KR20180065392A - Floating Fish Cage Having Solar Power Device - Google Patents

Abstract

The present invention relates to a marine farm including a solar power generator, capable of installing a solar power generator regardless of place by installing the generator in a marine farm, and also, reducing time and labor force for installation by making the installation quick and convenient. According to an embodiment of the present invention, the marine farm comprises: a plurality of floating bodies placed on the surface of the sea in longitudinal and widthwise directions to form an internal space part; a plurality of decks installed in the upper part of the plurality of floating bodies to connect the plurality of floating bodies with each other; a plurality of connection brackets installed on the upper surface of each of the plurality of floating bodies; a net located in the space part by being combined with a plurality of net fixing rings installed in a predetermined position of each of the plurality of connection brackets; and a solar power generating module combined with the plurality of connection brackets to be located in the space part above the net.

Description

{Floating Fish Cage Having Solar Power Device}

The present disclosure relates to a marine aquaculture facility having a solar power generator.

Recently, fossil fuel depletion is a concern, and the issue of environmental pollution due to the use of fossil fuels has become an important issue, and research on eco-friendly power generation facilities using natural forces such as solar power is becoming active.

Among the eco-friendly power generation facilities, the photovoltaic power generation system is a national project for national renewable energy, and it is being promoted as a very important business for the human future which is rapidly increasing under the government's support.

The photovoltaic power generation system is a device for generating electricity by installing a solar cell module, installing a solar cell module on a support structure installed on the ground, or installing a solar cell module on the outer wall of a building.

Such a solar power generation system is problematic in that it takes a long period of time to recover the investment cost because the initial investment cost of the power generation facility or the power generation facility using environmentally friendly and non-consuming resources is large.

In addition, the conventional solar power generation system needs to be installed in the same direction as the incoming sunlight, so the installation cost of the solar power generator is large, and the land can not be used for other purposes such as agriculture. There is a problem that economical efficiency is low.

In order to construct a solar power plant, it is necessary to have a large space, so there is a lot of natural damage, so it is not easy to build a power plant due to complaints from environmental groups and residents in the surrounding area.

Korean Patent No. 10-1075161 (October 12, 2011)

The present invention provides a marine aquaculture farm equipped with a solar power generation device capable of installing a solar power generation device in a marine aquaculture farm without restriction of the location by installing a solar power generation device in a marine farm.

In addition, it is an object of the present invention to provide a marine aquaculture farm equipped with a photovoltaic power generation device capable of quick and easy installation work of a farm and a photovoltaic power generation device, which can reduce the work force and the installation time of the work.

It is another object of the present invention to provide a marine aquaculture farm equipped with a photovoltaic power generation device capable of minimizing an external force due to a wave applied to a farm site.

The marine farm having the solar power generation apparatus according to the embodiment includes a plurality of buoyant bodies spaced apart in the transverse and longitudinal directions on the sea surface so as to form a space portion therein, and a plurality of buoyant bodies A plurality of connection brackets provided on respective upper surfaces of the plurality of buoyant bodies, and a plurality of connection brackets coupled to a plurality of net fixing rings provided at predetermined positions on one side of each of the plurality of connection brackets, And a solar power generation module coupled to the connection bracket so as to be positioned above the mesh in the space portion.

According to an embodiment of the present invention, the solar power generation module includes a plurality of support frames each having both ends coupled to one upper surface of a connection bracket provided on each upper surface of a buoyant body spaced apart in a lateral direction from a plurality of bushing members, A plurality of first bases, each of which is connected to an upper surface of one side of a connection bracket provided on each upper surface of the buoyant body so as to be spaced apart in the longitudinal direction on the upper surface of the buoyant body, A plurality of second support frames spaced from each other in the longitudinal direction on the upper surface of the plurality of support frames in a lateral direction between the plurality of first support frames, And a plurality of second supporting frames, the plurality of second supporting frames being mounted on the seating part, The.

According to the embodiment, the plurality of buoyant bodies includes a first body portion, a first buoyant portion formed on the first body portion and including a first receiving column portion having a space portion in the central portion thereof, a second body portion, A second buoyant portion formed on an upper portion of the first buoyant portion and having a second receiving column portion having a space portion in the center portion and connected to the first buoyant portion; and a second buoyant portion inserted into each of the first and second buoyant portions, A pair of upper fastening nuts are spaced apart from each other, and first and second support wires having a pair of side fastening nuts at respective left and right predetermined positions.

