KR101290999B1 - Gate structure for tidal power plant - Google Patents

Abstract

PURPOSE: A water gate structure for a tidal power plant is provided to prevent seawater from flowing into a headrace between the sea and a lake and to smoothly discharge reservoir water. CONSTITUTION: A water gate structure for a tidal power plant comprises an underwater rock part (10), a base layer part (20), a structure (30), a water gate, and a stop log. The underwater rock part comprises a structure installation part (11), apron parts (12a,12b), and slope parts (13a,13b) to be successively formed into an uneven shape. The structure installation part is formed between a lake and the sea. The apron parts are separately formed with flat planes towards the lake and the sea. A slope part is formed with an inclined surface of 10-15 degrees from an apron part to the bottom surface of the sea or the lake.

Description

Gate Structure for Tidal Power Plant

The present invention relates to a hydrological structure for tidal power plants, and more particularly, to smoothly block the flow of seawater in the waterway, which is the purpose of the hydrology between the seawater and the lake, and to facilitate the discharge of the stored water. The present invention relates to a hydrological structure for tidal power plants that is not easily damaged by repeated installation of a hydro gate or stoplog.

Recently, environmental problems have emerged as a global problem, and liquefaction and gasification of coal, petroleum, wind power, hydropower, fuel cells, coal, marine energy, waste energy and other geothermal and hydrogen For example, alternative fuels are being mentioned as fluid fuels in which coal-based materials are mixed. In particular, attention is focused on the discovery of alternative energy sources through the development of natural energy such as solar, tidal and wind power.

Tidal power generation is the principle of using the difference between the sea level and the lake due to the difference between tides. As is the case, the offshore water level, which is centered on the dike, changes several meters up and down over time, while the water level in the lake must be kept below a certain management level to avoid flooding or flooding to nearby areas.

The hydrologic structure included in the tidal power plant system together with the aberration structure can achieve the flood level control function to discharge fresh water whose water level rises rapidly due to the heavy rain and the like during the inflow and discharge of seawater used for power generation. It is composed of various forms to make it possible.

In hydrologic structures, the most common form is to open or close waterways by raising or lowering vertically. One of the most difficult problems in such a hydrology is a salt corrosion problem that occurs when the water contact with seawater, and various malfunctions occur due to corrosion, in which case, it is difficult to maintain the hydrology. Particularly, due to the characteristics of tidal power generation, the hydrological gate is not always in the seawater but is exposed to the atmosphere in seawater twice a day according to the tidal cycle, and the corrosion is promoted. The corrosion progresses rapidly while paint wear occurs.

In general, the hydrological gates of hydrological structures are often installed so that the functions are limited to the control of the distribution of seawater. Therefore, the roads or auxiliary facilities for the management of tidal power plants are poor, making it difficult for management personnel to reside and long-term relationships with neighbors. There was a downside.

As a background technology of the present invention, there is a patent registration No. 0727852 "Sluice structure for tidal power plant" (Patent Document 1). In the background art, as shown in Fig. 18, "a hydrological structure installed through the hydrologic structure wing wall and the connecting structure between the lake and the seawater, the hydrologic structure is located on the sea floor and has a flat plate-like base portion to form a foundation. (1) and stoplog support channels 13 are installed vertically at both ends of the upper portion of the base portion 1, respectively, so that the stoplog 11 at the seawater side and the stop at the lake side L are necessary. The log 10 is installed, respectively, and is installed vertically through the sluice support channel 14 installed in front of the stop log support channel 13 on the sea water (W) side and the sluice gate 12 to open and close the flow of sea water and A cylindrical hollow structure for inducing the flow of seawater to the upper portion of the base portion 1 is formed, the upper portion of the lake (L) side of the raceway 20 is formed of a hemispherical curved portion (A), Hydrologic winch installed to the upper seawater (W) side of the raceway 20 The upper portion of the support channel 14 is provided with a seawater side stoplog crane 40 for the stoplog lifting and lowering traction and a hydrologic winch 31 for the lifting and lowering traction of the sluice 12, the upper part of the raceway 20 Tidal power generation, characterized in that the lake side stop log crane 41 and the waterway 20, the primary access road 32 and the secondary access road 33 of the multi-layer structure is installed on the lake (L) side. Avail hydrological structure. "

However, the background art is configured to have the same height as the seabed rock portion, but the flow of seawater can be blocked, but there is a problem in that the discharge of the stored water on the lake side is not smooth.

In addition, by combining and forming in the shape of 1 unit 1 block of the form in which both the intermediate wall is cut on the basis of one channel, the concrete curing period is long, the process is delayed, the heat of hydration is generated by the increase of the concrete volume There was a problem, and in the case of the support channel in which the sluice and the stoplog were installed, there was a problem such as being easily broken by the repeated installation of the sluice and the stoplog.

