KR101183076B1 - Construction method for tidal power generator - Google Patents

Abstract

The present invention relates to a method of constructing a tidal power generation device, the method comprising: a first step of digging soil with a predetermined width and depth on land adjacent to a beach or a river; A second step of forming a plurality of channels in the transverse direction in the groove portion and forming a levee with a predetermined width and height; A third step of digging soil at a predetermined depth on the land surrounded by the embankment to form a water tank; A fourth step of attaching the aberration to the waterway; A fifth step of mounting a generator interlocked with the aberration; And a sixth step of removing soil remaining on the outside of the dike to allow water to flow into the reservoir through a water channel. By such a method, it can be mounted large and small in a required place. Due to the difference between tides, the work process is not affected and can be easily constructed at any time, thereby reducing the manufacturing cost.

Tidal, power, device, construction, methods

Description

Construction method of tidal power generation device. {CONSTRUCTION METHOD FOR TIDAL POWER GENERATOR}

The present invention relates to a construction method of the tidal power generation device, and more particularly, to a construction method of the tidal power generation device is cheap and construction cost is made quick and simple construction.

In general, tidal power generation has been done by creating a dike with a channel that can generate seawater at the entrance to the lake. However, the deep water and high pressure is impossible to complete the construction of the full barrier, there was a problem that the efficiency of power generation and production.

However, in the conventional tidal power generation, the dike that can generate electricity is installed at the entrance of the trough, so it is not possible to completely complete the construction of the water barrier under the water tank, so that it is not able to produce enough power in the real production, It is not practically used because it cannot secure durability enough to withstand external forces due to low tide and other weather conditions.

In addition, the above-described tidal power generator has a problem that a lot of manufacturing costs.

In addition, when tidal power generation is made by creating an embankment with a channel for generating water at the entrance to the lake, there is a problem in that the water is deep and high pressure is impossible to complete the water barrier construction, and the efficiency of power generation is inferior.

Accordingly, the present invention has been made to solve the problems described above, the object of the present invention is to provide a construction method of the tidal power generation device that can be installed easily and quickly, and can be installed in a large, small size in the required place. There is.

And digging deep into the land and digging the land where there is a huge natural gutter (lake) along the tidal flat, the high tidal and low tide, or where there is a large land where the land can be dug at sea or tide It is to provide the installation and construction method of the two-way hydrological opening and closing tidal power plant to efficiently produce power generation because the dike can be installed well, so that the water leaking under the dike can be done well.

This object is achieved by the present invention, and according to one aspect of the present invention, the construction method of the tidal power generation device, by digging soil in a predetermined width and depth on the shore, a land adjacent to a river or a lake, or a tidal flat to form a groove portion A first step of performing; A second step of forming a plurality of channels in the transverse direction in the groove portion and forming a levee with a predetermined width and height; A third step of digging soil at a predetermined depth on the land surrounded by the embankment to form a water tank; A fourth step of attaching the aberration and the water gate to the waterway; A fifth step of mounting a generator interlocked with the aberration; And a sixth step of removing soil remaining on the outside of the dike to allow water to flow into the reservoir through a water channel.

In the present invention, the embankment is characterized in that formed in one (-) shape.

And the embankment is characterized in that it is formed in the shape of a base (a).

In the present invention, the embankment 40 is a d-shaped (c) shape, characterized in that the flow channel is connected to the water channel is formed on both sides.

In addition, the embankment is formed on the tidal flat, characterized in that formed in the shape of a taste (ㅁ).

In addition, the embankment is formed on the tidal flat, characterized in that formed in the shape of Di (c).
The deep water, such as the lake entrance, is a landfill type filled with soil and gravel (the lake inlet 40 embankment of FIG. 11). It is characterized in that the solder is installed in parallel (see Fig. 11) in the form of a beam consisting of a and a gate (see Fig. 9).

According to the above-described method of the present invention, it can be mounted large and small in a required place. Due to the difference between tides, the work process is not affected and can be easily constructed at any time, thereby reducing the manufacturing cost.

In addition, there are many places to install and good water barrier, so there is a high efficiency in electricity production, electrical energy can be transformed into tidal power generation.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, and like reference numerals designate like parts throughout the drawings.

