the inner side of the cover O4 as the cover BT. Characterized by installing as much as can be installed spaced apart from (Y)

A buoyancy force, such as 555, is provided on the buoyancy cylinder blade (D) upper surface OJ installed on the blade mounting base (PF) on the saw blade stage PF with the saw blade AC installed inside the pivot cover BT. By the action of the spring (K) which causes the (key) acting as the spring (K) of the barrel blade (S) switch (S) to be engaged with the saw blade (AC) of each saw blade stand (PF) as shown in (505). If the switch (S) and the saw blade (AC) is to be described in detail as follows.

In FIG. 1, the buoyancy cylinder blades a, b, and b, which protrude out of the rotor cover BT of the rotor body (male), installed on the rotor cover BT, are used for buoyancy in water. As shown by the dotted arrow (X) with the force, wings (a), (b), and (c) are floating on the water, so the wing mount (A) installed on the rotating shaft (A) is turned and (X) direction. Rotation axis (A) is rotated

In the present invention, the buoyancy cylinder wing (a), (b), (c) protruding out of the cover (BT) buoyancy action (X) and the buoyancy cylinder wing (1), turning in the rotor cover (BT), (2 Wing (a), (b), (c) spaced around the axis of rotation from the wing mount (A) fixed to the rotation axis (A) in the action (R) against the buoyancy of (3) The buoyancy force is largely applied to the rotating shaft (A) like the (X) through the wing mount (A).

And the buoyancy cylinder wing (1) and (2) and (3) and (4) buoyancy cylinder wing (d) is moved near the rotation axis (A) through the wing mounting (a) so that the wing (d) receives buoyancy It is technical feature

The buoyancy cylinder blade (1) positioned in the rotor cover (O4) with the buoyancy force (X) received from the buoyancy cylinder blades (a) and (b) and (c) about the rotation axis (A), (2), (3) and (4) are pressed against the buoyancy in the direction of the bottom (600) with (R) as the force of buoyancy (X) and (B) and (B) rise above the water (X). The rotation axis (A) is interlocked with (X) and (R) by

In the above, the movement of each buoyancy cylinder blade (D) intersecting the inside of the rotating body cover and the rotating body cover BT with respect to the rotation axis A is performed as shown in (R) and (X).

Upper cloud zone (C) in the operation of the wing (TT) in which the wing enters the rotor cover (BT) at the position of the buoyancy wing (a) in the cross motion of the wing (L) as shown in (R) and (X) In order for the bottom wheel of each buoyancy wing (L) to hang like (AX), the wing (a) is attached to the wing shaft (A) by the rotation axis (701) of the upper wheel of the wing (A). Buoyant buoyant vanes (D) are no longer held as buoyant buoys such as (AX) through the wing mounts.

In the above, the upper rolling table C installed on the left and right plates 108 of the rotating body cover gradually moves closer to the rotating shaft A, such as QX, as in the OX, so that the inside of the rotating body cover BT is located on the side plate DT. It is installed oval in (O4)

The buoyancy cylinder wing by the upper rolling blade (C) acts to roll the wing wheels (ㅈ) in the buoyancy cylinder wing mounting (A), such as (PR), so that the upper roller (C) into the rotor cover (BT) ( It acts as a function of moving the buoyant wing (D) moving near the rotation axis as R).

In the action (QX), the buoyancy wing (1), (2), (3), (4) is in the water by the effect of the rotor cover (BT) to block and reduce the buoyancy energy of water as (PP) The effect of receiving buoyancy less than buoyant wing (a), (b), (c) in the cover of the body

And the buoyancy cylinder blades (1), (2), (3), (4), (5), the key (key) of the switch (S) installed on the upper surface (OJ) of the wing is the wing in the rotor cover (BT) When rotating as shown in (R), the lower wheel (C) rolls on the upper cloud (C) and the lower cloud (G).

The wing mount (A) is a moving path (TA), where the aberration left and right mounts (A) rotate, and are saw blades (E) protruding out of the rotor cover (BT).

In the above operation, the key (key) of the switch S installed on the upper surface OJ of the buoyant cylinder blade D is lifted up like the (AP) by the spring K. The buoyant blade (C) and the lower blade (G) are buoyant blades (1), (2) so that the distance between the blade upper surface (OJ) and the inside of the pivot cover (O4) is kept constant so as to contact the saw blade (AC) of the blade. ), (3), (4), (5) is installed when the wheel (접촉) is in contact with the upper cloud (C) and the lower cloud (G) by the buoyancy acting when rolling like (PR) rolls Switch (S) key (key) installed on the upper surface (OJ) of the wing (D) while the ellipsoidal surface (O4) and the buoyant cylinder blade upper surface (OJ) are maintained at regular intervals (TC). ), The upper rolling table (C) and the lower rolling table (G) is installed inside the left and right plates (DT) of the rotating body cover so as to control the distance (TC) uniformly through the under wheels rolling the rolling clouds.

When the key (key) of the switch (S) is caught by the saw blade (AC) of the saw blade band (PF) as shown in (AP) in the above, the force due to the buoyancy of the buoyancy cylinder blade (D) is centered around the rotation axis (A). The buoyancy energy acting on the buoyancy cylinder wing is the key (key) of the switch (S) of the buoyancy cylinder blade (L) like (AP), so the force of the floating buoyancy of the wing is reduced.

As shown in FIG. 5 and the partial detailed explanatory drawing (Y7) as a configuration for more effectively reducing the buoyancy of the buoyancy cylinder blade (D) moving inside the pivot cover BT with the effect of (AP) above. The operation of the (AC) and switch (S) keys (keys) is as follows.