Patent Registration No. 0727852 "Sluice structure for tidal power plant"

The present invention is to solve the above problems, to form a slope and apron portion in the shape of the seabed rock portion concave to smoothly block the flow of seawater flow in the waterway, which is the purpose of the hydrology between the seawater and the lake Of course, it is possible to facilitate the discharge of the stored water, and also by forming two units in one block, it is possible to significantly shorten the air, while reducing the volume of concrete to suppress the generation of hydration heat, It is an object of the present invention to provide a sluice structure for tidal power plant that is not easily damaged by repeated installation of sluice or stoplog by forming a support part formed of non-contraction concrete in the support channel on which the stoplog is installed.

The present invention is a hydrological structure installed between the lake and the sea water, the structure installation portion formed between the lake and the sea water, the apron portion formed in each of the flat surface in the lake and sea water direction from the structure installation portion, and the apron A seabed rock portion which is formed in an inclined portion formed in an inclined portion that forms a slope of 10 to 15 ° from the portion to the sea bottom or the lake bottom; A base layer portion formed by forming a structure installation portion of the seabed rock portion as a ground portion to form a foundation; It penetrates to connect the seawater and the lake, and is formed continuously with an intermediate wall. The upper part of the lake side is formed with a hemispherical curved part, and the upper end of the seawater side is formed of a hydrologic support channel, a stoplog support channel, At the upper end of the lake side, a stop log support channel is formed vertically, and the guide groove is vertically formed on the intermediate wall facing both ends of the raceway, and the surface and the bottom surface exposed to the outside of the guide groove are made of non-condensed concrete. Each part is formed and formed by forming a multi-layered primary access road and a secondary access road on the upper part of the raceway, and constitute one structure block in a shape in which an intermediate wall is cut every two raceways. A structure installed on an upper portion of the base layer so as to be continuously installed; A water gate that is pulled up and down by a hydrologic winch configured at an upper portion of a sea side of the structure, and is vertically installed through a hydrologic support channel to open and close the flow of seawater; It is to provide a hydrological structure for tidal power plant, characterized in that consisting of; stoplog is installed through the stoplog support channel as a crane installed on the top of both ends of the sea and the lake side of the structure.

In addition, the base portion is to provide a sluice structure for tidal power plant, characterized in that the lower portion of the lake and sea water side ends protrude downward to form a horizontal shear key.

In addition, it is to provide a hydrologic structure for tidal power plant, characterized in that the scour prevention portion formed of a bare concrete on the side end of the lake and sea water side of the base portion.

In addition, the scour prevention portion is to provide a hydrological structure for tidal power plant, characterized in that the upper portion is configured in a wide and narrow form.

 In addition, the intermediate wall located in the central portion of the structure block is a hollow portion is formed therein, the hollow portion is to provide a hydrological structure for tidal power plant, characterized in that the filling is configured.

In addition, the support portion is to provide a hydrological structure for tidal power plant, characterized in that the reinforcement is embedded so that the surface is exposed to the outside.

In addition, the sluice guide structure is formed in front of the seawater side stoplog support channel, the sluice is composed of a 1,2-stage sluice to open and close the flow of seawater through the sluice guide structure, both sides of the second stage sluice of the sluice Dogging arm holders respectively installed in the, and the salvage to the maximum lifting height after lifting the water gate to each of the dogging arms mounted on the docking arm cradle, and the water gate is installed on the inner upper side of the sluice guide structure, the water gate located at the maximum lifting height again When descending, the dogging arm is seated and mounts the dogging arm base beam which mounts the second stage hydrology, and the first stage hydrology is separated from the second stage hydrology by dismantling of the bolt, and the hydrologic support is installed on the top surface of the hydrologic guide structure. Remove the support frame, the first stage hydrobase mounted on the upper surface of the hydrobase support frame and the separated first stage hydrogate, and a part of the hydrobase support frame. By reassembling the demolition part after the salvage of the second stage hydrogate to provide a hydrologic structure for tidal power plant, characterized in that it comprises a second stage hydrobase mounted on the support frame.

In addition, to provide a sluice structure for tidal power plant, characterized in that the maintenance lug bracket for fixing the sluice support frame on the top of the sluice guide structure is further installed.

The hydrological structure for tidal power plant according to the present invention allows the seabed rock portion to form a slanted portion and an apron portion in a concave shape to smoothly block the flow of seawater in the raceway, which is the inherent purpose of the floodgate between the seawater and the lake. To facilitate the discharge of the stored water.

