KR102222022B1 - Solar photovoltaic power generation system installed on the sea surface - Google Patents

Abstract

In the solar power automatic tracking power generation system operating along the trajectory of the sun, a large area of underground exposed to a considerable height from sea level if it has a metal exterior with a metal inner tube and an outer corrosion-preventing coating surface at the bottom of the excavation needle and vertically. A pillar built into the wall; A sharp anchor is formed on the hemispherical surface, and the ribs are integrally formed on both sides of the wing and the vertical with the bolt through hole, and the connection fixing piece is built up on the column at sea level; A fixed connecting rod coupled to the connecting fixing piece in a horizontal grid direction to connect a plurality of pillars; A coil spring having an upper and lower cross-section horizontally formed and enclosing the outer surface of the column to be burnt on the upper surface of the connecting fixing piece; Doedoe tanseol on the upper surface of the coil spring, freely vertical movement while receiving the guidance of the column; A bearing cylinder provided with a sleeve bearing to enable up and down vertical motion and having a plurality of bolt through holes formed at the upper and lower ends of the blades; A lower main frame and an upper main frame coupled to the upper and lower end blades formed on the bearing cylinder to form a fuselage frame at an appropriate height from the sea level; A buoyancy body box connected to the space between the lower main frame and the upper main frame so as to provide buoyancy to the fuselage when a high wave height occurs; Provides a solar power automatic tracking power generation system installed on the sea surface, characterized in that a plurality of light collecting plates are installed and a bottom plate coupled to the upper main frame and the upper surface of the buoyancy body box are constructed so that the facility management worker can move.

Description

Solar photovoltaic power generation system installed on the sea surface}

The present invention is not significantly affected by storms or tidal currents in places such as sea, beach, river or large-scale lake where sufficient space area can be secured, and sunlight is automatically applied from the time the sun rises to the sun sets. It relates to a solar power automatic tracking power generation system installed on the sea level provided to maximize solar power generation efficiency by tracking.

Human civilization demands more electricity as it continues to develop, and this demand goes beyond fossil energy and nuclear power to use wind, hydro, geothermal and solar energy generated from nature as new and renewable energy.

As is well known, fossil energy such as petroleum and coal is expanding to serious environmental disasters beyond the problem of depletion of underground resources, and nuclear energy is clean, but there are defects in facilities or equipment, especially the Chernobyl nuclear power plant and Fukushima. When a problem such as a nuclear power plant accident occurs, a disaster that is difficult to imagine occurs.

However, it turns out that the world is investing a lot of manpower and money in the development of new and renewable energy using geothermal heat, including wind, hydro, and solar energy as safe, inexpensive and limitless energy.

On the other hand, among renewable energies, solar light is the first in the production of electric energy, but it has a problem of increasing energy production cost due to a low energy density and a disadvantage of requiring an area for installing a light collecting plate.

The method of converting sunlight into electric energy consists of a module that absorbs sunlight and a system that sends the electricity obtained from these modules to an inverter, converts DC electricity into converted AC power, and connects it with a distribution line suitable for the grid voltage. .

The means of using the current solar power generation system is generally known as a means of installing in the plains, salt fields, and forest fields from small-scale residential solar power systems, but it is limited and limited due to the problem of land price increase. Water solar power systems are being actively researched.

In addition, if a solar power generation system is installed on the surface of a lake, river, coast, or sea, there is no need to worry about the land price to purchase the installation site, and there are no obstacles such as buildings or trees, so the solar power system for a long time. This irradiation makes it possible to stably receive solar energy. In particular, the module that absorbs sunlight or the connection panel connected thereto, inverters, switchgear, circuit breakers, and connection wiring are generated throughout the system. It is effective in preventing and blocking fever.

On the other hand, a generally known floating solar power generation system consists of a floating structure floating on the surface of the water and a photovoltaic power generation system on the floating structure. It can be confirmed by a number of patent publications that it consists of a mooring device that makes it move, and that there is a device that automatically moves along the sunlight.

However, in the floating solar power generation system known so far, the floating structure is not moored firmly, and the shock is applied according to the movement of the wind or the water surface, and the connection of the floating solar power generation system installed on the floating structure and the cable connected to the floating solar power generation system There is a problem of damaging them.

In the case of seashore, there are high tide (wild water) and low tide (day water) that sea level rises due to tidal phenomenon, but when the sea level decreases due to low tide, the floating structure cannot maintain the level and is irregular and irregular surface along the ground. As a result, the absorption or irradiation of sunlight becomes irregular, reducing the efficiency of solar power generation, and in particular, a problem occurs in that connection parts and cables of each engine part wear and breakage in the repeated process.

In addition, among the conventionally known systems, there is a case where a mooring device is placed as a concrete structure on the underwater floor, one cable is connected to the concrete structure, and a weight is suspended on the other. In this case, the configuration of the mooring device is Although it may be simple, there is a problem that the floating structure must be larger as the weight of the weight, especially in this case, it is accompanied by a condition that the water depth must be deep. There will be no.

Next, if you look at the technical details of Korean Patent No. 1318791 (hereinafter referred to as selection number 1 on October 10, 2013) and Patent No. 1636543 (hereinafter referred to as selection number 2 on June 29, 2016), the summary will be described. ;, First, in the first invention, the anchor is fixed on the underwater ground, the winding drum is provided on the floating body floating on the water surface, the anchor and the winding drum are connected with a support rope, and a tension sensor is mounted on the support rope located in the water. Therefore, it is a technology to support the floating body by maintaining a certain tension on the support rope while winding or unwinding the support rope with a winding drum according to the tension detected by the tension sensor. , A floating structure mooring device of a floating solar power generation system, comprising: a fixing member mounted on the solar power generation device and fixed to the underwater ground under the floating structure floating on the water surface; A wire rope having one end connected to the fixing member; A tension control unit that is slidably mounted on the floating structure, and the other side of the wire rope is connected to pull or loosen the wire rope to adjust the tension of the wire rope; A tension sensing unit that senses a tension of a wire rope connected to the tension control unit due to a change in the position of the tension control unit according to the movement of the floating structure; It can be seen that it is disclosed to include a; control unit for controlling the tension control unit according to the tension sensed by the tension sensing unit.

