KR101241453B1 - Solar power plant constructed on the water with easy install structure for solar cell panel - Google Patents

Abstract

PURPOSE: A photovoltaic power generation apparatus is provided to prevent the water intrusion of a solar panel by using a safety rope and a bypass rope. CONSTITUTION: A cell frame(181) holds both edges of s solar panel. A frame assembly includes an inclined frame(130a) and a pair of intermediate frames(140). A supporting part supports the upper side of the cell frame. A supporting member fixes the solar panel. The cell frame joint is combined with the lower side of the cell frame.

Description

SOLAR POWER PLANT CONSTRUCTED ON THE WATER WITH EASY INSTALL STRUCTURE FOR SOLAR CELL PANEL}

The present invention relates to a water-based photovoltaic device, and in particular, it is easy to install a solar panel that can reduce work time and increase productivity by allowing the installation of the solar panel to be easily performed without the use of fasteners. It relates to a water-based photovoltaic device.

In general, electricity generating devices can be classified into thermal power generation using fossil fuels such as petroleum or coal, and solar, nuclear, hydro, tidal, and wind power generation depending on the energy source used.

Among these power generation devices, a power generation device using nuclear power has an advantage that it can generate electricity at a lower cost than thermal power generation, but installation is limited due to environmental pollution due to radioactivity and harmfulness of human body. Moreover, recently, facility investment has not been smoothly carried out due to the disposal of nuclear waste generated after electricity production.

In the case of thermal power generation, fossil fuels such as coal and petroleum are used. These generation fuels not only discharge substances that pollute the environment when electricity is generated, but also have high fuel costs. In addition, in recent years, oil prices have increased due to a decrease in resource reserves. Accordingly, power generation costs have increased, and thus, development of clean energy that does not generate substances polluting the environment is required.

In addition, recently, regulations are being implemented to curb the emission of carbon dioxide globally, and it is required to develop a new power generation device that does not emit carbon dioxide.

As such, there is no emission of carbon dioxide, and as a power generation device using clean energy, a power generation device using solar is typical, and in recent years, the development and installation cost of technology have become inexpensive, and its spread is expanding. However, the photovoltaic power generation device has a difference in power generation capacity depending on the generation area and the amount of sunshine.Therefore, there are many restrictions on the purchase of land due to the huge use of land in order to install it in a large area. Due to the costly problem, there was a practical difficulty of inducing cooperation of neighboring people in order to install power generation facilities on a large scale.

In addition, the solar power generating device installed on the land as in the prior art generates a huge amount of heat in the process of generating electricity by receiving the solar light, solar cell panels due to the enormous amount of energy transferred from the land on which the solar power generating device is installed It had a problem that degraded the performance and caused the failure.

Accordingly, in order to reduce the problems and to secure a large amount of sunshine and open installation area, water-based photovoltaic devices for installing solar panels on rivers, lakes, reservoirs, dams and the like have been actively proposed.

1 is a reference cross-sectional view for explaining a water-based photovoltaic device according to the prior art.

As shown, the water based photovoltaic device according to the prior art has an intermediate frame 11 installed in the transverse direction with respect to the inclined frame in order to install the solar panel 12, the solar against the intermediate frame 11 The edge of the panel 12 was caught and the cell frame 13 was fastened with screws 15.

However, according to the configuration according to the prior art as described above, there was a considerable difficulty in securing a work space for fastening the cell frame 13 to the screw 15 with respect to the intermediate frame 11. Therefore, the solar panel 12 and the cell frame 13 are not coupled to each other while the screw 15 is not fastened as it is, and the solar panel 12 and the cell frame 13 are separated. The screw 15 was fastened to the intermediate frame 11 and then the solar panel 12 had to be coupled to the cell frame 13.

As such, the laborious labor of the workers was repeatedly performed to install the solar panels 12, and the labor and work time of the workers were inevitably consumed, and the productivity in the field was inevitably deteriorated.

In addition, FRP (fiberglass reinforced plastic), which is used as a material of other frames, including the intermediate frame 11 in the related art, is light in weight and relatively inexpensive while securing sufficient strength to support the solar panel 12. It is used. However, despite its advantages, FRP materials are difficult to recycle and, because of their high cost expenditures, are disposed of rather than recycled. Therefore, when it is necessary to repair or dismantle the water-based photovoltaic device, not only waste of resources but also environmental problems were caused.