In addition, by forming two units in one block, it is possible to significantly shorten the air, but also to reduce the volume of concrete, thereby suppressing the generation of hydration heat, and formed of non-condensed concrete in the support channel in which the sluice or stoplog is installed. By constructing the support, there is an effect that it is not easily damaged by repeated installation of the water gate or stoplog.

In addition, the handle-type gear drive is removed to reduce the hydrologic removal facility cost, manpower operation is unnecessary, the need for handle operation is eliminated, eliminating the inconvenience that the operator enters into the guide structure.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention. It should not be construed as limited.
1 is a plan view schematically illustrating an overall tidal power plant system in which the hydrologic structure of the present invention is installed.
Figure 2 is a side cross-sectional view showing a cut side of the hydrological structure for tidal power plant of the present invention.
3 is an enlarged view of a structure part of the hydrologic structure for tidal power plant of the present invention.
4 is an enlarged view of the base portion of the present invention.
5A is a top cross-sectional view of the structure block 30a of the present invention.
FIG. 5C is an enlarged view of a part '' of FIG. 5A.
FIG. 5D is a view illustrating a state in which the stoplog 60 is coupled to FIG. 5C.
Figure 6 is a normal operating state of the water gate in FIG.
7 is a state diagram in which the seawater side stoplog is installed in FIG. 6.
8 is a state diagram in which the dogging arm is mounted on the dogging arm holder after the water gate has risen to the maximum height.
FIG. 9 is a state diagram in which the dogging arm is seated on the dogging arm base beam because the floodgate is lowered.
10 is a state diagram in which the first stage hydrology is separated and lifted from the second stage hydrology.
11 is a state diagram of assembling the first stage hydrobase to the lower side of the first stage hydrograph.
12 is a state diagram in which the first stage hydrology is mounted on the first stage hydrobase.
FIG. 13 is a state diagram in which the first stage floodgate is moved to one side of the floodgate support frame. FIG.
14 is a state in which a part of the hydrobase support frame is removed.
15 is a state diagram in which the dogging arm is removed after lifting the second stage floodgate.
FIG. 16 is a state diagram in which a part of the dismantled hydrobase support frame is reassembled.
17 is a state diagram in which the second stage hydrology is mounted on the second stage hydrobase.
18 is a partial cross-sectional view showing a part of the conventional hydrological structure for tidal power plant.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described in detail below with reference to the embodiments shown in the accompanying drawings, but the present invention is not limited thereto.

 Hereinafter, the technical structure of the present invention will be described in detail with reference to the preferred embodiments.

1 is a plan view schematically illustrating an overall tidal power plant system in which the hydrologic structure of the present invention is installed.

As shown in Figure 1, the hydrological structure (2) of the present invention, while the tidal power plant between the lake (L) and the seawater (W) in the tidal power plant construction site where the difference between tides is suitable, the surrounding park site A water structure (1), a water gate structure (2), and a connecting structure (3) formed between a plurality of units between the land and the land, and the sea tourism function, access road function, and power plant function coexist together. It is a hydrologic structure for a friendly tidal power plant. In the drawings, reference numeral 4 denotes an aberration structure wing wall 4 connected to the outermost aberration structure 1, and reference numeral 5 illustrates a hydrological structure wing wall 5 connected to the outermost hydrological structure 2. .

Figure 2 is a side cross-sectional view showing a cut side of the hydrological structure for tidal power plant of the present invention.

As shown in FIG. 2, the hydrologic structure for tidal power plant of the present invention is constructed by using the seabed rock portion 10 and the seabed rock portion 10 as a ground portion to form a foundation, a base portion 20, and a base portion 20. It consists of a structure 30 formed on the top.

The seabed rock portion 10 is formed by processing the seabed rock, and the structure installation portion 11, the apron portion 12a, 12b and the inclined portion 13a, 13b is formed in a recessed shape.

The structure installation unit 11 is formed between the lake (L) side and the seawater (W) side, the structure installation unit 11 is formed with a base portion 20, the structure above the base portion 20 30 is formed. Since the structure installation part 11 is a part in which the base part 20 is formed, it is formed in the same size as the base part part 20 is installed.

In the structure installation part 11, flat apron portions 12a and 12b are formed in both directions of the lake L side and the seawater W side, and from the apron portions 12a and 12b to the bottom of the seawater or the bottom of the lake. Inclined portions 13a and 13b having an inclined surface of 10 to 15 ° are formed in sequence.

That is, by forming the seabed rock, the structure installation portion 11, the apron portion 12a (12b) and the inclined portion (13a) 13b is formed in a recessed form. Thus, in the concave form, since the sea level rises with time and changes by several meters, even when the sea level W reaches the minimum sea level, the water level in the lake will not be flooded or flooded from nearby areas. This is to keep below a certain management level to avoid.