However, in the above inventions 1 and 2, since the tension sensor for detecting the tension of the support rope is always located in the water, the life of the tension sensor is shortened, and when a failure occurs in the tension sensor, the tension sensor is replaced. There is a difficulty in achieving the purpose due to the problem of

And another Republic of Korea Patent Registration No. 1662387 (2016.07.19. hereinafter referred to as the first invention 3); relates to the mooring device of the floating photovoltaic power generation system, so that it is located around the floating structure in which the photovoltaic power generation device is installed. A plurality of pillars fixed to the underwater ground; A plurality of guide members positioned on the pillar in the longitudinal direction and each provided with guide grooves on both side surfaces; A rolling support assembly coupled to be movable vertically along the guide member; A connection unit connecting the rolling support assembly and the floating structure; A buffer unit connected to the connection unit to relieve external impact, wherein the rolling support assembly includes a plurality of rollers respectively located in the guide grooves of the guide member and moving along the inner surface of the guide groove, and the roller It consists of a roller support member that connects them, and a fastening unit that is provided on the roller support member and is fastened to the connection unit. The means for supporting and connecting the structure is connected by wires, and especially, the up and down structure is a structure that constitutes a guide with a guide groove around the column, and a support member with rollers and a fastening unit connected thereto, so wave movement. It is inevitable to be flexible, and under such conditions, severe fluctuations occur when there is a storm and the waves are high, so the risk of damage is very high, and the purpose cannot be achieved.

The present invention is provided to enable efficient energy production by solving the above-described problems, and is installed on the water surface in rivers or beaches, including the sea, where land price is relatively inexpensive and civil complaints do not occur. It is possible, but the water quality is not stigmatized by the installation, it does not fluctuate even if there is a severe storm due to high waves, and it is not damaged, and the solar panel operates according to the real-time weather, and the track that the sun moves by hour and season is saved. It automatically tracks by and enables efficient solar power generation accordingly.

The present invention for achieving the above object is to securely fix the several pillars by fixing to the connection fixing piece, a plurality of pillars to be fixed in a rectangular shape in the ground at regular intervals, the structure is supported and installed. A fixed connecting rod, a spring that is extrapolated to the column and placed on the upper surface of the connecting fixture, a sleeve bearing that is extrapolated to the column and can slide up and down and is located on the upper surface of the spring, and is extrapolated to this sleeve bearing and up and down. A sliding bearing cylinder, an upper main frame and a lower main frame fixed to the bearing cylinder and in which several buoyancy body boxes are firmly combined in a rectangular shape, and a buoyancy body box installed in a large area in the space between the upper main frame and the lower main frame. , The upper plate frame installed horizontally on the upper surface of the buoyancy body box, the floor plate installed on the upper surface of the upper plate frame, the connection fixing piece that is fixed to the top of the column to fix the connecting rod, the lightning rod that is combined with the top of the column to absorb lightning, and the connection A connecting rod that is combined with a fixed piece to fix the pillars, a windbreak plate that protects the light collecting plate from wind or waves by forming a fence around the perforated plate, a light collecting plate that absorbs sunlight to generate solar power and automatically tracks the movement of the sun, A main driving gear and a differential gear that assist the rotation of the light collecting plate, and a joint bearing that enables rotation even in a bent state; The body and rotating body that rotates up and down and in the clockwise direction are combined with a geared motor and a geared box that operates the rotating body in the clockwise direction, a lightning rod that prevents lightning damage, and a ladder for the boarding and disembarkation of the manager. There are features.

The solar power automatic tracking power generation system installed on the sea surface according to the present invention is the first; The economic effect of installing at low cost is not affected by the land price on the sea level not far from the beach or beach, on the surface of a river or a relatively large lake, or on the waterfront of the river or lake. have.

second ; In the present invention, the solar power automatic tracking power generation system installed above the sea level has the effect of preventing and blocking water pollution in the first place because the body is installed in the air with an appropriate space on the surface of the water.

third ; The solar power automatic tracking power generation system installed on the sea level according to the present invention has the effect of providing high-efficiency power generation because it automatically tracks the sun's trajectory from the morning time when the sun rises to the evening time when the sun is inclined.

fourth ; The solar power automatic tracking power generation system installed on the sea level according to the present invention provides an effect of preventing damage due to bad weather since the light collecting plate is changed to a defensive posture by an automatic device according to weather conditions.

1 is a front view showing the installation state of the solar power automatic tracking power generation system installed on the sea level according to the present invention
Figure 2 is an exemplary view of the structure and operation state of the windshield installed in the form of a fence on the top of the fuselage of the solar power automatic tracking power generation system installed on the sea level in the embodiment of the present invention
Figure 3 is an exemplary cross-sectional view of the main part of the solar power automatic tracking power generation system installed on the sea level in the embodiment of the present invention
Figure 4 is an enlarged cross-sectional view of a lightning rod installed at the upper end of the pillar of the solar power automatic tracking power generation system installed on the sea level according to the present invention
5 is a partially enlarged cross-sectional view illustrating the coupling relationship between the pillar of the solar power automatic tracking power generation system installed on the sea level according to the present invention and the bearing cylinder extrapolated to the pillar.
Figure 6 is an enlarged cross-sectional view illustrating the body configuration process of the solar power automatic tracking power generation system installed on the sea level in the embodiment of the present invention
7 is a partially enlarged cross-sectional view showing a sub-sphere box of the solar power automatic tracking power generation system installed on the sea level according to the present invention, coupled to a column by a bearing cylinder
8 is an enlarged cross-sectional view illustrating the structure and operation relationship of the bearing cylinder of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention.
9 is a partially enlarged cross-sectional view illustrating the coupling relationship between the upper and lower main frames and the sub sphere box of the solar power automatic tracking power generation system installed on the sea level according to the present invention.
10 is an exemplary cross-sectional view showing a part of the configuration of the light collecting plate and the body of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention.
11 is a front internal view illustrating the structure of the fixing piece for connection of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention
FIG. 12 is an exemplary cross-sectional view in a planar state illustrating a state in which the connecting fixing piece viewed from the direction of line A-A' of FIG. 11 is coupled to a column;
13A is a cross-sectional view illustrating the structure of the bearing cylinder of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention.
13B is a front view of the complete assembly of FIG. 13
14A is a front view showing another embodiment of the bearing cylinder of FIG. 13
Figure 14b is a longitudinal cross-sectional view showing the coupling state of the bearing cylinder of Figure 14a
FIG. 15 is a plan view illustrating a coupling state of a pillar, a main frame, and a subsphere box of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention.
16 is a partially enlarged cross-sectional view illustrating in detail the coupling state of the pillar, the upper and lower main frames, and the sub sphere box of the solar power automatic tracking power generation system installed on the sea level according to the present invention
FIG. 17 is a plan view illustrating a state in which an upper plate for scaffolding with smooth drainage is installed on the entire upper surface of the state of FIG. 15
Figure 18 is a plan view of the solar power automatic tracking power generation system installed on the sea level in the embodiment of the present invention
FIG. 19 is a perspective view of an exploded and combined embodiment explaining the structure of a sub sphere box of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention
FIG. 20 is a perspective view illustrating a state in which the sub-sphere box of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention is connected in a rectangular shape.
Figure 21 is a plan view illustrating another embodiment of the vertical operation of the fuselage of the solar automatic tracking power generation system installed on the sea level of the present invention embodiment
22A to 22C are schematic plan views of another embodiment of the vertical movement unit of the body of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention.
23 is a cross-sectional view showing a state as viewed from the front of FIG. 22C
24 and 25 are side views illustrating a state in which the solar collector plate of the solar power automatic tracking power generation system installed on the sea level according to the present invention automatically tracks the trajectory of the sun.
26 is a side view illustrating a gear device for driving the light collecting plate of FIG. 24
FIG. 27 is an exemplary plan view of FIG. 26
28 to a plane illustrating the coupling state of a geared motor and wire having a column and a frame and a geared box configured to rotate the rotating body of the solar power automatic tracking power generation system installed on the sea level in the forward and reverse direction Illustrative diagram
FIG. 29 is an exemplary plan view showing a state in which an upper plate with smooth drainage is installed on the upper surface of the frame structure of FIG. 28
30 is a plan view showing a state in which a light collecting plate is installed on the upper surface of FIG. 29
31 is an exemplary cross-sectional view illustrating a rotating body of a solar power automatic tracking power generation system installed on the sea level according to the present invention
FIG. 32 is an enlarged cross-sectional view illustrating a part of the rotating body of FIG. 30
33 is a block diagram of a driving signal unit of a solar power automatic tracking power generation system installed on the sea level according to the present invention
34 is an understanding diagram explaining the state of the sun's trajectory by season

