KR20150069886A - Mooring system for floating photovoltaic power plant structure - Google Patents

Abstract

The present invention relates to a device to moor a floating solar power generation structure, capable of fixing a plurality of floating solar power generation structures, in which a plurality of solar cell modules are placed, on a fixed block on the surface of the water. To fix the movement of the floating solar power generation structures, the device includes a rope connecting an end of the floating solar power generation structures with the fixed block on the surface of the water, but a distance change compensating member is installed on the rope to compensate for a change of a linear distance between the fixed block and the end of the structures according to the movement of the structures moving up and down depending on the water level. According to the present invention, even when the water level becomes low in the drought, the rope is able to maintain tension by pulling the structures through the distance change compensating member. Moreover, as the rope maintains constant tension, the movement or rotation of the structures is prevented as much as possible by external force such as water flow or wind, and therefore, the efficiency of power generation is improved. The device is able to be used for a long time as the rope is hardly cut.

Description

{Mooring system for floating photovoltaic power plant structure}

The present invention relates to a mooring system for a floating photovoltaic power generation floating structure, and more particularly, it relates to a mooring system for a floating photovoltaic power generation floating structure, and more particularly, The present invention relates to a mooring device for a floating solar photovoltaic floating structure capable of being installed in a building.

In general, solar cells convert the sun's light energy into electrical energy. The minimum unit for generating electricity using the photoelectric effect is called a cell, and a plurality of cells are connected in series or in parallel to generate electric power. A photovoltaic power station (also known as a photovoltaic system) is a collection of structures mounted in series or in parallel with a plurality of photovoltaic modules.

Such solar power plants are generally installed on the land, which requires huge land acquisition costs and civil engineering costs, and the environment is destroyed because they are used mainly as a site by cutting down the mountains. In addition, when installed on the land, the solar modules are heated by the geothermal heat in the summer, thereby failing to effectively cool the solar modules. As a result, the power generation efficiency of the solar module is lowered.

In order to solve such a problem, a method of installing water on a lake, a river, a pond, a dam, or the like has been developed. Such a water PV system is a power generation system using a plurality of solar photovoltaic floating structures in which a plurality of solar modules installed on a water surface are disposed together with a buoy.

Such floating structure of solar power generation should not move out of the set range in a place where it is installed by the external force such as water flow or wind in floating state on the water surface. If the floating structure of the solar power generation system of the floating solar power generation system floats on the surface of the water, the alignment between the solar and the solar module is distorted and the power generation amount is lowered. In addition, .

Therefore, as shown in FIG. 1, a plurality of solar photovoltaic floating structures 10 installed on the water surface by the buoys 11 are connected to each other to prevent movement, and a plurality of solar PV floating structures 10 The pulley 13 is hung on the rope 14 and joined to the fixed block 15 fixed to the ground in the water.

However, such a plurality of solar photovoltaic floating structures 10 is required to be aligned to the south to maximize the amount of generated electricity. As shown in FIG. 2, the power generation amount is reduced due to the rotation or flow of water due to external forces such as water flow or wind, .

In order to overcome this problem, a pair of fixed piles 15 are fixed on the ground hill as shown in FIGS. 3 and 4, one end of the rope 14 is connected to each of the fixed piles 15, 14 is coupled to a weight 13 by means of a pulley 12 and the weight 13 is fixed to the fixed block 15 by means of a rope 14.

Thus, the plurality of solar photovoltaic floating structures 10 are supported by two ropes 14 connected to the ground to prevent lateral flow and rotation.

However, in the above-mentioned two prior arts, when the water level is lowered during a drought or the like, the weight 13 is brought into contact with the bottom surface as shown in FIG. 5, and the rope 14 installed in the water is loosened, There is a problem that the power generation efficiency is reduced due to the weakening of the power and the rotation or rotation of the plurality of solar cell floating structures 10.

SUMMARY OF THE INVENTION It is an object of the present invention, which has been devised to solve the problems as described above, to provide a floating solar photovoltaic power generation system capable of always maintaining the tension of a rope fixing a floating solar photovoltaic floating structure, The present invention provides a mooring device for a floating photovoltaic power generation floating structure.