According to the embodiment having the above-described configuration, there is an effect that the solar photovoltaic device can be installed in a marine farm without restrictions on the place.

In addition, the installation work of the farm and the photovoltaic power generation device can be performed quickly and easily, which can reduce the labor of the work and reduce the installation time.

In addition, there is an effect that the external force due to waves applied to a farm site can be minimized.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a marine aquaculture plant having a solar power generation apparatus according to an embodiment of the present disclosure; FIG.
2 is a perspective view of the buoyant body shown in Fig.
3 is an exploded perspective view of the buoyant body shown in Fig.
Fig. 4 is an enlarged perspective view of the first and second buoyant portions shown in Fig. 3; Fig.
5 is a partially enlarged view of "A" shown in Fig.
6 is a partially enlarged view of "B" shown in Fig.
7 is a side view of a marine aquaculture plant having a solar power generation apparatus according to an embodiment of the present disclosure;

Embodiments of the present disclosure will now be described in more detail with reference to the accompanying drawings. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation.

In addition, the terms described below are defined in consideration of the functions in this disclosure, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a marine aquaculture farm equipped with a solar power generator according to an embodiment of the present disclosure; FIG.

1, an aquaculture farm 100 having a photovoltaic power generation apparatus according to an embodiment includes a plurality of buoyant bodies (not shown) spaced apart in the horizontal and vertical directions on the sea surface so as to form a space portion 110a therein A plurality of decks 160 mounted on upper portions of the plurality of buoyant bodies 110 to interconnect the plurality of buoyant bodies 110; A net 180 which is coupled to a plurality of net fixing rings 172 provided at predetermined positions on one side of each of the plurality of connection brackets 170 and is located in the space portion 110a, And a photovoltaic power generation module 190 installed above the net 180 in the portion 110a.

Fig. 2 is a perspective view of the buoyant body shown in Fig. 1, and Fig. 3 is an exploded perspective view of the buoyant body shown in Fig.

Referring to FIGS. 2 and 3, the buoyant body 110 includes a first buoyant portion 120, a second buoyant portion 130, and first and second support wires 140 and 150.

The first buoyant portion 120 includes a first body portion 122 and a first receiving post 124 formed at an upper portion of the first body portion 122 and having a space S at a central portion thereof.

The second buoyant portion 130 is coupled to the first buoyant portion 120 and includes a second body portion 132 and a space portion S formed at the upper portion of the second body portion 132, And a second supporting column portion 134 provided thereon.

Here, the first and second body portions 122 and 132 are submerged below the sea surface when installed on the sea, and the first and second receiving column portions 124 and 134 are positioned on the sea surface.

Since the first and second body portions 122 and 132 are submerged below the sea level and the first and second receiving column portions 124 and 134 are positioned on the sea surface in this manner, The external force exerted on the buoyant body 110 can be minimized by the space S formed in the central portion of the first and second receiving column portions 124 and 134. [

The first and second buoyant portions 120 and 130 are made of expanded polypropylene (EPP), which is an eco-friendly material that is excellent in heat resistance, impact resistance, and durability and can be recycled.

First and second auxiliary body portions 126 and 136 are provided in each of the first body portion 122 and the second body portion 132 so that the first body portion 122 and the second body portion 132 are separated from each other, Thereby improving the buoyancy of the valve 132 and reducing the weight.

The first and second auxiliary body portions 126 and 136 may be made of the same material as the first and second body portions 122 and 132 and may have a density greater than that of the first and second body portions 122 and 132 And is foam-molded at a low temperature.

Specifically, since the first and second body portions 122 and 132 must have sufficient strength not to be damaged by an external impact, they are foam-molded at a high density with a narrow gap between particles and particles of EPP foamed beads, The first and second auxiliary body portions 126 and 136 are formed at a low density having a large gap between the particles and the particles of the EPP foamed beads for weight reduction.