Hereinafter, the present invention will be described. 1 is a front view showing the installation state of the solar power automatic tracking power generation system installed on the sea level, and FIG. 2 is a fence on the top of the fuselage of the solar power automatic tracking power generation system installed on the sea level of the present invention. It is an exemplary view of the structure and operation state of the windshield installed in the form, Figure 3 is an exemplary cross-sectional view of the main part of the solar power automatic tracking power generation system installed on the sea level of the embodiment of the present invention, Figure 4 is installed on the sea level of the embodiment of the present invention An enlarged cross-sectional view of the lightning rod installed on the upper part of the pillar of the solar automatic tracking power generation system, and FIG. 5 is a coupling relationship between the pillar of the solar automatic tracking power generation system installed on the sea level of the present invention and the bearing cylinder extrapolated to the pillar. It is a partially enlarged cross-sectional example diagram illustrating, and FIG. 6 is an enlarged cross-sectional view illustrating the body configuration process of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention, and FIG. 7 is installed on the sea level in the embodiment of the present invention A partially enlarged cross-sectional view showing a sub-sphere box of the solar power automatic tracking power generation system being coupled to the column by a bearing cylinder, and FIG. 8 is a bearing cylinder of the solar power auto-tracking power generation system installed on the sea level according to the embodiment of the present invention. It is an enlarged sectional example explaining the structure and the working relationship, and FIG. 9 is a partially enlarged sectional example explaining the coupling relationship between the upper and lower main frames and the subsphere box of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention. Figure 10 is a cross-sectional view showing a part of the configuration of the light collecting plate and the body of the solar power automatic tracking power generation system installed on the sea level of the embodiment of the present invention, Figure 11 is installed on the sea level of the embodiment of the present invention It is a front internal schematic diagram explaining the structure of the connection fixing piece of the solar power automatic tracking power generation system, and FIG. 12 is a planar state explaining the state in which the connection fixing piece viewed from the line A-A' of FIG. 11 is coupled to the pillar. 13A is a cross-sectional view illustrating the structure of the bearing cylinder of the solar automatic tracking power generation system installed on the sea level according to the embodiment of the present invention, and FIG. 13B is a cross-sectional view of the complete assembly of FIG. Front view FIG. 14A is a front view showing another embodiment of the bearing cylinder of FIG. 13, FIG. 14B is a longitudinal cross-sectional view showing the coupling state of the FIG. 14A bearing cylinder, and FIG. 15 is installed on the sea level in the embodiment of the present invention. It is a plan view explaining the coupling state of the pillar, the main frame and the subsphere box of the solar power automatic tracking power generation system, and FIG. 16 is a column and the upper and lower parts of the solar power automatic tracking power generation system installed on the sea level according to the present invention. It is a partially enlarged cross-sectional view illustrating in detail the coupling state of the main frame and the subsidiary box, and FIG. 17 is a plan view illustrating a state in which a top plate for a scaffold with smooth drainage is installed on the entire upper surface of the state of FIG. 15, and FIG. 18 is a schematic plan view of a solar power automatic tracking power generation system installed on the sea level according to an embodiment of the present invention, and FIG. 19 is a disassembled combination explaining the structure of a sub sphere box of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention. It is a perspective view of an embodiment, and FIG. 20 is a perspective view for explaining a state in which the subsphere box of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention is connected in a rectangular shape, and FIG. 21 is installed on the sea level of the embodiment of the present invention It is a plan view illustrating another embodiment of the upper and lower vertical operation unit of the body of the solar power automatic tracking power generation system, and FIGS. 22A to 22C are another vertical movement part of the body of the solar power auto-tracking power generation system body installed on the sea level according to the present invention. As an exemplary plan view of another embodiment, it is an exemplary cross-sectional view showing a process of combining structures by process, FIG. 23 is an exemplary cross-sectional view showing a state viewed from the front of FIG. 22C, and FIGS. 24 and 25 are the present invention. It is an exemplary side view of a light collecting plate installation state explaining a state in which the solar light collecting plate of the solar automatic tracking power generation system installed on the sea level in practice automatically tracks the trajectory of the sun, and FIG. 26 is a description of a gear unit for driving the light collecting plate of FIG. 24 Fig. 27 is an exemplary plan view of Fig. 26, and the rotating body of the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention is in the forward and reverse direction. It is a plan view illustrating the coupling state of a geared motor and wire having a column and a frame and a geared box configured to rotate in a circular direction, and FIG. 29 is a state in which an upper plate with smooth drainage is installed on the upper surface of the frame structure of FIG. 28 Is a plan view showing, and FIG. 30 is a plan view showing a state in which the light collecting plate is installed on the upper surface of FIG. 29, and FIG. 31 is a front view illustrating the rotating body of the solar power automatic tracking power generation system installed on the sea level in which the present invention is implemented. Fig. 32 is a cross-sectional view showing an enlarged view of a part of the rotating body of Fig. 30, and Fig. 33 is a block diagram of a driving signal unit of a solar power automatic tracking power generation system installed on the sea level according to the present invention, 34 is an understanding diagram illustrating a state of a trajectory of the sun by season, and the present invention will be described in detail with reference to the drawings.