Looking at the seabed rock portion 10 from the sea water (W) side, the apron portion 12b and the slope to the lake (L) side through the inclined surface 13a, apron portion 12a, the structure installation portion 11 through the sea bottom surface The part 13b is comprised.

When the water stored on the lake L side is discharged to the seawater W side through the hydrologic structure, the seawater structure is passed through the apron portion 12b through the apron portion 12b on the inclined surface 13b of the lake L side. W) is discharged to the side.

The apron portion 12a of the sea water (W) side is formed at the same height as the apron portion (12b) of the lake (L) side, so that the water discharged from the lake (L) side can be easily discharged, the hydrologic structure It must be maintained at a constant length so that the water discharged through it can move at a constant speed. Preferably, the sea water (W) side apron portion 12a is formed to have a length of 3 to 4 times the length of the lake (L) side apron portion 12b.

The inclined portion 13a of the seawater W is inclined to induce water stored on the lake L side to be discharged more easily in the seawater W direction from the apron portion 12a on the seawater W side. .

The inclined portions 13a and 13b form an inclined surface of 10 to 15 degrees. This is to induce a constant and effective speed of the water discharged from the lake (L) side to the sea water (W) side, when formed below 10 ° apron portion (12a) (12b) and in the seabed rock portion 10 and Since the formation range of the inclined portions 13a and 13b is wide, the construction cost is excessively expended, and when formed at 15 ° or more, the speed of seawater moving along the inclined surface 13a due to the difference between tides is not constant. In addition, this is because it is not discharged smoothly to the sea water (W) side.

Figure 3 is an enlarged view of the structure portion of the hydrological structure for tidal power plant of the present invention, Figure 4 is an enlarged view of the base portion of the present invention.

As shown in FIG. 3, the hydrologic structure of the present invention includes a base part 20 and a structure 30 formed on the base part 20.

As shown in FIG. 4, the base portion 20 is constructed by using the structure installation portion 11 of the seabed rock portion 10 as a ground portion to form a foundation.

Displacement between the blocks of the upper part 30 of the base part 20 occurs in the horizontal and vertical directions, and in order to control such displacement, the base part 20 forms a shear key at the lower part of the base part 20 and the bottom rock part 10. Strengthen your support.

At this time, the lower portion of both ends of the lake (L) and the sea water (W) side protrudes downward to form a horizontal shear key 24, both sides of the base portion 20 can act as a shear key.

In addition, the side end portions of the lake L and the seawater W side of the base portion 20 may be configured so that the scour prevention portion 23 formed of bare concrete is formed.

As described above, forming the scour prevention portion 23 may cause the earth and sand to scour the base portion 20 due to the difference between tides, and at this time, the lake L and the sea water of the base portion 20 which is the portion to be scoured. The scour prevention part 23 is formed in the side end part of the W) side.

In addition, the scour prevention part 23 may be configured to have a wide upper portion and narrow lower portion that the scour occurs more severely.

The structure 30 is formed on the basis of the base portion 20.

The structure 30 is installed between the lake L and the seawater W, and has a shape that blocks the lake L and the seawater W.

The raceway 31 penetrates to connect the seawater W and the lake L in the upper structure 30 of the base portion 20 and is continuously formed with the intermediate walls 37a and 37b, and the base portion 20 Induces a flow of seawater to penetrate the structure 30 of the upper portion of the).

The raceway 31 is formed of a hemispherical curved portion A on the upper side of the lake L to improve economic efficiency, workability, and maintainability, and vortex generation and resistance due to a sharp decrease in the width of the raceway 31. To minimize.

At the upper ends of the intermediate walls 37a and 37b on the seawater W side of the raceway 31, stoplog support channels 50a and hydrological support channels 50c are formed in the vertical direction from the outside, respectively, and the raceway 31 is formed. The stop log support channels 50a and 50b are vertically formed at the upper ends of the intermediate walls 37a and 37b on the lake L side.

The primary access road 32 and the secondary access road 33 having a multi-layer structure are formed on the raceway 31. A soil layer 32a may be formed at the lower portion of the primary access road 32 to secure stability by increasing the weight of the hydrologic structure.

The water gate 40 is pulled up and down by the water gate winch 150 configured at the top of the sea water (W) side of the structure 30, is installed vertically through the water support channel 50c to open and close the flow of sea water do.