Accordingly, the present invention has been proposed to solve the above-mentioned conventional problems, and an object of the present invention is to eliminate the use of fasteners in the installation of solar panels and to simplify the installation, thereby reducing work time and improving productivity. It is to provide a water-based photovoltaic device that is easy to install a solar panel to be expected.

In order to achieve the above object, the water-based photovoltaic device according to the technical idea of the present invention, a plurality of solar panels; A cell frame holding the left edge and the post edge of the solar panel; A frame assembly including an inclined frame installed in an inclined direction and a pair of intermediate frames installed in a state in which the inclined frame is cross-coupled in a transverse direction and supporting the solar panel in an inclined manner; The solar panel is placed on the left side and the post and coupled to the intermediate frame at a corresponding point so as to be installed therebetween, and corresponding to the side of the cell frame holding the solar panels located on the left and the post on the left and right sides, respectively. U-shaped body portion for contacting, and a support portion extending from the upper end of the body portion to the left and the post respectively toward the outside to contact and support the upper surface of the cell frame, between the intermediate frame By supporting the cell frame, it can be characterized in that it comprises a support member configured to fix the solar panel located on the left side and the post.

Here, the lower surface of the support member of the support member may be characterized in that the plurality of friction protrusions formed in the front and rear directions are continuously arranged left and right so as to prevent the cell frame in contact with the left side or slipping in the post.

In addition, the fixing of the support member and the intermediate frame is made by the fastening of the bolts and nuts, the outer surface of the intermediate frame is further provided with a bolt restraint groove formed along the longitudinal direction so as to slide by sliding the bolt head, It may be characterized in that the bolt used for fixing the support member and the intermediate frame is restrained by sliding in the bolt restraint groove.

In addition, the support member may be made of an aluminum alloy material.

In addition, the frame assembly including the inclined frame and the intermediate frame may be made of an aluminum alloy material.

In addition, the cell frame coupling portion coupled to the state in contact with the lower surface of the cell frame; An intermediate frame engaging portion extends perpendicularly downward from the cell frame coupling portion to be in contact with the rear surface of the intermediate frame, and further includes a locking member for preventing the solar panel from sliding down along the inclined frame. It can be characterized by.

In addition, there is a mooring rope that connects the frame assembly and the underwater surface to support the frame assembly and the solar panel is not floated, has a weaker tensile strength than the mooring rope and is installed in the middle of the mooring rope to apply a predetermined tension or more A safety rope to prevent the flooding of the frame assembly due to the ground disconnection and the pulling of the mooring rope; Bypass the area where the safety rope is installed is connected between the mooring ropes before and after the safety rope, but even if the separation between the mooring ropes due to disconnection of the safety rope is more relaxed than the safety rope to accommodate this It may be characterized in that it further comprises a bypass circuit provided with a length.

In addition, the one end and the other end of the safety rope, one end and the other end of the bypass loop, while having a modular form with the safety rope and the bypass loop on both sides, and having a ring connected to the mooring rope with respect to the mooring rope A pair of brackets connecting the safety rope and the bypass loop in the middle, a gas supply that operates when the safety rope is disconnected, and supplies a gas, a mark balloon that is connected to the gas supply and floats on the water while receiving gas, and safety It may be characterized in that it further comprises a communicator to operate when the rope is disconnected to communicate with the external management center.

The water-based photovoltaic device according to the present invention has a support member that can be easily inserted and fixed to the cell frame holding the solar panel, so that the installation of the solar panel can be easily performed without the use of fasteners. You can expect to save time and increase productivity.

In addition, the present invention allows for a very stable connection by tightly contacting the parts while excluding the use of fastening parts to the maximum.

In addition, the present invention can implement an environmentally friendly product by applying all frames including all supporting members and locking members to an aluminum alloy material that is environmentally friendly and easy to recycle, and excludes the use of numerous fasteners. have.