Hereinafter, according to an embodiment of the present invention, it will be described in detail so that a person having ordinary skill in the art can easily implement it.

The present invention may be implemented in various different forms and is not limited to the embodiments described herein.

In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and the same reference numerals are assigned to the same or similar components throughout the specification.

Throughout the specification, when a part is said to be “connected” with another part, this includes not only the case that it is “directly connected” but also “indirectly connected” with another member interposed therebetween.

In addition, when a part "includes" a certain component, it means that other components may be further included, not excluding other components unless specifically stated to the contrary.

The terms used in the present invention are terms defined in consideration of functions in the present invention, and since these may vary according to the intention or custom of users or operators, the definitions of these terms correspond to the technical matters of the present invention. And should be interpreted as a concept.

In addition, optional terms in the following embodiments are used to distinguish one component from other components, and the component is not limited by the terms. Hereinafter, in describing the present invention, detailed descriptions of related known technologies that may unnecessarily obscure the subject matter of the present invention will be omitted, and the present invention will be described below.

The present invention is intended to improve the efficiency of solar power generation as new and renewable energy, and provides for solar power generation in rivers or beaches, including the sea, where land prices are relatively inexpensive and civil petitions do not occur. Water quality is not polluted by facilities and installations for photovoltaic power generation, and it does not fluctuate even if there is a severe storm due to high waves, so that it is not damaged, and also provides efficient solar power generation by automatically tracking the trajectory of the sun's movement. It is provided so that it can be done.

On the other hand, the present invention relates to a photovoltaic device installed on the sea surface to perform photovoltaic power generation by installing in a sea or a beach or a river or lake where the water depth is not relatively deep.

In addition, since it will be an unnecessarily lengthy description if it follows the embodiments of the present invention one by one, it will be described as an example when it is installed in a seaside sea where the depth of the water is not deep.

On the other hand, the Earth has a tidal phenomenon in which the sea level rises and falls periodically due to the tidal power according to the relative position of the Earth, the moon, and the sun, and this tidal phenomenon is caused by the movement of the seawater in the horizontal direction, causing the sea level to rise and the seawater to the shore. As the sea level is lowered, the tide flows in and the sea water is swept toward the sea.

In other words, the state in which the sea level is highest in the day due to the tidal phenomenon is called high tide or high tide, and the state in which the sea level is lowest due to the exit of the tide is called low tide or low tide. This occurs twice a day, and the difference in sea level at high tide and low tide may be only 20 cm on average in some areas depending on the location and time, while a large difference of more than 10 m may occur in some areas.

Therefore, when installing a photovoltaic power generation system or device on the sea or water surface, especially in the case of a floating structure in which several are connected, whenever the seawater enters or flows due to the ebb and flow of seawater, especially in the case of a storm such as a typhoon, the connection part of the floating structure Due to extreme impact and friction on people, the connection part is damaged and the floating structure is scattered, causing a problem that the photovoltaic system device is completely damaged and lost.

In addition, in the case of a photovoltaic power generation system device in which a floating structure is installed on the water surface, the offshore installation plan is canceled because the sun is blocked in the seawater on the bottom of the floating structure, causing serious problems such as destroying the marine ecosystem. There is a fact that even a problem occurred.

However, the solar power generation device installed on the sea level according to the present invention is installed at an appropriate height from the water surface and is not affected by high tide and low tide between tides and evenings, and in particular, it is not affected by storms such as typhoons, thereby preventing damage such as damage. There will be.

1 is a schematic front view of an installation state of a solar power generation device installed on the sea level according to the present invention.

According to the above FIGS. 1 and 3, a foundation is prepared by driving several pillars 1 in the ground.

At this time, the pillar 1 is formed with a through hole in the center of the axial direction as illustrated in FIG. 5, so that a metal inner tube 1a is embedded, and the outer surface thereof is wrapped with a metal exterior 1b that surrounds the reinforced/concrete pillar 1 Lose.

On the other hand, the metal inner tube (1a) and the metal exterior (1b) are made of stainless steel or zinc material that does not cause corrosion by seawater, or a coating surface (1c) made of epoxy coating material is formed, and the bottom end is excavated. The needle portion 1d is formed.

In addition, the lightning rod 2 is coupled to the upper end of the pillar 1 as illustrated in FIG. 4, and at this time, a lightning rod portion 2a and a trunk shaft portion 2b are formed in the upper and lower centers of the lightning rod 2, while a cylindrical cap portion (2c) is formed, and the trunk shaft portion (2b) at the center of the lower portion is fitted into the metal inner tube (1a), and the cylindrical cap portion (2c) is covered by covering the outer surface of the column to be combined, such as fire and damage from frequent lightning strikes on the beach. To prevent damage.

The pillar (1) constructed as described above is installed in a state that matches the top height by tableting or excavation after specifying the location on the beach (including underwater) of an appropriate area, and connected to the appropriate height of the erected pillar (1). Combine the dragon fixing piece (3).

At this time, the connection fixing piece (3) is a powerful coil spring (5) that connects the fixing connector (4) as illustrated in FIGS. 1 and 3 to maintain and fix the columns (1) in an accurate vertical state. It is burnt on the upper surface and acts as a pedestal to support the power generation system fuselage 200.

In addition, looking at the connection fixing piece 3 based on FIGS. 11 and 12, a hemispherical surface 3a in the shape of a pipe divided in half and an anchor 3b sharp like a blade on the inner surface of the hemispherical surface 3a. ) Is formed, and a wide wing (3c) is integrally formed at the upper and lower portions, and has several bolt through holes (3d), and a rib (3f) having a bolt through hole (3e) between the wings (3c). Is formed. The formed connection fixing pieces 3 are combined to form a pair.