4, at least one first fitting protrusion 127 and a first fitting groove 128 are formed on one side of the first buoyant portion 120 so as to be symmetrical with respect to left and right predetermined positions, respectively, At least one second fitting protrusion 137 and a second fitting groove 138 are formed on one side of the second buoyant portion 130 so as to be symmetrical to the left and right predetermined positions, respectively.

The first fitting protrusion 127 is engaged with the second fitting groove 138 and the second fitting protrusion 137 is fitted into the first fitting groove 128.

Since the first fitting protrusion 127 is engaged with the second fitting groove 138 and the second fitting protrusion 137 is interference fit with the first fitting groove 128, the first and second buoyant portions 120 130 of the first and second buoyant portions 120, 130 are mutually coupled.

At least one first coupling part 129 is formed at a predetermined position in the height direction of the first buoyant part 120 and a first coupling part 129 is provided at a predetermined position in the height direction of the second buoyant part 130 At least one second fastening portion 139 is formed.

The first and second coupling portions 129 and 139 are coupled by a pair of coupling holes F to further improve the coupling force of the first and second buoyancy portions 120 and 130. [

At this time, a ring R is formed at one end of each of the pair of fasteners F, and a rope R. which connects mutually adjacent buoyant bodies is coupled to the ring R. Thus, the buoyant bodies adjacent to each other are interconnected by the rope R. Thus, the durability of the buoyant body is improved.

The first and second support posts 124 and 134 are mounted on the top of the first and second support posts 124 and 134 to support a deck 160 that allows an operator to work or pass, A pair of vertical portions 124a and 134a projecting in parallel to the upper portion of each of the vertical portions 124a and 134a and horizontal portions 124b and 134b connecting the pair of vertical portions 124a and 134a.

At this time, the upper surfaces of the horizontal portions 124b and 134b are flattened so that the lower surface of the deck 160 can be closely contacted.

The first and second support wires 140 and 150 are inserted into each of the first and second buoyant portions 120 and 130 during the molding of the first and second buoyant portions 120 and 130, 2 improves the strength of the buoyant portions 120, 130.

A pair of upper coupling nuts 142 and 152 are provided at predetermined positions on the upper and lower sides of the first and second supporting paper wires 140 and 150, The deck 160 is fixed to the upper portions of the second support post portions 124 and 134 by bolts or the like.

A pair of side coupling nuts 144 and 154 are provided at predetermined left and right predetermined positions of the first and second supporting wires 140 and 150. The pair of side coupling nuts 144 and 154, Both side surfaces of the plurality of connection brackets 170 are coupled.

A plurality of net fixing hooks 172 are provided at predetermined positions on one side of each of the plurality of connecting brackets 170. The net fixing hooks 172 are formed by a plurality of buoyant bodies 110 on the sea surface in the horizontal and vertical directions So as to fix the net 180 located in the space portion 110a formed therein.

At this time, a wire 182 coupled to the upper end of the net 180 is engaged with the net fixing ring 172.

5 to 7, a plurality of the buoyant bodies 110 are installed in the space portion 110a formed in the inside thereof by being spaced apart from each other in the lateral and longitudinal directions, A plurality of first support frames 194, a plurality of second support frames 196, and a solar panel 198. The support frame 192 includes a plurality of first support frames 194, a plurality of second support frames 196,

The plurality of support frames 192 are coupled to the upper surface of one side of the connection bracket 170 installed on the upper surface of the buoyant body spaced apart in the lateral direction among the plurality of buoyant bodies 110.

The plurality of first support frames 194 are disposed on the upper surface of the plurality of support frames 192 so as to be spaced laterally along the longitudinal direction of the plurality of support frames 192, Both ends of which are coupled to the upper surface of one side of the connection bracket 170 provided on the upper surface of the connection bracket 170.

The plurality of second support frames 196 are installed on the upper surface of the plurality of support frames 192 so as to be spaced apart from each other in the longitudinal direction so as to be positioned laterally between the plurality of first support frames 194.

A plurality of foot plates 196a are installed on the rear side of each of the plurality of second support frames 196 such that the foot plates 196a are positioned in the lateral direction. So that the operator can perform work or passage so as to be easily installed on the second support frames 194 and 196.