1 is an overall process diagram according to an embodiment of the present invention, Figures 2, 7 is a view for explaining the process diagram.

As shown in the figure, in order to install the tidal power generation apparatus according to the present invention shown by the reference numeral 10 in the land (C) adjacent to the shore (A) or the river (B) to excavate the soil to a certain width and depth to the groove portion A first step (S10) of forming (20) is performed. That is, as shown in FIG. 2, the sea (A) and the river (B) is constructed in a place adjacent to, as shown in Figure 3 the area (B) and a distance away from the coast (A) to the area (b) The groove-shaped groove 20 is formed.

In addition, a second process S20 is performed in which the plurality of water channels 30 are formed in the groove portion 20 in the transverse direction, and the embankment 40 is formed at a predetermined width and height. (See FIG. 4).

When the dike 40 is completed as described above, a third step S30 of digging soil to a certain depth on the land C surrounding the dike 40 to form a reservoir 50 is performed. At this time, the depth of the reservoir 50 is preferably formed to the same depth as the depth in which the water channel 30 is formed. When the reservoir 50 is formed as shown in FIG. 5, the water channel 30 is exposed.

The size of the reservoir 50 is adjusted to suit the power production and the terrain, it is preferable that the 3-1 step (S31) to form a waterproof layer 80 on the lower surface. The waterproof layer 80 is made of a synthetic resin such as vinyl (see FIG. 6).

And the waterway 30 is a fourth step (S40) is equipped with a water wheel (60) that rotates according to the flow rate and the water gate 100 for opening and closing the flow of water is made, and also a generator that is linked to the aberration (60) ( The fifth step S50 of mounting 70 is performed.

As shown in FIG. 7, the aberration 60 is mounted on the waterway 30 so that a difference in water level occurs due to the high and low tide, and at this time, the water is rotated by the movement of the stored water by the opening of the water gate 100. . The generator 70 is driven in conjunction with the aberration 60, it is located above the aberration 60.

And the sixth step (S60) to remove the soil remaining on the outside of the embankment 40 to allow the water to flow into the reservoir 50 through the water channel 30 is completed as shown in FIG.

As illustrated in FIG. 8, the embankment 40 may be formed in a single (-) shape, or may be formed in a dichroic (c) shape as illustrated in FIGS. 9, 10, and 11. . When the embankment 40 is formed as a dichro, the flow channel 90 connected to the water channel 30 is further formed on both sides.

Another embodiment of the present invention will be described in detail with reference to FIGS. 10 and 11.

Another embodiment is a construction method of the tidal power generation device is installed on the terrain forming a huge lake (D) by the sea water at high tide.

As shown in the figure, the ditch (90) is made in a portion connected to the land (C) of both sides of the lake (D), the dike at the inlet of the lake (D) by the gravel and soil discharged from the ditch (90) Construct 40. As shown in FIG. 11, the generator 70 is mounted between the lake D and the adjacent water channel 90.
Deep areas, such as the lake's inlet, are filled with soil and gravel (see Lake Inlet, Figure 11), where the soil is dug up (groove 20) or shallow mud flats. It is a method of installing solder in the form of beams (see Figs. 9 and 12) of structures having several channels and gates for efficient power generation.

And yet another embodiment is shown in Figure 12, the embankment 40 is formed on the tidal flat, it forms a taste (ㅁ) shape. Therefore, tidal power generation apparatus can be easily constructed even on a tidal flat.
In another embodiment, the embankment 40 is formed on a tidal flat, forms a diagonal shape, and has many places for soldering, so that tidal power generation solder can be installed the most.
The deep water is installed in parallel with the landfill type, which is filled with soil and gravel, and in the form of a beam type consisting of several waterways and hydrologic gates that can effectively develop the ditches and grooves 20 ( See FIG. 11).
Since the entrance to the bay of the sea has a lot of deep water, it is difficult and expensive to construct, so if the solder is installed after the water barrier construction with the steel structures of Figs. The solder is slightly longer than it can, but can produce more floodgates. If the whole solder is constructed with several channels and flood gates (see Fig. 9 and Fig. 12), the power generation can be completed and the water can be quickly drained and filled quickly so that the next generation of efficient power generation can be achieved.