According to an aspect of the present invention, a plurality of solar photovoltaic floating structures in which a plurality of solar modules installed on a water surface together with a buoy are disposed are fixed to a floor of a water surface by a rope, And a fixing rope fixed to a bottom of the water surface of the floating solar photovoltaic power generation floating structure so as to restrain the movement of the floating solar photovoltaic floating structure, Wherein a change in the straight line distance between an end of the floating solar photovoltaic power generation floating structure and the fixed block moves in accordance with the movement of the floating solar photovoltaic floating structure moving up and down due to a change in the height of the water surface in the rope, And a length variation compensating member for compensating for the length variation.

The length change compensating member does not include a separate mechanism and is characterized in that the tension of the rope is maintained while compensating for the change in the linear distance between the end of the solar photovoltaic power generation floating structure and the fixed block by using buoyancy and gravity of water .

One end of the rope and the other end of the rope are connected to the fixing block and the end of the floating solar photovoltaic structure, respectively. The length variation compensating member is positioned between one end and the other end of the rope, A plurality of buoys spaced apart from each other by a predetermined distance; And a weight weight provided between the buoys adjacent to each other in the buoys while being coupled to the rope so that the height of the water surface is changed so that even if the straight line distance between the fixed block and the solar photovoltaic floating structure changes, And the movement of the floating photovoltaic power generation floating structure is restricted as the tension is kept constant due to the length variation compensating member.

In addition, in the member for compensating for the change of length made up of alternating buoys and weight weights coupled to the rope, the buoy is light in weight so that it is directed upward and the weight is heavier than water, So that the tension of the rope is kept constant even if the linear distance between the fixed block and the floating photovoltaic power generation floating structure is changed.

Further, when the level of the rope is lowered, the straight distance between the fixed block and the floating photovoltaic power generation floating structure is shortened, and the tension of the rope is kept constant as the distance between the buoy and the weight is increased. .

When the water level of the rope increases, the straight line distance between the fixed block and the floating photovoltaic power generation floating structure becomes longer, and the tension of the rope is kept constant as the distance between the fixed block and the floating solar power generation floating structure approaches.

In addition, the fixed block may be spaced apart by a predetermined distance,

The length change compensating member may further include a branch rope branched at one end of the rope and connected to two or more fixed blocks, wherein the branch rope is provided with a plurality of additional buoys and weight .

As described above, according to the present invention, even if the water level is lowered in a drought or the like, the rope can pull the floating solar power generation floating structure constantly by the member for compensating for the length to maintain the tension, It is possible to increase the power generation efficiency by preventing the floating structure of the floating photovoltaic power generation system or the rotation of the floating structure of the solar photovoltaic power generation as much as possible by the external force such as the water flow or the wind by maintaining the tension state and it is possible to use the rope for a long time It is possible to provide a mooring device for a floating solar photovoltaic floating structure.

Fig. 1 is a first embodiment of a conventional floating solar photovoltaic system floating structure.
2 is a plan view showing a conventional floating structure of an aquamarine power generator rotating right and left.
Fig. 3 is a second embodiment of a floating solar photovoltaic system floating structure according to the related art.
Fig. 4 is a plan view of Fig. 3. Fig.
5 is a view of a conventional floating solar photovoltaic power generation floating structure showing a state in which the water level is lowered.
6 is a view showing a state where a mooring device of a floating solar photovoltaic floating structure according to a preferred embodiment of the present invention is installed on a floating solar battery floating structure and a fixed block.
7 is a plan view showing a mooring apparatus for a floating solar photovoltaic floating structure according to a preferred embodiment of the present invention.
8 is a side view showing a branch rope branched at two or more ends to one end of a rope of a floating solar photovoltaic floating structure according to a preferred embodiment of the present invention and connected to the fixed block.
9 is a state diagram showing a state of a member for compensating for length variation as the water level of a mooring device of a floating solar photovoltaic floating structure according to a preferred embodiment of the present invention is lowered.

Hereinafter, the present invention will be described with reference to the drawings for explaining a mooring system of a floating solar photovoltaic floating structure according to embodiments of the present invention.

FIG. 6 is a view showing a state in which a mooring device of a floating solar photovoltaic floating structure according to a preferred embodiment of the present invention is installed on a floating solar power generating floating structure and a fixed block, and FIG. Fig. 3 is a plan view showing a mooring device of a solar power generation floating structure.