The method of coupling and fixing the formed connecting fixing pieces (3) to the column (1) as a pair is, as illustrated in FIG. 12, two hemispherical surfaces (3a) with the column (1) interposed therebetween. In the state of joining the upper and lower wing joint surfaces (3g) and the body joint surface (3h), insert a bolt/nut (B) into the bolt through hole (3e) of the rib (3f) and fasten it.

When the bolt/nut (B) is fastened, the sharp-end anchor (3b) penetrates the outer coating surface (1c) and the metal exterior (1b) of the column (1), and thus the connection fixing piece (3) slides. It remains firmly fixed in the column 1 without phenomenon.

Subsequently, a coil spring 5 is burnt on the upper portion of the connection fixing piece 3 coupled to the pillar 1, as illustrated in FIG. 3, and a sleeve bearing ( A cylindrical bearing cylinder (7) having 6) is coupled to the column (1), and the bearing cylinder (7) at this time is in a form where the lower pipe cylinder (7a) surrounds the column (1) as illustrated in FIG. The lower main frame (8), the buoyancy body box (9), and the upper main frame (10) are connected in a state of being inserted from top to bottom, and then the correlation cylinder (7a') is fastened to the lower pipe cylinder (7a). Are combined.

More specifically, the coupled bearing cylinder 7 is, as illustrated in Figs. 13A and 13B, a blade 7b (7b') having a bolt through hole (7f) (7f') and an inner periphery and an outer periphery. Each of the female threaded wire portions 7d and male threaded wires 7d' on the creepage surface, the lower pipe joint 7e and the correlation joint 7e', and the lower pipe upper end 7h and the correlated lower end 7h' It is composed of the lower pipe cylinder (7a) and the correlation cylinder (7a').
On the other hand, the above-described bearing cylinder 7 is formed by forming ribs 7i having a plurality of bolt through holes 7" on both sides in the vertical direction as illustrated in FIGS. 14A and 14B as another embodiment. It is also desirable to change to the structure to be formed.

In order to keep the lower main frame 8, the buoyancy body box 9, and the upper main frame 10 in a solid coupling state with the bearing cylinder 7 as one body, as illustrated in FIG. 6, the buoyancy force While placing the bottom of the lower main frame (8) connected to the body box (9) on the upper surface of the blade (7b) of the lower pipe cylinder (7a) connected to the column (1), attach the bolt (B) to the blade (7b). When fastened from the bottom to the top, the lower pipe cylinder 7a and the lower main frame 8 are combined.

Next, in the state that the male threaded portion 7d' of the correlation cylinder 7a' is aligned with the female threaded portion 7b of the lower pipe cylinder 7a, a separate C-type wrench (tool) is inserted into the wrench use groove (7g'). When rotated at, the correlation cylinder 7a' is combined with the lower pipe cylinder 7a as one body, and at the same time, the upper surface of the upper main frame 10 is pressed against the lower surface of the wing 7b' of the correlation cylinder 7a'. , In such a state, when the bolt (B) is fastened to the bolt through hole (7f'), as illustrated in FIG. 7, the lower main frame 8 and the upper main frame 10 are coupled to the buoyancy body box 9 ) Is to maintain a solid coupling state to the bearing cylinder (7) coupled to the column (1).

Meanwhile, as illustrated in FIG. 19, the buoyancy body box 9 is opened at the top to form a stepped jaw 9b on the upper inner edge thereof, and a partition wall 9c is formed in the inner space, and the upper outer wall A body 9a having a protruding jaw 9e having a threaded hole 9d on an inclined surface, a step 9f mounted on the open step 9b of the body 9a, and the threaded hole 9d It is composed of a cover (9h) with a bolt through hole (9g) matching the ).

And on the other hand, when considering the situation in which the buoyancy body box 9 constituted is always close to the sea level or the surface and is exposed to bad weather, the material is formed of synthetic resin or nylon material. As illustrated in Fig. 9, a metal reinforcing plate 9i may be insert-molded on the body 9a or the cover 9h of the portion where a large amount of force is applied and pressure is generated.

On the other hand, the buoyancy body box 9 is a means for increasing buoyancy, and it is preferable to increase the buoyancy effect by filling the inner space with a filler such as a foamed synthetic resin material.

And the formed buoyancy body box 9 is connected in a square shape or a rectangle shape by the lower main frame 8 and the upper main frame 10 to form a wide area, and the connected state is the lower main frame 8 and The inner buoyancy body boxes 9 coupled to the upper main frame 10 are firmly coupled with fittings 11a and bolts in the horizontal and vertical directions as illustrated in FIG. 20.

In the above, the large area refers to the plane area in which the solar energy collecting plate 100 is installed, and for this purpose, it is very important to maintain a flat and sturdy state. In order to do this, the upper surface jaw (9b') of the buoyancy body box (9) It is preferable to match the step of the joint plate fastening surface 9e' with the standard of the fitting 11a.

As illustrated in FIG. 20, the fitting 11a is formed in a standard corresponding to the height and width of the upper surface jaw 9b' of the buoyancy body box 9, and a bolt through hole 11b is formed in both length and both directions.

The formed fitting (11a) is placed on the upper joint plate fastening surface (9e') of the buoyancy body box (9) entrusted in a rectangular shape, and the bolt through hole (9d) coincides with the threaded hole (9d) of the buoyancy body box (9). When the bolt (B) is rotated while the bolt (B) is inserted into 11b), the bolt (B) screw is fastened to the screw hole (9d), and several buoyancy body boxes (9) are firmly coupled in a rectangular shape, as illustrated in FIG. Likewise, a wide flat area constituting the power generation system body 200 is made so that a large number of solar energy condensing plates 100 can be installed.