The stop log 60 is installed through the stop log support channels 50a and 50b as cranes 70a and 70b which are installed at the upper ends of the seawater (W) side and the lake (L) side of the structure 30. In order to facilitate the maintenance of the water gate 40 and the raceway 31, it is configured to block the raceway 31. The stoplog 60 is towed to the cranes 70a and 70b, if necessary, and is installed through the stoplog support channels 50a and 50b formed at both ends of the raceway 31 so that the seawater flows from the raceway 31. It is configured to shut off and drain the water inside the raceway 31 to perform the necessary work.

The stoplog 60 may be installed by storing the stoplog underground storage installed on each of the seawater (W) side and the lake (L) side of the hydrological structure wing wall (5) and the connecting structure (3).

The present invention is a structure 30 composed of the base portion 20, the raceway 31 of the above-described structure, the primary access road 32 and the secondary access road 33 of the multi-layer structure is a single structure as a whole Rather, it consists of a combination of a plurality of structure blocks 30a of the same shape.

Each structure block 30a is composed of a base portion 20, a raceway 31, a first access road 32 and a second access road 33 having a multi-layer structure.

Conventionally, there was a case in which both intermediate walls were configured in the shape of 1 unit 1 block in the form of cuts based on one raceway, but there was a problem that the concrete curing period was long, the process was delayed, and the concrete volume was increased. There was also a problem of high heat of hydration.

FIG. 5A is a plan sectional view of the structure block 30a of the present invention, and FIG. 5B is a plan sectional view showing the combined state of FIG. 5A.

As shown in FIG. 5A, the structure block 30a is formed by blocking one unit into two blocks in which the intermediate wall 37a is cut out every two raceways 31, and as shown in FIG. 5B, two blocks are formed. Since the structure block 30a, which unitizes one unit, can be constructed in succession by constructing two units at the same time, it is possible to shorten the air, and the intermediate wall 37b located at the center of the structure block 30a has a hollow inside. By forming the portion 38 can be reduced in the concrete volume can suppress the generation of hydration heat.

The intermediate wall 37b located at the center of the structure block 30a forms a hollow portion 38 at an excessive portion other than the effective cross section, and afterwards, the inner wall 39b is filled in water to secure stability and economy against buoyancy. You can do it.

The stoplog support channels 50a and 50b and the sluice support channel 50c have the same shape, and the guide grooves 51 are vertically formed on the intermediate wall 37a facing both ends of the raceway 31. A support portion 52 made of non-condensed concrete is formed on the surface and the bottom surface exposed to the outside.

The guide groove 51 into which the sluice 40 or the stop log 60 is fitted and the bottom surface where the lower end abuts, that is, the exposed portion 52 is formed with a support 52 made of non-condensed concrete.

Non-condensed concrete forming the support portion 52 has no volume change, excellent corrosion resistance, excellent adhesion to the mother, impact resistance and vibration resistance, stoplog that the water gate 40 or stoplog 60 is repeatedly installed The strength of the support channels 50a and 50b and the hydrologic support channel 50c can be enhanced.

In addition, as shown in Figure 5c, the support portion 52 is to be configured so that the reinforcing steel 53 is embedded so that the surface is exposed to the outside, the damage of the guide groove 51 by repeated installation and sea water or lake water pressure Damage due to the impact caused by the stop log 60 can be minimized.

In FIG. 5D, the structures of the water gate 40 and the stop log 60 are the same, and only the stop log 60 is illustrated and described.

As shown in FIG. 5D, guide rollers 60a are formed at both ends of the sluice 40 or the stop log 60, and both ends of the sluice 40 or the stop log 60 of the support 52. On the opposite surface, the guide 55 may be formed to protrude.

The guide 55 is coupled to one side of the guide hardware 53a having an H-shaped cross section, and the guide 55 is embedded at a predetermined interval in the support 52 so that the guide 55 is guide roller 60a. It acts as a guide so that it is inserted into and moved.

That is, the guide portion 60 is formed at the center of the guide roller 60a formed at both ends of the sluice 40 and the stop log 60 so as to fit the guide 55 protruding outward from the center of the guide hardware 53a. This allows for easy installation and removal without being dislodged against hydraulic pressure.

In addition, support protrusions 60b are coupled to both sides of the end of the sluice 40 or the stoplog 60 of the support 52, and the surfaces facing the surfaces of the support 52 are respectively exposed at regular intervals such that the surface is exposed. The reinforcing steels 53b and 53c having a cross-sectional shape are embedded, so that the support protrusions 60b are supported by the reinforcing steels 53b and 53c, thereby repeatedly installing the water gate 40 or the stoplog 60 and Damage to the guide groove 51 can be minimized by hydraulic pressure.

At this time, one side of the opposite side in contact with the sea water or the lake at the end of the water gate 40 or stoplog 60 of the support 52, the auxiliary projection 60c is coupled to the side of the support protrusion 60b, the auxiliary protrusion The surface exposed to the outside of the reinforcing steel 53c in contact with the 60c may be configured to extend to the corner portion of the support 52.