In (Y7), if one saw blade side is provided next to the saw blade band between the saw blade (AC) and the saw blade (AC) space (S8), so that one saw blade (AC) is provided, the switch (S) The operating time of the key is shortened like ½

If you have two saw blades in (S8) as shown in (ㅋ), the operation time of the switch (S) key (key) is shortened to ⅓.

If (3) has three saw blades (AC) in (S8), the operation time of switch (S) key (key) is shortened to ¼.

In the above, when there are many saw blades in the spacing between saw blades (S8), when the buoyancy cylinder blade (R) rotates on the rotational axis (R), the operating time of the switch (S) is shortened and becomes close to zero.

In the above switch is operated, but many switches (S) to effectively block the buoyancy installed on the upper surface (OJ) of the buoyancy cylinder effectively installed in a jig-zig as shown in (555) on the upper surface (OJ) of each switch (S) ) Is installed to operate differently within the interval between saw blades (S8)

As above (XY), if the point is connected to a line, the switch (S) key (key) and saw blade (AC) is operated, but the key (key) of many switches (S) is fast in one buoyant blade It is to act quickly to reduce the buoyancy of the wing (d) more effectively.

In the above, the buoyancy of the buoyancy cylinder wing (D) turning about the rotational axis (A) into the rotor cover (BT) is effectively reduced significantly, and the wing receiving the buoyancy outside the rotor cover (BT) has a bottom dead center (6). The wing mount moves to the end as it is buoyant as it passes through

In the structure of the buoyant bent wing (d) bent in the shape of a hook and bent in the shape of an elliptical and bent in a hook while moving away from the rotary shaft (A), the buoyant (d) is mounted in the buoyant wing (d). Buoyancy cylinder upper surface (OJ) when the buoyancy cylinder blade (4) passes through the bottom dead center (6) at the time of the action arrow (TJ) to be operated and the wing (5) protrudes out of the rotating body cover (BT). Switch (key) protruded outward from the rotating body cover (BT) to be engaged with the saw blade (AC) of the saw blade stand (E).

In the above, when the buoyancy cylinder blade 4 passes through the bottom dead center 6, the buoyancy cylinder blade 4 extends inside and outside the cover BT around the cover 108 and the rotation axis A. A device that prevents buoyancy energy of the blade Ra 4, which is located in the rotor cover BT, when the buoyancy force acting on the blade Ra 4 is placed in the rotor cover BT when it is positioned as follows. The switch (key) is installed on the saw blade (AC) of the saw blade (PF) to operate like (GG) along the saw blade (E) outside the rotor cover (BT).

In the above, when the blade (4) moves along with the switch (key) out of the cover (BT) and the switch (key) passes through the end (SS) of the saw blade (E), the bottom wheel of the blade (4) Of the lower cloud platform AA is installed so that the rolling section YA of the lower cloud platform AA protrudes out of the cover.

In the above, the lower wheel (YO) of the wing installed on the mounting table where the under wheel rotates by buoyancy is bent in the direction of the rotation axis outside the cover BT as shown by the arrow CB. A bent portion of the saw blade stand E and the lower cloud stand AA protruding from the bottom dead center 6 so that the wing 4 lifts the mounting stand while rolling in the rising direction X of D4. (YA) is installed

It is the aberration that the rotation axis (A) can be interlocked by the force of the strong buoyancy energy by the powerful buoyancy action of the wing (a), (b), (c) to rotate the wing mounting (a) in the above.

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Claims (3)

In hydroelectric aberration using buoyancy A rotor cover provided with a wheel rolling block, a water tank hole, and a saw blade bar so that the rotor body and the rotor body protruding out of the elliptical cover are smoothly rotated by the buoyancy of water, and the rotor mounting part and the shaft bearing are installed; Rotating shaft is inserted into the bearing installed on the rotating body cover, and it is located inside the rotating body cover installed in an oval shape around the rotating shaft, and it is located outside the rotating body cover, and is installed on the rotating shaft in the shape of a hook. Rotating body is installed to be rotated by the buoyancy of water; An elliptical tubular structure that is fixed and welded at regular intervals to the rotating shaft, and is installed on the blade mounting platform installed on the rotating shaft so that the gap between the stand and trumpets is open. Buoyant wing; And The rotor cover is fixed to a certain depth in the water and is installed on the bottom of the water to install the rotor cover to prevent the rotor from floating by buoyancy. Hydroelectric aberration using buoyancy characterized by having The method of claim 1 A hook-shaped elliptical fixed to the rotating shaft of the rotational body and a buoyant wing shaft movement path in the mounting table and the tungsten-shaped gap between the stand and the stand is installed on the rotating shaft by connecting the stand and the stand; Switch installed inside the rotor cover to slide the key of the switch on the upper side of the rotor blade and slide in the state where the key of the rotor blade switch is in contact with it, and operate the key to reduce the buoyancy of the blade in the rotor cover. Saw blade for activating the key; The wing of the rotor is buoyant in the water so that the wing protrudes into the water, and the buoyancy of the wing is reduced to the saw blade and the cover in the oval cover and half of the elliptical cylinder is installed so that half of the rotor protrudes. Hydroelectric aberration using buoyancy, characterized by including a rotor cover The method of claim 1 Rotor cover to control buoyancy cylinder blade to move near the rotation axis when the wheel installed on the shaft of the buoyancy cylinder wing that protrudes and protrudes, and to control the buoyancy cylinder wing away from the rotation shaft when the bottom dead center passes. A wheel cloud mounted inside a left and right oval semicircular plate; And The rotating shaft is installed on the cover of the rotating body horizontally, and the blade mounting stand is installed with a trumpet shape around the rotating shaft, and the buoyant cylinder wing is installed on the mounting table to greatly increase the buoyancy energy of the water on the buoyant blade wing installed outside the rotating cover. Hydroelectric aberration using buoyancy, characterized in that it comprises rotating the rotating shaft installed horizontally

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