The mooring structure of the floating photovoltaic power generation floating structure according to the present invention includes a plurality of floating solar photovoltaic floating structures 110 installed on the water surface together with the buoys 132, And a rope 136 connecting an end of the floating solar photovoltaic system floating structure 110 with a fixed block 120 fixed to the bottom of the water surface.

First, as shown in FIG. 6, a plurality of photovoltaic modules are assembled to form a floating photovoltaic power generation floating structure 110. That is, the end of the floating solar photovoltaic power generation floating structure 110 is connected with a rope and fixed to the fixed block fixed to the bottom of the water surface to restrain the motion of the floating solar power generation floating structure 110.

6 and 7, in the rope 136, the end of the floating solar photovoltaic system floating structure 110 and the fixed solar cell floating structure 110 are moved in accordance with the movement of the floating solar photovoltaic floating structure 110, A length variation compensating member 130 for compensating for a change in the linear distance of the light source 120 is provided.

The length variation compensating member 130 does not include a separate mechanism and uses buoyancy and gravity of water to compensate for the linear distance variation between the end of the floating solar photovoltaic floating structure 110 and the fixed block 120, 136).

One end and the other end of the rope 136 are connected to the fixing block 120 and the end of the aft solar photovoltaic system floating structure 110, respectively.

The length change compensating member 130 provided on the rope 136 includes a buoy 132 and a weight 134.

The buoy 132 includes a length variation compensating member 130 coupled to the rope 136 while being positioned between one end and the other end of the rope 136 and spaced apart from each other by a predetermined distance.

At this time, the buoys 132 float above the water with a specific gravity smaller than that of the water.

The weight 134 is provided between the buoys 132 adjacent to each other in the buoys 132 while being coupled to the rope 136.

At this time, the weight 134 is heavier than water and is directed to the bottom of the water, and sinks below the water.

The buoy 132 and the weights 134 are connected to the ropes 136 and are connected to the rope 136 such that the ropes 136 are connected to the hooks 132 or the hooks 134 formed on the weights 134, Fixed and connected. Thus, the buoy 132 and the weight 134 are not limited to the rope 136 because they are connected and coupled in various manners.

In other words, in the member 130 for compensating for the length of change made up of the buoy 132 and the weight 134 which are alternately connected to the rope 136, the buoy 132 is slightly light in weight than water, 134 are arranged so that the rope 136 is bent upward and downward due to its specific gravity being greater than that of water and is directed downward so that the rope 136 can be rotated even if the straight line distance between the fixed block 120 and the aft solar photovoltaic floating structure 110 changes. 136 are kept constant.

Accordingly, the mooring structure of the floating photovoltaic power generation floating structure according to the present invention is such that even if the height of the water surface changes and the linear distance between the fixed block 120 and the floating photovoltaic power generation floating structure 110 changes, The tension compensating member 130 keeps the tension constant, thereby restricting the motion of the floating solar photovoltaic system floating structure 110.

Even if the height of the water surface changes and the linear distance between the fixed block 120 and the aft solar photovoltaic system floating structure 110 changes, the length variation compensating member 130 provided on the rope 136 causes the tension to be constant The movement of the floating photovoltaic system floating structure 110 is restrained and the rope 136 is worn out and there is less risk of breaking, so that it can be used for a long time.

FIG. 8 is a side view showing a branch rope branched at two or more ends to one end of a rope of a floating apparatus for a floating solar photovoltaic floating structure according to a preferred embodiment of the present invention, Is a state diagram showing the state of the member for compensating for the length change as the water level of the mooring device of the floating solar photovoltaic floating structure is lowered.

Referring to FIGS. 8 and 9, the operation of the floating structure of the floating solar photovoltaic floating structure 110 according to the present invention is as follows.

When the water level is lowered, the rope 136 shortens the straight line distance between the fixed block 120 and the floating photovoltaic power generation floating structure 110, and the distance between the buoy 132 and the weight 134 becomes long The tension of the rope 136 is kept constant.

On the contrary, when the water level rises, the rope 136 becomes longer as the straight distance between the fixed block 120 and the aft solar photovoltaic system floating structure 110 becomes longer, The tension is kept constant.