That is, when the water pressure of the sea water and the lake side acts on the water gate 40 or the stop log 60, the water gate 40 or the stop log 60 is pushed inward by the water pressure, whereby the support 52 There was a problem of being damaged.

Accordingly, the auxiliary projection 60c is formed on one side of the side facing the water pressure, that is, on the opposite side of the water gate 40 or the end of the stop log 60 of the support portion 52 and the lake, and the auxiliary protrusion ( In order for the 60c to be supported without damaging the support 52, the surface exposed to the outside of the reinforcement 53c that is in contact with the auxiliary protrusion 60c is configured to extend to the edge of the support 52. .

In addition, the guide hardware (53a) and reinforcing steel (53b, 53c) constitutes a shear anchor 54 for the coupling of the structure block (30a) and the support 52, the reinforcement ( 53) can be combined.

As shown in FIG. 3, the sluice guide structure 130 is formed at the front of the seawater side stoplog support channel 50a, and the sluice gate is composed of 1,2-stage sluices 41 and 42 that open and close the flow of seawater through the sluice guide structure 130. 40 is installed, the hydrological winch 150 for raising and lowering the water gate 40 is installed on the top of the water guide structure 130. The hydrologic winch 150 lifts the hydrologic 40 through the sheave pulley P.

On both sides of the second stage sluice 42 of the sluice 40, each of the dogging arm holder 44 is provided as shown in FIG. The dogging arm holder 44 is provided on the lower side of the uppermost hydrological roller R of the two-stage hydrological 42. The dogging arm holder 44 has a top surface in a plate shape and has a structure reinforced by ribs. The dogging arm holder 44 has a size that is at least smaller than the cross-sectional area of the guide roller passage through which the sluice roller R is moved, and has rigidity that can withstand the weight of the dogging arm 160 to be described later. .

As shown in FIG. 8, the water gate 40 is provided with a dogging arm 160 mounted on the dogging arm holder 44 after lifting the maximum lifting height. The dogging arm 160 has a constant width and length. The width of the dogging arm 160 may be equal to or slightly larger than the width of the sluice roller R, and the length thereof may be equal to or greater than the distance between the installation positions of the dogging arm base beams 132 and 132 which are separated from each other as shown in FIG. 9. It may be configured slightly longer. Since the dogging arm 160 serves to temporarily mount the second stage sluice 42, the dogging arm 160 is made of steel that can sufficiently withstand the weight of the second stage sluice 42. The dogging arm 160 has chain connection holes 161 at both ends. Accordingly, the dogging arm 160 may be stably supported by the second stage water gate 42 through the chain C to prevent sagging to either side after being placed on the dogging arm holder 44.

The dogging arm base beams 132 and 132 are installed on the upper side of the sluice guide structure 130. As shown in FIG. 9, the dogging arm base beams 132 and 132 exhibit the supporting force necessary to mount the dogging arm 160 when the water gate 40 located at the maximum lifting height descends again to mount the second stage water gate 42. . In this embodiment, the dogging arm base beams 132 and 132 are made of steel. The width of the dogging arm base beams 132 and 132 is formed to be relatively larger than the width of the dogging arm 160. Therefore, as shown in FIG. 9, when the two-stage water gate 42 descends and is supported by the dogging arm base beams 132 and 132 through the dogging arm 160, the impact received by the hydrological guide structure 130 made of concrete is the dogging arm base. Since the beams 132 and 132 are directly transmitted, damage or breakage of the hydroguide structure 130 is prevented.

As shown in FIG. 11, the first stage hydrology 41 is separated from the second stage hydrology 42 by disassembly of the bolt, and a hydrologic support support frame 170 is installed on the top surface of the hydrology guide structure 130. The hydrobase support frame 170 is constructed by bolting a plurality of unit support frames having sliding rails.

11 to 17 and the first stage hydro-mount bracket 180 for mounting the first stage hydrology 41 is mounted on the upper surface of the hydrolurgical support frame 170 and separated, and part of the hydrological support frame 170 After dismantling and reassembling the demolition part of the second stage sluice 42 again, the second stage sluice holder 182 mounted on the sluice holder supporting frame 170 is provided.

On the other hand, at the top of the sluice guide structure 130, a maintenance lug bracket 138 for fixing the sluice support frame 170 may be further installed.

Referring to the operational state of the water gate 40 of the present invention in detail.

During the normal operation of the gate, the gate 40 is operated by blocking or opening the raceway 31 while lifting up and down in the gate guide structure 130. In this state, if it is necessary to remove the watermark for maintenance, the following occurs.