In addition, the present invention is provided with a safety rope and a bypass loop installed in the middle of the mooring rope to prevent the frame assembly and the solar panel on the water surface to be submerged below the water surface in a sudden situation where the water level is stuck in the soil or suddenly increases the water level. Can be.

1 is a reference cross-sectional view for explaining a water-based photovoltaic device according to the prior art.
Figure 2 is a perspective view of the entire offshore photovoltaic device according to an embodiment of the present invention.
Figure 3 is a side view showing a part of the water photovoltaic device according to an embodiment of the present invention.
Figure 4 is a partial cross-sectional view for explaining a solar panel coupling structure of the water photovoltaic device according to an embodiment of the present invention.
Figure 5 is a perspective view of the support member of the water photovoltaic device according to an embodiment of the present invention.
Figure 6 is a front view of the support member of the water photovoltaic device according to an embodiment of the present invention.
FIG. 7 is a cross-sectional view taken along line II of FIG. 4 for explaining an intermediate frame configuration of the water photovoltaic device according to the embodiment of the present invention. FIG.
8 is a perspective view for explaining the intermediate frame configuration of the water photovoltaic device according to an embodiment of the present invention.
Figure 9 is a perspective view of the locking member of the water photovoltaic device according to an embodiment of the present invention.
10 and 11 are a series of reference diagrams for explaining the operation of the safety module in the water photovoltaic device according to an embodiment of the present invention.
12 is a configuration diagram for explaining a safety module in the water photovoltaic device according to an embodiment of the present invention.

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

2 is a perspective view of the entire water-based photovoltaic device according to an embodiment of the present invention.

As shown, the water-based photovoltaic device according to an embodiment of the present invention, the solar panel 180, the frame assembly is formed in the form of a plurality of frames connected to support the solar panel 180, and by the buoyancy It includes a buoyancy body 170 to lift the frame assembly above the water surface.

Here, the frame assembly, the horizontal horizontal frame 110, the vertical horizontal frame 120, the inclined frame 130a and the auxiliary inclined frame 130b, with respect to the inclined frame 130a from the top and bottom It is installed in a cross-coupled state in the horizontal direction is made of a pair of intermediate frames 140 that are inclined to support the solar panel 180, the solar panel 180 as shown by the circle (A) in the drawing And a support member to be described later is installed in a position where the solar panel 180 is spaced apart so that the solar panel 180 can be inserted and fixed simply without fastening parts such as screws or bolts.

As described above, the water-based photovoltaic device according to the embodiment of the present invention can easily and quickly install the solar panel 180 without the fastening parts by the above-mentioned support member, and is easily recycled to various frames and water pollution. By applying aluminum, which is an environmentally friendly material without any concern, it is possible to drastically reduce work time and improve productivity, as well as to implement environmentally friendly products suitable for photovoltaic devices installed in the water.

Hereinafter, the configuration of the water-based photovoltaic device according to an embodiment of the present invention will be described in detail with reference to the solar panel coupling structure.

Figure 3 is a side view showing a part of the water-based photovoltaic device according to an embodiment of the present invention, Figure 4 is a partial cross-sectional view for explaining a solar panel coupling structure of the water-based photovoltaic device according to an embodiment of the present invention. 5 is a perspective view of a support member of the water-based photovoltaic device according to the embodiment of the present invention, FIG. 6 is a front view of the support member of the water-based photovoltaic device according to the embodiment of the present invention, and FIG. 7 is an embodiment of the present invention. 4 is a cross-sectional view taken along line II of FIG. 4 for explaining an intermediate frame configuration of a water-based photovoltaic device according to an example. 9 is a perspective view of a locking member of the water photovoltaic device according to the embodiment of the present invention.

As shown, the water-based photovoltaic device according to an embodiment of the present invention, the solar panel provided with a support member 150 that can be easily fixed by inserting the cell frame 181 holding the solar panel 180 180 is configured to be easily installed in the intermediate frame 140. In addition, the support member 150 is fixed to the intermediate frame 140 by a bolt 153 and a nut 154, the bolt 153 is used is a bolt restraint groove 141 formed in the intermediate frame 140 It is configured so that it can be easily inserted into the restraint in a sliding manner.