Here, if you summarize the fuselage 200 above, first, the depth in the ground (T) at each predetermined position so that several pillars (1) form a rectangular shape and a rectangular shape in a plane as illustrated in FIGS. 1 and 15. It is installed in a state that is mounted and aligned so that the upper end is horizontal, and the connecting fixing pieces 3 are combined at the sea level (K) level to each of the columns 1 installed in this way, and the combined connecting fixing pieces 3 are In this, the fixed connecting rods 4 are connected on a horizontal line, so that the pillars 1 in the independent state are connected as a whole to be first fixed.
In addition, in the pillars (1), a bearing cylinder (7) consisting of a lower pipe cylinder (7a) and a correlation cylinder (7a') in which a sleeve bearing (6) is inserted, following the coil spring (5), is connected to the fixing piece (3). The bearing cylinder 7 built on the column 1 has a lower main frame 8 on the upper surface of the wing 7b of the lower pipe cylinder 7a, and the upper main frame 10 It is connected in the grid direction from the bottom of the wing 7b' of the correlation cylinder 7a'.
A space of considerable height is formed between the lower main frame 8 and the upper main frame 10, and in the space, the buoyancy body boxes 9 are connected by fittings 11a to form a wide area, 1 and 10, a bottom frame 14 and a bottom plate 15 having a perforated hole for drainage are connected and installed on the upper surface of the upper main frame 10 and the buoyancy body box 9 configured. A large-area solar power system body 200 is configured, and the configured body 200 is connected to the lower main frame 8 and the ring 12 with the fixed connector 4 by a wire 13.
In addition, the lower main frame (8) and the upper main plane (10) maintains a solid state by fixing the pillars (1) secondary after the connecting rod (4) first fixes several pillars (1). , The buoyancy body box 9 and the wire 13 act as a buoyant force when a storm wave occurs, so that the fuselage 200 does not rise above the limit, and at the same time, the coil spring 5 performs tension and compression, while the fuselage 200 It absorbs the shock applied to it in real time.
More specifically, when the water surface is calm, the fuselage 200 is stopped at a certain height (preferably at least 5m) from the sea level K as illustrated in FIG. The wave height due to the storm hits the bottom of the buoyancy body box (9), and thus, buoyancy is generated in the buoyancy body box (9) combined with the upper main frame (8) and the lower main frame (10) as one parent body. The body 200 is lifted or lowered according to the rise and fall of the wave height, and when the body 200 rises, the rise of the body 200 is regulated at the limit point by the length of the wire 13 and at the same time, the coil spring ( 5) is tensioned and when the wave height is lowered, the coil spring 5 is compressed by the weight of the body 200 to absorb the impact applied to the body 200.
On the other hand, the impact of the fuselage 200 rising and sinking by the storm waves is greatly changed according to the situation of the storm waves.
When the fuselage 200 rises (rising), the height of the rise is limited due to the limit of the length of the wire 13, and the coil spring 5 is tensioned when the fuselage 200 rises with a wave height, whereas the fuselage 200 The impact applied to the fuselage 200 is absorbed while compressing when it descends.
On the other hand, the fuselage 200 is a weight of several tens tons or hundreds of tons, and as illustrated in FIGS. 1 and 3, the coil spring 5 is compressed in the air at a height of about 5 mm from the water surface K It is installed and the wire 13 is in a state in which the fixed connecting rod 4 and the lower main frame 8 are connected.

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Therefore, the usual sea breeze can pass through the space between the sea level (K) and the fuselage 200, effectively preventing seawater contamination, and at the same time, fundamentally blocking the deterioration of the power generation effect by contaminating the light collecting plate 100 with salt water. .
In particular, in the case of a storm, the body 200 moves vertically according to the fluctuation of seawater in a state in which the body 200 is placed on the coil spring 5; It cushions the effective wind wave shock by performing up and down vertical motion.
In addition, as illustrated in FIG. 10, the body 200 has a bottom frame 14 and a bottom plate 15 sequentially installed on the upper main frame 10, and the upper main frame 10 and the lower main frame (8) In the space between the buoyancy body boxes 9 are rigidly connected and installed with fittings 11a, and the upper surface of the connected bottom plate 15 is shown in Figs. 1 and 10, and also in Fig. 18. Likewise, the supports 16 are installed at appropriate intervals, and each of the light collecting plates 100 having the pedestal 100a is installed at the upper ends of the supports 16.
At this time, the light collecting plate 100 is rotated by a stored program by connecting the main gear 17 and the differential gear 18 to the main shaft 17a and the differential shaft 18a in a meshed state as illustrated in FIG. The main shaft (17a) and the differential shaft (18a) at this time are combined with the joint bearings (19a) (19b) at regular intervals, and together with the connecting rod function to hold the light collecting plate (100), the main shaft (17a) and the differential shaft (18a) are generated in the long axis. It maintains the rotational motion smoothly without malfunction even in the event of bending or twisting.

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In addition, a guide rail 20 having a frame structure as illustrated in FIG. 18 is firmly installed on the entire upper circumference of the fuselage 200, and a windbreak plate 21 made in the form of a window is installed on the guide rail 20. , At this time, the windbreak plate 21 is a guide rail 20 having a guide groove 20a is fixedly installed vertically, as in the example of FIG. 2, so that the upper pulley 22a and the lower pulley 22b are at the lower end and the upper end thereof. It consists of a built-up and solid plate and a frame, in which guide grooves (21a) are formed in both longitudinal directions, and the lower end is coupled with a hinge pin (21b) at a certain distance from the lower pulley (22b). The moving guide pulley (21c) is coupled to the upper end of the groove (21a) in a state that is fitted into the guide groove (20a) of the guide rail (20) by the moving shaft (21d).

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On the other hand, the moving guide pulley (21c) is connected to both ends of the wire (23) winding the pulley (22a) (22b) that is built up at the upper end and one end of the guide rail (20) to drive a motor (not shown) When the upper pulley (22a) is rotated by this, the movement guide pulley (21c) is moved in the vertical direction to open or close the windbreak plate (21).

In another embodiment of the present invention in which the body 200 can slide up and down by receiving the guidance of the pillar 101, as illustrated in FIG. 21, a pillar having guide grooves 101a in both vertical directions ( 101), and the door car 201 built on the frame fixing means 202 can be changed to a means for allowing vertical movement by being coupled to both sides of the column 101.
In another embodiment, as illustrated in FIGS. 22A to 23, a column 300 is formed of an H-shaped steel, and a door roller 302, 303 is formed in a right angle oblique direction so that the column 300 can be moved up and down in the main axis. ), but the door car 302, 303 is assembled into a fixed box 306 and an anchor 307, so that the upper and lower main frames 8 and 10 constituting the fuselage 200 can be combined. do.