First, as shown in FIG. 7, a stop log 60 is installed on the hydrological seawater W side and the lake L side to block seawater flow. The stop log 60 is provided in the support channel 50a on the sea water W side and the support channel 50b on the lake L side.

Next, as shown in FIG. 8, the dogging arm holder 44 fixed to the second stage sluice 42 of the sluice 40 reaches the upper position of the sluice guide structure 130 so that the sluice 40 has the maximum lifting height. It lifts through the winch 150. At this time, the sluice 40 is made of the lifting through the sheave pulley (P) connected to the upper end. Thereafter, the dogging arm holder 44 is mounted on the dogging arm 160, respectively. At this time, in order to prevent sagging of the dogging arm 160 placed on the docking arm holder 44, it is preferable to fix with a chain (C) or the like.

Next, as illustrated in FIG. 9, the water gate 40 is lowered to seat the dogging arm 160 on the dogging arm base beams 132 and 132 installed in the upper side of the water guide structure 130. At this time, the descending of the water gate 40 is made until the water-side guide roller (R) is mounted on the upper surface of the dogging arm (160).

Next, as shown in FIG. 10, the bolt (not shown) connecting the second stage gate 42 and the first stage gate 41 is dismantled, and the first stage gate 41 is lifted up to the maximum lifting height. The water gate 41 and the second stage water gate 42 are separated.

Next, assembling and installing the sluice support frame 170 on the top surface of the sluice guide structure 130 as shown in FIG. After the installation of the hydrostatic support frame 170, the hydrostatic support frame 170 is fixed to the lug bracket 138 for maintenance of the hydrological guide structure 130 side. At this time, the road-side railing interfered with the installation of the hydrologic support frame 170 may be removed.

Then, as shown in FIG. 12, the first stage hydrobase 180 is installed on the upper surface of the hydrologic support base 170, and the first stage hydrobase 41 is slightly lowered and mounted on the first stage hydrobase 180. And remove the sheave pulley (P). Thereafter, the chain block 100 is connected to the first stage hydrobase 180 as shown in FIG. 13, and then the first stage hydrobase 180 is moved to one side of the hydrobase support frame 170.

Next, as shown in FIG. 14, after removing a part of the hydrobase holder supporting frame 170, which is an interference portion that is positioned before the first stage hydrobase 180 is moved, the sheave pulley P is replaced with the second stage hydrogate 42. Connect to the top of the) and lift the second stage sluice 42 as shown in FIG. Here, after removing the dogging arm 160 lifted together when the second stage gate 42 is lifted, the second stage gate 42 is re-lifted to the maximum lifting height.

Then, after reassembling the demolished part to the hydrobase holder support frame 170 as shown in FIG. 16, the second stage hydrobase holder 182 is installed to the hydrobase holder support frame 170 as shown in FIG. 17. Thereafter, the second stage floodgate 42 is lowered and placed on the second stage floodgate 182.

In this way, the sluice gate 40 is separated into the first stage sluice 41 and the second stage sluice 42 and completely removed from the sluice guide structure 130.

The sluice structure for tidal power plant of the present invention configured as described above is to form a slope and apron in the shape of the seabed rock part to smoothly block the flow of seawater flow in the waterway which is the purpose of sluice between the seawater and the lake. Of course, it is possible to facilitate the discharge of the stored water, and also by forming two units in one block, it is possible to significantly shorten the air, while reducing the concrete volume to suppress the generation of hydration heat, By constructing the support portion formed of non-concrete concrete in the support channel on which the stoplog is installed, there is an effect that it is not easily damaged by repeated installation of the water gate or the stoplog.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art in light of the above teachings. will be. The invention is not limited by these variations and modifications, but is limited only by the claims appended hereto.

10: seabed rock part
11: structure installation
12a, 12b: apron part
13a, 13b: inclined portion
20: base part
23: scour prevention part
24: horizontal shear key
30: Structure
31: raceway
37a, 37b: intermediate wall
40: sluice
41: First Stage Sluice
42: Second Stage Sluice
44: dogging arm holder
50a, 50b: Stoplog support channel
50c: hydrologic support channel
51: Guide groove
52: support
70a, 70b: crane
150: hydrologic winch
160: dogging arm
170: hydrobase frame
180: first stage hydrobase
182: 2nd stage hydrobase
W: Seawater
L: Lake

Claims (6)