As described above, in the embodiment of the present invention, the solar panel 180 may be installed very simply and quickly by the intermediate frame 140 having the support member 150 and the bolt restraint groove 141. These components will be described in detail below.

The support member 150 is coupled to the intermediate frame 140 at a corresponding point so that the solar panel 180 is placed on the left side and the post and coupled to the edge of the solar panel 180. It simply serves to fix the frame 181. To this end, the support member 150 is composed of a U-shaped body portion 151 and a support portion 152.

Here, the body portion 151 of the support member 150 is composed of a base plate 151b and a pair of vertical plates 151c and 151d extending upward from the left side and the post of the base plate 151b. . A bolt hole 151a is formed in the base plate 151b to allow the body of the bolt 153 bound to the intermediate frame 140 to pass therethrough. As a result, the vertical plates 151c and 151d of the body 151 are positioned at the left side and the post to support the side of the cell frame 181 holding the solar panel 180 so as not to be pushed.

In addition, the support portion 152 of the support member 150 is provided with a pair extending in the form of a left side and a mail toward the outside from the upper end of the vertical plate (151c, 151d) of the body portion 151, respectively. As a result, the support part 152 and the intermediate frame 140 may contact and fix the cell frame 181 holding the solar panel 180 in contact with the upper and lower surfaces thereof. Here, the lower surface of the support portion 152 is provided with a plurality of friction protrusions (152a) formed in the front and rear direction in a continuous arrangement from side to side. As a result, the friction force with respect to the cell frame 181 in contact with the lower surface of the support part 152 is increased, thereby effectively suppressing the slippage of the cell frame 181 once inserted.

For reference, the cell frame 181 is provided with a fitting portion 181 at the upper portion to hold and support the solar panel 180, and a lower portion of the base portion having a wide plate shape to be in close contact with the intermediate frame ( 181b).

The intermediate frame 140 is provided with a bolt restraint groove 141 formed along the longitudinal direction so as to slide the head of the bolt 153 used to fix the support member 150 on its outer surface. As such, when the bolt restraint groove 141 is provided, it is troublesome to perforate the intermediate frame 140 to restrain the bolt 153 used to fix the support member 150 to the intermediate frame 140 in the field. It can be reliably restrained only by simply sliding it in without it. According to this configuration, the nut 154 is loosely fastened in a state in which the body of the bolt 153 penetrates the bolt hole 151a of the support member 150 to form an assembly, and then the head of the bolt 153 is fixed to the intermediate frame. Sliding along the bolt restraint groove 141 of 140 and positioned in the corresponding position, then simply tighten the loose bolt 153 and the nut 154, the support member 150 to the intermediate frame 140 It is fixed. Looking at the bolt restraint groove 141 in more detail is formed in a narrower width than the insertion portion (141a) and the insertion portion (141a) is inserted into the head of the bolt 153 to the body of the bolt 153 to the outside It consists of a protrusion 141b for protruding.

The locking member 160 assists the support member 150 to support the solar panel 180 more firmly. To this end, the locking member 160 has a cell frame coupling portion 161 and the intermediate frame locking portion 162 is formed in a right angle. Here, the cell frame coupling part 161 is coupled by a bolt and a nut in contact with the bottom surface of the cell frame 181, and the intermediate frame locking part 162 is downward from the cell frame coupling part 161. Is orthogonally extended so as to be in contact with the rear surface of the intermediate frame 140. Accordingly, the cell frame coupling portion 161 is provided with a bolt hole 161a, but the bolt frame 162a is selectively provided at the intermediate frame locking portion 162.

According to the configuration of the locking member 160, the intermediate frame locking portion 162 on the intermediate frame 140 in a state in which the locking member 160 is first coupled to the cell frame 181 holding the solar panel 180. By simply using), the solar panel 180 can be simply supported without slipping along the inclined frame 130a without any fastening parts.

On the other hand, the water photovoltaic device according to an embodiment of the present invention, including the support member 150 and the locking member 160, the horizontal horizontal frame 110, the vertical horizontal frame 120, the inclined frame ( 130a), the auxiliary inclination frame 130b, the intermediate frame 140 are all made of an aluminum alloy material. As a result, it is possible to implement an eco-friendly water-based photovoltaic device that can be easily recycled at a lower cost than FRP and has no concern about water pollution.