In addition, the light collecting plate 100 of the solar power automatic tracking power generation system installed on the sea level K according to the present invention is installed on the fuselage 200 as described above to rotate in the direction of automatically tracking the trajectory of the sun between tides and evenings. However, in another embodiment, the body 200 carrying the light collecting plate 100 is provided to rotate forward and backward in a horizontal state as illustrated in FIGS. 28 to 32.

However, in view of the fact that the fuselage 200 is a structure that slides only in the vertical direction and does not rotate, the planar shape of the fuselage 200 is as illustrated in FIGS. 15, 17, and 18. It may be square or may be implemented in a circular shape as illustrated in FIGS. 28 to 30.

However, the reason exemplified in a circular shape in FIGS. 28 to 30 is to easily explain a state in which a rotating drive body is configured on the upper surface of the body 200 so that the light collecting plate 100 rotates forward and backward in the horizontal direction, and the rotation at this time As illustrated in Figs. 28 and 32, the driving body has several steps while drawing a large circle in a radial direction from the driving body wheel 301 coupled to the bearing cylinder 7 surrounding the column 1 installed in the center. The auxiliary frame ring 302 and the driving wheel 303 are connected to one body by a radial frame 303, and a rolling wheel 310 is installed in the driving wheel 303 toward the outside.

And around the outer circumference of the rolling wheel 310, a pedestal 311 is rigidly fixed to the upper surface of the fuselage 200 along a circular direction, and the upper surface of the pedestal 311 helps guide the rotation of the rotating drive member. Guide ring 320 is configured to be coupled.

In addition, a wire guide groove (301a) is formed in the circumference of the drive wheel body 301, and a fixing pin (301b) is installed at four points, so that the ends of the steel wire wire 315 are knotted, and the ends of the four stems of the steel wire wire are knotted. 315 is wound in a form in which a quarter circle portion of the driving wheel 301 is wrapped, as illustrated in FIGS. 28 and 32, and is wound around a tension pulley 316, and the driving motor M and The rotation drive body is rotated by the operation of the geared box 317 configured as one shaft.

The drive motor (M) provided with the geared box 317 is rigidly coupled by a fixed die (317a) that is rigidly coupled to the column (1), and the drive wheel (including the auxiliary frame 302) ( On the upper surface of 303), the floor frame 318 and the floor plate 15 are combined, and a large amount of light collecting plate 100 is installed on the upper surface of the floor plate 15 to automatically follow the sun trajectory by operating a separate sensor. It will rotate.

On the other hand, the upper part of the pillar (1) is attached to the upper end of the body 200 in a state as illustrated in Fig. 1, the connection fixing piece (4') is coupled, and the connection fixing member (3') is rigid. It is combined to prevent the problem of shaking the pillars (1) by vibration or the like.

Next, the operating state of the solar power automatic tracking power generation system installed on the sea surface according to the embodiment of the present invention will be described.

Considering that there is a difference depending on conditions such as the latitude and longitude of the earth, the position of the sun and its moving trajectory based on Korea with four seasons, as illustrated in FIG. 34, are in the east, west, south, and north directions. As a guide, the position of the sun changes according to the summer (summer), equinox/fall equinox (spring/autumn), and winter solstice (winter), such as A, B, and C.

Therefore, when the light collecting plate 100 is installed at a fixed angle, it is concluded that the efficiency of solar power generation decreases at other times coincident with the center of the light collecting plate 100. Therefore, in recent years, various measures to increase the light collecting efficiency have been studied. It is true.

In addition, since solar power generation facilities are not allowed to irradiate the photovoltaic panel (100); obstruction facilities are not allowed, it is necessary to purchase and install a large area of the mountain to have a wide empty condition, and then the purchase of the land is a lot of financial conditions. It is true that it is the cause of the increase in electricity production cost due to solar power generation because many civil complaints arise at the same time as the premise.

Therefore, while countries around the world are investing enormous technologies and costs in developing renewable energy using solar power, they are focusing on technology to achieve solar power generation at sea level, and some countries including Korea A large-scale solar power plant is already installed and operated at sea level.

On the other hand, it is true that the initial facility cost is largely invested in sea level solar power generation, unlike the case of facilities in Sanya, but the power generation efficiency and power compared to the investment cost are so high that it is incomparable to that of facilities in Sanya. Because it can be produced and supplied in a stable manner, and in particular, it can prevent loss of companies due to delays in construction or cancellation of construction plans due to civil complaints, so even if problems arise due to pollution of seawater, there is a lot of economic benefit. It is clear that interest will grow even higher worldwide.

Accordingly, the solar power automatic tracking power generation system installed on the sea level in the implementation of the present invention is also an invention in consideration of economic benefits, but above all, it is provided for the purpose of preventing pollution of the sea level along with the fact that it is a permanently installed facility. The solar power generation efficiency is maximized by automatically tracking the trajectory of the sun, including weather such as wind volume and waves.

As illustrated in FIG. 34, the trajectory on which the Korean standard sun moves is the position of the sun according to the summer solstice (summer), the vernal equinox/autumn equinox (spring/autumn), and winter solstice (winter) based on the east, west, south, and north directions as illustrated in FIG. As A, B, C, the position of the sun rising and setting is changed, and the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention automatically tracks the movement trajectory of the sun according to the season, while generating solar power. Maximize.

To this end, the present invention provides a block diagram of the automatic drive signal unit of the solar power automatic tracking power generation system installed on the sea level as illustrated in FIG. /Earth equinox (spring/autumn) and winter solstice (winter) track the trajectory of the sun, the temperature sensor unit 2002 detects the temperature of the light collecting plate 100, and the snowfall sensor unit 2003 is used in winter. It detects the amount of snowfall in the snow, the air volume sensor unit (2004) detects wind pressure such as a typhoon, the wave height sensor unit (2005) detects waves and tsunamis caused by a storm, and the vibration sensor unit (2006) detects an earthquake, etc. The vibration of the axis of the axis is sensed, and all the detected information is sent to the comparison circuit unit 2008 so that the light collecting plate 100 performs solar power while tracking the solar trajectory.

This will be explained in more detail. As illustrated in FIG. 34, the comparison circuit unit 2008 is divided into three sections: summer, spring, autumn, and winter seasons, and transmits a signal according to each season to each signal unit.

The summer of the Republic of Korea To explain by taking an example, the summer of the Republic of Korea has the most severe weather changes caused by rain and wind, and this is the time when the waves caused by typhoons are the highest in the sea.