As a hydrological structure installed between the lake (L) and sea water (W),
The structure installation part 11 formed between the lake L and the seawater W, and the apron part 12a which respectively formed the flat surface in the direction of the lake L and the seawater W from the structure installation part 11, respectively. 12b and the seabed rock part which is formed in the form of the recessed part 13a, 13b which formed the inclined surface of 10-15 degrees from the apron part 12a, 12b to the sea bottom or the lake bottom in order. 10);
It is constructed with the structure installation part 11 of the seabed rock part 10 as the ground part, and forms a foundation. The side ends of the lake L and the seawater W are formed of bare concrete and have a wide top and a narrow bottom. Scour prevention portion 23 is formed, the base portion 20, the lower portion of the lake (L) and the sea water (W) side end protrudes to the bottom to form a horizontal shear key 24;
It penetrates to connect the sea water (W) and the lake (L) and is formed continuously with the intermediate walls (37a, 37b) and the upper portion of the lake (L) side is a hemispherical curved portion (A), the raceway 31 is formed, The stoplog support channel 50b formed vertically from the outside at the upper end of the sea water (W), the hydrologic support channel 50c, and the stoplog support channel 50b formed vertically at the upper end of the lake (L) side, respectively. The guide groove 51 is vertically formed on the intermediate wall 37a facing the opposite ends of the raceway 31, and the support and the bottom surface of the guide groove 51 exposed to the outside are made of non-condensed concrete. 52 are formed respectively, and the first access road 32 and the second access road 33 having a multi-layer structure are formed on the upper portion of the raceway 31, and the intermediate wall is formed every two raceways 31. The structure block 30a is formed by cutting the shape 37a, and the structure block 30a is opened. A structure 30 installed on an upper portion of the base layer 20 so as to be installed and formed continuously;
It is pulled up and down by the hydrologic winch 150 configured in the upper portion of the seawater (W) side of the structure 30, is installed vertically through the hydrologic support channel (50c) and the water gate 40 to open and close the flow of seawater and ;
Stop logs 60 installed through the stop log support channels 50a and 50b as cranes 70a and 70b installed at the upper ends of the seawater (W) side and the lake (L) side of the structure (30). Sluice structure for tidal power plant, characterized in that consisting of. The method according to claim 1,
The intermediate wall 37b located at the center of the structure block 30a has a hollow portion 38 formed therein, and the hollow portion 38 is a hydrologic structure for tidal power plant, characterized in that a filling 39 is formed. . The method according to claim 1 or 2,
On one side of the opposite side of the water contact 40 or the end of the stop log 60 of the support portion 52 in contact with the sea water or the lake, the auxiliary protrusion 60c is coupled to the side of the support protrusion 60b, and the auxiliary protrusion 60c A hydrological structure for tidal power plant, characterized in that the surface exposed to the outside of the reinforcing steel (53c) to be interviewed to extend to the edge portion of the support (52). The method according to claim 3,
The joint part 36 of the intermediate wall 37a, 37a which is interviewed between the structure block 30a and the structure block 30a has a copper plate, a continuous concave-convex shape and a convex U-shaped cross-section with a central portion, and a c-shaped concave shape on both sides. An index plate 80 integrally formed to have a cross section is formed at each side of the sea water (W) and the lake (L), and a central portion of the index plate 80 is located at the joint of the structure block 30a and the structure block 30a. A hydrological structure for tidal power plants, characterized in that both sides are embedded in the intermediate wall (37a) (37a) and the openings on both sides are embedded so as to face the sea or lake side. The method according to claim 1 or 4,
The sluice guide structure 130 is formed in front of the sea water (W) stoplog support channel 50a, and the sluice 40 opens and closes the first and second stage gates to open and close the flow of seawater through the sluice guide structure 130. Composed of 41, 42,
Dogging arm holders 44 installed on both sides of the second stage gate 42 of the sluice 40 and the dogging arm mounted on the dogging arm holder 44 after lifting the sluice 40 to the maximum lifting height, respectively. The 160 and the guiding arm 160 is installed on the inner upper side of the sluice guide structure 130, and when the sluice 40 positioned at the maximum lifting height is lowered again, the second stage sluice 42 The first stage hydrology 41 is separated from the second stage hydrology 42 by the dismantling of the bolt after the dogging arm base beam 132 for mounting) and the hydrologic support base installed on the upper surface of the hydrologic guide structure 130. A first stage hydrobase 180 to mount the support frame 170, the first stage hydrogate 41 is mounted on the upper surface of the hydrolurgical support frame 170 and separated, and part of the hydrologic support base 170 To dismantle the second stage sluice 42 by lifting the second stage and then reassemble the dismantled part and then mounted on the sluice support frame 170 Sluice structure for tidal power plant, characterized in that it comprises a sluice base (182). The method according to claim 5,
Sluice structure for tidal power plant, characterized in that the maintenance lug bracket (138) for fixing the sluice support frame (170) on the top of the sluice guide structure (130) is further installed.

Images