The solar panel 198 is mounted on a seating portion 194a formed on an upper portion of a plurality of first support frames 194 and a predetermined position on both sides in the longitudinal direction is coupled to an upper portion of the plurality of second support frames 196 .

A fixing bracket 195 for fixing one side of the solar panel 198 positioned on the outermost side is provided on the upper surfaces of both ends of each of the first and second support frames 194 and 196.

A plurality of coupling holes H are formed in the longitudinal direction on the upper surfaces of the plurality of first and second supporting frames 194 and 196. The coupling holes H are formed in the upper surface And a pressing member 197 for press-fixing is fastened.

While the embodiments of the present disclosure have been described with reference to the accompanying drawings, those skilled in the art will appreciate that various modifications and changes may be made thereto without departing from the scope of the present disclosure described in the following claims It will be understood.

110; Buoyant body
120; The first buoyancy portion
130; The second buoyant portion
140; The first support wire
150; The second support wire
160; Deck
170; Connection bracket
180; net
190; PV module

Claims (7)

A plurality of buoyant bodies disposed on the sea surface so as to be spaced apart from each other in the transverse direction and the longitudinal direction so as to form a space portion therein;
A plurality of decks installed on top of the plurality of buoyant bodies to interconnect the plurality of buoyant bodies;
A plurality of connection brackets provided on respective upper surfaces of the plurality of buoyant bodies;
A net disposed in the space portion, the net being connected to a plurality of net fixing rings provided at predetermined positions on one side of each of the plurality of connection brackets; And
And a photovoltaic generation module coupled to the plurality of connection brackets so as to be positioned on the space above the net.
The method according to claim 1,
In the solar power generation module,
A plurality of support frames each having opposite ends joined to upper surfaces of connection brackets provided on upper surfaces of the buoyant members spaced apart from each other in the lateral direction of the plurality of buoyant members;
And a connection bracket provided on each upper surface of the buoyant body spaced apart in the vertical direction among the plurality of buoyant bodies so as to be spaced laterally along the longitudinal direction on the upper surface of the plurality of support frames, A plurality of first supporting frames;
A plurality of second support frames spaced apart from each other in the longitudinal direction on an upper surface of the plurality of support frames in a lateral direction between the plurality of first support frames; And
And a solar cell panel having a first end mounted on a seating portion formed on the upper portion of the plurality of first support frames and a predetermined position on both sides in the longitudinal direction coupled to an upper portion of the plurality of second support frames. A marine farm with equipment.
The method of claim 2,
And a plurality of foot plates are installed in the rear of each of the plurality of second support frames so as to be positioned in the horizontal direction.
The method according to claim 1,
Wherein the plurality of buoyant bodies comprises:
A first buoyant portion formed of a first body portion and a first receiving column portion formed on an upper portion of the first body portion and having a space portion in a central portion thereof;
A second buoyant portion formed on an upper portion of the second body portion and having a second receiving column portion having a space portion at a central portion thereof and coupled to the first buoyant portion; And
And a pair of upper side fastening nuts are provided at left and right predetermined positions of the upper and lower sides, respectively. Wherein the first and second supporting wires are connected to the first and second supporting wires.
The method of claim 4,
The first body portion and the second body portion are provided with first and second auxiliary body portions, respectively,
The first body portion, the second body portion, the first auxiliary body portion, and the second auxiliary body portion are formed by foaming into a polypropylene (EPP) material,
Wherein the first auxiliary body portion and the second auxiliary body portion are formed by foam molding to have a density lower than that of the first body portion and the second body portion.
The method of claim 4,
At least one first fitting protrusion and a first fitting groove are formed symmetrically on one side surface of the first buoyant portion,
At least one second fitting protrusion and a second fitting groove are formed symmetrically on one side surface of the second buoyant portion,
Wherein the first fitting protrusion is coupled to the second fitting groove, and the second fitting protrusion is coupled to the second fitting groove.
The method of claim 4,
At least one first fastening portion is formed at a predetermined position in the height direction of the first buoyant portion,
At least one second fastening portion is formed at a predetermined position in the height direction of the second buoyant portion to be coupled to the first fastening portion,
Wherein the first and second fastening portions are coupled by a fastener.

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