In addition, when a typhoon occurs on the sea in summer, a control signal is transmitted by the control center, but by its own function, the height of the wind or waves generated in front of it is measured by the air volume sensor unit (2004) and the wave height sensor unit (2005). Is detected and the signal is sent to the comparison circuit unit 2008.

The comparison circuit unit 2008 receiving the signal compares and analyzes the input and stored information and transmits the air volume and wave information to the light collecting plate down signal unit 210 and the windshield operation signal unit 2011, and the transmitted signal is driven by the windshield drive unit. At the same time, the driving of the sun trajectory tracking sensor unit 2002 is stopped and the light-condensing plate 100 is converted to a horizontal state by switching to a down signal, and then lowered to the bottom plate 15, and the windshield drive shaft on which the pulley 22a is built. By rotating the wire (23) by rotating (22a'), the moving guide pulley (21c) of the windbreak plate (21), which is connected by knotting both ends, is pulled up to the maximum angle forming the slope as illustrated in FIG. And protects the light collecting plate 100 from being damaged from waves.

And when the typhoon passes and recovers to normal weather, the light collecting plate 100 is erected in a normal state by the reverse order, and the windbreak plate 21 is laid in a dotted line in FIG. 2 to circulate the pure wind to prevent the temperature increase of the light collecting plate 100. Therefore, the solar trajectory tracking sensor unit 2001, which has been stopped, is also activated to track the trajectory of the sun to perform normal power generation.

In addition, the solar power automatic tracking power generation system installed on the sea level according to the embodiment of the present invention, which operates above, is a comparison circuit unit (2008) to position signals according to the summer season (summer), equinox/fall equinox (spring/autumn), winter solstice (winter) And the drive motor (M) is operated by the drive motor operation signal unit (2009) by the drive circuit unit (2007), and the operation of the drive motor (M) leads to the operation of the geared box 317, at this time, the geared box 317 ) Pulls the steel wire 315 by performing the forward and reverse rotation.

The steel wire 315 pulled as described above is tense and at the same time, its end is tied to the driving body wheel 301 with a fixing pin 301b, so that the driving body on the fuselage 200 rotates at a predetermined angle of the season. As it is located, it will generate power by absorbing the maximum solar energy stably throughout the four seasons.

B: Bolt/Nut K: Sea level
M: Motor T: Underground
1, 101, 300: pillar 1a: metal inner tube
1b: metal appearance 1c: coated surface
1d: excavation needle part 2: lightning rod
2a: lightning rod part 2b: trunk shaft part
2c: cap portion 3, 3': fixing piece for connection
3a: hemispherical surface 3b, 307: anchor
3c, 7b, 7b': wing 3d, 3e, 7f, 7f', 7f", 9g, 11b: bolt through hole
3f, 7i: rib 3g: wing joint surface
3h: body junction surface 4, 4': fixed connecting rod
5: coil spring 6: sleeve bearing
7: bearing cylinder 7a: lower pipe cylinder
7a': Correlation cylinder 7c: Lower Gwan
7c': Correlated cylinder part 7d: Female thread line part
7d': male thread 7e: lower pipe joint jaw
7e': correlation jaw 7h: upper section of lower pipe
7h': Correlated lower section 8: Lower main frame
9: buoyancy body box 9a: body
9b, 9f: stepped jaw 9b': upper jaw
9c: partition wall 9d: screw hole
9e protruding jaw 9e': joint plate fastening surface
9h: cover 9i: reinforcement plate
10: upper main frame 11a: fitting
12: ring 13, 23: wire
14, 318: floor frame 15: floor plate
16: support 17: main gear
17a: main shaft 18: differential gear
18a: differential gear shaft 19a, 19b: joint bearing
20: guide rail 21: windshield
20a, 21a, 101a: guide groove 21b hinge pin
21c: moving guide pulley 21d moving axis
22a: upper pulley 22a': windbreak plate drive shaft
22b: lower pulley 100: light collecting plate
200: body 201, 302, 303: door car
202: frame fixing means 301: drive wheel
301a: wire guide groove 301b: fixing pin
302: auxiliary framing 303: drive wheel
304: radial frame 306: fixed box
310: rolling wheel 311: pedestal
315: steel wire 316: tension pulley
317: geared box 317a: fixed die
320: guide ring

Claims (9)

In the solar power automatic tracking power generation system operating according to the sun's trajectory,
A column installed in the ground in a large area to be exposed to a considerable height from the sea level if it has a metal exterior with a metal inner tube and an outer corrosion-resistant coating on the bottom part and the vertical inner surface;
A sharp anchor is formed on the hemispherical surface, and the ribs are integrally formed on both sides of the wing and the vertical with the bolt through hole, and the connection fixing piece is built up on the column at sea level;
A fixed connecting rod coupled to the connecting fixing piece in a horizontal grid direction to connect a plurality of pillars;
A coil spring having an upper and lower sectional surface formed horizontally and enclosing the outer surface of the column and struck on the upper surface of the connecting fixing piece;
Doedoe tanseol on the upper surface of the coil spring, freely vertical movement while receiving the guidance of the column; A bearing cylinder provided with a sleeve bearing to enable up and down vertical motion and having a plurality of bolt through holes formed at the upper and lower ends of the blades;
A lower main frame and an upper main frame coupled to the upper and lower end blades formed on the bearing cylinder to constitute a fuselage frame at an appropriate height from the sea level;
A buoyancy body box connected to the space between the lower main frame and the upper main frame so as to provide buoyancy to the fuselage when a high wave height occurs;
A floor plate coupled to the upper main frame and the upper surface of the buoyancy body box so that a plurality of light collecting plates are installed and the facility management worker can move; And an automatic solar tracking power generation system installed on the sea surface, characterized in that a fence is formed with a windbreak plate around the outer circumference of the bottom plate.
delete delete delete delete The method of claim 1,
The buoyancy body box of claim 1 further comprises a partition wall formed therein and sealed with a protruding jaw having a threaded hole, a stepped top jaw, a body having a joint plate fastening surface, and a cover having a bolt through hole. Solar power automatic tracking power generation system installed on the sea level.
delete delete The method of claim 1,
The bearing cylinder described in Clause 1 is formed with ribs with bolt through holes to which bolts are fastened in the vertical direction of a semi-circular tube with a large area of wings with a large number of bolt through holes, and two semi-circular tubes are combined to form a circular tube. Solar power automatic tracking power generation system that is installed on the sea surface further including that.

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