On the other hand, the water photovoltaic device according to an embodiment of the present invention, as shown in Figures 10 and 11, by connecting the frame assembly and the sinker installed in the underwater ground so that the frame assembly and the solar panel 180 is not floated. Supporting mooring rope 102 is installed, the safety module 190 is installed in the middle. The safety module 190 is configured to open apart the mooring rope 102 while being quickly disconnected when excessive tension is applied through the mooring rope 102. Accordingly, the frame assembly and the solar panel 180 are mooring ropes 102 in a sudden situation in which the water level is rapidly increased due to flooding during flooding when a part installed on the lower side of the chimney 103 is buried in the open soil during low water level. Can be effectively prevented from being submerged below the surface while being pulled by.

Hereinafter, the safety module 150 will be described in detail.

12 is a configuration diagram illustrating a safety module in the water photovoltaic device according to an embodiment of the present invention.

As shown, the safety module 190 includes a safety rope 191, a bypass loop 192, a pair of brackets 193a, a communicator 196, a gas supply 197, and a balloon 198, which will be described in more detail below for each component.

The safety rope 191 is submerged in water but is installed in the middle of the mooring rope 102 at a position relatively close to the water surface and is provided with a weaker tensile strength than the mooring rope 102. In this case, the tensile strength of the safety rope 191 is appropriate to the extent that it can be surely broken when a tension of a magnitude exceeding the buoyancy of the buoyancy body 170 is applied. To this end, the safety rope 191 is provided with a fracture portion 191a that is easily formed and has a narrower width than other portions. In addition, as described above, even if the safety rope 191 does not have a breakage portion 191a in the middle thereof, the overall thickness is made thin so that it can be easily broken with respect to the tension exceeding the buoyancy of the buoyancy body 170, The mooring rope 102 may be made of a material or a material having a lower tensile strength than the mooring rope 102.

As a result, the safety rope 191 is rapidly disconnected at the moment when a predetermined or more tension exceeding the buoyancy of the buoyancy body 170 through the mooring rope 102, so that some invasion 103 is stuck in the soil. In the situation where the water level is rapidly increased or prevents the frame assembly or the solar panel 180 is submerged below the water surface.

The detour rope 192 connects the mooring ropes 102 connected to the front and rear of the safety rope 191 by bypassing an area in which the safety rope 191 is installed. As a result, the bypass loop 192 connects the mooring rope 102 spaced apart from the bypass loop 192 while accepting the safety rope 191 when the safety rope 191 is disconnected and the mooring rope 102 is spaced apart. Here, the bypass loop 192 is provided with a length sufficient to allow the mooring rope 102 to be smoothly connected in the middle when the safety rope 191 is disconnected (however, the bypass circuit 192 in the drawing). ) Is shown only slightly longer than the safety rope 191 for convenience, but may be provided as much longer than that.

The bracket 193a is a member made of a high-strength metallic material or a synthetic resin material, which is positioned on both sides of the bracket 193a to form a modular form with the safety rope 191 and the bypass circuit 192, and one end and the other end of the safety rope 191, One end and the other end of the bypass loop 192 is fixed. The bracket 193a has a ring 193b connected to the mooring rope 102 and serves to connect the safety rope 191 and the bypass circuit 192 to the mooring rope 102 in the middle. do.

The gas supplier 197 is formed together with the marker balloon 198 and the communicator 196 to form a display means for notifying the outside that the problem has occurred and indicating the position thereof. The gas supplier 197 operates when the safety rope 191 is disconnected. It serves to supply gas to the balloon 198. To this end, the gas supplier 197 is connected to the detonation line 195 to operate. The detonation line 195 is installed in a state connected to the other one via any one of the pair of brackets 193a. When the separation between the bracket (193a) due to the disconnection of the safety rope 191 is to transmit the physical force to the gas supply (197) to operate.