That is, even if the water level drops due to a drought or the like, the rope 136 pulls the floating solar photovoltaic floating structure 110 constantly by the length change compensating member 130 to maintain the tension, The power generation efficiency can be increased by preventing flow of the floating photovoltaic power generation floating structure 110 or rotation of the floating photovoltaic structure 110 to the left or right by the external force such as water flow or wind while maintaining a constant tension.

On the other hand, the fixed block 120 is spaced apart by a predetermined distance and formed of two or more. Preferably two, spaced apart from each other by a predetermined distance, and installed in water.

Further, the member 130 for compensating for the length variation further includes a branch rope 138. [

The branch ropes 138 branch more than one to one end of the rope 136 and are connected to two or more fixed blocks 120. Preferably, the branch ropes 138 are connected to two fixed blocks 120, respectively.

The branch rope 138 may be provided with a plurality of the buoys 132 and the weight 134 as described above.

As described above, since the branch ropes 138 are further connected to one end of the rope 136, the fixed block 120 and the buoys 132, which will be described later, are connected in a Y-shape, It is possible to prevent the floating solar photovoltaic system floating structure 110 from rotating or horizontally rotating as much as possible.

110: Water photovoltaic floating structure 120: Fixed block
130: Length change compensating member 132: Buoy
134: weight 136: rope
138: branch rope

Claims (7)

A mooring system for a floating solar photovoltaic floating structure for fixing a plurality of solar photovoltaic floating structures having a plurality of solar modules installed on a water surface together with a buoy to a fixed block fixed to a floor of a water surface by a rope,
And a mooring device including a rope connecting an end of the floating photovoltaic power generation floating structure and a fixed block fixed to the bottom of the water surface to restrain the motion of the floating solar PV floating structure,
The rope is provided with a length variation compensating member for compensating for a change in a linear distance between an end of the floating solar photovoltaic power generation floating structure and the fixed block in accordance with the movement of the floating photovoltaic power generation floating structure moving up and down by the height change of the water surface Wherein the floating structure of the floating solar photovoltaic system is installed.
The method according to claim 1,
Wherein the length change compensating member does not include a separate mechanism and uses the buoyant force and the gravity of water to maintain the tension of the rope while compensating for the change in the linear distance between the end of the solar photovoltaic power generation floating structure and the fixed block A floating solar power generation floating structure mooring device.
3. The method of claim 2,
One end and the other end of the rope are respectively connected to the fixed block and the end of the floating solar photovoltaic structure,
The length variation compensating member may include a buoy having a plurality of buckets connected to the rope while being positioned between one end and the other end of the rope and spaced apart from each other by a predetermined distance; And
A weighed weight attached between adjacent buoys in the buoys while being coupled to the rope;
Even if the linear distance between the fixed block and the solar photovoltaic floating structure changes due to the change of the height of the water surface, the tensile force is kept constant due to the member for compensating for the length of the rope, And the movement of the floating solar power generation floating structure is restricted.
The method of claim 3,
In the member for compensating for the length change, which is composed of the buoy and the weight, which are alternately connected to the rope, the buoy is light in weight and has a specific gravity larger than that of the water, And the tension of the rope is kept constant even if the linear distance between the fixed block and the aft solar photovoltaic system floating structure changes.
5. The method of claim 4,
When the water level is lowered, the straight distance between the fixed block and the floating photovoltaic power generation floating structure is shortened, and the tension of the rope is kept constant as the distance between the buoy and the weight is increased. Mooring device of floating solar power generation floating structure.
5. The method of claim 4,
Wherein the rope has a linear distance between the fixed block and the aft photovoltaic power generation floating structure when the level of the rope becomes high and the tension of the rope is kept constant as the distance between the fixed block and the floating photovoltaic power generation floating structure approaches the weight. Mooring device of power generation floating structure.
5. The method of claim 4,
Wherein the fixed blocks are spaced apart from each other by a predetermined distance,
Wherein the member for compensating for the length further comprises a branching rope connected to two or more fixed blocks branched at two or more ends of the rope,
Wherein the branch rope is provided with a plurality of additional buoys and an additional weight.

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