The tidal flats can be installed as shown in the process diagram of FIG. 1 or additionally, by constructing a water barrier using the structures of FIG. 13 and FIG. After the installation of the 뗌 can be done by hatching the structure and removing the tidal flats in the structure.

What has been described above is only one embodiment for carrying out the construction method of the tidal power generation apparatus according to the present invention, it is apparent that the present invention is not limited to the dimensions of the above-mentioned number and can be changed as necessary, As claimed in the claims of the present invention, those skilled in the art to which the present invention pertains will have the technical idea of the present invention to the extent that various changes can be made without departing from the gist of the present invention. It should be clarified that the installation is exemplified by numbers.

It is considered that tidal power is the only renewable energy that generates a large amount of electricity in a short time. Until now, tidal power has been generated by blocking tidal power generation by blocking the entrance of a simple natural lake. There are few places to install due to the disadvantages of not carrying a lot of power and efficient power generation, and the natural lake is not much. However, according to the present invention, it is possible to do well construction of the water under the soldering, and the place of installation is infinite. Especially when digging a tidal flat, water does not come out from the bottom and does not penetrate from the side, so soldering work is excellent in waterproofing and there are many places to install it. We think that usability is very good because we can change into.
In addition, it is possible to install bi-directional power generation by installing a lot of auxiliary gates, so it is very easy to use because it can produce more and produce less in the same place.

1 is an overall process diagram according to an embodiment of the present invention.

2, 3, 4, 5, 6, and 7 are diagrams for explaining process diagrams.

FIG. 8 is a diagram for describing an exemplary embodiment in which the embankment 40 is formed in a single (-) shape.

9, 10, and 11 are diagrams for describing still another embodiment.

12 is a view for explaining another embodiment.

Figure 13 and Figure 14 is a prefabricated steel structure for the cladding when installing the solder on the tidal flat.

Description of the Related Art [0002]

10: tidal power generator, 20: groove part,

30: channel, 40: dike,

50: reservoir, 60: aberration,

70: generator, 80: waterproof layer,

90: runoff, 100: sluice

Claims (12)

A first step (S10) of digging soil with a predetermined width and depth in the land (C) or the tidal flat (E) adjacent to the sea (A), the river (B), and the lake (D) to form the groove portion 20; A second step (S20) of forming a plurality of waterways (30) in the transverse direction in the groove (20), and forming the embankment (40) with a predetermined width and height; A third step (S30) of digging soil to a certain depth on land (C) or tidal flats (E) surrounded by the embankment (40) to form a reservoir (50); A fourth step (S40) of mounting the aberration (60) and the water gate (100) on the waterway (30); A fifth step (S50) of mounting a generator (70) interlocked with the aberration (60); And a sixth step (S60) for removing water remaining in the outside of the dike 40 to allow the water to flow into the water storage tank 50 through the water channel 30. Way. The method according to claim 1, wherein the embankment (40) is formed in a single (-) shape. The method of claim 1, wherein the embankment (40) is formed in the shape of a base (a) shape. The construction of the tidal power generation apparatus according to claim 1, wherein the dike 40 has a diagonal shape and additionally formed flow paths 90 connected to the channel 30 on both sides thereof. Way. The method of claim 1, wherein the embankment (40) is formed in the shape of a taste (ㅁ) on the tidal flat. delete The method of claim 1, wherein the embankment (40) is a prefabricated structure on the shallow mud flat in the form of a ditch (C) after the water barrier construction method of the tidal power generator. delete delete delete According to claim 1, wherein the ditch (90) is made in a portion connected to the land (C) on both sides of the lake (D) and embedded in the deep lake (D) inlet with gravel and soil discharged from the ditch (90) A tidal power generation, characterized in that the construction of a dike (40) in the form and to build a beam-type solder (40), which is a structure consisting of a waterway and a sluice in parallel in order to efficiently develop the groove portion 20 dug out Construction method of the device. The method of claim 1, wherein the construction of the tidal power generator in the shallow water of the tidal flat using a prefabricated steel structure to prevent water from entering during the construction process, and to dismantle it after construction of the tidal power generator Construction method of tidal power generator characterized in that.

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