When the safety rope 191 is disconnected, the marker balloon 198 is connected to a gas supplier 197 that supplies gas while operating through the detonation line 195 to inflate and float above the water surface while receiving gas. As a result, the marker balloon 198 is able to indicate to the outside that the safety rope 191 is disconnected to cause a problem. Referring to FIG. 4, when the safety rope 191 is disconnected, the marker balloon 198 inflated on the surface by receiving gas from the gas supplier 197 may be confirmed.

The communicator 196 is connected to the above-described detonation line 195 and acts at the time of disconnection of the safety rope 191 to transmit a radio signal to an external management center. As a result, the management center receives a signal from the communicator 196 and checks whether or not a problem occurs and a problem occurrence position.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is clear that the present invention can be suitably modified and applied in the same manner. Accordingly, the above description does not limit the scope of the invention as defined by the limitations of the following claims.

110: horizontal horizontal frame 120: vertical horizontal frame
130a: inclined frame 130b: auxiliary inclined frame
140: middle frame 141: bolt restraint groove
150: support member 160: locking member
170: buoyant body 180: solar panel
190: Safety module 191: Safety rope

Claims (8)

A plurality of solar panels;
A cell frame holding the left edge and the post edge of the solar panel;
A frame assembly including an inclined frame installed in an inclined direction and a pair of intermediate frames installed in a state in which the inclined frame is cross-coupled in a transverse direction and supporting the solar panel in an inclined manner;
The solar panel is placed on the left side and the post and coupled to the intermediate frame at a corresponding point so as to be installed therebetween, and corresponding to the side of the cell frame holding the solar panels located on the left and the post on the left and right sides, respectively. U-shaped body portion for contacting, and a support portion extending from the upper end of the body portion to the left and the post respectively toward the outside to contact and support the upper surface of the cell frame, between the intermediate frame A support member configured to secure the solar panel positioned on the left side and the post by sandwiching the cell frame;
A cell frame coupling part coupled to the bottom surface of the cell frame in contact with the cell frame; It comprises an intermediate frame engaging portion extending orthogonally downward from the cell frame coupling portion in contact with the rear surface of the intermediate frame, the locking member for suppressing the solar panel does not slide down along the inclined frame; Water photovoltaic device, characterized in that configured. The method of claim 1,
The lower surface of the support member is characterized in that the friction projections to increase the frictional force with respect to the cell frame in contact to prevent the cell frame from slipping off to the left or the post is formed long in the front and rear direction is arranged continuously left and right Water solar power plant. The method of claim 2,
Fixing of the support member and the intermediate frame is made by the fastening of bolts and nuts,
The outer surface of the intermediate frame is further provided with a bolt restraint groove formed along the longitudinal direction so as to slide the bolt head, the bolt used for fixing the support member and the intermediate frame by sliding the bolt into the bolt restraint groove. A water-based photovoltaic device, characterized in that bound in a manner. 4. The method according to any one of claims 1 to 3,
The support member is a water-based photovoltaic device, characterized in that made of aluminum alloy material. 5. The method of claim 4,
Frame assembly including the inclined frame and the intermediate frame is a water-based photovoltaic device, characterized in that made of aluminum alloy material. delete The method of claim 1,
It is provided with a mooring rope for connecting the frame assembly and the underwater ground to support the frame assembly and the solar panel does not float,
A safety rope having a tensile strength weaker than the mooring rope and installed in the middle of the mooring rope to prevent the flooding of the frame assembly due to the pulling of the mooring rope while disconnecting when a predetermined tension is applied thereto;
Bypass the area where the safety rope is installed is connected between the mooring ropes before and after the safety rope, but even if the separation between the mooring ropes due to disconnection of the safety rope is more relaxed than the safety rope to accommodate this The water photovoltaic device further comprises a bypass circuit provided with a length. The method of claim 7, wherein
Secure one end and the other end of the safety rope, one end and the other end of the bypass loop while forming a modular form with the safety rope and the bypass loop on both sides, and having a ring connected to the mooring rope. A pair of brackets connecting the rope and the bypass loop in the middle, a gas supply that operates when the safety rope is disconnected, and supplies a gas, a mark balloon that is connected to the gas supply and floats on the water while receiving the gas, and a safety rope Water photovoltaic device characterized in that it further comprises a communicator to operate when disconnected to communicate with the external management center.

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